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Role of the Salmonella Pathogenicity Island 1 Effector Proteins SipA, SopB, SopE, and SopE2 in Salmonella enterica Subspecies 1 Serovar Typhimurium Colitis in Streptomycin-Pretreated Mice

Institute of Microbiology, ETH Zürich, CH-8092 Zürich, Switzerland,¹ Institute of Pathology, Technische Universität München, D-81675 Munich, Germany²

Received 10 July 2003/ Returned for modification 8 September 2003/ Accepted 12 November 2003

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Salmonella enterica subspecies 1 serovar Typhimurium (serovar Typhimurium) induces enterocolitis in humans and cattle. The mechanisms of enteric salmonellosis have been studied most extensively in calf infection models. The previous studies established that effector protein translocation into host cells via the Salmonella pathogenicity island 1 (SPI-1) type III secretion system (TTSS) is of central importance in serovar Typhimurium enterocolitis. We recently found that orally streptomycin-pretreated mice provide an alternative model for serovar Typhimurium colitis. In this model the SPI-1 TTSS also plays a key role in the elicitation of intestinal inflammation. However, whether intestinal inflammation in calves and intestinal inflammation in streptomycin-pretreated mice are induced by the same SPI-1 effector proteins is still unclear. Therefore, we analyzed the role of the SPI-1 effector proteins SopB/SigD, SopE, SopE2, and SipA/SspA in elicitation of intestinal inflammation in the murine model. We found that sipA, sopE, and, to a lesser degree, sopE2 contribute to murine colitis, but we could not assign an inflammation phenotype to sopB. These findings are in line with previous studies performed with orally infected calves. Extending these observations, we demonstrated that in addition to SipA, SopE and SopE2 can induce intestinal inflammation independent of each other and in the absence of SopB. In conclusion, our data corroborate the finding that streptomycin-pretreated mice provide a useful model for studying the molecular mechanisms of serovar Typhimurium colitis and are an important starting point for analysis of the molecular events triggered by SopE, SopE2, and SipA in vivo.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Salmonella enterica is frequently isolated from wildlife and livestock and can cause diseases ranging from mild gastroenteritis to systemic infections. Humans are usually infected by consumption of contaminated animal products. S. enterica subspecies 1 serovar Typhimurium (serovar Typhimurium) infections are among the leading causes of bacterial food poisoning in industrialized countries. Interestingly, an S. enterica serovar can cause different diseases in different animal species (45, 47). For example, serovar Typhimurium causes a self-limiting enterocolitis in cattle and humans but a typhoid-like systemic infection in susceptible mouse strains.

Serovar Typhimurium employs a multitude of virulence factors to colonize and replicate within the host. These factors include a large array of adhesins, superoxide dismutases, flagella, resistance to complement and antimicrobial peptides, and two type III secretion systems (TTSS) (12, 19). These TTSS have attracted much attention because they enable bacteria to inject effector proteins directly into the host cell cytoplasm, where the proteins manipulate host cell signaling (14). Both S. enterica TTSS have been characterized extensively in susceptible mice (40). The TTSS encoded in Salmonella pathogenicity island 1 (SPI-1) plays a small but detectable role in breaching the intestinal epithelium, while the SPI-2 TTSS is essential for replication within phagocytic cells and systemic infection (21). Nevertheless, due to the absence of any apparent intestinal inflammation comparable to enteric salmonellosis in humans, this animal model has yielded little information about the pathological mechanisms of serovar Typhimurium enterocolitis. Therefore, bovine infection models have been established in recent years. In the bovine models, serovar Typhimurium causes pronounced enterocolitis which is thought to mimic the human disease closely. Type III secretion via the SPI-1 TTSS (14, 40, 48) and to some extent type III secretion via the SPI-2 TTSS (3) play an important role in the induction of enterocolitis. Recently, the SPI-1 TTSS effector proteins SipA, SopA, SopB, SopD, SopE, and SopE2 were found to affect fluid secretion and inflammation in the bovine intestine, as determined by oral infection and ligated ileal loop assays (27, 35, 51, 53, 54).

Several SPI-1 effector proteins have been characterized biochemically. SipA binds actin and has a nebulin-like function. It catalyzes actin polymerization and bundling of actin filaments and is required for efficient invasion of tissue culture cells (15, 24, 57, 58). In line with its role in bovine enterocolitis (54), SipA has been identified as a key SPI-1 effector protein for inducing polymorphonuclear granulocyte (PMN) migration across intestinal epithelial cell monolayers (30).

SopE and SopE2 are approximately 70% identical at the amino acid level and act as G-nucleotide exchange factors for host cellular Rho GTPases (1, 4, 22, 37, 41, 52). These proteins have differential preferences for different members of the Rho GTPase family (13), and both of them play a role in host cell invasion. In the case of SopE it has been demonstrated that the activation of host cellular Rho GTPases leads not only to cytoskeletal rearrangements but also to activation of signaling cascades which trigger cytokine production (5, 22).

SopB contains two motives common to inositol polyphosphatases and has profound effects on inositol and phosphatidylinositol levels in host cells (35, 43, 55, 56). Due to its broad spectrum of substrate specificity, the identity of the relevant substrate(s) in vivo and therefore its exact molecular function(s) in pathogenesis are still a matter of discussion. SopB has been found to affect cytoskeletal rearrangements and host cell invasion (26, 33, 43, 55), to mediate phospholipase C activation (55), to facilitate membrane fission (43), to affect chloride homeostasis (11, 35), and to inhibit nuclear mRNA export (11). Experiments with transiently transfected cells or stable cell lines expressing sopB demonstrated that SopB alone is sufficient to induce cytoskeletal rearrangements, to modulate membrane elasticity and chloride homeostasis, and to inhibit nuclear mRNA export (11, 43, 55). Although SopB cooperates with several other effector proteins during host cell infection, these observations indicate that SopB alone is capable of manipulating host cell signaling.

Molecular analysis of effector protein function has revealed how serovar Typhimurium manipulates host cell signaling. However, it is still not clear how the effects translate into an inflammatory response during the course of a real infection. To investigate this, a mouse model for serovar Typhimurium colitis was recently established (2). Upon oral infection with serovar Typhimurium, streptomycin-pretreated mice develop pronounced colitis on top of the well-known systemic infection. The intestinal inflammation develops within 8 to 20 h postinfection (p.i.) and is strongly dependent on the SPI-1 TTSS. This suggests that streptomycin-pretreated mice provide a versatile animal model to study how serovar Typhimurium induces intestinal inflammation. However, the SPI-1 effector proteins required for the initiation of serovar Typhimurium colitis in streptomycin-pretreated mice have not been identified thus far. Identification of these effectors is of considerable interest because streptomycin-mediated diminution of the intestinal microflora most likely affects the intestinal environment, and environmental signals are known to have a great impact on the expression of Salmonella virulence factors like the SPI-1 TTSS (6, 18, 21). Therefore, it was desirable to compare the effects of specific SPI-1 effector proteins in serovar Typhimurium colitis in streptomycin-pretreated mice with the effects observed in bovine models.

In this study, we identified the SPI-1 effector proteins required for initiation of serovar Typhimurium colitis in streptomycin-pretreated mice. We characterized serovar Typhimurium mutants lacking single or multiple effector proteins in terms of virulence in vivo and cell invasiveness in vitro. Our results are in line with previous studies in which the bovine models were used and corroborate the conclusion that streptomycin-pretreated mice are useful surrogate hosts for studying serovar Typhimurium colitis, and provide the experimental basis for a detailed analysis of the pathogenetic functions of several important SPI-1 effector proteins.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Bacterial strains and growth conditions. Serovar Typhimurium strains were grown for 12 h at 37°C in Luria-Bertani (LB) broth containing 0.3 M NaCl, diluted 1:20 in fresh medium, and subcultured for 4 h with mild aeration. For infection experiments bacteria were washed twice in ice-cold phosphate-buffered saline (PBS) and suspended in cold PBS (10⁸ CFU/50 µl).

Serovar Typhimurium wild-type strain SL1344 (25) and the isogenic derivatives SB161 (invG) (28), SB225 (sipA::aphT) (29), SB566 (invC::aphT) (10), and SB757 (sopE::pSB1128) (23) were kindly provided by J. E. Galán. The serovar Typhimurium ATCC 14028s derivatives MvP101 (sseD::aphT) (31) and HH110 (ssaV::cat) (M. Hensel, unpublished data) were kindly provided by M. Hensel. Serovar Typhimurium wild-type strain IR715 (ATCC 14028s; nalidixic acid resistant [Nal^r]) (42) was provided by A. J. Bäumler.

The SL1344 derivatives used in this study were constructed by allelic exchange, which yielded in-frame deletions, and/or by phage P22-mediated transduction of antibiotic resistance marker-tagged mutant alleles. We used strains SB757, M200 (sopE2) (41), and MvP101 as donors for phage P22-mediated transduction of the mutant alleles sopE::pSB1128 (Amp^r), sopE2::pM218 (Tet^r), and sseD::aphT (Kan^r), respectively. Strains M556, M557, M704, and M708 were created by P22 phage transduction of the sseD::aphT allele into recipient strains SL1344, SB161, M509 (SL1344 sopB) (33), and M566 (SL1344 sopE sopE2 sopB sipA) (8a), respectively. Strain M719 was obtained by repeated phage transduction of sopE2::pM218, sopE::pSB1128, and sseD::aphT into strain SL1344. In-frame deletions of sopE and sipA were created by allelic exchange by using the suicide plasmids pM608 and pM585 (8a) (see below), respectively. In brief, the appropriate suicide vector was integrated into the serovar Typhimurium chromosome by single recombination, which yielded tetracycline-resistant exconjugants, and this was followed by a second recombination event forced by selection on sucrose agar. Strain M715 was constructed by in-frame deletion of sipA in the chromosome of SL1344 by using the suicide vector pM585 (8a), followed by phage transduction of sseD::aphT. Strain M722 was obtained by sequential phage transduction of sopE2::pM218 and sopE::pSB1128 into strain M715. Strain M716 was created by allelic exchange of sopE in the chromosome of M509 (SL1344 sopB) by using the suicide vector pM608 (8a), followed by phage transduction of the sseD::aphT allele. M707 was obtained by sequential in-frame deletion of sipA and sopE in the chromosome of M509 by using the suicide vectors pM585 and pM608, respectively, followed by phage transduction of sseD::aphT. M717 was constructed by in-frame deletion of sipA in the chromosome of M509 by using the suicide vector pM585, followed by sequential phage transduction of sseD::aphT and sopE2::pM218. For complementation analysis, the suicide plasmids pM706 and pM707 (described below) were integrated into the chromosome of M708 by single recombination, which yielded strains M732 and M734, respectively. These strains express sopE/sopE2 under control of the native chromosomal promoter (Fig. 1). The site of insertion of plasmids pM706 and pM707 was verified by PCR analysis by using the following primer pairs: primer 5'-CAATATCGCCACTTTCAACG plus primer 5'-GTACTAAGCTCTCATGTTTCACG and primer 5'-CGGGATCCTCTTGGCGCGTAGTCCTTC plus primer 5'-GTACTAAGCTCTCATGTTTCACG for pM706; and primer 5'-CTTAAAAGCAGCCATACAGAT plus primer 5'-GTACTAAGCTCTCATGTTTCACG, primer 5'-GCGCAGGCGTTTAGAAGACAGTT plus primer 5'-TGGCATAACCTCTCCTGACA, and primer 5'-AGAAGAACAAAATCCATCAGG plus primer 5'-GCGTTCCAGCATCAGCCACTTG for pM707. All strains were tested for invasiveness in tissue culture cells (COS7) and were compared to appropriate mutant strains.

View larger version (24K): [in this window] [in a new window]   FIG. 1. Schematic representation of the recombinational events leading to chromosomal vector integration in strains M732 and M734. The shaded areas indicate sequence identity in the plasmid and bacterial chromosome. Designations of the plasmids and Salmonella strains are indicated. The site of homologous recombination that resulted in chromosomal integration of a plasmid is indicated by X and was verified by PCR analysis (see Materials and Methods).

All gene disruptions and deletions were verified by PCR analysis and by Western blot analyses with rabbit polyclonal antisera directed against SopE (34) and SopE2 (41). The stability of the gene disruptions and the retention of plasmids during animal infection were verified by replica plating of the bacterial colonies obtained from intestinal contents and organs (see below).

Recombinant DNA techniques. Cloning of DNA fragments was performed by using standard protocols (38).

Construction of chromosomal in-frame deletions. To construct a suicide vector for deletion of sipA, the sequences located directly upstream (primers 5'-GCGGCCGCACCTGGGGTTGAGTCCTAC and 5'-TCTAGAAGGGGGCTGAGTCCTTACAC; 33 cycles of 92°C for 30 s, 53°C for 30 s, and 68°C for 3 min) and downstream (primers 5'-TCTAGAGGCCCGGCTTACGAGTC and 5'-CCCGGGACACCAAGGCACGAG; 33 cycles of 92°C for 30 s, 55°C for 30 s, and 72°C for 3 min) of the sipA coding sequence were amplified by PCR. The PCR products were cloned into pCR-BluntII-Topo (Invitrogen), which yielded pM582 and pM583. The insert of pM582 was cloned into the XbaI sites of pM583, which yielded pM584, and the resulting insert was subcloned into the SmaI/NotI sites of the suicide vector pSB890 (a derivative of pSB377; oriR6K Tet^r sacAB) (W.-D. Hardt and J. E. Galán, unpublished data), which yielded the suicide vector pM585, which was used for deletion of sipA.

To construct a suicide vector for deletion of sopE, we amplified the sequences located directly upstream (primers 5'-CGGGATCCTCTTGGCGCGTAGTCCTTC and 5'-GCTCTAGACACGGTAATGATCCTTTTATATGT; 33 cycles of 94°C for 30 s, 55°C for 30 s, and 72°C for 2 min) and downstream (primers 5'-GCTCTAGACCCTGAACACTGAAAAACCA and 5'-TTTGCGGCCGCGCACTGGATACGCTGAACGA; 33 cycles of 94°C for 30 s, 55°C for 30 s, 72°C for 2 min) of the open reading frame by PCR and cloned the PCR products into pBluescriptSKII+ (Stratagene), which yielded pM593 and pM606. The insert of pM606 was cloned by using XbaI/NotI into pM593, which yielded pM607, and the resulting insert was subcloned into the BamHI/NotI sites of pSB890, which yielded the suicide vector pM608.

To construct a suicide vector for deletion of sopE2, we amplified the sequences located directly upstream (primers 5'-CGGGATCCGCGCAGGCGTTTAGAAGACAGTT and 5'-GCTCTAGAAGTCACGGTAGTTCTCCTTTT; 33 cycles of 94°C for 30 s, 53°C for 30 s, and 72°C for 2 min) and downstream (primers 5'-GCTCTAGAAATGCCTCCTGATGGTAGTAA and 5'-GCGGCCGCGTTCCAGCATCAGCCACTTG; 33 cycles of 94°C for 30 s, 57°C for 30 s, and 72°C for 3.5 min) of the open reading frame by PCR and cloned the PCR products into pBluescriptSKII+ (Stratagene), which yielded pM559 and pM560. The insert of pM560 was cloned by uisng XbaI/NotI into pM559, which yielded pM581, and the resulting insert was subcloned into the BamHI/NotI sites of pSB890, which yielded the suicide vector pM586.

All PCR products and inserts were analyzed by sequencing.

Construction of complementation vectors. Plasmid pM706 is a suicide vector encoding the sopE promoter region and coding sequence. By single-crossover recombination into the sopE strain M708 this allows chromosomal complementation with a sopE gene under control of the native chromosomal promoter (Fig. 1). The insert of plasmid pSB1120 (Hardt and Galán, unpublished) containing the sopE coding sequence plus 985 bp of upstream sequence was subcloned into the SalI and XbaI sites of suicide vector pGP704 (Amp^r) (32), which yielded plasmid pM706. To construct the suicide vector pM707 for chromosomal complementation of sopE2 in the chromosome of strain M708 (Fig. 1), the insert of plasmid pM149 (a pACYC184 derivative) (41) containing the sopE2 coding sequence, 818 bp of upstream sequence, and 444 bp of downstream sequence was subcloned into the XbaI and BamHI sites of suicide vector pSB377 (Tet^r) (29), which yielded plasmid pM707. To construct a low-copy-number expression vector for sipA complementation in trans, the sipA gene was cloned from the chromosome of SL1344. In brief, the suicide plasmid pM585 (described above) was integrated into the chromosome of SL1344 by single recombination. Subsequently, integration of pM585 downstream of the sipA coding sequence was verified by PCR, chromosomal DNA of the appropriate clones was isolated by standard techniques (38), and the chromosomal DNA was digested with BamHI, treated with DNA ligase, and electroporated into Escherichia coli CC118pir, which yielded pM711. Plasmid pM711 harbors the sipA coding sequence and 2,207 bp of upstream sequence. The 2,819-bp HindIII/EcoRV fragment of pM711 harboring the sipA coding sequence and 31 bp of upstream sequence was subcloned into the HindIII and EcoRV sites of the low-copy-number vector pWKS30 (Amp^r, lac promoter, pSC101 ori) (49), which yielded pM712.

Gentamicin protection assay. An analysis of the invasiveness of mutant Salmonella strains for COS7 cells was carried out as described previously (33). COS7 tissue culture cells were grown for 2 days in Dulbecco modified Eagle medium (DMEM) containing 5% fetal bovine serum (FBS) in 24-well dishes to obtain 80% confluence. The culture medium was removed, and 500 µl of Hanks' buffered salt solution was added 3 min before addition of the bacteria. The bacteria were grown as described above. The actual bacterial density was determined by plating appropriate dilutions on LB agar. To start the assay, bacteria were added to COS7 cells at a multiplicity of infection of approximately 15 and incubated for 50 min at 37°C in the presence of 5% CO₂. The cells were washed three times with Hanks' buffered salt solution and incubated for 2 h in 500 µl of DMEM containing 5% FBS and 400 µg of gentamicin per ml at 37°C in the presence of 5% CO₂. The cells were washed three times with 1x PBS and lysed in 1x PBS-0.1% sodium deoxycholate, and the number of CFU of intracellular bacteria was determined by plating on LB agar. Usually about 25% of the inoculum of the wild-type strain was recovered from COS7 cells at the end of the assay. An analysis of the invasiveness of mutant Salmonella strains for murine embryonic fibroblasts (C57BL/6 genetic background; kindly provided by H. Rüssmann) was carried out as described above for COS7 cells, but the tissue cell culture medium was replaced by DMEM containing 5% FBS, 50 µM 2-mercaptoethanol, and 2 mM glutamine. The numbers given below were determined in at least six independent experiments for each strain. The statistical significance of differences between the invasiveness of different strains was analyzed by using the Mann-Whitney U test.

Animal experiments. Animal experiments were performed as described recently (2) by using specific-pathogen-free female C57BL/6 mice that were 6 to 9 weeks old and were obtained from Harlan (Horst, The Netherlands). For the experiments, animals were housed individually or in groups of up to five animals under standard barrier conditions in individually ventilated cages (Tecniplast, Buguggiate, Italy) equipped with steel grid floors and autoclaved filter paper at the BZL (Zürich, Switzerland). Water and food were withdrawn 4 h before per os (p.o.) treatment with 20 mg of streptomycin (50 µl of a sterile solution). After this, the animals were given water and food ad libitum. Twenty hours after streptomycin treatment, water and food were withdrawn again for 4 h before the mice were infected p.o. with 10⁸ CFU of serovar Typhimurium (50 µl of a suspension in PBS). After this, drinking water was offered ad libitum immediately and food was offered at 2 h p.i. At different times after infection, the mice were sacrificed by cervical dislocation, and tissue samples from the intestinal tract, spleen, and liver were removed for analysis. Animal experiments were approved by the Swiss authorities and were performed according to the legal requirements.

Analysis of serovar Typhimurium loads in the intestine, mesenteric lymph nodes, spleen, and liver. To analyze colonization, spleens and livers were removed aseptically and homogenized in 4°C PBS containing 0.5% Tergitol and 0.5% bovine serum albumin by using a Potter homogenizer as described recently (2). The numbers of CFU were determined by plating appropriate dilutions on MacConkey agar plates containing streptomycin (50 µg/ml). The minimal detectable levels were 20 CFU/organ in the spleen and 100 CFU/organ in the liver.

Intestinal contents of the cecum were collected on day 2 p.i. and weighed before they were suspended in 500 µl of 4°C PBS. The number of CFU was determined by plating appropriate dilutions on MacConkey agar plates containing streptomycin (50 µg/ml). The minimum detectable level was 10 CFU per sample (between 25 and 150 mg of intestinal contents).

Histological procedures. Segments of ileum, cecum, and colon were embedded in O.C.T. (Sakura, Torrance, Calif.), snap-frozen in liquid nitrogen, and stored at -80°C. Cryosections (5 µm) were mounted on glass slides, air dried for 2 h at room temperature, and stained with hematoxylin and eosin (HE).

Cecum pathology was evaluated by pathologists in a blinded manner by using 5-µm HE-stained sections and the following histopathological scoring scheme, as previously described (2).

(i) Submucosal edema. For submucosal edema a score of 0 indicated that there were no pathological changes; a score of 1 indicated that there was mild edema (the submucosa was <0.20 mm wide and accounted for <50% of the diameter of the entire intestinal wall [tunica muscularis to epithelium]); a score of 2 indicated that there was moderate edema (the submucosa was 0.21 to 0.45 mm wide and accounted for 50 to 80% of the diameter of the entire intestinal wall); and a score of 3 indicated that there was profound edema (the submucosa was >0.46 mm wide and accounted for >80% of the diameter of the entire intestinal wall). The widths of the submucosa were determined by quantitative microscopy and were the averages for 30 evenly spaced radial measurements of the distance between the tunica muscularis and the lamina mucosalis mucosae.

(ii) PMN infiltration into the lamina propria. PMN in the lamina propria were enumerated by examining 10 high-power fields (magnification, x400; field diameter, 420 µm), and the average number of PMN per high-power field was calculated. The scores were as follows: 0, less than 5 PMN per high-power field; 1, 5 to 20 PMN per high-power field; 2, 21 to 60 PMN per high-power field; 3, 61 to 100 PMN per high-power field; and 4, more than 100 PMN per high-power field. Transmigration of PMN into the intestinal lumen was consistently observed when the number of PMN was more than 60 PMN per high-power field.

(iii) Goblet cells. The average number of goblet cells per high-power field (magnification, x400) was determined by examining 10 different regions of the cecal epithelium. The scores were as follows: 0, more than 28 goblet cells per high-power field (in the ceca of the normal specific-pathogen-free mice we observed an average of 6.4 crypts per high-power field, and the average crypt consisted of 35 to 42 epithelial cells, 25 to 35% of which were differentiated into goblet cells); 1, 11 to 28 goblet cells per high-power field; 2, 1 to 10 goblet cells per high-power field; and 3, less than 1 goblet cell per high-power field.

(iv) Epithelial integrity. For epithelial integrity a score of 0 indicated that no pathological changes were detectable in 10 high-power fields (magnification, x400); a score of 1 indicated that there was epithelial desquamation; a score of 2 indicated that there was erosion of the epithelial surface (gaps of 1 to 10 epithelial cells per lesion); and a score of 3 indicated that there was epithelial ulceration (gaps of >10 epithelial cells per lesion) (at this stage, there was generally granulation tissue below the epithelium).

The combined pathological score for each tissue sample was determined by adding the averaged scores. The values ranged from 0 to 13 arbitrary units and covered the following levels of inflammation: 0, intestine intact without any signs of inflammation; 1 to 2, minimal signs of inflammation (these scores were frequently obtained for the ceca of specific-pathogen-free mice, and this level of inflammation is generally not considered a sign of disease); 3 to 4, slight inflammation; 5 to 8, moderate inflammation; and 9 to 13, profound inflammation.

Statistical analysis. Statistical analysis of the individual pathological scores for submucosal edema, PMN infiltration, loss of goblet cells, and epithelial integrity and for the combined pathological score was performed by using the exact Mann-Whitney U test and the SPSS software (version 11.0), as described previously (2). P values of <0.05 were considered statistically significant. Bacterial colonization was analyzed in a similar way. To allow statistical analysis of the bacterial loads, the values used for animals that yielded no CFU were the minimal detectable values (20 CFU for the spleen, 100 CFU for the liver, and between 67 and 400 CFU for the intestinal contents [see above]). After this, the median values were calculated by using Microsoft Excel XP, and a statistical analysis was performed by using the exact Mann-Whitney U test and the SPSS software (version 11.0). P values of <0.05 were considered statistically significant.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
SipA plays an important role in murine serovar Typhimurium colitis. It has recently been shown that the SPI-1 TTSS plays a key role in serovar Typhimurium-induced colitis in streptomycin-pretreated mice (2). Serovar Typhimurium mutants incapable of translocating effector proteins into host cells are strongly attenuated in this animal model and induce only mild signs of intestinal inflammation (2), but previously it was not known which SPI-1 effector proteins are involved. Therefore, we analyzed serovar Typhimurium mutants lacking one or more SPI-1 effector proteins. In order to optimize the sensitivity of the assay, most of the experiments in this study were performed in the serovar Typhimurium mutant M556 (SL1344 sseD::aphT) background, which lacks an essential component of the SPI-2 translocon. This choice was based on previous observations demonstrating that the SPI-2 TTSS can affect enteric disease in the bovine model (3). Later, we confirmed that the results obtained in the M556 genetic background can be reproduced with SPI-2-positive serovar Typhimurium strains (see below).

The effector proteins SopB, SopE, SopE2, and SipA have been shown to contribute to enteric salmonellosis in calves (35, 50, 52-54). To assess the role of these proteins in the murine model, we constructed a series of M556 derivatives carrying in-frame deletions of sopB (M704) or sipA (M715) and a sopEE2 double effector mutant strain (M719) (Table 1) (see Materials and Methods). These strains were characterized by performing murine infection experiments and tissue culture cell invasion assays (see below).

The densities of the different serovar Typhimurium strains in the cecal contents did not differ significantly (median, 10⁸ to 10⁹ CFU/g) (Fig. 2A). Also, the numbers of bacteria present in the liver and spleen did not differ significantly for the different serovar Typhimurium strains and were below the limit of detection in most cases (Fig. 2B and C). Signs of strong inflammation were evident in the cecal tissues of mice infected with M556 (sseD::aphT), the sopB mutant (M704), and the sopEE2 double effector mutant (M719) (Fig. 2D). These signs included strong edema in the submucosa, massive PMN infiltration, erosion or desquamation of the intestinal epithelium, and loss of goblet cells. In this experiment the total pathological score (P = 0.041), but none of the individual scores for the sopB mutant M704, appeared to be significantly reduced (Fig. 2D and Table 2). Additional experiments confirmed that the pathological scores of M704 did not differ significantly from those of M556 (data not shown). The sipA mutant (M715) caused significantly less inflammation (P = 0.002), indicating that SipA plays an important role in serovar Typhimurium colitis in streptomycin-pretreated mice. M557 (invG sseD::aphT) was attenuated even more strongly than M715 (P = 0.004) (Fig. 2D). This suggested that effector proteins in addition to SipA might be involved in the induction of serovar Typhimurium colitis.

View larger version (40K): [in this window] [in a new window]   FIG. 2. Analysis of sopB and sipA mutants and a sopEE2 double effector mutant of serovar Typhimurium SL1344. Five groups of streptomycin-pretreated mice were infected for 2 days with 108 CFU of serovar Typhimurium strains M556 (six mice), M704 (six mice), M719 (six mice), M715 (six mice), and M557 (five mice). These strains had disrupted SPI-1 effector genes and/or disrupted genes encoding structural components of the SPI-1 and SPI-2 TTSS. (A) Bacterial loads in the cecal contents. (B) Bacterial loads in the liver. (C) Bacterial loads in the spleen. (D) Histopathological analysis. HE-stained sections of cecal tissue were scored with respect to edema in the submucosa, PMN infiltration (PMN inf.), reduction in the number of goblet cells, and desquamation, erosion, or ulceration of the epithelial layer (see Materials and Methods), and the scores were plotted as stacked vertical bars. The total pathological score (sum of the separate scores) was statistically analyzed (stat. analysis) by using the exact Mann-Whitney U test (with comparison to M556). The dotted lines indicate the limits of detection. NS, not statistically significant (P 0.05); S. Tm, serovar Typhimurium; wt, wild type.

Based on analyses in which bovine infection models were used (54), SopB, SopE, and SopE2 were good candidates to account for the residual cecal inflammation observed with the sipA mutant M715 (Fig. 2D and Table 2).

In fact, preliminary experiments indicated that a serovar Typhimurium SL1344 sipA sopBEE2 quadruple effector deletion mutant (M708) (Table 1) was not capable of causing substantial intestinal inflammation (Fig. 3D and data not shown). This indicated that the effector proteins SipA, SopE, SopE2, and SopB or subsets of these proteins are required for the SPI-1-dependent induction of intestinal inflammation in streptomycin-pretreated mice.

View larger version (44K): [in this window] [in a new window]   FIG. 3. Analysis of effector gene triple mutants and a sipA sopBEE2 quadruple effector mutant of serovar Typhimurium SL1344. Seven groups of five streptomycin-pretreated mice were infected for 2 days with 108 CFU of serovar Typhimurium strains M556, M722, M717, M707, M716, M708, and M557. The relevant genotypes are indicated. (A) Bacterial loads in the cecal contents. (B) Bacterial loads in the liver. (C) Bacterial loads in the spleen. (D) Histopathological analysis. HE-stained sections of cecal tissue were scored with respect to edema in the submucosa, PMN infiltration (PMN inf.), reduction in the number of goblet cells, and desquamation, erosion, or ulceration of the epithelial layer (see Materials and Methods), and the scores were plotted as stacked vertical bars. The total pathological score (sum of the separate scores) was statistically analyzed (stat. anal.) by using the exact Mann-Whitney U test (with comparison to M708). The dotted lines indicate the limits of detection. NS, not statistically significant (P 0.05); S. Tm, serovar Typhimurium.

Preliminary experiments were performed to identify the optimal genetic constructs for complementation. Transformation of M708 with a low-copy-number sipA expression plasmid (pM712) could complement this strain's enteric virulence, while various sopE and sopE2 expression plasmids could not (data not shown). For this reason, we constructed the suicide vectors pM706 and pM707, which were integrated into the chromosome of M708 by single-crossover recombination, which yielded M732 and M734, respectively (see Materials and Methods) (Table 1).

To perform the complementation analysis, streptomycin-pretreated C57BL/6 mice were infected p.o. with 10⁸ CFU of M708, M732, M734, M708(pWKS30) (empty control vector), or M708(pM712). Infections with M556 and M557 served as additional controls. The mice were sacrificed at 2 days p.i. and were analyzed for intestinal colonization and for bacterial numbers in the liver and spleen, as well as for pathological changes in the cecal tissue. The cecal contents of the mice from every group generally contained between 10⁸ and 10¹⁰ CFU/g (Fig. 4A), and we did not detect significant differences in colonization of the liver and spleen (Fig. 4B and C). The pathological analysis revealed that M708(pM712) induced more severe inflammatory changes than the control strain M708(pWKS30) induced. Similar results were obtained for the chromosomal complementation of sopE and sopE2 (Fig. 4D and Table 4 [compare M708 with M732 and M734]). These data verified that the SPI-1 effector proteins SipA, SopE, and SopE2 contribute to murine serovar Typhimurium colitis and demonstrated that each of these proteins is sufficient to induce inflammation in the absence of the other two proteins and of SopB.

View larger version (45K): [in this window] [in a new window]   FIG. 4. Complementation analysis of the sipA, sopE, and sopE2 mutations in serovar Typhimurium SL1344. Groups of five (or six in the case of M734) streptomycin-pretreated mice were infected for 2 days with 108 CFU of serovar Typhimurium strains M708(pWKS30), M708(pM712), M708, M732, M734, and M556 (Table 1). The relevant genotypes are indicated. (A) Bacterial loads in the cecal contents. (B) Bacterial loads in the liver. (C) Bacterial loads in the spleen. (D) Histopathological analysis. HE-stained sections of cecal tissue were scored with respect to edema in the submucosa, PMN infiltration (PMN inf.), reduction in the number of goblet cells, and desquamation, erosion, or ulceration of the epithelial layer (see Materials and Methods), and the scores were plotted as stacked vertical bars. The total pathological score (sum of the separate scores) was statistically analyzed (stat. anal.) by using the exact Mann-Whitney U test [with comparison to M708(pWKS30) or M708]. The dotted lines indicate the limits of detection. c, chromosomal complementation; p, complementation in trans with a plasmid; NS, not statistically significant (P 0.05); S. Tm, serovar Typhimurium.

COS7 tissue culture cells were infected (multiplicity of infection, 15 bacteria per cell) with wild-type serovar Typhimurium SL1344, the isogenic mutant with a defective SPI-2 translocon (M556), and the different isogenic strains carrying mutations in one or several of the genes encoding the effector proteins SipA, SopB, SopE, and SopE2. Fifty minutes after infection all extracellular bacteria were killed with gentamicin, and the numbers of internalized bacteria were determined as described in Materials and Methods.

As expected, the invasiveness of strain M556 (sseD::aphT) with a defective SPI-2 translocon did not differ significantly from that of the isogenic wild-type strain (P 0.05) (Table 5). In contrast, both strains carrying a disrupted SPI-1 TTSS apparatus (SB161 and M557) were about 1,000-fold less invasive than M556 or wild-type serovar Typhimurium strain SL1344. These observations indicate that the SPI-1-mediated invasion of COS7 tissue culture cells by serovar Typhimurium strain SL1344 does not require a functional SPI-2 TTSS.

The invasiveness of the sipA sopBEE2 quadruple effector mutant M708 was recomplemented by introduction of SopE (pM706) (P = 0.004) or SopE2 (pM707) (P = 0.004) (Table 6). M708 carrying the sipA expression vector pM712 was slightly more invasive than M708 (P = 0.015) (Table 6) or M708 carrying the empty control vector. These data verified that the genes encoding SopE, SopE2, SopB, and SipA were fully functional in the strains used in this study and that the mutations did disrupt gene function. Thus, we excluded the possibility that technical problems (i.e., undetected second-site mutations which might have occurred during strain construction) were the cause of our failure to detect a virulence defect for sopB strains in the streptomycin-pretreated mouse model.

View larger version (45K): [in this window] [in a new window]   FIG. 5. Analysis of the contribution of sopB from serovar Typhimurium strain ATCC 14028s to murine colitis. Six groups of five streptomycin-pretreated mice were infected for 2 days with 108 CFU of serovar Typhimurium strains M741, M744, M746, M745, M743, and M742. The relevant genotypes are indicated. (A) Bacterial loads in the cecal contents. (B) Bacterial loads in the liver. (C) Bacterial loads in the spleen. (D) Histopathological analysis. HE-stained sections of cecal tissue were scored with respect to edema in the submucosa, PMN infiltration (PMN inf.), reduction in the number of goblet cells, and desquamation, erosion, or ulceration of the epithelial layer (see Materials and Methods), and the scores were plotted as stacked vertical bars. The total pathological score (sum of the separate scores) was statistically analyzed (stat. anal.) by using the exact Mann-Whitney U test (with comparison to M743). The dotted lines indicate the limits of detection. NS, not statistically significant (P 0.05); S. Tm, serovar Typhimurium.

We also compared the virulence of ATCC 14028s mutants carrying an intact or disrupted SPI-2 TTSS. The same levels of intestinal inflammation were observed with M741 and M744 (Fig. 5D) (P > 0.05). Similarly, M746, M743, M745, and M742 were attenuated to similar degrees and produced the same level of residual inflammation (Fig. 5D and Table 8). In conclusion, the data confirmed that translocation of the effector protein SipA and/or SopE2 via the SPI-1 TTSS is a key virulence mechanism in the induction of murine serovar Typhimurium colitis and that the results of our analysis were not affected by the presence of a functional SPI-2 TTSS.

To further characterize the serovar Typhimurium ATCC 14028s mutants, we performed COS7 tissue culture cell invasion assays (Table 9). The results were very similar to the invasion results obtained with serovar Typhimurium strain SL1344. Most importantly, both sipA sopE2 double effector mutants (M746 and M743; intact sopB) were highly invasive (43 or 50%) (Table 9), which suggested that the sopB gene was functional in these two strains. Together with our studies of the SL1344 strain, these data confirmed that SipA, SopE, and SopE2 are important Salmonella virulence factors in vitro and in vivo. In contrast, SopB plays an important role in virulence assays in vitro, but it does not seem to be required for induction of intestinal inflammation in the streptomycin-pretreated mouse model.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

It should be noted that many experiments in the present study were performed with serovar Typhimurium strains with a disrupted SPI-2 translocon. In this way we ensured that subtle SPI-1-mediated mechanisms were not masked by the onset of the SPI-2-dependent systemic disease. However, our results were subsequently confirmed with SPI-2-proficient strains. Also, it should be kept in mind that the murine colitis model requires antibiotic treatment. In spite of these limitations, our observations are in line with findings obtained with the bovine model and support the notion that streptomycin-pretreated mice offer a useful animal model to study the pathogenetic mechanism of serovar Typhimurium colitis.

SopE contributes to intestinal inflammation in calves and streptomycin-pretreated mice. Interestingly, SopE is not present in all Salmonella species (23, 34, 36). In the sopE-positive serovar Typhimurium strains SopE is encoded by a P2-like prophage (34). Interestingly, serovar Typhimurium strains carrying this prophage have been associated with a major epidemic in the 1970s and 1980s in England and the former German Democratic Republic (34). This suggested that acquisition of the additional sopE gene by lysogenic conversion was an important step in the emergence of these epidemic serovar Typhimurium clones. Experiments with the bovine model have demonstrated that sopE and sopE2 are involved in the elicitation of intestinal inflammation and that lysogenic conversion by SopE can increase the virulence of the naïve serovar Typhimurium strain ATCC 14028s (48, 53, 54). The present analysis provides an experimental framework to study how SopE enhances Salmonella virulence.

In bovine ligated ileal loop assays, serovar Dublin sopB mutants are significantly attenuated for induction of PMN influx and fluid secretion (16, 27, 35, 50). Serovar Typhimurium sopB mutants exhibit similar, although much milder, virulence defects in bovine ligated ileal loops (39, 54). However, in orally infected calves, disruption of serovar Typhimurium sopB did not affect the severity of diarrhea and intestinal inflammation (44). In line with the latter observation, we could not detect a virulence defect for the serovar Typhimurium SL1344 sopB mutant. Similarly, the sipA sopEE2 triple effector mutant was attenuated to the same extent as the sopA sopBEE2 quadruple effector mutant. We confirmed these results using the same serovar Typhimurium strain (ATCC 14028s) which had been used for the previous studies with the bovine model (see above). Therefore, the phenotypes of sopB mutants are strikingly similar in streptomycin-pretreated mice and orally infected calves (44).

Why do sopB mutants not show virulence defects in oral infection experiments? Species differences can probably be excluded. All tissue culture experiments performed with primate and murine cells and bovine ligated ileal loop assays (39, 54) suggest that cells having diverse mammalian origins are principally responsive to SopB. Might expression of sopB play a role? For tissue culture and ligated ileal loop experiments, Salmonella spp. are pregrown in culture broth under SPI-1-inducing conditions. In contrast, upon oral infection, the bacteria grow under the specific conditions present in the host's intestine. Therefore, it is conceivable that sopB expression in the intestine is simply insufficient to produce a detectable response in the current oral infection models. However, it should be noted that expression of sopB is controlled by the same regulator (InvF/SicA) as sopE, which does exhibit a virulence phenotype both in tissue culture and in oral infection models (8, 9, 46, 53, 54). Additional work is required to determine the molecular mechanism that explains why sopB mutants do not show virulence defects in bovine and murine oral infection models.

Similar to findings obtained with the bovine model (54), we found that SipA elicits pronounced murine colitis in the absence of SopE, SopE2, and SopB. Furthermore, SopE induced colitis independent of SipA, SopE2, and SopB, and also SopE2 could induce mild inflammation in the absence of SipA, SopE, and SopB. Therefore, SopE, SipA, and to a limited extent SopE2 can induce intestinal inflammation independent of each other and SopB. Interestingly, these effector proteins have quite different cellular targets; SopE and SopE2 are potent activators of host cell Rho GTPases (4, 7, 13, 22, 37, 41), while SipA acts as an actin binding and bundling protein (15, 24, 57, 58). In spite of these fundamental functional differences, SopE-induced inflammation and SipA-induced inflammation are histologically very similar; both include epithelial damage, loss of goblet cells, submucosal edema, PMN infiltration into the lamina propria, and transmigration of PMN into the intestinal lumen. Future work should identify the molecular mechanisms responsible for this observation.

Overall, the results presented here are in line with results obtained with the bovine model. SipA has a key function in elicitation of intestinal inflammation in calves and streptomycin-pretreated mice. SopE (in SL1344) and to a lesser extent SopE2 play a role in both models. The histopathologies induced by SipA, SopE, and/or SopE2, including massive PMN infiltration and epithelial damage, are very similar in the murine and bovine models. Interestingly, the overall contribution of the serovar Typhimurium SPI-1 TTSS to intestinal inflammation seems to vary significantly in different bovine ileal loop and oral infections. In bovine ileal loop assays, serovar Typhimurium mutants with a disrupted SPI-1 TTSS are clearly attenuated but still induce appreciable inflammation (54). However, in orally infected calves these mutants do not induce appreciable inflammation (44). A similar degree of attenuation is observed in the streptomycin-pretreated mouse model. Serovar Typhimurium mutants lacking the effector proteins SipA, SopE, and SopE2 (this study) or an essential component of the SPI-1 TTSS apparatus (2) did not induce obvious intestinal inflammation. Due to this low background inflammation streptomycin-pretreated mice are a sensitive surrogate host model to analyze the inflammatory cascades triggered by the serovar Typhimurium effector proteins SipA, SopE, and SopE2 in the host intestine. Further analyses should profit from the completed mouse and Salmonella genome sequences and from the multitude of immunological reagents and knockout mouse strains available today.

	ACKNOWLEDGMENTS

 
We are grateful to Günther Paesold for discussions, to Natalie Schlegel for critical reading of the manuscript, to Andrew Macpherson for scientific discussions, for help with the histopathological evaluation, and for comments on the manuscript, and to Burkhardt Seifert for advice on the statistical analysis. We thank R. Zinkernagel and H. Hengartner for generous support of our animal work at the BZL Zurich.

This work was funded in part by a grant from the Swiss National Foundation (to W.-D.H.).

	FOOTNOTES

 
* Corresponding author. Mailing address: Institute of Microbiology, ETH Zürich, Schmelzbergstr. 7, 8092 Zürich, Switzerland. Phone: 41-1-632-5143. Fax: 41-1-632-1129. E-mail: hardt{at}micro.biol.ethz.ch.

Editor: B. B. Finlay

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