Contribution of the Major Secreted Yops of Yersinia enterocolitica O:8 to Pathogenicity in the Mouse Infection Model

Pathogenic yersiniae (Yersinia pestis, Y. pseudotuberculosis,and Y. enterocolitica) harbor a 70-kb virulence plasmid (pYV)that encodes a type III secretion system and a set of at leastsix effector proteins (YopH, YopO, YopP, YopE, YopM, and YopT)that are injected into the host cell cytoplasm. Yops (Yersiniaouter proteins) disturb the dynamics of the cytoskeleton, inhibitphagocytosis by macrophages, and downregulate the productionof proinflammatory cytokines, which makes it possible for yersiniaeto multiply extracellularly in lymphoid tissue. Y. enterocoliticaserotype O:8 belongs to the highly mouse-pathogenic group ofyersiniae in contrast to Y. enterocolitica serotype O:9. However,there has been no systematic study of the contribution of Yopsto the pathogenicity of Y. enterocolitica O:8 in mice. We generateda set of yop gene deletion mutants of Y. enterocolitica O:8by using the novel Red cloning procedure. We subsequently analyzedthe contribution of yopH, -O, -P, -E, -M, -T, and -Q deletionsto pathogenicity after oral and intravenous infection of mice.Here we showed for the first time that a ${Delta}$ yopT deletion mutantcolonizes mouse tissues to a greater extent than the parentalstrain. The ${Delta}$ yopO, ${Delta}$ yopP, and ${Delta}$ yopE mutants were only slightlyattenuated after oral infection since they were still able tocolonize the spleen and liver and cause systemic infection.The ${Delta}$ yopO mutant was lethal for mice, whereas ${Delta}$ yopP and ${Delta}$ yopE mutantswere successfully eliminated from the spleen and liver 2 weeksafter infection. In contrast the ${Delta}$ yopH, ${Delta}$ yopM, and ${Delta}$ yopQ mutantswere highly attenuated and not able to colonize the spleen andliver on any of the days tested. The ${Delta}$ yopH, ${Delta}$ yopO, ${Delta}$ yopP, ${Delta}$ yopE, ${Delta}$ yopM, and ${Delta}$ yopQ mutants had only modest defects in the colonizationof the small intestine and Peyer's patches. The ${Delta}$ yopE mutantwas eliminated from the small intestine 3 weeks after infection,whereas the ${Delta}$ yopH, ${Delta}$ yopP, ${Delta}$ yopM, and ${Delta}$ yopQ mutants continued tocolonize the small intestine at this time.

INTRODUCTION

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Introduction

Yersiniae that are pathogenic to humans include Yersinia pestis,Y. pseudotuberculosis, and Y. enterocolitica. Y. pestis is thecause of bubonic plague, which is transmitted by fleas, whereasY. enterocolitica and Y. pseudotuberculosis cause self-limitedfood-borne gastrointestinal disease in humans. In the mousemodel of infection, however, both Y. enterocolitica and Y. pseudotuberculosiscause systemic disease. Common to all of these species is thepresence of a 70-kb virulence plasmid that harbors a type IIIsecretion system (TTSS) and several secreted and translocatedproteins called Yersinia outer proteins (Yops) (reviewed byCornelis [17]). This plasmid-encoded TTSS enables yersiniaeto survive and proliferate extracellularly in host lymphatictissues. Y. enterocolitica and Y. pseudotuberculosis both translocatea set of at least five effector proteins (YopH, YopO/YpkA, YopP/J,YopE, and YopM), whereas Y. enterocolitica is known to translocatea sixth effector called YopT (35). Four of the above-mentionedYops (YopH, YopE, YopT, and, YopO/YpkA) disturb cytoskeletaldynamics and thereby inhibit phagocytosis by polymorphonuclearleukocytes and macrophages (12, 23, 28, 49). YopH is a phosphotyrosinephosphatase (61) that dephosphorylates focal adhesion kinase(Fak), paxillin, Fyn-binding protein (FYB), p130^cas, and SKAP-HOM,thereby disrupting focal adhesions (2, 10, 11, 16, 29, 46, 47),and suppresses the oxidative burst of macrophages (12, 47).YopH has been shown to contribute not only to evasion of theinnate immune response but also to the adaptive immune responseby impairing T- and B-cell activation (1, 60). YopE is a GTPase-activatingprotein that acts preferentially on Rac GTPases, which may explainthe YopE-associated effect of actin stress fiber destruction(9, 44, 50). YopT is a cysteine protease that preferentiallyinactivates RhoA GTPases by cleaving at the C-terminal geranylgeranyl-cysteineresidue (52, 62). YopO (YpkA in Y. pseudotuberculosis) is anautophosphorylating serine/threonine kinase that interacts withRhoA, Rac and actin (6, 22, 62). YopP/J induces apoptosis ofmacrophages and inhibits activation of the transcription factorNF- ${kappa}$ B, thereby inhibiting tumor necrosis factor alpha and interleukin-8release by macrophages and epithelial cells (14, 19, 20). YopMis a leucine-rich repeat protein that traffics to the nucleusof infected cells (54), but its target and function are as yetunknown. Recently, it was shown that YopM forms a protein complexwith the two cellular kinases PRK2 and RSK1 (39). YopQ (YopKin Y. pseudotuberculosis) is not one of the translocated effectorproteins but has been shown to control the translocation ofYop effectors into eukaryotic cells with a yopK mutant hypertranslocatingYops and inducing a larger YopB-dependent pore in eukaryoticcell membranes (33).

Virulence of Yersinia yop mutants has been previously studiedmostly in Y. pseudotuberculosis. It is, however, not possibleto generally extrapolate these results to Y. enterocoliticasince many differences in virulence factor profile and clinicalmanifestations exist between the two species. Mutations in yopH,ypkA, yopJ, yopE, yopM, and yopK of Y. pseudotuberculosis serotypeIII have been shown to result in various degrees of attenuation(13, 15, 24, 27, 34, 37, 38, 42). In most cases, the 50% lethaldose was determined in order to assess virulence. Several studiesalso analyzed colonization of mouse tissue after oral infection(9, 26, 27, 34, 42, 55). However, comparison of data is difficultbecause different inbred mouse strains, different strains ofYersinia, and different infection doses and routes of applicationwere used.

The influence of the complete set of Yops on virulence of Y.enterocolitica in the mouse model has been only partially studied(35, 43) with Y. enterocolitica of serotype O:9. This serotypeis only weakly pathogenic for mice (due to lack of the highpathogenicity island encoding the biosynthesis and uptake ofthe siderophore yersiniabactin [ybt] which contributes to mousevirulence), and therefore mice have to be pretreated with aniron chelator such as desferrioxamine, which not only promotesgrowth of yersiniae by iron delivery via ferrioxamine uptakebut also leads to immunosuppression of the host (5). We generatedhere a set of yop deletion mutants of Y. enterocolitica of thehighly pathogenic O:8 serotype WA-314 (biotype 1B) by the recentlyreported Red recombination procedure (18) and studied the pathogenicityof these mutants and the course of colonization of the smallintestine (SI), Peyer's patches (PP), liver, and spleen over3 weeks after intravenous and oral infection of C57BL/6 mice.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and plasmids. The bacterial strains and plasmids used in the present studyare listed in Table 1. Bacteria were cultured aerobically inLuria-Bertani (LB) broth or on LB agar plates (Difco Laboratories,Detroit, Mich.) at 27°C (Yersinia spp.) or 37°C (Escherichiacoli). Antibiotics were used at the following concentrations:kanamycin, 25 µg/ml; nalidixic acid, 60 µg/ml; andchloramphenicol, 20 µg/ml.

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TABLE 1. Bacterial strains and plasmids

Nucleic acid manipulations. Plasmid DNA was isolated with Qiagen kits (Hilden, Germany)according to the manufacturer's recommendations. Restrictionenzyme digestions, recovery of DNA fragments from agarose gels,ligations, and transformations were performed as previouslydescribed (3). Enzymes and deoxynucleoside triphosphates werepurchased from Invitrogen (Karlsruhe, Germany). High-fidelitypolymerase was obtained from Roche (Mannheim, Germany). Oligonucleotideswere synthesized by Thermo (Ulm, Germany).

Red cloning. We generated stable Y. enterocolitica Yop mutants by using the ${lambda}$ phage recombinases Red ${alpha}$ and Redß as previously describedfor E. coli (18). Recombinases were expressed directly in Yersinia.For this purpose, we transformed WA-314 with plasmid pKD46 harboringrecombinases red ${alpha}$ and redß, as well as red ${gamma}$ , an inhibitorof bacterial exonucleases. Yersiniae were grown overnight at27°C, diluted 1:100, and grown to exponential phase in LBmedium containing 0.1% arabinose to induce the expression ofrecombination functions. Yersiniae were made electrocompetentand frozen at –80°C. Recombination fragments consistingof an antibiotic resistance gene with its own promoter, flankedby 50-nucleotide (nt) homology arms, were generated by PCR.The 3'-end 21 nt of each primer were designed to amplify thekanamycin resistance (Kan^r) cassette from pACYC177 (forward,5-TCACTGACACCCTCATCAGTG-3'; reverse, 5'-CGTCAAGTCAGCGTAATGCTC-3')or the chloramphenicol resistance (Cm^r) cassette from pACYC184(forward, 5'-TGACGGAAGATCACTTCGCAG-3'; reverse, 5'-TTGAGAAGCACACGGTCAC-3'),whereas the 5' end of each primer contained the 50-nt homologyarms. These were designed so that the entire coding region ofeach yop gene (yopH, -O, -P, -E, and -T) would be replaced bythe antibiotic resistance marker. Homology arms were derivedfrom the sequence of pYVa127/90 (GenBank accession number NC_004564)(25). The ${Delta}$ yopQ mutant used for virulence experiments harborsthe first 50 amino acids of YopQ. The ${Delta}$ yopM mutant was constructedby ligating a PstI-restricted 1.2-kb Kan^r cassette cut frompUK4k into the NsiI site of the yopM gene, which was clonedinto the suicide vector pGPCAT. Mutagenesis was performed aspreviously described (58). WA-C(pYV::CM) was constructed byinserting a Cm^r cassette amplified from pACYC184 into the noncodingregion of the pYV plasmid, upstream of yadA, by the Red cloningprocedure. This strain was shown to be as virulent as the unmarkedparental strain WA-314 (results not shown). All mutated pYVconstructs were transferred to a plasmidless WA-C strain. Allstrains were passaged through mice before virulence experimentswere performed by intraperitoneal infection with 10⁸ CFU andreisolation of yersiniae from the peritoneum after 20 h.

Analysis of Yop secretion. Secretion of Yop proteins was induced as previously described(57). Yersiniae were grown overnight in LB medium at 27°C,diluted 1:40 in brain heart infusion broth (Difco), and incubatedfor 2 h at 37°C. Yop expression and/or secretion was inducedby the addition of EGTA (5 mM) for Ca²⁺ chelation, MgCl₂ (15mM), and glucose (0.2%). Bacteria were grown at 37°C for2 to 3 h and centrifuged (10,000 x g, 15 min), and proteinswere precipitated from the culture supernatant with trichloroaceticacid. Released proteins were separated by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) (36) on an 11.5% polyacrylamidegel and then stained with Coomassie blue. Immunoblotting wasperformed as described previously (31) with nitrocellulose sheets(Schleicher & Schuell). Blocking was performed overnightwith 5% bovine serum albumin in phosphate-buffered saline (PBS)at 4°C. Polyclonal rabbit anti-YopO, anti-YopQ, and anti-YopT(1:5,000) antisera, as well as a horseradish peroxidase-conjugatedsecondary antirabbit antibody (Sigma) diluted 1:5,000, wereused for immunostaining.

Mouse infections. Six- to eight-week-old female C57BL/6 mice (Harlan, Winkelmann,Germany) were infected with 10⁸ CFU orally or 4 x 10⁴ CFU intravenouslyfrom frozen stock suspensions. Stock suspensions were preparedby growing bacteria to stationary phase in LB medium at 27°C,followed by freezing in 15% glycerol. After appropriate dilutions,bacteria were washed twice with PBS, and mice were fed 50 µlby using a microliter pipette, or 100 µl was injectedinto the lateral tail vein. Mice were subjected to fasting 16h prior to oral infection. The actually administered dose wasdetermined by plating serial dilutions on Mueller-Hinton agarfor 36 h at 27°C. Mice were sacrificed by CO₂ asphyxiation.Liver, spleen, and PP were aseptically removed and homogenizedin 5 ml (liver) or 1 ml (spleen and PP) PBS. PP were washedto remove loosely attached bacteria by rinsing them with 2 mlof PBS. The SI was washed with 5 ml of ice-cold PBS. To determinethe numbers of CFU/organ, serial dilutions of homogenates wereplated on Yersinia selective CIN agar (BD Biosciences, Heidelberg,Germany). P values were determined by using a two-tailed, unpairedStudent t test. P values of <0.05 were considered significant.For the competition experiment, a two-tailed paired Studentt test was used.

RESULTS

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Results

Generation of stable Yop mutants by Red cloning. Yersinia yop mutants were generated by replacing the codingregion of each yop by a Kan^r cassette. This was accomplishedby Red ${alpha}$ - and Redß-mediated homologous recombinationbetween the pYV plasmid and a PCR product consisting of theKan^r resistance gene flanked by 50-nt homology arms. Correctreplacement of the respective yop genes by the Kan^r cassettewas verified by PCR and SDS-PAGE of secreted Yop proteins andWestern blotting (Fig. 1). To rule out any unwanted recombinationin the chromosome due to the action of Red ${alpha}$ and Redß,we transferred all mutated plasmids to the previously pYV-curedstrain WA-C. Furthermore, we checked that no unwanted recombinationin the mutant pYV plasmids had taken place by restriction endonucleasedigestion of the resulting ${Delta}$ yop-pYV plasmids with HindIII andBamHI (results not shown). Two of the mutants ( ${Delta}$ yopQ and ${Delta}$ yopM)generated by replacement of the entire coding region with aKan^r cassette turned out to be deregulated when grown at 37°C(temperature-sensitive phenotype) and consequently unable tocolonize any mouse tissue after oral infection. Therefore, toperform virulence studies, we generated another ${Delta}$ yopQ mutantby Red cloning, sparing the first 50 amino acids of YopQ. Thismutant did not show a growth deficit at 37°C. For yopM weused a mutant that we had already constructed by the suicidevector approach. This mutant harbors a 1.2-kb Kan^r cassetteat nt 661, expresses a truncated version of YopM of $~$ 25 kDa (verifiedby Western blotting), and shows Ca²⁺- and temperature-dependentgrowth like that of the wild type.

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FIG. 1. (A) Coomassie blue-stained SDS-PAGE gel showing secreted proteins of WA-C(pYV::CM) (wild type [WT], lane 1) and ${Delta}$ yop mutants (lanes 2 to 9) precipitated from the culture supernatant. (B) Western blot of secreted proteins from culture supernatant of WA-C(pYV::CM) [WT, lane 1] and WA-C(pYV ${Delta}$ T) ( ${Delta}$ T, lane 2) with a rabbit anti-YopT polyclonal antibody.

Course of colonization and persistence after oral infection. Groups of six C57BL/6 mice were orally infected with 10⁸ CFUof each ${Delta}$ yop mutant (WA-C(pYV ${Delta}$ Yop) and WA-C(pYV::CM). The courseof colonization was determined by counting the surviving bacteriain the liver, spleen, PP, and SI on days 2, 5, 7, 12, and 21postinfection by plating tissue homogenates (Fig. 2 and 3).Two days after oral infection, all mutants ( ${Delta}$ yopH, ${Delta}$ yopO, ${Delta}$ yopP, ${Delta}$ yopE, ${Delta}$ yopM, ${Delta}$ yopT, and yopQ) and WA-C(pYV::CM) were able to efficientlycolonize the SI and PP, with ${Delta}$ yopH, -O, -P, -E, -M, and -Q mutantsshowing only moderate defects in colonizing these tissues. Thecourse of infection with WA-C(pYV::CM), as well as the ${Delta}$ yopO, ${Delta}$ yopP, ${Delta}$ yopE, and ${Delta}$ yopT mutants, was progressive, with bacteriadisseminating systemically and forming abscesses in livers andspleens by day 5. By this time all mice infected with thesemutants showed severe signs of illness. The ${Delta}$ yopH, ${Delta}$ yopM, and ${Delta}$ yopQ mutants, on the other hand, were highly attenuated andwere not able to significantly colonize spleens and livers onany of the days tested (limit of detection of 10 CFU in thespleen and 50 CFU in the liver). By day 7, the ${Delta}$ yopT, ${Delta}$ yopO, ${Delta}$ yopE,and ${Delta}$ yopP mutants showed the highest colony counts in spleensand livers, with most mice infected with WA-C(pYV::CM), ${Delta}$ yopT,and ${Delta}$ yopO mutants dying between days 7 and 12 due to systemicinfection and high bacterial load in organs (Fig. 3). The ${Delta}$ yopEand ${Delta}$ yopP mutants were, however, successfully eliminated fromspleens and livers by day 12. Furthermore, ${Delta}$ yopP, ${Delta}$ yopE, ${Delta}$ yopM,and ${Delta}$ yopQ mutants were still able to colonize the SI and PP bythis time. The ${Delta}$ yopH mutant was able to colonize only the SIbut had been eliminated from the PP by this time. At 3 weeksafter infection, ${Delta}$ yopH, ${Delta}$ yopM, and ${Delta}$ yopQ mutants were able to colonizethe lumen of the SI only, whereas the ${Delta}$ yopP mutant continuedto colonize both the SI and the PP. To demonstrate that attenuationof our mutants was not due to polar effects caused by the Kan^rcassette, we complemented the most highly attenuated mutant( ${Delta}$ yopH) with a low-copy plasmid (pACYC184) harboring yopH andsycH under their natural promoters (57). At 5 days after oralinfection, this strain was able to colonize the spleens andlivers of infected mice to an extent comparable to WA-C(pYV::CM)(Fig. 4).

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FIG. 2. Time course of colonization and persistence of Y. enterocolitica ${Delta}$ yop mutants and WA-C(pYV::CM) after oral infection of C57BL/6 mice with 10⁸ CFU. Two (A), five (B), seven (C), twelve (D), and twenty-one (E) days after infection, surviving bacteria in the SI (), PP ( ${square}$ ), spleen ( ${blacksquare}$ ), and liver () were determined. Values represent the average log CFU per organ for six mice with the standard errors of the means indicated by error bars. The limits of detection were 10 CFU/organ for PP and spleen and 50 CFU/organ for liver and SI. A "+" indicates that the strain was lethal for mice. Asterisks indicate statistical significance (P $≤$ 0.05) between colonization of WA-C(pYV::CM) and the mutants.

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FIG. 3. Colonization and persistence in spleens over 3 weeks by Y. enterocolitica ${Delta}$ yop mutants and WA-C(pYV::CM) after oral infection of C57BL/6 mice with 10⁸ CFU. Asterisks indicate death of mice between days 7 and 12 postinfection. ${Delta}$ yopQ, -H, and -M mutants were below the limit of detection (10 CFU/organ). Values indicate the average log CFU per organ for six mice.

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FIG. 4. Colonization of spleens, livers, PP, and SIs of C57BL/6 mice after oral infection with 10⁸ CFU of WA-C(pYV ${Delta}$ YopH) ( ${blacksquare}$ ), WA-C(pYV ${Delta}$ YopH+H) ( ${square}$ ), and WA-C(pYV::CM) () on day 5 postinfection.

Virulence of yop mutants after intravenous infection. Groups of five C57BL/6 mice were infected with 4.5 x 10⁴ CFUof the ${Delta}$ yop mutants and WA-C(pYV::CM). Surviving bacteria inlivers and spleens were determined on days 2 and 4 postinfection(Fig. 5). WA-C(pYV::CM) showed high colony counts in spleensand livers on day 2 (6.53 ± 0.40 and 4.88 ± 0.37log CFU) with infection progressing by day 4 (8.33 ±0.54 and 5.73 ± 0.32 log CFU). The ${Delta}$ yopH mutant was themost highly attenuated mutant, with a 2,100-fold reduction inCFU compared to WA-C(pYV::CM) by day 2. The colony counts were100-fold lower for ${Delta}$ yopQ and 13-fold lower for ${Delta}$ yopM, whereasthe ${Delta}$ yopE and ${Delta}$ yopP mutants (4.7-fold and 2-fold, respectively)were not dramatically attenuated compared to the parental strain(P > 0.05). The ${Delta}$ yopT mutant, on the other hand, colonizedthe spleen to a sevenfold-greater extent on day 2 than did WA-C(pYV::CM).By day 4, infection had progressed for the WA-C(pYV::CM), ${Delta}$ yopO, ${Delta}$ yopT, ${Delta}$ yopM, ${Delta}$ yopE, and ${Delta}$ yopP mutants, showing 63-, 229-, 18-,17-, 4.3-, and 4-fold-higher CFU counts, respectively, in thespleen than on day 2, whereas the CFU counts in the spleensof mice infected with the ${Delta}$ yopH mutant dropped 40-fold. By day4 the colony counts in spleens were 219,000-fold lower for the ${Delta}$ yopH mutant than for WA-C(pYV::CM), 6,300-fold lower for the ${Delta}$ yopQ mutant, 50-fold lower for the ${Delta}$ yopM mutant, and 63-foldlower for the ${Delta}$ yopE and ${Delta}$ yopP mutants. The ${Delta}$ yopO mutant showedslightly fewer CFU in the spleen (2.7-fold) but more CFU inthe liver (3.2-fold), which was significant only for the liver.The ${Delta}$ yopT mutant showed higher CFU counts in spleens (1.4-fold)and livers (28-fold) than WA-C(pYV::CM), values that were statisticallysignificant only for livers (P < 0.05). Generally, the CFUcounts of the yop mutants and WA-C(pYV::CM) in the livers ofinfected mice were 10- to 100-fold lower than the CFU countsin the spleens except for the ${Delta}$ yopH and ${Delta}$ yopQ mutants on day 4,which showed comparable numbers of bacteria in the liver andspleen.

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FIG. 5. Colonization of spleen ( ${blacksquare}$ ) and liver ( ${square}$ ) of C57BL/6 mice 2 (A) and 4 (B) days after intravenous infection with 4 x 10⁴ CFU of the indicated Y. enterocolitica ${Delta}$ yop mutants and WA-C(pYV::CM). Each bar represents the mean log CFU for five mice. Asterisks indicate statistical significance between colonization of the ${Delta}$ yop mutants and of the WA-C(pYV::CM) (P $≤$ 0.05).

The ${Delta}$ yopT mutant outcompetes WA-C(pYV::CM). The oral and intravenous infections suggested that the ${Delta}$ yopTmutant was slightly more virulent than the wild-type strain.To confirm this, we infected six mice with an equal mixture(10⁸ CFU) of WA-C(pYV::CM ${Delta}$ YopT) and WA-C(pYV::CM) by the intravenousroute. Two days later, the mice were killed, and serial dilutionsof organs were plated on kanamycin (for selection of the ${Delta}$ yopTmutant) and chloramphenicol [for selection of WA-C(pYV::CM)]plates. The ${Delta}$ yopT mutant showed a mean log of 4.23 ± 0.99CFU in the liver, whereas WA-C(pYV::CM) showed a mean log of3.05 ± 1.03 CFU. Therefore, the ${Delta}$ yopT mutant outcompetedWA-C(pYV::CM) by 1.18 log CFU (P = 0.0075). No such differencecould be detected for the spleens of mice, with the ${Delta}$ yopT mutantshowing a mean log of 6.61 ± 0.36 CFU and WA-C(pYV::CM)showing a mean log of 6.49 ± 0.34 CFU.

DISCUSSION

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Discussion

The objective of this study was to systematically analyze thecontribution of seven Yops of Y. enterocolitica O:8, one ofthe highly virulent serotypes of biotype IB (New World strains),to virulence by using the same inbred mouse strain, the sameroute of application, and the same dose of bacteria. Althoughseveral studies have dealt with the effects of Yops on virulence,most of these were performed for Y. pseudotuberculosis serotypeIII, which differs considerably in virulence factor repertoire(e.g., lacking yersiniabactin) and clinical manifestations fromY. enterocolitica. This is exemplified by one study showingthat even a plasmidless Y. pseudotuberculosis strain is ableto multiply in the spleen after intravenous infection or tosurvive in human serum, whereas plasmid-cured Y. enterocoliticais rapidly eliminated from this organ or killed by serum (53,59). Most importantly for the present study, Y. enterocoliticaharbors the TTSS effector YopT, which is usually absent in Y.pseudotuberculosis (35), and several differences in a multitudeof other virulence factors exist between the different Yersiniastrains, e.g., YopP from Y. enterocolitica O:8 is substantiallymore efficient in suppressing the NF- ${kappa}$ B pathway and mediatingapoptosis than serotype O:9 (51). Invasin-mediated uptake efficiencyin cell culture is much higher for Y. pseudotuberculosis thanfor Y. enterocolitica (21, 40). YadA and its collagen-bindingpotential are required for virulence in Y. enterocolitica butnot in Y. pseudotuberculosis (45, 56). Furthermore, differencesin serum resistance between the two species have been detected(59), and it has been reported that Y. pseudotuberculosis ismore resistant to bactericidal cationic peptides (8) and showsincreased outer membrane permeability to hydrophobic agentscompared to Y. enterocolitica (7). It is therefore not justifiedto generally extrapolate mouse virulence studies obtained withY. pseudotuberculosis to Y. enterocolitica.

The study of virulence in the mouse infection model with a naturallyhigh-pathogenicity-island-negative Y. enterocolitica of serotypeO:9 and O:3 is further complicated by the fact that mice haveto be pretreated with desferrioxamine B (DFO) to achieve mousevirulence, and this pretreatment may influence pathogenicitybecause of the immunosuppressive effect of DFO (4). The virulenceof yopQ and yopM (43) mutants in the mouse model was previouslystudied by using Y. enterocolitica O:9. Both mutants were shownto be attenuated after intravenous infection of mice pretreatedwith DFO. Both mutants were able to colonize spleens and liversof Swiss mice for at least 4 days at reduced levels comparedto the wild-type strain. We were able to confirm these resultshere and extend them to the oral infection model, showing forthe first time that both of these mutants are highly attenuatedand able to colonize only the SI and PP but are not able todisseminate to the spleens and livers of orally infected mice. ${Delta}$ yopQ and ${Delta}$ yopM mutants were able to colonize PP for 2 and SIfor 3 weeks but the numbers were somewhat lower than for WA-C(pYV::CM).These oral infections are consistent with studies of a yopKmutant in Y. pseudotuberculosis (34). YopQ fine-tuning of translocationor gating of the YopB-induced pore might be essential for effectiveimmunosuppression of the host and systemic spread of yersiniaeas proposed by Holmström et al. (33). Oral infections with ${Delta}$ yopM mutants have not been performed previously. Together withthe intravenous infections, our results indicate that YopM andYopQ are mainly involved in the establishment of a systemicinfection in mice.

The virulence of ${Delta}$ yopH, ${Delta}$ yopO, ${Delta}$ yopP, and ${Delta}$ yopE mutants has beenpreviously studied only for Y. pseudotuberculosis. The moststriking difference between the virulence of our mutants andthat of Y. pseudotuberculosis is that our ${Delta}$ yopE mutant is onlyslightly attenuated after oral infection and caused systemicdisease with regular seeding of yersiniae to spleens and livers.Furthermore, our ${Delta}$ yopE mutant was able to colonize the SI andPP at somewhat reduced levels until day 12 postinfection. Y.pseudotuberculosis yopE mutants, on the other hand, were reportedto be highly attenuated, being cleared from PP within 4 daysand not able to reach the spleens of orally infected mice (34).These differences could be due to the use of a yadA yopE doublemutant in that study (34). Another study using Y. pseudotuberculosisshowed a markedly reduced ability of yopE mutants to colonizespleens of mice but only minor defects in colonizing the SIand PP (38). Possibly, the additional presence of YopT in Y.enterocolitica could also account for the more virulent phenotypeof our yopE mutant since both of these Yops act on Rho GTPasesand are involved in the inhibition of phagocytosis. Presumably,a ${Delta}$ yopT ${Delta}$ yopE double mutant of Y. enterocolitica is comparableto a yopE mutant of Y. pseudotuberculosis.

Our ${Delta}$ yopO and ${Delta}$ yopT mutants behaved most like WA-C(pYV::CM) afteroral and intravenous infections, and in fact most mice succumbedto oral infection with these mutants at around day 7 just likethe parental strain. For a yopO mutant, this is consistent witha recent study with Y. pseudotuberculosis (38) but contrastswith another (27) in which a ${Delta}$ yopO mutant failed to cause a systemicinfection. The mutant used in the latter study, however, alsoharbored a mutation in yadA, which could have had an effecton colonization of the spleen. There is only scarce evidencefor the role of YopT in animal models, with one preliminarystudy showing that a yopT mutant was not affected in its capacityto colonize PP on day 2 after oral infection (35). Surprisingly,our yopT mutant was not attenuated and even showed higher colonizationof mouse tissues after oral and intravenous infection than WA-C(pYV::CM).This is a surprising finding in light of the fact that YopTand YopO have a strong influence on phagocytosis resistancein cell culture models (28). YopO binds RhoA and Rac and YopTmodifies RhoA and presumably Rac, which may also change bindingproperties to YopO. Possibly, YopT is redundant in this animalmodel, and its functions are taken over by other Yops, suchas YopO and YopE. Another possibility is that the functionsof these effector proteins become apparent only after severalweeks of infection, when the adaptive immune system becomeseffective. Since C57BL/6 mice succumb to infection after 1 week,it is not possible to study these effects in this model. Weare therefore generating double mutants for yopT and other yopgenes to test this hypothesis.

Our yopP mutant colonized gut tissues, as well as spleens andlivers, at reduced levels but was not impaired in its abilityto cause systemic disease, with bacteria regularly colonizingthe livers and spleens of all mice after oral infection. Byday 12 most mice had eliminated bacteria from spleens and livers,but colonization of gut tissues continued for at least 3 weeks.The role of yopJ in virulence has been previously studied onlyfor Y. pseudotuberculosis. One study claims yopJ to be dispensablefor virulence (27), and another shows that a yopJ mutant ishighly attenuated, with only two of three PP and one of fivespleens being colonized after oral infection (42). These differencescould be due to the different Yersinia species used, the differentmouse strains used, or different doses of applied bacteria.

Our ${Delta}$ yopH mutant was by far the most attenuated mutant in bothoral and intravenous infections. ${Delta}$ yopH mutants were only slightlydeficient in colonizing the SI and PP initially and were notable to disseminate and cause systemic disease. ${Delta}$ yopH mutantswere eliminated from the PP by day 12, earlier than the othersurviving yop mutants, but colonization of the gut lumen continuedfor at least 3 weeks. Intravenous infections showed that the ${Delta}$ yopH mutant initially implants into spleens and livers, butcolony counts dramatically decrease between days 2 and 4. Thisindicates that YopH plays important roles in PP, as well asduring the systemic stage of disease.

In summary, the ${Delta}$ yopH, ${Delta}$ yopO, ${Delta}$ yopP, ${Delta}$ yopE, ${Delta}$ yopM, and ${Delta}$ yopQ mutantshad only modest defects in colonization of the SI and PP. Thisis consistent with results obtained for Y. pseudotuberculosis(38) and indicates that no single effector Yop is absolutelynecessary for colonizing the SI or translocating to the underlyingPP. YopH, YopQ, and YopM of Y. enterocolitica are importantvirulence factors for inducing systemic disease in mice, whereasYopO, YopP, and YopE are dispensable for yersiniae to reachthe spleen and liver. The presence of YopT on the other handeven seems to slightly decrease virulence of Y. enterocoliticain this model.

ACKNOWLEDGMENTS

We thank Laryssa Teplytska for excellent technical assistance.

This study was supported by Deutsche ForschungsgemeinschaftDFG (SFB 1887 and Graduiertenkolleg "Infektion und Immunität").J.H. and H.R. were supported by the Deutsche Forschungsgemeinschaft(priority program "novel vaccination strategies"; HE1297/9-2and RU838/1-2).

FOOTNOTES

* Corresponding author. Mailing address: Max von Pettenkofer-Institut, Universität München, Pettenkoferstr. 9a, 80336 Munich, Germany. Phone: 49-89-5160-5279. Fax: 49-89-5160-5223. E-mail: truelzsch{at}m3401.mpk.med.uni-muenchen.de.

Editor: J. B. Bliska

REFERENCES

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