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Yersinia pseudotuberculosis

January 01, 1970

Yersinia pseudotuberculosis is a Gram-negative bacterium that causes Far East scarlet-like fever in humans, who occasionally get infected zoonotically, most often through the food-borne route.[1] Animals are also infected by Y. pseudotuberculosis. The bacterium is urease positive.

Yersinia pseudotuberculosis
Yersinia scanned with electron micrograph
SpecialtyInfectious disease

Yersinia pseudotuberculosis
Scientific classification
Domain: Bacteria
Phylum: Pseudomonadota
Class: Gammaproteobacteria
Order: Enterobacterales
Family: Yersiniaceae
Genus: Yersinia
Species:
Y. pseudotuberculosis
Binomial name
Yersinia pseudotuberculosis
(Pfeiffer 1889)
Smith & Thal 1965

Pathogenesis edit

In animals, Y. pseudotuberculosis can cause tuberculosis-like symptoms, including localized tissue necrosis and granulomas in the spleen, liver, and lymph nodes.

In humans, symptoms of Far East scarlet-like fever are similar to those of infection with Yersinia enterocolitica (fever and right-sided abdominal pain), except that the diarrheal component is often absent, which sometimes makes the resulting condition difficult to diagnose. Y. pseudotuberculosis infections can mimic appendicitis, especially in children and younger adults, and, in rare cases, the disease may cause skin complaints (erythema nodosum), joint stiffness and pain (reactive arthritis), or spread of bacteria to the blood (bacteremia).

Far East scarlet-like fever usually becomes apparent five to 10 days after exposure and typically lasts one to three weeks without treatment. In complex cases or those involving immunocompromised patients, antibiotics may be necessary for resolution; ampicillin, aminoglycosides, tetracycline, chloramphenicol, or a cephalosporin may all be effective.

The recently described syndrome "Izumi-fever" has been linked to infection with Y. pseudotuberculosis.[2]

The symptoms of fever and abdominal pain mimicking appendicitis (actually from mesenteric lymphadenitis) [3][4][5] associated with Y. pseudotuberculosis infection are not typical of the diarrhea and vomiting from classical food poisoning incidents. Although Y. pseudotuberculosis is usually only able to colonize hosts by peripheral routes and cause serious disease in immunocompromised individuals, if this bacterium gains access to the blood stream, it has an LD50 comparable to Y. pestis at only 10 CFU.[6]

Relationship to Y. pestis edit

Genetically, the pathogen causing plague, Y. pestis, is very similar to Y. pseudotuberculosis. The plague appears to have diverged from Y. pseudotuberculosis relatively recently - about 1,500 to 20,000 years ago, and shortly before the first historically recorded outbreaks in humans.[7] A 2015 paper in Cell argued for a divergence around 6,000 years ago.[8] These modern estimates differ dramatically from earlier suggestions in popular scientific literature which claimed that Y. pestis evolved in rodents "millions of years ago."[9]

Virulence factors edit

To facilitate attachment, invasion, and colonization of its host, this bacterium possesses many virulence factors. Superantigens, bacterial adhesions, and the actions of Yops (which are bacterial proteins once thought to be "Yersinia outer membrane proteins") that are encoded on the "[plasmid] for Yersinia virulence" – commonly known as the pYV – cause host pathogenesis and allow the bacteria to live parasitically.

pYV edit

The 70-kb pYV is critical to Yersinia's pathogenicity, since it contains many genes known to encode virulence factors and its loss gives avirulence of all Yersinia species.[6] A 26-kb "core region" in the pYV contains the ysc genes, which regulate the expression and secretion of Yops.[5] Many Ysc proteins also amalgamate to form a type-III secretory apparatus, which secretes many Yops into the host cell cytoplasm with the assistance of the "translocation apparatus", constructed of YopB and YopD.[10][11] The core region also includes yopN, yopB, yopD, tyeA, lcrG, and lcrV, which also regulate Yops gene expression and help to translocate secretory Yops to the target cell.[5] For example, YopN and TyeA are positioned as a plug on the apparatus so only their conformational change, induced by their interaction with certain host cell membrane proteins, will cause the unblocking of the secretory pathway.[5][12] Secretion is regulated in this fashion so that proteins are not expelled into the extracellular matrix and elicit an immune response. Since this pathway gives secretion selectivity, it is a virulence factor.

Effector Yops edit

In contrast to the ysc and yop genes listed above, the Yops that act directly on host cells to cause cytopathologic effects – "effector Yops" – are encoded by pYV genes external to this core region.[5] The sole exception is LcrV, which is also known as the "versatile Yop" for its two roles as an effector Yop and as a regulatory Yop.[5] The combined function of these effector Yops permits the bacteria to resist internalization by immune and intestinal cells and to evade the bactericidal actions of neutrophils and macrophages. Inside the bacterium, these Yops are bound by pYV-encoded Sycs (specific Yop chaperones), which prevent premature interaction with other proteins and guide the Yops to a type-III secretory apparatus.[11] In addition to the Syc-Yop complex, Yops are also tagged for type III secretion either by the first 60nt in their corresponding mRNA transcript or by their corresponding first 20 N-terminal amino acids.[4] LcrV, YopQ, YopE, YopT, YopH, YpkA, YopJ, YopM, and YadA are all secreted by the type-III secretory pathway.[4][5][12] LcrV inhibits neutrophil chemotaxis and cytokine production, allowing Y. pseudotuberculosis to form large colonies without inducing systemic failure[12] and, with YopQ, contributes to the translocation process by bringing YopB and YopD to the eukaryotic cell membrane for pore-formation.[4][13] By causing actin filament depolymerisation, YopE, YopT, and YpkA resist endocytosis by intestinal cells and phagocytosis while giving cytotoxic changes in the host cell. YopT targets Rho GTPase, commonly named "RhoA", and uncouples it from the membrane, leaving it in an inactive RhoA-GDI (guanine nucleotide dissociation inhibitor)-bound state[14] whereas YopE and YpkA convert Rho proteins to their inactive GDP-bound states by expressing GTPase activity.[12] YpkA also catalyses serine autophosphorylation, so it may have regulatory functions in Yersinia[15] or undermine host cell immune response signal cascades since YpkA is targeted to the cytoplasmic side of the host cell membrane.[16] YopH acts on host focal adhesion sites by dephosphorylating several phosphotyrosine residues on focal adhesion kinase (FAK) and the focal adhesion proteins paxillin and p130.[17] Since FAK phosphorylation is involved in uptake of yersiniae[18] as well as T cell and B cell responses to antigen-binding,[12] YopH elicits antiphagocytic and other anti-immune effects. YopJ, which shares an operon with YpkA, "...interferes with the mitogen-activated protein (MAP) kinase activities of c-Jun N-terminal kinase (JNK), p38, and extracellular signal-regulated kinase",[19] leading to macrophage apoptosis.[4] In addition, YopJ inhibits TNF-α release from many cell types, possibly through an inhibitory action on NF-κB, suppressing inflammation and the immune response.[20] By secretion through a type III pathway and localization in the nucleus by a vesicle-associated, microtubule-dependent method, YopM may alter host cell growth by binding to RSK (ribosomal S6 kinase), which regulates cell cycle regulation genes.[12] YadA has lost its adhesion,[21] opsonisation-resisting, phagocytosis-resisting, and respiratory burst-resisting functions[22][23] in Y. pseudotuberculosis due to a frameshift mutation by a single base-pair deletion in yadA in comparison to yadA in Y. enterocolitica, yet it still is secreted by type III secretion.[24] The yop genes, yadA, ylpA, and the virC operon are considered the "Yop regulon" since they are coregulated by pYV-encoded VirF. virF is in turn thermoregulated. At 37 degrees Celsius, chromosomally encoded Ymo, which regulates DNA supercoiling around the virF gene, changes conformation, allowing for virF expression, which then up-regulates the Yop regulon.[25]

Adhesion edit

Y. pseudotuberculosis adheres strongly to intestinal cells via chromosomally encoded proteins[4] so that Yop secretion may occur, to avoid being removed by peristalsis, and to invade target host cells. A transmembrane protein, invasin, facilitates these functions by binding to host cell αβ1 integrins.[26] Through this binding, the integrins cluster, thereby activating FAK, and causing a corresponding reorganization of the cytoskeleton.[4][26] Subsequent internalization of bound bacteria occurs when the actin-depolymerising Yops are not being expressed.[12] The protein encoded on the "attachment invasion locus" named Ail also bestows attachment and invasive abilities upon Yersiniae[27] while interfering with the binding of complement on the bacterial surface.[28] To increase binding specificity, the fibrillar pH6 antigen targets bacteria to target intestinal cells only when thermoinduced.[29]

Superantigens edit

Certain strains of Yersinia pseudotuberculosis express a superantigenic exotoxin, YPM, or the Y. pseudotuberculosis-derived mitogen, from the chromosomal ypm gene.[30] YPM specifically binds and causes the proliferation of T lymphocytes expressing the Vβ3, Vβ7, Vβ8, Vβ9, Vβ13.1, and Vβ13.2 variable regions [31] with CD4+ T cell preference, although activation of some CD8+ T cells occurs.[3] This T cell expansion can cause splenomegaly coupled with IL-2 and IL-4 overproduction.[32] Since administering anti-TNF-α and anti-IFN-γ monoclonal antibodies neutralizes YPM toxicity in vivo,[30] these cytokines are largely responsible for the damage caused indirectly by the exotoxin. Strains that carry the exotoxin gene are rare in Western countries, where the disease, when at all apparent, manifests itself largely with minor symptoms, whereas more than 95% of strains from Far Eastern countries contain ypm[33] and are correlated with Izumi fever and Kawasaki disease.[34] Although the superantigen poses the greatest threat to host health, all virulence factors contribute to Y. pseudotuberculosis viability in vivo and define the bacterium’s pathogenic characteristics. Y. pseudotuberculosis can live extracellularly due to its formidable mechanisms of phagocytosis and opsonisation resistance through the expression of Yops and the type III pathway;[11] yet, by limited pYV action, it can populate host cells, especially macrophages, intracellularly to further evade immune responses and be disseminated throughout the body.[35]

YpM
 
crystal structure of yersinia pseudotuberculosis-derived mitogen (ypm)
Identifiers
SymbolYpM
PfamPF09144
InterProIPR015227
SCOP21pm4 / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Function edit

Yersinia pseudotuberculosis-derived mitogens (YpM) are superantigens, which are able to excessively activate T cells by binding to the T cell receptor. Since YpM can activate large numbers of the T cell population, this leads the release of inflammatory cytokines.

Structure edit

Members of this family of Yersinia pseudotuberculosis mitogens adopt a sandwich structure consisting of 9 strands in two beta sheets, in a jelly roll fold topology. YpM molecular weight is about 14 kDa. Structurally, it is unlike any other superantigen, but is remarkably similar to the tumour necrosis factor and viral capsid proteins. This suggests a possible evolutionary relationship.[36]

Subfamilies edit

Some highly similar homologous variants of YPM have been characterized, including YPMa, YPMb, and YPMc.

small non-coding RNA edit

Numerous bacterial small non-coding RNAs have been identified to play regulatory functions. Some can regulate the virulence genes. 150 unannotated sRNAs were identified by sequencing of Y. pseudotuberculosis RNA libraries from bacteria grown at 26 °C and 37 °C, suggesting they may play a role in pathogenesis.[37] By using single-molecule fluorescence in situ hybridisation smFISH technique it was shown that the number of YSR35 RNA increased 2.5 times upon temperature shift from 25 °C to 37 °C.[38] Another study uncovered that a temperature-induced global reprogramming of central metabolic functions are likely to support intestinal colonization of the pathogen. Environmentally controlled regulatory RNAs coordinate control of metabolism and virulence allowing rapid adaptation and high flexibility during life-style changes.[39] High-throughput RNA structure probing identified many thermoresponsive RNA structures.[40]

See also edit

References edit

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This article incorporates text from the public domain Pfam and InterPro: IPR015227

External links edit

 
Wikispecies has information related to Yersinia pseudotuberculosis.
  • Yersinia pseudotuberculosis genome
  • "Yersinia pseudotuberculosis". NCBI Taxonomy Browser. 632.
  • Type strain of Yersinia pseudotuberculosis at BacDive - the Bacterial Diversity Metadatabase

January 01, 1970
yersinia, pseudotuberculosis, gram, negative, bacterium, that, causes, east, scarlet, like, fever, humans, occasionally, infected, zoonotically, most, often, through, food, borne, route, animals, also, infected, pseudotuberculosis, bacterium, urease, positive,. Yersinia pseudotuberculosis is a Gram negative bacterium that causes Far East scarlet like fever in humans who occasionally get infected zoonotically most often through the food borne route 1 Animals are also infected by Y pseudotuberculosis The bacterium is urease positive Yersinia pseudotuberculosisYersinia scanned with electron micrographSpecialtyInfectious disease Yersinia pseudotuberculosis Scientific classification Domain Bacteria Phylum Pseudomonadota Class Gammaproteobacteria Order Enterobacterales Family Yersiniaceae Genus Yersinia Species Y pseudotuberculosis Binomial name Yersinia pseudotuberculosis Pfeiffer 1889 Smith amp Thal 1965 Contents 1 Pathogenesis 2 Relationship to Y pestis 3 Virulence factors 3 1 pYV 3 2 Effector Yops 3 3 Adhesion 3 4 Superantigens 3 4 1 Function 3 4 2 Structure 3 4 3 Subfamilies 3 5 small non coding RNA 3 6 See also 4 References 5 External linksPathogenesis editIn animals Y pseudotuberculosis can cause tuberculosis like symptoms including localized tissue necrosis and granulomas in the spleen liver and lymph nodes In humans symptoms of Far East scarlet like fever are similar to those of infection with Yersinia enterocolitica fever and right sided abdominal pain except that the diarrheal component is often absent which sometimes makes the resulting condition difficult to diagnose Y pseudotuberculosis infections can mimic appendicitis especially in children and younger adults and in rare cases the disease may cause skin complaints erythema nodosum joint stiffness and pain reactive arthritis or spread of bacteria to the blood bacteremia Far East scarlet like fever usually becomes apparent five to 10 days after exposure and typically lasts one to three weeks without treatment In complex cases or those involving immunocompromised patients antibiotics may be necessary for resolution ampicillin aminoglycosides tetracycline chloramphenicol or a cephalosporin may all be effective The recently described syndrome Izumi fever has been linked to infection with Y pseudotuberculosis 2 The symptoms of fever and abdominal pain mimicking appendicitis actually from mesenteric lymphadenitis 3 4 5 associated with Y pseudotuberculosis infection are not typical of the diarrhea and vomiting from classical food poisoning incidents Although Y pseudotuberculosis is usually only able to colonize hosts by peripheral routes and cause serious disease in immunocompromised individuals if this bacterium gains access to the blood stream it has an LD50 comparable to Y pestis at only 10 CFU 6 Relationship to Y pestis editGenetically the pathogen causing plague Y pestis is very similar to Y pseudotuberculosis The plague appears to have diverged from Y pseudotuberculosis relatively recently about 1 500 to 20 000 years ago and shortly before the first historically recorded outbreaks in humans 7 A 2015 paper in Cell argued for a divergence around 6 000 years ago 8 These modern estimates differ dramatically from earlier suggestions in popular scientific literature which claimed that Y pestis evolved in rodents millions of years ago 9 Virulence factors editTo facilitate attachment invasion and colonization of its host this bacterium possesses many virulence factors Superantigens bacterial adhesions and the actions of Yops which are bacterial proteins once thought to be Yersinia outer membrane proteins that are encoded on the plasmid for Yersinia virulence commonly known as the pYV cause host pathogenesis and allow the bacteria to live parasitically pYV edit The 70 kb pYV is critical to Yersinia s pathogenicity since it contains many genes known to encode virulence factors and its loss gives avirulence of all Yersinia species 6 A 26 kb core region in the pYV contains the ysc genes which regulate the expression and secretion of Yops 5 Many Ysc proteins also amalgamate to form a type III secretory apparatus which secretes many Yops into the host cell cytoplasm with the assistance of the translocation apparatus constructed of YopB and YopD 10 11 The core region also includes yopN yopB yopD tyeA lcrG and lcrV which also regulate Yops gene expression and help to translocate secretory Yops to the target cell 5 For example YopN and TyeA are positioned as a plug on the apparatus so only their conformational change induced by their interaction with certain host cell membrane proteins will cause the unblocking of the secretory pathway 5 12 Secretion is regulated in this fashion so that proteins are not expelled into the extracellular matrix and elicit an immune response Since this pathway gives secretion selectivity it is a virulence factor Effector Yops edit In contrast to the ysc and yop genes listed above the Yops that act directly on host cells to cause cytopathologic effects effector Yops are encoded by pYV genes external to this core region 5 The sole exception is LcrV which is also known as the versatile Yop for its two roles as an effector Yop and as a regulatory Yop 5 The combined function of these effector Yops permits the bacteria to resist internalization by immune and intestinal cells and to evade the bactericidal actions of neutrophils and macrophages Inside the bacterium these Yops are bound by pYV encoded Sycs specific Yop chaperones which prevent premature interaction with other proteins and guide the Yops to a type III secretory apparatus 11 In addition to the Syc Yop complex Yops are also tagged for type III secretion either by the first 60nt in their corresponding mRNA transcript or by their corresponding first 20 N terminal amino acids 4 LcrV YopQ YopE YopT YopH YpkA YopJ YopM and YadA are all secreted by the type III secretory pathway 4 5 12 LcrV inhibits neutrophil chemotaxis and cytokine production allowing Y pseudotuberculosis to form large colonies without inducing systemic failure 12 and with YopQ contributes to the translocation process by bringing YopB and YopD to the eukaryotic cell membrane for pore formation 4 13 By causing actin filament depolymerisation YopE YopT and YpkA resist endocytosis by intestinal cells and phagocytosis while giving cytotoxic changes in the host cell YopT targets Rho GTPase commonly named RhoA and uncouples it from the membrane leaving it in an inactive RhoA GDI guanine nucleotide dissociation inhibitor bound state 14 whereas YopE and YpkA convert Rho proteins to their inactive GDP bound states by expressing GTPase activity 12 YpkA also catalyses serine autophosphorylation so it may have regulatory functions in Yersinia 15 or undermine host cell immune response signal cascades since YpkA is targeted to the cytoplasmic side of the host cell membrane 16 YopH acts on host focal adhesion sites by dephosphorylating several phosphotyrosine residues on focal adhesion kinase FAK and the focal adhesion proteins paxillin and p130 17 Since FAK phosphorylation is involved in uptake of yersiniae 18 as well as T cell and B cell responses to antigen binding 12 YopH elicits antiphagocytic and other anti immune effects YopJ which shares an operon with YpkA interferes with the mitogen activated protein MAP kinase activities of c Jun N terminal kinase JNK p38 and extracellular signal regulated kinase 19 leading to macrophage apoptosis 4 In addition YopJ inhibits TNF a release from many cell types possibly through an inhibitory action on NF kB suppressing inflammation and the immune response 20 By secretion through a type III pathway and localization in the nucleus by a vesicle associated microtubule dependent method YopM may alter host cell growth by binding to RSK ribosomal S6 kinase which regulates cell cycle regulation genes 12 YadA has lost its adhesion 21 opsonisation resisting phagocytosis resisting and respiratory burst resisting functions 22 23 in Y pseudotuberculosis due to a frameshift mutation by a single base pair deletion in yadA in comparison to yadA in Y enterocolitica yet it still is secreted by type III secretion 24 The yop genes yadA ylpA and the virC operon are considered the Yop regulon since they are coregulated by pYV encoded VirF virF is in turn thermoregulated At 37 degrees Celsius chromosomally encoded Ymo which regulates DNA supercoiling around the virF gene changes conformation allowing for virF expression which then up regulates the Yop regulon 25 Adhesion edit Y pseudotuberculosis adheres strongly to intestinal cells via chromosomally encoded proteins 4 so that Yop secretion may occur to avoid being removed by peristalsis and to invade target host cells A transmembrane protein invasin facilitates these functions by binding to host cell ab1 integrins 26 Through this binding the integrins cluster thereby activating FAK and causing a corresponding reorganization of the cytoskeleton 4 26 Subsequent internalization of bound bacteria occurs when the actin depolymerising Yops are not being expressed 12 The protein encoded on the attachment invasion locus named Ail also bestows attachment and invasive abilities upon Yersiniae 27 while interfering with the binding of complement on the bacterial surface 28 To increase binding specificity the fibrillar pH6 antigen targets bacteria to target intestinal cells only when thermoinduced 29 Superantigens edit Certain strains of Yersinia pseudotuberculosis express a superantigenic exotoxin YPM or the Y pseudotuberculosis derived mitogen from the chromosomal ypm gene 30 YPM specifically binds and causes the proliferation of T lymphocytes expressing the Vb3 Vb7 Vb8 Vb9 Vb13 1 and Vb13 2 variable regions 31 with CD4 T cell preference although activation of some CD8 T cells occurs 3 This T cell expansion can cause splenomegaly coupled with IL 2 and IL 4 overproduction 32 Since administering anti TNF a and anti IFN g monoclonal antibodies neutralizes YPM toxicity in vivo 30 these cytokines are largely responsible for the damage caused indirectly by the exotoxin Strains that carry the exotoxin gene are rare in Western countries where the disease when at all apparent manifests itself largely with minor symptoms whereas more than 95 of strains from Far Eastern countries contain ypm 33 and are correlated with Izumi fever and Kawasaki disease 34 Although the superantigen poses the greatest threat to host health all virulence factors contribute to Y pseudotuberculosis viability in vivo and define the bacterium s pathogenic characteristics Y pseudotuberculosis can live extracellularly due to its formidable mechanisms of phagocytosis and opsonisation resistance through the expression of Yops and the type III pathway 11 yet by limited pYV action it can populate host cells especially macrophages intracellularly to further evade immune responses and be disseminated throughout the body 35 YpM nbsp crystal structure of yersinia pseudotuberculosis derived mitogen ypm IdentifiersSymbolYpMPfamPF09144InterProIPR015227SCOP21pm4 SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summary Function edit Yersinia pseudotuberculosis derived mitogens YpM are superantigens which are able to excessively activate T cells by binding to the T cell receptor Since YpM can activate large numbers of the T cell population this leads the release of inflammatory cytokines Structure edit Members of this family of Yersinia pseudotuberculosis mitogens adopt a sandwich structure consisting of 9 strands in two beta sheets in a jelly roll fold topology YpM molecular weight is about 14 kDa Structurally it is unlike any other superantigen but is remarkably similar to the tumour necrosis factor and viral capsid proteins This suggests a possible evolutionary relationship 36 Subfamilies edit Some highly similar homologous variants of YPM have been characterized including YPMa YPMb and YPMc small non coding RNA edit Numerous bacterial small non coding RNAs have been identified to play regulatory functions Some can regulate the virulence genes 150 unannotated sRNAs were identified by sequencing of Y pseudotuberculosis RNA libraries from bacteria grown at 26 C and 37 C suggesting they may play a role in pathogenesis 37 By using single molecule fluorescence in situ hybridisation smFISH technique it was shown that the number of YSR35 RNA increased 2 5 times upon temperature shift from 25 C to 37 C 38 Another study uncovered that a temperature induced global reprogramming of central metabolic functions are likely to support intestinal colonization of the pathogen Environmentally controlled regulatory RNAs coordinate control of metabolism and virulence allowing rapid adaptation and high flexibility during life style changes 39 High throughput RNA structure probing identified many thermoresponsive RNA structures 40 See also edit Intergenic RNA thermometerReferences edit Ryan KJ Ray CG eds 2004 Sherris Medical Microbiology 4th ed McGraw Hill ISBN 978 0 8385 8529 0 Jani Asim 2003 Pseudotuberculosis Yersina Retrieved 2006 03 04 a b Carnoy C Lemaitre N Simonet M 2005 The superantigenic toxin of Yersinia pseudotuberculosis In Ladant Daniel Alouf Joseph E Popoff Michel R eds The Comprehensive Sourcebook of Bacterial Protein Toxins Academic Press pp 862 871 ISBN 978 0 08 045698 0 a b c d e f g Robins Browne R Hartland E 2003 Yersinia species In Miliotis Marianne D Bier Jeffrey W eds International Handbook of Foodborne Pathogens CRC Press pp 323 355 ISBN 978 0 203 91206 5 a b c d e f g Lindler L 2004 Virulence plasmids of Yersinia characteristics and comparison In Funnell B E Phillips G J eds Plasmid biology ASM Press pp 423 437 ISBN 978 1555812652 a b Brubaker RR 1983 The Vwa virulence factor of yersiniae the molecular basis of the attendant nutritional requirement for Ca Rev Infect Dis 5 Suppl 4 S748 58 doi 10 1093 clinids 5 supplement 4 s748 PMID 6195719 Achtman M Zurth K Morelli G Torrea G Guiyoule A Carniel E 23 November 1999 Yersinia pestis the cause of plague is a recently emerged clone of Yersinia pseudotuberculosis Proc Natl Acad Sci U S A 96 24 14043 8 Bibcode 1999PNAS 9614043A doi 10 1073 pnas 96 24 14043 PMC 24187 PMID 10570195 Rasmussen Simon Allentoft Morten Erik Nielsen Kasper Orlando Ludovic Sikora Martin Sjogren Karl Goran Pedersen Anders Gorm Schubert Mikkel Van Dam Alex Kapel Christian Moliin Outzen Nielsen Henrik Bjorn Brunak Soren Avetisyan Pavel Epimakhov Andrey Khalyapin Mikhail Viktorovich Gnuni Artak Kriiska Aivar Lasak Irena Metspalu Mait Moiseyev Vyacheslav Gromov Andrei Pokutta Dalia Saag Lehti Varul Liivi Yepiskoposyan Levon Sicheritz Ponten Thomas Foley Robert A Lahr Marta Mirazon Nielsen Rasmus et al 2015 Early Divergent Strains of Yersinia pestis in Eurasia 5 000 Years Ago Cell 163 3 571 582 doi 10 1016 j cell 2015 10 009 PMC 4644222 PMID 26496604 The disease started millions of years ago in rodents in the Himalayan foothills Karlen Arno 22 May 1996 Man and Microbes Disease and Plagues in History and Modern Times Simon amp Schuster p 76 ISBN 9780684822709 Iriarte M Cornelis GR 1999 Identification of SycN YscX and YscY three new elements of the Yersinia yop virulon J Bacteriol 181 2 675 80 doi 10 1128 JB 181 2 675 680 1999 PMC 93427 PMID 9882687 a b c Cornelis GR Boland A Boyd AP Geuijen C Iriarte M Neyt C Sory MP Stainier I 1998 The virulence plasmid of Yersinia an antihost genome Microbiol Mol Biol Rev 62 4 1315 52 doi 10 1128 MMBR 62 4 1315 1352 1998 PMC 98948 PMID 9841674 a b c d e f g Lee VT Tam C Schneewind O 2000 LcrV a substrate for Yersinia enterocolitica type III secretion is required for toxin targeting into the cytosol of HeLa cells J Biol Chem 275 47 36869 75 doi 10 1074 jbc M002467200 PMID 10930402 Zumbihl R Aepfelbacher M Andor A Jacobi CA Ruckdeschel K Rouot B Heesemann J 1999 The cytotoxin YopT of Yersinia enterocolitica induces modification and cellular redistribution of the small GTP binding protein RhoA J Biol Chem 274 41 29289 93 doi 10 1074 jbc 274 41 29289 PMID 10506187 Persson C Carballeira N Wolf Watz H Fallman M 1997 The PTPase YopH inhibits uptake of Yersinia tyrosine phosphorylation of p130Cas and FAK and the associated accumulation 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13658 PMC 24875 PMID 9811856 Galyov EE Hakansson S Forsberg A Wolf Watz H 1993 A secreted protein kinase of Yersinia pseudotuberculosis is an indispensable virulence determinant Nature 361 6414 730 2 Bibcode 1993Natur 361 730G doi 10 1038 361730a0 PMID 8441468 S2CID 4347737 Boland A Cornelis GR 1998 Role of YopP in suppression of tumor necrosis factor alpha release by macrophages during Yersinia infection Infect Immun 66 5 1878 84 doi 10 1128 IAI 66 5 1878 1884 1998 PMC 108138 PMID 9573064 Skurnik M el Tahir Y Saarinen M Jalkanen S Toivanen P 1994 YadA mediates specific binding of enteropathogenic Yersinia enterocolitica to human intestinal submucosa Infect Immun 62 4 1252 61 doi 10 1128 iai 62 4 1252 1261 1994 PMC 186266 PMID 8132332 China B Sory MP N Guyen BT De Bruyere M Cornelis GR 1993 Role of the YadA protein in prevention of opsonization of Yersinia enterocolitica by C3b molecules Infect Immun 61 8 3129 36 doi 10 1128 iai 61 8 3129 3136 1993 PMC 280979 PMID 8335343 China B N 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Bliska JB Falkow S 1992 Bacterial resistance to complement killing mediated by the Ail protein of Yersinia enterocolitica Proc Natl Acad Sci U S A 89 8 3561 5 Bibcode 1992PNAS 89 3561B doi 10 1073 pnas 89 8 3561 PMC 48908 PMID 1565652 Lindler LE Tall BD 1993 Yersinia pestis pH 6 antigen forms fimbriae and is induced by intracellular association with macrophages Mol Microbiol 8 2 311 24 doi 10 1111 j 1365 2958 1993 tb01575 x PMID 8100346 S2CID 33124727 Miyoshi Akiyama T Fujimaki W Yan XJ Yagi J Imanishi K Kato H Tomonari K Uchiyama T 1997 Identification of murine T cells reactive with the bacterial superantigen Yersinia pseudotuberculosis derived mitogen YPM and factors involved in YPM induced toxicity in mice Microbiol Immunol 41 4 345 52 doi 10 1111 j 1348 0421 1997 tb01211 x PMID 9159409 a b Uchiyama T Miyoshi Akiyama T Kato H Fujimaki W Imanishi K Yan XJ 1993 Superantigenic properties of a novel mitogenic substance produced by Yersinia pseudotuberculosis isolated from patients manifesting acute and systemic symptoms J Immunol 151 8 4407 13 PMID 8409410 Carnoy C Loiez C Faveeuw C Grangette C Desreumaux P Simonet M 2004 Impact of the Yersinia pseudotuberculosis Derived Mitogen YPM on the Murine Immune System The Genus Yersinia Advances in Experimental Medicine and Biology Vol 529 pp 133 5 doi 10 1007 0 306 48416 1 26 ISBN 978 0 306 47759 1 PMID 12756744 Yoshino K Ramamurthy T Nair GB Fukushima H Ohtomo Y Takeda N Kaneko S Takeda T 1995 Geographical heterogeneity between Far East and Europe in prevalence of ypm gene encoding the novel superantigen among Yersinia pseudotuberculosis strains J Clin Microbiol 33 12 3356 8 doi 10 1128 jcm 33 12 3356 3358 1995 PMC 228710 PMID 8586739 Fukushima H Matsuda Y Seki R Tsubokura M Takeda N Shubin FN Paik IK Zheng XB 2001 Geographical heterogeneity between Far Eastern and Western countries in prevalence of the virulence plasmid the superantigen Yersinia pseudotuberculosis derived mitogen and the high pathogenicity island among Yersinia pseudotuberculosis strains J Clin Microbiol 39 10 3541 7 doi 10 1128 JCM 39 10 3541 3547 2001 PMC 88386 PMID 11574570 Nikolova S Najdenski H Wesselinova D Vesselinova A Kazatchca D Neikov P 1997 Immunological and electronmicroscopic studies in pigs infected with Yersinia enterocolitica 0 3 Zentralbl Bakteriol 286 4 503 10 doi 10 1016 s0934 8840 97 80053 9 PMID 9440199 Smith MG 1992 Destruction of bacteria on fresh meat by hot water Epidemiol Infect 109 3 491 6 doi 10 1017 s0950268800050482 PMC 2271933 PMID 1468533 Donadini R Liew CW Kwan AH Mackay JP Fields BA January 2004 Crystal and solution structures of a superantigen from Yersinia pseudotuberculosis reveal a jelly roll fold Structure 12 1 145 56 doi 10 1016 j str 2003 12 002 PMID 14725774 Koo Jovanka T Alleyne Trevis M Schiano Chelsea A Jafari Nadereh Lathem Wyndham W 2011 09 13 Global discovery of small RNAs in Yersinia pseudotuberculosis identifies Yersinia specific small noncoding RNAs required for virulence Proceedings of the National Academy of Sciences of the United States of America 108 37 E709 717 doi 10 1073 pnas 1101655108 ISSN 1091 6490 PMC 3174644 PMID 21876162 Shepherd Douglas P Li Nan Micheva Viteva Sofiya N Munsky Brian Hong Geller Elizabeth Werner James H 2013 05 21 Counting small RNA in pathogenic bacteria Analytical Chemistry 85 10 4938 4943 doi 10 1021 ac303792p ISSN 1520 6882 PMID 23577771 S2CID 18708152 Nuss Aaron M Heroven Ann Kathrin Waldmann Barbara Reinkensmeier Jan Jarek Michael Beckstette Michael Dersch Petra 2015 03 01 Transcriptomic profiling of Yersinia pseudotuberculosis reveals reprogramming of the Crp regulon by temperature and uncovers Crp as a master regulator of small RNAs PLOS Genetics 11 3 e1005087 doi 10 1371 journal pgen 1005087 ISSN 1553 7404 PMC 4376681 PMID 25816203 Righetti Francesco Nuss Aaron M Twittenhoff Christian Beele Sascha Urban Kristina Will Sebastian Bernhart Stephan H Stadler Peter F Dersch Petra 2016 06 28 Temperature responsive in vitro RNA structurome of Yersinia pseudotuberculosis Proceedings of the National Academy of Sciences of the United States of America 113 26 7237 7242 doi 10 1073 pnas 1523004113 ISSN 1091 6490 PMC 4932938 PMID 27298343 This article incorporates text from the public domain Pfam and InterPro IPR015227External links edit nbsp Wikispecies has information related to Yersinia pseudotuberculosis Yersinia pseudotuberculosis genome Yersinia pseudotuberculosis NCBI Taxonomy Browser 632 Type strain of Yersinia pseudotuberculosis at BacDive the Bacterial Diversity Metadatabase Retrieved from https en wikipedia org w index php title Yersinia pseudotuberculosis amp oldid 1211277189, wikipedia, wiki, book, books, library,

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