| CVQN01000001.1_5 |
99.619 |
0.0 |
sspH2 |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sspH2) type III secretion system effector SspH2 (Salmonella secreted protein H2), novel E3 ubiquitin ligase [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_98 |
93.694 |
3.5E-65 |
steD |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(steD) type III secretion system effector SteD [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_130 |
64.116 |
0.0 |
KP1_RS17340 |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(KP1_RS17340) polysaccharide export protein [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_140 |
88.108 |
0.0 |
gmd |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(gmd) GDP-mannose 4,6-dehydratase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_141 |
76.803 |
0.0 |
KP1_RS17305 |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(KP1_RS17305) GDP-L-fucose synthase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_143 |
60.688 |
0.0 |
KP1_RS17295 |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(KP1_RS17295) glycosyltransferase WbuB [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_144 |
62.076 |
0.0 |
KP1_RS17280 |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(KP1_RS17280) mannose-1-phosphate guanylyltransferase/mannose-6-phosphate isomerase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_145 |
75.824 |
0.0 |
rfbK1 |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(rfbK1) O9 family phosphomannomutase RfbK1 [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_146 |
63.383 |
0.0 |
wcaJ |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(wcaJ) undecaprenyl-phosphate glucose phosphotransferase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_152 |
92.542 |
0.0 |
galF |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(galF) GalU regulator GalF [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_153 |
62.573 |
2.18E-159 |
rffG |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(rffG) dTDP-glucose 46-dehydratase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000001.1_155 |
62.414 |
7.55E-140 |
wbtL |
VF0542 |
LPS |
Immune modulation |
VFC0258 |
The structure of Francisella spp. lipid A is unique in that it is modified by various carbohydrates that greatly reduce TLR4 activation and allow for immune evasion |
(wbtL) glucose-1-phosphate thymidylyltransferase [LPS (VF0542) - Immune modulation (VFC0258)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000001.1_158 |
79.377 |
3.74E-162 |
rfbF |
VF0392 |
O-antigen |
Immune modulation |
VFC0258 |
Clinical Y. enterocolitica isolates from humans predominantly belong to serotypes O:3, O:9, O:8 and O:5,27; Y. enterocolitica O antigen expression is temperature regulated. |
(rfbF) glucose-1-phosphate cytidylyltransferase [O-antigen (VF0392) - Immune modulation (VFC0258)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_159 |
69.944 |
0.0 |
rfbG |
VF0392 |
O-antigen |
Immune modulation |
VFC0258 |
Clinical Y. enterocolitica isolates from humans predominantly belong to serotypes O:3, O:9, O:8 and O:5,27; Y. enterocolitica O antigen expression is temperature regulated. |
(rfbG) CDP-glucose 4,6-dehydratase [O-antigen (VF0392) - Immune modulation (VFC0258)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_170 |
95.085 |
0.0 |
gndA |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(gndA) NADP-dependent phosphogluconate dehydrogenase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_171 |
82.216 |
0.0 |
ugd |
VF0560 |
Capsule |
Immune modulation |
VFC0258 |
The Klebsiella polysaccharide capsule is produced through a Wzy-dependent process, for which the synthesis and export machinery are encoded in a single 10-30 kb region of the genome known as the K locus.; 78 distinct capsule phenotypes have been recognized by serological typing, but many isolates are serologically non-typable.; capsular serotypes vary substantially in the degree of serum resistance; K1, K2 and K5 are highly serum resistant and are associated with hypervirulent strains that differ from classical K. pneumoniae in that they commonly cause community-acquired disease. |
(ugd) UDP-glucose 6-dehydrogenase [Capsule (VF0560) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_185 |
96.238 |
0.0 |
sopA |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopA) type III secretion system effector SopA, HECT-like E3 ubiquitin ligase [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_186 |
93.567 |
2.33E-109 |
sopA |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopA) type III secretion system effector SopA, HECT-like E3 ubiquitin ligase [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_187 |
92.308 |
1.05E-26 |
sopA |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopA) type III secretion system effector SopA, HECT-like E3 ubiquitin ligase [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_262 |
64.251 |
1.97E-98 |
rcsA |
VF0571 |
RcsAB |
Regulation |
VFC0301 |
|
(rcsA) transcriptional activator for ctr capsule biosynthesis [RcsAB (VF0571) - Regulation (VFC0301)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000001.1_263 |
66.406 |
4.07E-103 |
fliR |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliR) flagellar biosynthetic protein FliR [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_264 |
74.157 |
2.47E-36 |
fliQ |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliQ) flagellar biosynthetic protein FliQ [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_265 |
85.652 |
1.94E-141 |
fliP |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliP) flagellar biosynthetic protein FliP [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_267 |
76.087 |
4.03E-70 |
fliN |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliN) flagellar motor switch protein FliN [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_268 |
84.685 |
0.0 |
fliM |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliM) flagellar motor switch protein FliM [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_272 |
83.48 |
0.0 |
fliI |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliI) flagellum-specific ATP synthase FliI [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_274 |
83.283 |
0.0 |
fliG |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliG) flagellar motor switch protein G [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_275 |
63.309 |
0.0 |
fliF |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliF) flagellar M-ring protein FliF [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_283 |
71.875 |
1.3E-62 |
fliS |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliS) flagellar protein FliS [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_288 |
83.193 |
9.01E-144 |
fliA |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(fliA) flagellar biosynthesis sigma factor [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_312 |
75.862 |
5.28E-53 |
flhD |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flhD) flagellar transcriptional activator FlhD [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_313 |
80.612 |
8.47E-116 |
flhC |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flhC) flagellar biosynthesis transcription activator FlhC [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_314 |
82.712 |
0.0 |
motA |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(motA) flagellar motor protein MotA [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_315 |
68.571 |
3.79E-154 |
motB |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(motB) flagellar motor protein MotB [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_316 |
75.664 |
0.0 |
cheA |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheA) chemotaxis protein CheA [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_317 |
84.375 |
4.41E-96 |
cheW |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheW) purine-binding chemotaxis protein CheW [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_319 |
73.239 |
3.85E-151 |
cheR |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheR) chemotaxis methyltransferase CheR [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_320 |
85.387 |
0.0 |
cheB |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheB) chemotaxis-specific methylesterase CheB [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_321 |
90.698 |
5.38E-84 |
cheY |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheY) chemotaxis regulatory protein CheY [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_322 |
78.155 |
2.28E-110 |
cheZ |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheZ) chemotaxis regulator CheZ [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_323 |
65.789 |
0.0 |
flhB |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flhB) flagellar biosynthetic protein FlhB [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_324 |
85.507 |
0.0 |
flhA |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flhA) flagellar biosynthesis protein FlhA [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000001.1_339 |
60.494 |
6.26E-107 |
CBU_1566 |
VF0696 |
T4SS secreted effectors |
Effector delivery system |
VFC0086 |
|
(CBU_1566) Coxiella Dot/Icm type IVB secretion system translocated effector [T4SS secreted effectors (VF0696) - Effector delivery system (VFC0086)] [Coxiella burnetii RSA 493] |
Coxiella burnetii |
| CVQN01000001.1_380 |
98.052 |
4.29E-112 |
sopE2 |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopE2) type III secretion system effector SopE2, guanine nucleotide exchange factor [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000001.1_466 |
81.915 |
1.9E-178 |
kdsA |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(kdsA) 2-dehydro-3-deoxyphosphooctonate aldolase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000002.1_103 |
68.063 |
3.66E-100 |
sodB |
VF0169 |
SodB |
Stress survival |
VFC0282 |
|
(sodB) superoxide dismutase [SodB (VF0169) - Stress survival (VFC0282)] [Legionella pneumophila subsp. pneumophila str. Philadelphia 1] |
Legionella pneumophila |
| CVQN01000002.1_111 |
99.716 |
0.0 |
ssaU |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaU) type III secretion system export apparatus switch protein SsaU [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_112 |
98.456 |
0.0 |
ssaT |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaT) type III secretion system minor export apparatus protein SsaT [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_113 |
98.864 |
1.18E-58 |
ssaS |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaS) type III secretion system minor export apparatus protein SsaS [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_114 |
99.535 |
8.59E-153 |
ssaR |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaR) type III secretion system minor export apparatus protein SsaR [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_115 |
98.758 |
0.0 |
ssaQ |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaQ) type III secretion system C ring protein SsaQ [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_116 |
100.0 |
2.45E-92 |
ssaP |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaP) type III secretion system needle length regulator SsaP [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_117 |
98.4 |
2.4E-86 |
ssaO |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaO) type III secretion system stalk protein SsaO [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_118 |
99.307 |
0.0 |
ssaN |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaN) type III secretion system ATPase SsaN [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_119 |
99.266 |
0.0 |
ssaV |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaV) type III secretion system major export apparatus protein ssaV [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_120 |
99.18 |
1.59E-88 |
ssaM |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaM) type III secretion system protein SsaM [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_121 |
97.576 |
0.0 |
ssaL |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaL) type III secretion system gatekeeper SsaL [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_122 |
98.661 |
4.92E-167 |
ssaK |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaK) type III secretion system stator SsaK [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_123 |
98.795 |
1.96E-55 |
ssaX |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaX) type III secretion system base-pod connector [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_124 |
99.07 |
3.5E-160 |
ssaJ |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaJ) type III secretion system inner MS ring protein SsaJ [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_125 |
95.062 |
6.48E-53 |
ssaI |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaI) type III secretion system inner rod protein SsaI [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_127 |
100.0 |
1.02E-47 |
ssaG |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaG) type III secretion system needle filament protein SsaG [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_128 |
98.253 |
4.85E-170 |
sseG |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseG) type III secretion system effector SseG [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_129 |
96.538 |
0.0 |
sseF |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseF) type III secretion system effector SseF [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_130 |
99.296 |
2.35E-105 |
sscB |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sscB) chaperone for sseF [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_131 |
99.275 |
7.9E-100 |
sseE |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseE) type III secretion system effector SseE [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_132 |
98.462 |
1.44E-139 |
sseD |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseD) type III secretion system hydrophilic translocator, pore protein SseD [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_133 |
95.248 |
0.0 |
sseC |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseC) type III secretion system hydrophilic translocator, pore protein SseC [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_134 |
98.089 |
8.56E-116 |
sscA |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sscA) chaperone for sseC [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_135 |
100.0 |
6.21E-145 |
sseB |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseB) type III secretion system effector SseB [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_136 |
99.065 |
1.98E-75 |
sseA |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(sseA) chaperone for sseB and sseD [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_137 |
98.75 |
6.07E-53 |
ssaE |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaE) chaperone for sseB [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_138 |
99.504 |
0.0 |
ssaD |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaD) type III secretion system outer MS ring protein SsaD [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_139 |
99.396 |
0.0 |
ssaC |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssaC) type III secretion system secretin SsaC [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_140 |
100.0 |
5.49E-93 |
spiC/ssaB |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(spiC/ssaB) Salmonella pathogenicity island 2 protein C (SpiC); Type III secretion system apparatus protein B (SsaB) [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_141 |
98.261 |
0.0 |
ssrA |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssrA) hybrid sensor histidine kinase/response regulator [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_142 |
100.0 |
5.31E-159 |
ssrB |
VF0321 |
TTSS (SPI-2 encode) |
Effector delivery system |
VFC0086 |
SPI-2 T3SS effector repertoire varies greatly among different Salmonella serovars.; All serovars seem to have a set of 'core' effectors (SseF, SseG, PipB, SteA, SifA, SteD and PipB2), suggesting that they are critical for virulence in different hosts.; Another group of effectors (SseL, SifB, SopD2, SseJ, SteB, SteC, SlrP, and SseK2) always seem to be present in intestinal serovars but are frequently non-functional in extraintestinal or highly host-adapted serovars, suggesting these effectors contribute to virulence in the intestine, but not always in deeper tissues.;A further group of 'accessory' effectors (SspH2, SseK1, SrfJ, GtgA, GtgE, SseI, GogB, SteE, SseK3, SspH1, SpvB, SpvC, and SpvD) encoded on mobile genetic elements (MGEs) or DNA close to the remnants of MGEs are found sporadically across different serovars.;The only known effector genes in SPI-2, sseF and sseG, are likely to have conferred an early selective advantage to intracellular bacteria.;several sets of effectors that share high levels of sequence similarity. Examples of paralog effectors include Pathogenicity island-encoded protein B (PipB) and PipB2, which share 33% identity and 67% similarity, SifA and SifB that share 26% identity and 46% similarity, SopE and SopE2, which share 69% similarity, SopD and SopD2 that share 43% identity and 63% similarity. These effector protein paralogs often share structural similarity and/or biochemical activities but demonstrate functional divergence in intracellular localization and/or host protein targets or interaction partners. |
(ssrB) DNA-binding response regulator [TTSS (SPI-2 encode) (VF0321) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000002.1_220 |
92.571 |
0.0 |
ompA |
VF0236 |
OmpA |
Invasion |
VFC0083 |
Major outer membrane protein in E. coli, homologous to Neisseria Opa proteins which have been shown to be involved in invasion of eukaryotic cells |
(ompA) outer membrane protein A [OmpA (VF0236) - Invasion (VFC0083)] [Escherichia coli O18:K1:H7 str. RS218] |
Escherichia coli (NMEC) |
| CVQN01000002.1_314 |
69.478 |
4.07E-125 |
nueA |
VF0473 |
Polar flagella |
Motility |
VFC0204 |
Types of bacterial movement: swimming, swarming, gliding, twitching and sliding. Only swimming and swarming are correlated with the presence of flagella. Swimming is an individual endeavour, while swarming is the movement of a group of bacteria; constitutively expressed for motility in liquid environments |
(nueA) NeuA protein [Polar flagella (VF0473) - Motility (VFC0204)] [Aeromonas hydrophila ML09-119] |
Aeromonas hydrophila |
| CVQN01000002.1_319 |
66.263 |
0.0 |
msbA |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(msbA) lipid transporter ATP-binding/permease [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000002.1_331 |
90.868 |
4.78E-149 |
sopD2 |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopD2) type III secretion system effector SopD2 [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000003.1_51 |
99.119 |
1.03E-166 |
mgtC |
VF1365 |
MgtC |
Nutritional/Metabolic factor |
VFC0272 |
An inner membrane protein; anti-virulence protein CigR inhibits the virulence functions of MgtC at early times inside macrophages |
(mgtC) Salmonella virulence protein MgtC [MgtC (VF1365) - Nutritional/Metabolic factor (VFC0272)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000003.1_52 |
99.339 |
0.0 |
mgtB |
VF0106 |
MgtB |
Nutritional/Metabolic factor |
VFC0272 |
A magnesium transporter |
(mgtB) Mg2+ transport protein [MgtB (VF0106) - Nutritional/Metabolic factor (VFC0272)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000003.1_60 |
97.328 |
0.0 |
misL |
VF0397 |
MisL |
Adherence |
VFC0001 |
MisL is located within Salmonella Pathogenicity Island SPI-3 |
(misL) putative autotransporter [MisL (VF0397) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000003.1_61 |
99.119 |
2.75E-156 |
misL |
VF0397 |
MisL |
Adherence |
VFC0001 |
MisL is located within Salmonella Pathogenicity Island SPI-3 |
(misL) putative autotransporter [MisL (VF0397) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000003.1_107 |
63.714 |
2.03E-157 |
rfaF |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(rfaF) ADP-heptose-LPS heptosyltransferase II [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000003.1_108 |
77.922 |
0.0 |
rfaD |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(rfaD) ADP-L-glycero-D-mannoheptose-6-epimerase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000003.1_327 |
63.964 |
7.82E-102 |
rpe |
VF0543 |
Capsule |
Immune modulation |
VFC0258 |
Group 4 capsule; high molecular weight (HMW) O-antigen capsule |
(rpe) ribulose-phosphate 3-epimerase [Capsule (VF0543) - Immune modulation (VFC0258)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000003.1_345 |
67.327 |
4.49E-100 |
vfr |
VF0082 |
Type IV pili |
Adherence |
VFC0001 |
PilA, B, C, D, E, F, M, N, O, P, Q, T, U, V, W, X, Y1, Y2, Z, and fimT, U, V are involved in the biogenesis and mechanical function of pili, pilG, H, I, K, chpA, B, C, D, E, pilS, R, fimS, rpoN, algR, algU, and vfr are involved in transcriptional regulation and chemosensory pathways that control the expression or activity of the twitching motility of the pili |
(vfr) cAMP-regulatory protein [Type IV pili (VF0082) - Adherence (VFC0001)] [Pseudomonas aeruginosa PAO1] |
Pseudomonas aeruginosa |
| CVQN01000003.1_367 |
79.646 |
0.0 |
tufA |
VF0460 |
EF-Tu |
Adherence |
VFC0001 |
|
(tufA) elongation factor Tu [EF-Tu (VF0460) - Adherence (VFC0001)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000004.1_153 |
69.892 |
0.0 |
rfaE |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(rfaE) ADP-heptose synthase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000004.1_226 |
61.212 |
6.88E-73 |
hcp/tssD |
VF0944 |
HSI-3 |
Effector delivery system |
VFC0086 |
The expression of T6SSs in P. aeruginosa is regulated by the QS system. There are several QS systems in P. aeruginosa, two N-acyl-homoserine lactone based QS systems (las and rhl systems) and one quinolone PQS system (pqs). The expression of H1-T6SS is negatively regulated by both las and pqs QS systems, while the expression of H2- and H3-T6SS is positively regulated by las, rhl, and pqs |
(hcp/tssD) Hcp family type VI secretion system effector [HSI-3 (VF0944) - Effector delivery system (VFC0086)] [Pseudomonas aeruginosa PAO1] |
Pseudomonas aeruginosa |
| CVQN01000005.1_63 |
98.423 |
0.0 |
sopD |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopD) type III secretion system effector SopD [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_86 |
98.802 |
0.0 |
rpoS |
VF0112 |
RpoS |
Regulation |
VFC0301 |
|
(rpoS) RNA polymerase sigma factor RpoS [RpoS (VF0112) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_107 |
99.32 |
2.83E-106 |
invH |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invH) type III secretion system pilotin invG [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_108 |
100.0 |
1.76E-163 |
invF |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invF) type III secretion system regulatory protein InvF [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_109 |
99.288 |
0.0 |
invG |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invG) type III secretion system secretin invG [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_110 |
99.731 |
0.0 |
invE |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invE) type III secretion system gatekeeper invE [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_111 |
100.0 |
0.0 |
invA |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invA) type III secretion system major export apparatus protein InvA [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_112 |
100.0 |
5.36E-99 |
invB |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invB) type III secretion system protein InvB [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_113 |
100.0 |
0.0 |
invC/sctN |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invC/sctN) type III secretion system ATPase InvC [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_114 |
99.32 |
2.44E-99 |
invI |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invI) type III secretion system stalk protein InvI [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_115 |
98.214 |
0.0 |
invJ |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(invJ) type III secretion system needle length regulator InvJ [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_116 |
99.34 |
0.0 |
spaO/sctQ |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(spaO/sctQ) type III secretion system C ring protein SpaO [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_117 |
99.554 |
7.25E-165 |
spaP |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(spaP) type III secretion system minor export apparatus protein SpaP [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_118 |
100.0 |
1.03E-56 |
spaQ |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(spaQ) type III secretion system minor export apparatus protein SpaQ [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_119 |
99.24 |
0.0 |
spaR |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(spaR) type III secretion system minor export apparatus protein SpaR [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_120 |
99.438 |
0.0 |
spaS |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(spaS) type III secretion system export apparatus switch protein SpaS [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_121 |
100.0 |
1.17E-124 |
sicA |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sicA) chaparone for SipC and SipB [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_122 |
99.831 |
0.0 |
sipB/sspB |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sipB/sspB) type III secretion system hydrophilic translocator, pore protein SipB (Salmonella invasion protein B) [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_123 |
99.511 |
0.0 |
sipC/sspC |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sipC/sspC) type III secretion system hydrophilic translocator, pore protein SipC [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_124 |
87.172 |
0.0 |
sipD |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sipD) type III secretion system hydrophilic translocator, needle tip protein SipD [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_125 |
97.81 |
0.0 |
sipA/sspA |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sipA/sspA) type III secretion system effector SipA (Salmonella invasion protein A) [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_126 |
98.78 |
4.73E-55 |
iacP |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(iacP) putative acyl carrier protein [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_128 |
97.692 |
1.88E-91 |
sicP |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sicP) chaparone for SptP [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_129 |
94.291 |
0.0 |
sptP |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sptP) type III secretion system effector SptP, tyrosine phosphatase and GTPase-activating protein [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_130 |
98.125 |
1.85E-117 |
iagB |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(iagB) invasion protein IagB [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_131 |
99.819 |
0.0 |
hilA |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(hilA) transcriptional regulator [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_132 |
99.353 |
0.0 |
hilD |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(hilD) AraC family transcriptional regulator [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_133 |
99.235 |
0.0 |
prgH |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(prgH) type III secretion system outer MS ring protein PrgH [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_134 |
95.0 |
3.68E-52 |
prgI |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(prgI) type III secretion system needle filament protein PrgI [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_135 |
98.02 |
2.71E-68 |
prgJ |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(prgJ) type III secretion system inner rod protein PrgJ [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_136 |
99.603 |
0.0 |
prgK |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(prgK) type III secretion system inner MS ring protein PrgK [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_137 |
98.958 |
7.37E-140 |
orgA/sctK |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(orgA/sctK) type III secretion system accessory cytosolic protein OrgA [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_138 |
99.55 |
6.17E-169 |
orgB/SctL |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(orgB/SctL) type III secretion system stator OrgB [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_139 |
97.333 |
4.5E-108 |
orgC |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(orgC) type III secretion system effector OrgC [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_140 |
99.322 |
0.0 |
hilC |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(hilC) AraC family transcriptional regulator [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_141 |
99.203 |
0.0 |
sprB |
VF0116 |
TTSS (SPI-1 encode) |
Effector delivery system |
VFC0086 |
|
(sprB) transcriptional regulator [TTSS (SPI-1 encode) (VF0116) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_181 |
76.667 |
1.4E-30 |
csrA |
VF0261 |
CsrA |
Regulation |
VFC0301 |
Belongs to a highly conserved family of global regulators that typically control stationary phase traits post-transcriptionally |
(csrA) carbon storage regulator CsrA [CsrA (VF0261) - Regulation (VFC0301)] [Legionella pneumophila subsp. pneumophila str. Philadelphia 1] |
Legionella pneumophila |
| CVQN01000005.1_185 |
71.93 |
2.39E-93 |
luxS |
VF0406 |
AI-2 |
Biofilm |
VFC0271 |
AI-2 is produced and detected by a wide variety of bacteria and is presumed to facilitate interspecies communications. |
(luxS) S-ribosylhomocysteinase [AI-2 (VF0406) - Biofilm (VFC0271)] [Vibrio cholerae O1 biovar El Tor str. N16961] |
Vibrio cholerae |
| CVQN01000005.1_224 |
98.993 |
0.0 |
mig-14 |
VF0395 |
Mig-14 |
Antimicrobial activity/Competitive advantage |
VFC0325 |
Mig-14 expression is induced within macrophages and is under the control of the global regulator PhoP |
(mig-14) antimicrobial peptide resistance protein Mig-14 [Mig-14 (VF0395) - Antimicrobial activity/Competitive advantage (VFC0325)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_226 |
91.714 |
0.0 |
pipB2 |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(pipB2) type III secretion system effector PipB3 [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000005.1_227 |
83.425 |
0.0 |
iroN |
VF0563 |
Sal |
Nutritional/Metabolic factor |
VFC0272 |
Salmochelin is a glycosylated Ent that requires the iroA locus for production and transport |
(iroN) salmochelin receptor IroN [Sal (VF0563) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000005.1_228 |
61.812 |
3.08E-128 |
iroE |
VF0230 |
Salmochelin siderophore |
Nutritional/Metabolic factor |
VFC0272 |
Also identified as virulence factors in extracellular pathogenic Escherichia coli and Salmonella enterica serotype Typhi |
(iroE) esterase [Salmochelin siderophore (VF0230) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000005.1_229 |
68.861 |
0.0 |
iroD |
VF0230 |
Salmochelin siderophore |
Nutritional/Metabolic factor |
VFC0272 |
Also identified as virulence factors in extracellular pathogenic Escherichia coli and Salmonella enterica serotype Typhi |
(iroD) esterase [Salmochelin siderophore (VF0230) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000005.1_230 |
82.051 |
0.0 |
iroC |
VF0563 |
Sal |
Nutritional/Metabolic factor |
VFC0272 |
Salmochelin is a glycosylated Ent that requires the iroA locus for production and transport |
(iroC) ABC transporter [Sal (VF0563) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000005.1_231 |
86.523 |
0.0 |
iroB |
VF0230 |
Salmochelin siderophore |
Nutritional/Metabolic factor |
VFC0272 |
Also identified as virulence factors in extracellular pathogenic Escherichia coli and Salmonella enterica serotype Typhi |
(iroB) glucosyltransferase IroB [Salmochelin siderophore (VF0230) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000006.1_3 |
69.62 |
1.59E-123 |
sopE2 |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopE2) type III secretion system effector SopE2, guanine nucleotide exchange factor [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000006.1_54 |
100.0 |
1.11E-112 |
pilK |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilK) hypothetical protein [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_58 |
100.0 |
0.0 |
pilV |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilV) shufflon system plasmid conjugative transfer pilus tip adhesin PilV [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_59 |
100.0 |
6.48E-159 |
pilU |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilU) prepilin peptidase [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_60 |
100.0 |
2.39E-121 |
pilT |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilT) lytic transglycosylase domain-containing protein [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_61 |
100.0 |
1.28E-143 |
pilS |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilS) pilus assembly protein PilX [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_62 |
100.0 |
0.0 |
pilR |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilR) type II secretion system F family protein [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_63 |
100.0 |
0.0 |
pilQ |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilQ) Flp pilus assembly complex ATPase component TadA [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_64 |
100.0 |
6.86E-138 |
pilP |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilP) type IV pilus biogenesis protein PilP [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_65 |
100.0 |
0.0 |
pilO |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilO) type 4b pilus protein PilO2 [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_68 |
100.0 |
6.86E-99 |
pilM |
VF0966 |
T4P |
Invasion |
VFC0083 |
The T4P operon resides on Salmonella Pathogenicity Island SPI-7 in serovar Typhi along with the viaB gene cluster that encodes the Vi capsular antigen. |
(pilM) type IV pilus biogenesis protein PilM [T4P (VF0966) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000006.1_114 |
99.099 |
2.37E-163 |
pmrA |
VF1355 |
PmrAB |
Regulation |
VFC0301 |
|
(pmrA) response regulator PmrA [PmrAB (VF1355) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000006.1_115 |
98.876 |
0.0 |
pmrB |
VF1355 |
PmrAB |
Regulation |
VFC0301 |
|
(pmrB) sensory kinase PmrB [PmrAB (VF1355) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000006.1_147 |
98.051 |
0.0 |
siiE |
VF0970 |
SiiE |
Adherence |
VFC0001 |
SiiE is located within Salmonella Pathogenicity Island SPI-4, a 27-kb region that carries six genes designated siiABCDEF. SiiC, SiiD, and SiiF form a type I secretion apparatus for the secretion of SiiE.;With 595 kDa, SiiE is the largest protein of the Salmonella proteome.;SiiE, like many other non-fimbrial adhesins binds to glycostructures at the cell surface. |
(siiE) non-fimbrial adhesin SiiE [SiiE (VF0970) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000006.1_148 |
84.89 |
0.0 |
siiE |
VF0970 |
SiiE |
Adherence |
VFC0001 |
SiiE is located within Salmonella Pathogenicity Island SPI-4, a 27-kb region that carries six genes designated siiABCDEF. SiiC, SiiD, and SiiF form a type I secretion apparatus for the secretion of SiiE.;With 595 kDa, SiiE is the largest protein of the Salmonella proteome.;SiiE, like many other non-fimbrial adhesins binds to glycostructures at the cell surface. |
(siiE) non-fimbrial adhesin SiiE [SiiE (VF0970) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000006.1_201 |
61.593 |
0.0 |
icl |
VF0253 |
Isocitrate lyase |
Others |
VFC0346 |
|
(icl) Isocitrate lyase Icl (isocitrase) (isocitratase) [Isocitrate lyase (VF0253) - Others (VFC0346)] [Mycobacterium tuberculosis H37Rv] |
Mycobacterium tuberculosis |
| CVQN01000007.1_13 |
82.305 |
0.0 |
bapA |
VF0971 |
BapA |
Adherence |
VFC0001 |
" |
|
|
| CVQN01000007.1_51 |
97.619 |
2.53E-143 |
STM0266 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_52 |
99.254 |
2.23E-91 |
STM0266 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_53 |
98.489 |
0.0 |
STM0267 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_54 |
99.522 |
0.0 |
STM0268 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_55 |
98.78 |
3.17E-120 |
STM0269 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_56 |
98.54 |
0.0 |
STM0270 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_57 |
99.0 |
0.0 |
STM0271 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_58 |
98.744 |
0.0 |
STM0272 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_61 |
99.444 |
6.21E-130 |
STM0273 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_62 |
97.826 |
5.29E-24 |
STM0274 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_63 |
99.751 |
0.0 |
STM0274 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_66 |
100.0 |
2.36E-121 |
STM0276 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_67 |
99.438 |
2.47E-131 |
tssJ |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_68 |
100.0 |
0.0 |
tssK |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_69 |
99.77 |
0.0 |
STM0282 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_70 |
80.321 |
1.56E-150 |
STM0283 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_72 |
99.334 |
0.0 |
STM0285 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_73 |
98.752 |
0.0 |
STM0285 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_74 |
97.647 |
2.71E-180 |
STM0286 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_79 |
98.438 |
5.72E-95 |
STM0287 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_80 |
100.0 |
1.34E-109 |
tlde1 |
VF1195 |
SCI T6SS secreted effectors |
Effector delivery system |
VFC0086 |
|
(tlde1) type VI secretion system effector tlde1, L,D-transpeptidase [SCI T6SS secreted effectors (VF1195) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000007.1_81 |
99.726 |
0.0 |
vgrG |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_82 |
100.0 |
2.92E-111 |
STM0290 |
VF0974 |
SCI (Salmonella centrisome island)/SPI-6 T6SS |
Effector delivery system |
VFC0086 |
"The T6SS is widely distributed in all Salmonella species and subspecies.; Salmonella T6SSs are located on five different Salmonella pathogenicity island and phylogenetically belong to i1, |
|
|
| CVQN01000007.1_83 |
98.082 |
0.0 |
tre<sup>Tu</sup> |
VF1195 |
SCI T6SS secreted effectors |
Effector delivery system |
VFC0086 |
|
(tre<up>Tu</up>) Rhs polymorphic toxin, ADP-ribosyltransferase, type VI ribosyltransferase effector targeting EF-Tu [SCI T6SS secreted effectors (VF1195) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000007.1_106 |
98.326 |
7.57E-176 |
pagN |
VF0968 |
PagN |
Invasion |
VFC0083 |
Unlike rck, pagN is encoded on bacterial chromosome.;PagN is well conserved and widely distributed among the different species and subspecies of Salmonella.;PagN protein displays similarity to the Hek and Tia invasins/adhesins of pathogenic E. coli |
(pagN) outer membrane adhesin/invasin protein [PagN (VF0968) - Invasion (VFC0083)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000007.1_110 |
76.042 |
9.67E-111 |
gmhA/lpcA |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(gmhA/lpcA) phosphoheptose isomerase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000008.1_71 |
100.0 |
4.99E-111 |
fur |
VF0113 |
Fur |
Regulation |
VFC0301 |
|
(fur) ferric iron uptake transcriptional regulator [Fur (VF0113) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000008.1_95 |
62.703 |
2.76E-79 |
fimB |
VF0566 |
Type I fimbriae |
Adherence |
VFC0001 |
Type I fimbriae are expressed in 90% of both clinical and environmental K. pneumoniae isolates as well as almost all members of the Enterobacteriaceae.; Type I fimbriae are filamentous, membrane-bound, adhesive structures composed primarily of FimA subunits, with the FimH subunit on the tip. |
(fimB) tyrosine recombinase [Type I fimbriae (VF0566) - Adherence (VFC0001)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000008.1_98 |
76.716 |
0.0 |
rfbD |
VF0561 |
LPS |
Immune modulation |
VFC0258 |
In K. pneumoniae there are nine main O-serotypes. Three of these, O1, O2, and O3, are responsible for almost 80% of all Klebsiella infections.; Compared with other Enterobacteriaceae, such as Escherichia coli 161 defined O serotypes and Shigella flexneri at least 47 O serotypes, Klebsiella has a surprisingly low number of reported O serotypes which promises a more viable alternative for vaccine development compared with K-antigen-based vaccines; The O-antigen biosynthesis enzymes are encoded on the rfb locus. |
(rfbD) UDP-galactopyranose mutase [LPS (VF0561) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000008.1_100 |
69.6 |
0.0 |
KP1_RS17225 |
VF0561 |
LPS |
Immune modulation |
VFC0258 |
In K. pneumoniae there are nine main O-serotypes. Three of these, O1, O2, and O3, are responsible for almost 80% of all Klebsiella infections.; Compared with other Enterobacteriaceae, such as Escherichia coli 161 defined O serotypes and Shigella flexneri at least 47 O serotypes, Klebsiella has a surprisingly low number of reported O serotypes which promises a more viable alternative for vaccine development compared with K-antigen-based vaccines; The O-antigen biosynthesis enzymes are encoded on the rfb locus. |
(KP1_RS17225) glycosyltransferase family 4 protein [LPS (VF0561) - Immune modulation (VFC0258)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000008.1_166 |
97.468 |
6.29E-48 |
slrP |
VF0948 |
TTSS effectors secreted via both systems |
Effector delivery system |
VFC0086 |
|
(slrP) type III secretion system effector SlrP (Salmonella leucine-rich repeat protein),novel E3 ubiquitin ligase [TTSS effectors secreted via both systems (VF0948) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000008.1_167 |
91.737 |
0.0 |
slrP |
VF0948 |
TTSS effectors secreted via both systems |
Effector delivery system |
VFC0086 |
|
(slrP) type III secretion system effector SlrP (Salmonella leucine-rich repeat protein),novel E3 ubiquitin ligase [TTSS effectors secreted via both systems (VF0948) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000009.1_79 |
76.974 |
0.0 |
lpxC |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(lpxC) UDP-3-O-(R-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000009.1_170 |
64.201 |
5.76E-159 |
lpxD |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(lpxD) UDP-3-O-(3-hydroxymyristoyl) glucosamine N-acyltransferase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000009.1_172 |
67.557 |
2.72E-130 |
lpxA |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(lpxA) UDP-N-acetylglucosamine acyltransferase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000009.1_173 |
64.721 |
5.2E-179 |
lpxB |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(lpxB) lipid-A-disaccharide synthase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000010.1_166 |
89.081 |
0.0 |
ibeC |
VF0237 |
Ibes |
Invasion |
VFC0083 |
IbeA is unique to E. coli K1. The ibeB and ibeC are found to have K12 homologues p77211 and yijP respectively. |
(ibeC) phosphoethanolamine transferase CptA [Ibes (VF0237) - Invasion (VFC0083)] [Escherichia coli O45:K1:H7 str. S88] |
Escherichia coli (NMEC) |
| CVQN01000011.1_10 |
65.029 |
0.0 |
acrB |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrB) acriflavine resistance protein B [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000011.1_44 |
98.828 |
1.53E-174 |
shdA |
VF0398 |
ShdA |
Adherence |
VFC0001 |
The shdA gene is carried on a 25-kb genetic island at centisome 54 (CS54 island) of the Salmonella enterica serotype Typhimurium chromosome. |
(shdA) AIDA autotransporter-like protein [ShdA (VF0398) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_46 |
82.236 |
0.0 |
ratB |
VF0399 |
RatB |
Adherence |
VFC0001 |
Three putative intestinal colonization factors SinH, RatB and ShdA, are located in the same 25-kb pathogenicity island, called CS54. This island is present only in subspecies 1 of S. enterica. |
(ratB) putative outer membrane protein [RatB (VF0399) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_47 |
82.071 |
0.0 |
ratB |
VF0399 |
RatB |
Adherence |
VFC0001 |
Three putative intestinal colonization factors SinH, RatB and ShdA, are located in the same 25-kb pathogenicity island, called CS54. This island is present only in subspecies 1 of S. enterica. |
(ratB) putative outer membrane protein [RatB (VF0399) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_48 |
87.079 |
0.0 |
ratB |
VF0399 |
RatB |
Adherence |
VFC0001 |
Three putative intestinal colonization factors SinH, RatB and ShdA, are located in the same 25-kb pathogenicity island, called CS54. This island is present only in subspecies 1 of S. enterica. |
(ratB) putative outer membrane protein [RatB (VF0399) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_49 |
84.096 |
0.0 |
ratB |
VF0399 |
RatB |
Adherence |
VFC0001 |
Three putative intestinal colonization factors SinH, RatB and ShdA, are located in the same 25-kb pathogenicity island, called CS54. This island is present only in subspecies 1 of S. enterica. |
(ratB) putative outer membrane protein [RatB (VF0399) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_52 |
97.764 |
0.0 |
sinH |
VF0400 |
SinH |
Adherence |
VFC0001 |
N-terminal 350 residues exhibits homology with invasin of Yersinia pseudotuberculosis (49.5% identity) and intimin of E. coli O111 (enteropathogenic E. coli) (48% identity). The amino termini of invasin and intimin serve as membrane-spanning anchors in the bacterial outer membrane. |
(sinH) intimin-like protein [SinH (VF0400) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_53 |
96.386 |
2.16E-48 |
sinH |
VF0400 |
SinH |
Adherence |
VFC0001 |
N-terminal 350 residues exhibits homology with invasin of Yersinia pseudotuberculosis (49.5% identity) and intimin of E. coli O111 (enteropathogenic E. coli) (48% identity). The amino termini of invasin and intimin serve as membrane-spanning anchors in the bacterial outer membrane. |
(sinH) intimin-like protein [SinH (VF0400) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000011.1_126 |
65.445 |
1.05E-90 |
algU |
VF0091 |
Alginate |
Biofilm |
VFC0271 |
Alginate production is frequently referred to as mucoidy because colonies producing alginate have a wet glistening (mucoid) appearance, which is very different from that of colonies not producing alginate; most of the alginate biosynthetic genes are clustered in the algD operon; Alginate production is highly regulated. Regulatory genes are located in two areas far removed from the biosynthetic genes, with one exception algC |
(algU) alginate biosynthesis protein AlgZ/FimS [Alginate (VF0091) - Biofilm (VFC0271)] [Pseudomonas aeruginosa PAO1] |
Pseudomonas aeruginosa |
| CVQN01000012.1_92 |
88.571 |
6.64E-139 |
steA |
VF0948 |
TTSS effectors secreted via both systems |
Effector delivery system |
VFC0086 |
|
(steA) type III secretion system effector SteA (Salmonella translocated effector A) [TTSS effectors secreted via both systems (VF0948) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000012.1_110 |
98.544 |
2.33E-151 |
sifB |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sifB) type III secretion system effector SifB (Salmonella induced filament protein B) [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_16 |
91.992 |
0.0 |
acrB |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrB) acriflavine resistance protein B [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_17 |
85.025 |
0.0 |
acrA |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrA) acriflavine resistance protein A [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_58 |
73.443 |
1.6E-171 |
allS |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allS) DNA-binding transcriptional activator AllS [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_59 |
67.857 |
4.89E-8 |
allA |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allA) ureidoglycolate hydrolase [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_60 |
82.474 |
2.53E-58 |
allA |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allA) ureidoglycolate hydrolase [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_61 |
85.874 |
3.12E-176 |
allR |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allR) DNA-binding transcriptional repressor AllR [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_68 |
93.377 |
0.0 |
allB |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allB) allantoinase [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_72 |
79.951 |
0.0 |
allC |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allC) allantoate amidohydrolase [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_73 |
81.662 |
0.0 |
allD |
VF0572 |
Allantion utilization |
Nutritional/Metabolic factor |
VFC0272 |
An allantoin utilization operon has been associated with hypervirulent K. pneumoniae strains that cause pyogenic liver abscesses. |
(allD) ureidoglycolate dehydrogenase [Allantion utilization (VF0572) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_86 |
96.757 |
1.89E-127 |
fimA |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimA) type-1 fimbrial protein subunit A [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_87 |
98.305 |
1.99E-129 |
fimI |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimI) fimbrial protein internal segment [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_88 |
98.261 |
7.07E-168 |
fimC |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimC) chaperone protein FimC [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_89 |
98.276 |
0.0 |
fimD |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimD) usher protein FimD [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_90 |
97.015 |
0.0 |
fimH |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimH) type I fimbriae minor fimbrial subunit FimH, adhesin [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_91 |
98.837 |
6.17E-125 |
fimF |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimF) type I fimbriae adaptor protein FimF [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_92 |
99.048 |
6.24E-154 |
fimZ |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimZ) DNA-binding response regulator [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_93 |
97.083 |
1.62E-173 |
fimY |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimY) fimbriae Y protein [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_95 |
98.485 |
1.05E-147 |
fimW |
VF0102 |
Type 1 fimbriae |
Adherence |
VFC0001 |
Chaperone-usher assembly pathway |
(fimW) helix-turn-helix transcriptional regulator [Type 1 fimbriae (VF0102) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000013.1_99 |
88.235 |
0.0 |
gtrB |
VF0124 |
LPS |
Immune modulation |
VFC0258 |
Composed of the O-antigen, core polysaccharides and lipid A; the genes involved in the biosynthesis of the basic O-antigen are located in the rfb/rfc loci; O-antigen modification is associated with temperate bacteriophages. Four different serotype-converting phages have been found: SfII, Sf6, SfV and SfX, which are involved in conversion of a serotype Y stain to serotypes 2a, 3b, 5a and X, respectively |
(gtrB) bactoprenol glucosyl transferase [LPS (VF0124) - Immune modulation (VFC0258)] [Shigella flexneri 2a str. 301] |
Shigella flexneri |
| CVQN01000013.1_100 |
79.167 |
2.31E-70 |
gtrA |
VF0124 |
LPS |
Immune modulation |
VFC0258 |
Composed of the O-antigen, core polysaccharides and lipid A; the genes involved in the biosynthesis of the basic O-antigen are located in the rfb/rfc loci; O-antigen modification is associated with temperate bacteriophages. Four different serotype-converting phages have been found: SfII, Sf6, SfV and SfX, which are involved in conversion of a serotype Y stain to serotypes 2a, 3b, 5a and X, respectively |
(gtrA) bactoprenol-linked glucose translocase/flippase [LPS (VF0124) - Immune modulation (VFC0258)] [Shigella flexneri 2a str. 301] |
Shigella flexneri |
| CVQN01000013.1_119 |
82.119 |
0.0 |
fepA |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepA) ferrienterobactin outer membrane transporter [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_120 |
73.869 |
0.0 |
fes |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fes) enterobactin/ferric enterobactin esterase [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_122 |
78.825 |
0.0 |
entF |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entF) enterobactin synthase multienzyme complex component, ATP-dependent [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_123 |
60.256 |
4.68E-28 |
fepE |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepE) LPS O-antigen length regulator [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_124 |
77.083 |
1.01E-166 |
fepE |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepE) LPS O-antigen length regulator [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_125 |
92.395 |
0.0 |
fepC |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepC) ferrienterobactin ABC transporter ATPase [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_126 |
86.93 |
0.0 |
fepG |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepG) iron-enterobactin ABC transporter permease [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_127 |
84.478 |
0.0 |
fepD |
VF0562 |
Ent |
Nutritional/Metabolic factor |
VFC0272 |
Various iron acquisition systems in Klebsiella are needed to overcome host defenses in different anatomical compartments. |
(fepD) iron-enterobactin transporter membrane protein [Ent (VF0562) - Nutritional/Metabolic factor (VFC0272)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000013.1_128 |
90.709 |
0.0 |
entS |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entS) enterobactin exporter, iron-regulated [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_129 |
79.56 |
0.0 |
fepB |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(fepB) ferrienterobactin ABC transporter periplasmic binding protein [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_130 |
84.143 |
0.0 |
entC |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entC) isochorismate synthase 1 [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_131 |
85.768 |
0.0 |
entE |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entE) 2,3-dihydroxybenzoate-AMP ligase component of enterobactin synthase multienzyme complex [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_132 |
88.421 |
0.0 |
entB |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entB) isochorismatase [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000013.1_133 |
88.71 |
5.05E-163 |
entA |
VF0228 |
Enterobactin |
Nutritional/Metabolic factor |
VFC0272 |
An extremely effective iron chelator, with a formation constant for the iron complex of 1049. Fe3+ is coordinated by six catechol oxygens to form a metal chelate with a net negative charge of three |
(entA) 2,3-dihydro-2,3-dihydroxybenzoate dehydrogenase EntA [Enterobactin (VF0228) - Nutritional/Metabolic factor (VFC0272)] [Escherichia coli CFT073] |
Escherichia coli (UPEC) |
| CVQN01000014.1_9 |
71.474 |
2.48E-172 |
pla |
VF0139 |
Pla |
Exoenzyme |
VFC0251 |
Belongs to the family of OM proteases/adhesins known as omptins that share high sequence identity but differ in biological function; Omptins appear to constitute a unique class of proteases. Other omptin family outer membrane proteases include PgtE from S. enterica, OmpT and OmpR from E. coli, and SopA/IcsP from S. flexneri. Their catalytic residues are conserved. They require the presence of rough LPS for enzymatic activity and are inhibited by the O-antigen chains present in smooth LPS; unique to Y. pestis encoded by the pPCP1 plasmid not present in the enteropathogenic yersiniae Y. pseudotuberculosis and Y. enterocolitica |
(pla) plasminogen activator protease precursor [Pla (VF0139) - Exoenzyme (VFC0251)] [Yersinia pestis CO92] |
Yersinia pestis |
| CVQN01000014.1_13 |
73.973 |
5.56E-34 |
gtrB |
VF0124 |
LPS |
Immune modulation |
VFC0258 |
Composed of the O-antigen, core polysaccharides and lipid A; the genes involved in the biosynthesis of the basic O-antigen are located in the rfb/rfc loci; O-antigen modification is associated with temperate bacteriophages. Four different serotype-converting phages have been found: SfII, Sf6, SfV and SfX, which are involved in conversion of a serotype Y stain to serotypes 2a, 3b, 5a and X, respectively |
(gtrB) bactoprenol glucosyl transferase [LPS (VF0124) - Immune modulation (VFC0258)] [Shigella flexneri 2a str. 301] |
Shigella flexneri |
| CVQN01000014.1_14 |
72.34 |
7.54E-49 |
gtrA |
VF0124 |
LPS |
Immune modulation |
VFC0258 |
Composed of the O-antigen, core polysaccharides and lipid A; the genes involved in the biosynthesis of the basic O-antigen are located in the rfb/rfc loci; O-antigen modification is associated with temperate bacteriophages. Four different serotype-converting phages have been found: SfII, Sf6, SfV and SfX, which are involved in conversion of a serotype Y stain to serotypes 2a, 3b, 5a and X, respectively |
(gtrA) bactoprenol-linked glucose translocase/flippase [LPS (VF0124) - Immune modulation (VFC0258)] [Shigella flexneri 2a str. 301] |
Shigella flexneri |
| CVQN01000014.1_120 |
93.691 |
0.0 |
sseL |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sseL) type III secretion system effector SseL, deubiquitinase [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000015.1_111 |
77.26 |
4.48E-177 |
cheD |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(cheD) methyl-accepting chemotaxis protein CheD [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000016.1_74 |
75.758 |
0.0 |
htpB |
VF0159 |
Hsp60 |
Adherence |
VFC0001 |
|
(htpB) Hsp60, 60K heat shock protein HtpB [Hsp60 (VF0159) - Adherence (VFC0001)] [Legionella pneumophila subsp. pneumophila str. Philadelphia 1] |
Legionella pneumophila |
| CVQN01000016.1_99 |
100.0 |
3.23E-134 |
tviA |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(tviA) Vi polysaccharide biosynthesis regulator TviA [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_100 |
100.0 |
0.0 |
tviB |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(tviB) Vi polysaccharide biosynthesis protein, UDP-N-acetylglucosamine (UPD-GlcNAc) 6-dehydrogenase TviB [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_101 |
100.0 |
0.0 |
tviC |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(tviC) Vi polysaccharide biosynthesis protein, UDP-GlcNAcA 4-epimerase TviC [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_102 |
100.0 |
0.0 |
tviD |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(tviD) Vi polysaccharide biosynthesis protein TviD [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_103 |
100.0 |
0.0 |
tviE |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(tviE) Vi polysaccharide biosynthesis protein TviE, Glycosyl transferases group 1 [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_104 |
100.0 |
0.0 |
vexA |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(vexA) Vi polysaccharide export protein VexA [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_105 |
100.0 |
0.0 |
vexB |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(vexB) Vi polysaccharide export inner-membrane protein (ABC-2 type transporter) VexB [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_106 |
100.0 |
1.25E-174 |
vexC |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(vexC) Vi polysaccharide export ATP-binding protein VexC [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_107 |
100.0 |
0.0 |
vexD |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(vexD) Vi polysaccharide export inner-membrane protein VexD [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000016.1_108 |
100.0 |
0.0 |
vexE |
VF0101 |
Vi antigen |
Immune modulation |
VFC0258 |
Vi is abbreviation for virulence; the viaB locus is within Salmonella pathogenicity island SPI-7, which also encodes SopE and a type IVB pilus; The viaB locus encodes genes involved in regulation (tviA), Vi biosynthesis (tviBCDE), export, and retention of the Vi on the bacterial cell surface (vexABCDE); A viaB locus is absent from S. Paratyphi A, and most gastroenteritis-causing serovars including S. Typhimurium |
(vexE) Vi polysaccharide export protein VexE [Vi antigen (VF0101) - Immune modulation (VFC0258)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000018.1_60 |
66.323 |
4.11E-142 |
wbtL |
VF0542 |
LPS |
Immune modulation |
VFC0258 |
The structure of Francisella spp. lipid A is unique in that it is modified by various carbohydrates that greatly reduce TLR4 activation and allow for immune evasion |
(wbtL) glucose-1-phosphate thymidylyltransferase [LPS (VF0542) - Immune modulation (VFC0258)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000018.1_61 |
65.476 |
7.71E-171 |
rffG |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(rffG) dTDP-glucose 46-dehydratase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000019.1_17 |
75.0 |
3.37E-161 |
galU |
VF0044 |
LOS |
Immune modulation |
VFC0258 |
Lic1A (phosphorylcholine (ChoP) kinase) 5'-CAAT-3' within the 5'-end of its coding sequence; lic2A, also referred to as lexA, variation in the number of 5'-CAAT-3' repeats has been shown to correlate directly with phase variation of the Gal-alpha(1-4)beta-Gal LPS structure; But lgtC (glycosyltransferase), another phase-variable gene, ultimately dictates whether this structure is synthesized. lic3A encode a sialyl transferase which directs the substitution of LPS with sialic acid. |
(galU) glucosephosphate uridylyltransferase [LOS (VF0044) - Immune modulation (VFC0258)] [Haemophilus influenzae Rd KW20] |
Haemophilus influenzae |
| CVQN01000019.1_73 |
91.087 |
0.0 |
steC |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(steC) type III secretion system effector SteC (Salmonella translocated effector C), kinase [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000019.1_80 |
100.0 |
6.03E-105 |
pltC |
VF0407 |
Typhoid toxin |
Exotoxin |
VFC0235 |
Classic cytolethal distending toxins (CDTs) are three component AB toxins, composed of CdtA, CdtB and CdtC. CdtA and CdtC mediate target cell binding and membrane translocation of CdtB, which then induces DNA damage, most probably through its nuclease activity; In the case of S. typhi, however, genes encoding CdtA and CdtC are absent. CdtB from S. typhi is produced with the pertussis-like toxins PltA and PltB only inside the host cell and is then secreted from the infected Cell in a PltA/B-Dependent manner and acts then as a classical CDT from outside;typhoid toxin seemed to have evolved from the combination of the activities of two exotoxin ancestors, CDT and pertussis toxins; The typhoid toxin is an atypical AB toxin encoded on SPI-11; The toxin is expressed exclusively when S. Typhi is intracellualr and localized within the Salmonella containing vacuole (SCV); Homologues are found in S. Paratyphi A and several NTS serovars, but are absent from S. Typhimurium and S. Enteritidis; The typhoid toxin is secreted within vesicles originating from the SCV and released into the extracellular space |
(pltC) an orphan pertussis-like toxin delivery subunit [Typhoid toxin (VF0407) - Exotoxin (VFC0235)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000020.1_2 |
97.595 |
0.0 |
pipB |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(pipB) type III secretion system effector PipB [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_4 |
98.396 |
0.0 |
sopB/sigD |
VF0949 |
TTSS-1 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sopB/sigD) type III secretion system effector SopB, phosphoinositide phosphatase [TTSS-1 secreted effectors (VF0949) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_50 |
100.0 |
0.0 |
csgG |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgG) curli production assembly/transport protein CsgG [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_51 |
100.0 |
2.24E-100 |
csgF |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgF) curli production assembly/transport protein CsgF [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_52 |
100.0 |
1.59E-96 |
csgE |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgE) curli production assembly/transport protein CsgE [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_53 |
100.0 |
5.77E-157 |
csgD |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgD) DNA-binding transcriptional regulator CsgD [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_54 |
99.338 |
1.41E-107 |
csgB |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgB) minor curlin subunit precursor, curli nucleator protein CsgB [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_55 |
100.0 |
3.01E-106 |
csgA |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgA) curlin major subunit CsgA [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_56 |
99.074 |
6.2E-74 |
csgC |
VF0103 |
Agf |
Adherence |
VFC0001 |
Homology to csg of E.coli; nucleator-dependent assembly pathway |
(csgC) curli assembly protein CsgC [Agf (VF0103) - Adherence (VFC0001)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000020.1_82 |
60.606 |
2.28E-33 |
flgM |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgM) negative regulator of flagellin synthesis [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_84 |
78.102 |
2.17E-77 |
flgB |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgB) flagellar basal-body rod protein FlgB [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_85 |
81.343 |
1.06E-80 |
flgC |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgC) flagellar basal-body rod protein FlgC [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_86 |
71.287 |
9.94E-99 |
flgD |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgD) flagellar basal-body rod modification protein FlgD [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_87 |
63.183 |
2.55E-180 |
flgE |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgE) flagellar hook protein FlgE [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_88 |
70.12 |
5.52E-127 |
flgF |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgF) flagellar basal-body rod protein FlgF [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_89 |
87.308 |
5.49E-170 |
flgG |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgG) flagellar basal-body rod protein FlgG [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_90 |
82.16 |
4.37E-122 |
flgH |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgH) flagellar L-ring protein precursor FlgH [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_91 |
79.05 |
0.0 |
flgI |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgI) flagellar P-ring protein precursor FlgI [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000020.1_92 |
61.146 |
1.96E-137 |
flgJ |
VF0394 |
Flagella |
Motility |
VFC0204 |
|
(flgJ) <beta>-N-acetylglucosaminidase [Flagella (VF0394) - Motility (VFC0204)] [Yersinia enterocolitica subsp. enterocolitica 8081] |
Yersinia enterocolitica |
| CVQN01000024.1_52 |
66.495 |
2.42E-98 |
clpP |
VF0074 |
ClpP |
Stress survival |
VFC0282 |
21.6 kDa protein belongs to a family of proteases highly conserved in prokaryotes and eukaryotes |
(clpP) ATP-dependent Clp protease proteolytic subunit [ClpP (VF0074) - Stress survival (VFC0282)] [Listeria monocytogenes EGD-e] |
Listeria monocytogenes |
| CVQN01000025.1_8 |
99.554 |
6.41E-166 |
phoP |
VF0111 |
PhoPQ |
Regulation |
VFC0301 |
|
(phoP) response regulator in two-component regulatory system with PhoQ [PhoPQ (VF0111) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000025.1_9 |
99.795 |
0.0 |
phoQ |
VF0111 |
PhoPQ |
Regulation |
VFC0301 |
|
(phoQ) sensor protein PhoQ [PhoPQ (VF0111) - Regulation (VFC0301)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000025.1_15 |
93.155 |
0.0 |
sifA |
VF0947 |
TTSS-2 secreted effectors |
Effector delivery system |
VFC0086 |
|
(sifA) type III secretion system effector SifA (Salmonella induced filament protein A) [TTSS-2 secreted effectors (VF0947) - Effector delivery system (VFC0086)] [Salmonella enterica subsp. enterica serovar Typhimurium str. LT2] |
Salmonella enterica (serovar typhimurium) |
| CVQN01000025.1_45 |
61.538 |
1.93E-27 |
acpXL |
VF0367 |
LPS |
Immune modulation |
VFC0258 |
Brucella possesses a non-classical LPS as compared with the so-called classical LPS from enterobacteria such as Escherichia coli. B. abortus lipid A possesses a diaminoglucose backbone (rather than glucosamine), and acyl groups are longer (C28 rather than C12 and C16) and are only linked to the core by amide bounds (rather than ester and amide bonds).; In contrast to enterobacterial LPSs, Brucella LPS is several-hundred-times less active and toxic than E. coli LPS.; this is an evolutionary adaptation to an intracellular lifestyle, low endotoxic activity is shared by other intracellular pathogens such as Bartonella and Legionella. |
(acpXL) acyl carrier protein [LPS (VF0367) - Immune modulation (VFC0258)] [Brucella melitensis bv. 1 str. 16M] |
Brucella melitensis |
| CVQN01000025.1_46 |
77.459 |
1.72E-139 |
flmH |
VF0473 |
Polar flagella |
Motility |
VFC0204 |
Types of bacterial movement: swimming, swarming, gliding, twitching and sliding. Only swimming and swarming are correlated with the presence of flagella. Swimming is an individual endeavour, while swarming is the movement of a group of bacteria; constitutively expressed for motility in liquid environments |
(flmH) short chain dehydrogenase/reductase family oxidoreductase [Polar flagella (VF0473) - Motility (VFC0204)] [Aeromonas hydrophila ML09-119] |
Aeromonas hydrophila |
| CVQN01000026.1_2 |
91.892 |
3.31E-61 |
acrB |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrB) acriflavine resistance protein B [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000026.1_3 |
79.36 |
0.0 |
acrB |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrB) acriflavine resistance protein B [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000026.1_4 |
72.222 |
5.09E-65 |
acrA |
VF0568 |
AcrAB |
Antimicrobial activity/Competitive advantage |
VFC0325 |
|
(acrA) acriflavine resistance protein A [AcrAB (VF0568) - Antimicrobial activity/Competitive advantage (VFC0325)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000029.1_1 |
80.69 |
7.13E-87 |
tufA |
VF0460 |
EF-Tu |
Adherence |
VFC0001 |
|
(tufA) elongation factor Tu [EF-Tu (VF0460) - Adherence (VFC0001)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000030.1_30 |
100.0 |
0.0 |
cdtB |
VF0407 |
Typhoid toxin |
Exotoxin |
VFC0235 |
Classic cytolethal distending toxins (CDTs) are three component AB toxins, composed of CdtA, CdtB and CdtC. CdtA and CdtC mediate target cell binding and membrane translocation of CdtB, which then induces DNA damage, most probably through its nuclease activity; In the case of S. typhi, however, genes encoding CdtA and CdtC are absent. CdtB from S. typhi is produced with the pertussis-like toxins PltA and PltB only inside the host cell and is then secreted from the infected Cell in a PltA/B-Dependent manner and acts then as a classical CDT from outside;typhoid toxin seemed to have evolved from the combination of the activities of two exotoxin ancestors, CDT and pertussis toxins; The typhoid toxin is an atypical AB toxin encoded on SPI-11; The toxin is expressed exclusively when S. Typhi is intracellualr and localized within the Salmonella containing vacuole (SCV); Homologues are found in S. Paratyphi A and several NTS serovars, but are absent from S. Typhimurium and S. Enteritidis; The typhoid toxin is secreted within vesicles originating from the SCV and released into the extracellular space |
(cdtB) cytolethal distending toxin B [Typhoid toxin (VF0407) - Exotoxin (VFC0235)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000030.1_33 |
100.0 |
0.0 |
pltA |
VF0407 |
Typhoid toxin |
Exotoxin |
VFC0235 |
Classic cytolethal distending toxins (CDTs) are three component AB toxins, composed of CdtA, CdtB and CdtC. CdtA and CdtC mediate target cell binding and membrane translocation of CdtB, which then induces DNA damage, most probably through its nuclease activity; In the case of S. typhi, however, genes encoding CdtA and CdtC are absent. CdtB from S. typhi is produced with the pertussis-like toxins PltA and PltB only inside the host cell and is then secreted from the infected Cell in a PltA/B-Dependent manner and acts then as a classical CDT from outside;typhoid toxin seemed to have evolved from the combination of the activities of two exotoxin ancestors, CDT and pertussis toxins; The typhoid toxin is an atypical AB toxin encoded on SPI-11; The toxin is expressed exclusively when S. Typhi is intracellualr and localized within the Salmonella containing vacuole (SCV); Homologues are found in S. Paratyphi A and several NTS serovars, but are absent from S. Typhimurium and S. Enteritidis; The typhoid toxin is secreted within vesicles originating from the SCV and released into the extracellular space |
(pltA) typhoid-like toxin S-CDT ADP-ribosylating subunit PltA [Typhoid toxin (VF0407) - Exotoxin (VFC0235)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000030.1_34 |
100.0 |
4.5E-102 |
pltB |
VF0407 |
Typhoid toxin |
Exotoxin |
VFC0235 |
Classic cytolethal distending toxins (CDTs) are three component AB toxins, composed of CdtA, CdtB and CdtC. CdtA and CdtC mediate target cell binding and membrane translocation of CdtB, which then induces DNA damage, most probably through its nuclease activity; In the case of S. typhi, however, genes encoding CdtA and CdtC are absent. CdtB from S. typhi is produced with the pertussis-like toxins PltA and PltB only inside the host cell and is then secreted from the infected Cell in a PltA/B-Dependent manner and acts then as a classical CDT from outside;typhoid toxin seemed to have evolved from the combination of the activities of two exotoxin ancestors, CDT and pertussis toxins; The typhoid toxin is an atypical AB toxin encoded on SPI-11; The toxin is expressed exclusively when S. Typhi is intracellualr and localized within the Salmonella containing vacuole (SCV); Homologues are found in S. Paratyphi A and several NTS serovars, but are absent from S. Typhimurium and S. Enteritidis; The typhoid toxin is secreted within vesicles originating from the SCV and released into the extracellular space |
(pltB) typhoid-like toxin S-CDT binding subunit PltB [Typhoid toxin (VF0407) - Exotoxin (VFC0235)] [Salmonella enterica subsp. enterica serovar Typhi str. CT18] |
Salmonella enterica (serovar typhi) |
| CVQN01000031.1_1 |
87.179 |
1.89E-46 |
tufA |
VF0460 |
EF-Tu |
Adherence |
VFC0001 |
|
(tufA) elongation factor Tu [EF-Tu (VF0460) - Adherence (VFC0001)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |
| CVQN01000033.1_17 |
97.222 |
1.05E-153 |
rcsB |
VF0571 |
RcsAB |
Regulation |
VFC0301 |
|
(rcsB) transcriptional regulator RcsB [RcsAB (VF0571) - Regulation (VFC0301)] [Klebsiella pneumoniae subsp. pneumoniae NTUH-K2044] |
Klebsiella pneumoniae |
| CVQN01000037.1_4 |
67.528 |
1.07E-126 |
IlpA |
VF0513 |
IlpA |
Adherence |
VFC0001 |
|
(IlpA) immunogenic lipoprotein A [IlpA (VF0513) - Adherence (VFC0001)] [Vibrio vulnificus YJ016] |
Vibrio vulnificus |
| CVQN01000039.1_1 |
85.484 |
5.7E-76 |
tufA |
VF0460 |
EF-Tu |
Adherence |
VFC0001 |
|
(tufA) elongation factor Tu [EF-Tu (VF0460) - Adherence (VFC0001)] [Francisella tularensis subsp. tularensis SCHU S4] |
Francisella tularensis |