Molecular cloning and expression of calcium-regulated, plasmid-coded proteins of Y. pseudotuberculosis

lcrR, a low-Ca2(+)-response locus with dual Ca2(+)-dependent functions in Yersinia pestis

The low-Ca2+ response (Lcr) of Yersinia includes a regulatory cascade and a set of virulence-related proteins, one of which is the V antigen. The regulatory genes modulate both bacterial growth and expression of the virulence-related proteins in response to temperature and the presence of Ca2+ and nucleotides. In this study we defined a new Lcr locus, lcrR, in Yersinia pestis KIM. An lcrR mutant, obtained by insertion mutagenesis, failed to grow at 37 degrees C whether Ca2+ was present or not. However, it grew normally in the presence of ATP, showing that the Ca2(+)- and nucleotide-responsive mechanisms are separate in Y. pestis. The lcrR mutant was avirulent in mice, probably due to its compromised growth at 37 degrees C. beta-Galactosidase measurements and Northern (RNA blot) analysis revealed that lcrR transcription was regulated primarily by temperature. The DNA sequence of the lcrR locus contained a single open reading frame of 441 bases that could encode a protein with a molecular weight of 16,470 and a pI of 10.73. Expression of an lcrR-containing clone in Escherichia coli yielded a 16,000-molecular-weight protein. At 37 degrees C, the lcrR mutant strongly expressed V antigen and initiated lcrGVH transcription whether Ca2+ was present or not, indicating that this mutant had lost the transcriptional downregulation of lcrGVH shown by the parent in the presence of Ca2+. In the absence of Ca2+, the mutant failed to express LcrG, even though lcrGVH mRNA initiated upstream of lcrG at the normal sites. These data suggest that the lcrR locus is necessary for the regulation of LcrG expression in the absence of Ca2+. Therefore, this locus has a dual regulatory role in the low-Ca2+ response.

Homologous DNA sequences on the virulence plasmids of pathogenic Yersinia and Salmonella dublin lane

Yersinia and Salmonella harbour plasmids that encode traits important for virulence, enabling both pathogenic genera to survive and grow in cells of the reticulo-endothelial organs during systemic infections. We have detected DNA homology between the Salmonella dublin virulence plasmid pSDL2 and the plasmids of the pathogenic Yersinia species pestis, pseudotuberculosis, and enterocolitica. Three regions of pSDL2 were found to share homology with the virulence plasmid pIB1 of Yersinia pseudotuberculosis. Two separate hybridizing segments mapped within the previously characterized 6.4 kb vir region of pSDL2 in the SalI B fragment. The third homologous region involved the replicon of pIB1, which hybridized to the SalI C2 fragment of pSDL2. The virulence plasmid pCD1 from Y. pestis showed similar homology with the three regions of pSDL2. Homologies to the vir and SalI C2 regions of pSDL2 were also found on plasmids from Yersinia enterocolitica serotypes 0:9, 0:3 and 0:5, 27. The discovery of separate homologous regions on the virulence plasmids of Salmonella and Yersinia suggests a distant evolutionary relationship.

The lcrE gene is part of an operon in the lcr region of Yersinia enterocolitica O:3

The low-calcium response (lcr) region of the virulence plasmid of Yersinia pestis, Yersinia pseudotuberculosis, and Yersinia enterocolitica has been associated with calcium-dependent growth of bacteria. Mutations in the previously identified lcrE locus within the lcr region lack the repressor control of production of the lcr specific proteins, Yersinia outer membrane proteins (Yops) and V and W antigens. We sequenced a 3.3-kilobase-pair BamHI-ClaI fragment of the lcrE locus of pYVO3, the virulence plasmid of Y. enterocolitica O:3. The sequence of lcrE locus revealed six tightly packed open reading frames (ORFs), one of which was identified as the structural gene, lcrE, of the 32.9-kilodalton outer membrane protein LcrE (formerly known as Yop4b or YopN). Detection of large (greater than 2.3-kilobase-pair) transcripts strongly supports the conclusion that the lcrE gene and ORF1 to -5 function as an operon. Transcription of the lcrE-containing operon and the adjacent lcrB locus was found to be divergent, and the corresponding transcripts overlapped about 1,200 nucleotides. This extremely long overlap of the 5' ends of the transcripts produced from face-to-face promoters is a new finding; the longest overlap thus far found has been a few hundred nucleotides. Temperature was found to play the major role in regulation of transcription of the lcrE-containing operon of pYVO3, whereas Ca2+ concentration seemed to affect it only moderately.

The cytotoxic protein YopE of Yersinia obstructs the primary host defence

It has previously been shown that the plasmid-encoded YopE protein of Yersinia pseudotuberculosis is a virulence determinant. In this study, HeLa cells, macrophages and mice were used as different model systems to determine the actual role of YopE in the virulence process. The YopE protein mediates a cytotoxic response on a confluent layer of HeLa cells. A prerequisite of this activity is that the pathogen binds to the cell surface. YopE also induces a cytotoxic response on mouse macrophages where it influences the ability of the pathogen to resist phagocytosis. Bacterial mutants defective in their ability to express YopE are avirulent after oral or intraperitoneal infection but virulent following intravenous injection. On the basis of these results, we propose a role for YopE in the virulence process of Yersinia.

Genetic analysis of the yopE region of Yersinia spp.: identification of a novel conserved locus, yerA, regulating yopE expression

The yopE gene of Yersinia pseudotuberculosis was recently sequenced, and YopE was identified as an indispensable virulence determinant when tested in a mouse model (A. Forsberg and H. Wolf-Watz, Mol. Microbiol. 2:121-133, 1988). In the study described here, the DNA sequences of the yopE genes of Yersinia pestis EV76 and Yersinia enterocolitica 8081 were determined and compared with that of the Y. pseudotuberculosis gene. Only two codons were found to differ, both leading to amino acid replacements, when the gene from Y. pestis was compared. These two replacements were also present in the gene from Y. enterocolitica; in addition, 18 other codons were found to differ. Thirteen of these substitutions led to amino acid replacements. Downstream of the yopE gene, the plasmid partition locus par was found to be conserved in all three species. In Y. enterocolitica 8081, the sequence homology was interrupted by a putative insertion sequence element inserted between the yopE gene and the par region at a position only 5 base pairs downstream of the yopE stop codon. Upstream of the yopE gene, 620 base pairs were conserved in the three species. This region contained a 130-amino-acid-long open reading frame reading in the opposite direction to the yopE gene and expressed a 14-kilodalton protein in minicells. An insertion mutation in this region constructed in Y. pseudotuberculosis expressed significantly lower amounts of YopE protein in vitro than did the corresponding wild type. The expression level could be restored by transcomplementation. This new locus was designated yerA, for yopE-regulating gene A. The yerA mutant was avirulent when mice were challenged by oral infection.

Avidity of antibodies against released proteins of Yersinia spp: comparison of patients with or without reactive arthritis

The avidity of IgM, IgG, and IgA class antibodies against virulence plasmid encoded proteins of yersinia, so called released proteins (RPs), was studied in the serum samples of 22 patients with yersinia triggered reactive arthritis and 22 with uncomplicated yersiniosis. The avidity of anti-RP antibodies did not differ significantly between the patient groups, even though the total amount of IgA class anti-RP antibodies was significantly higher in patients with arthritis than in those with uncomplicated yersiniosis at the early stage of infection. Earlier results with whole bacterial extracts or lipopolysaccharide as the antigens have shown an increased avidity of IgA class anti-yersinia antibodies in patients with yersinia triggered reactive arthritis. This phenomenon was not observed in antibody response against RPs, and thus production of these proteins seems unimportant at later stages of infection for the yersinia organisms stimulating the persisting and maturing antibody response in the yersinia triggered reactive arthritis.

The Yersinia yop regulon

Growth of yersiniae is restricted at 37 degrees C in the absence of calcium ions. This phenomenon correlates with the massive release of a set of proteins called Yops. Growth restriction and Yops production are governed by a 70 kb plasmid called pYV. yop genes are distributed throughout pYV and constitute a thermoactivated regulon controlled by the gene virF. The transcription activator VirF is a member of a new family of regulators including those of the arabinose and rhamnose operons as well as a regulator of enteric colonization pili. The role of calcium ions on the release of Yops remains largely unknown.

Identification of additional virulence determinants on the pYV plasmid of Yersinia enterocolitica W227

This paper describes the mutagenesis of the pYV plasmid from Yersinia enterocolitica W22703 (serotype O:9) with Tn2507, a new element generating operon fusions. Analysis of the mutants allowed the identification of an additional Yop protein called Yop20 and the mapping of yop20, yop44, yop48, and lcrV, the gene encoding the V antigen. The last gene appeared to be part of an operon that also may contain yop37 and yop44. At 37 degrees C, mutants affected in this operon grew poorly, irrespective of the presence of Ca2+, or they even died in the presence of Ca2+. This operon is thus involved in the regulation by Ca2+, and we called it car, for Ca2+ regulation. It is presumably the Y. enterocolitica counterpart of the lcrGVH operon of Yersinia pestis. Transcription of yop20 and of the car operon was strongly regulated by temperature and only slightly by calcium. Hence, these genes behaved like the other genes of the yop regulon. Mutants affected in yop20 or in yop48 were markedly less virulent for the desferrioxamine-treated mouse than was the parental strain. Yop20 and Yop48 thus probably are Yersinia virulence factors.

A Yersinia pestis-specific DNA fragment encodes temperature-dependent coagulase and fibrinolysin-associated phenotypes

The effect of temperature on coagulase and fibrinolysin expression (Pla) by Yersinia pestis has been implicated in the transmission of plague by fleas. In an attempt to improve our understanding of this process, we have cloned, sequenced and characterized the gene encoding the Pla phenotypes in Y. pestis, and examined its temperature-dependent regulation. The coding region for this gene overlaps a 900bp Y. pestis-specific DNA fragment that we have previously shown to be capable of detecting plague bacilli in fleas. The pla gene contains a single open reading frame encoding 312 amino acids with a predicted molecular weight of 34.7 kD and a putative signal sequence of 20 amino acids. This coding region appears to be sufficient for both coagulase and fibrinolytic activities. In Y. pestis, modulation between coagulase and fibrinolytic activities is temperature-dependent: coagulase activity is most evident at temperatures below 30 degrees C but fibrinolytic activity increases with higher temperatures (greater than 30 degrees C), regardless of the temperature at which the bacteria are grown. Our results lead us to believe that this regulation occurs post-translationally. It is possible that the alternative forms of the Pla protein are essential to 'flea blockage' and subsequent transmission of the plague bacillus to animals.

lcrH, a gene necessary for virulence of Yersinia pestis and for the normal response of Y. pestis to ATP and calcium

We are investigating the functions of the three proteins encoded by the V operon (lcrGVH) of the low-calcium response virulence plasmid pCD1 of Yersinia pestis KIM5. The purpose of this study was to define the role of the 18-kilodalton protein encoded by lcrH, the third gene of the V operon. Using marker exchange mutagenesis, we constructed a Y. pestis mutant that failed to express the LcrH protein. This LcrH- mutant was "ATP blind" in that it failed to show altered growth and V-antigen expression at 37 degrees C when 18 mM ATP was present. It also showed only a partial response to 2.5 mM Ca2+. The parental Y. pestis strain showed full growth yield at 37 degrees C and depressed expression of V antigen and of yop (yersinial pCD1-encoded outer membrane protein) genes in response to ATP or Ca2+. In contrast, the LcrH- mutant failed to grow at 37 degrees C in the presence of ATP and showed only limited growth when Ca2+ was present. V-antigen expression in the mutant was not depressed by ATP and only partially depressed by Ca2+. These findings show that LcrH is necessary for the normal response of Y. pestis to ATP and that LcrH contributes to Ca2+ responsiveness. The mutant also showed abnormal yopJ expression, indicating that LcrH also is necessary for normal yop regulation. The LcrH- mutant was avirulent in mice, probably because of its compromised growth at 37 degrees C. These findings indicate that the responses of Y. pestis to ATP and Ca2+ are distinct and that lcrH encodes a protein that is an important mediator of Ca2+ and ATP regulation of pCD1-encoded virulence determinant(s) in Y. pestis.

Differential clearance and host-pathogen interactions of YopE- and YopK- YopL- Yersinia pestis in BALB/c mice

This study characterized infections in BALB/c mice by the nonpigmented Yersinia pestis KIM and its derivatives lacking the low-Ca2+-response virulence plasmid pCD1 or failing to express selected yersinial outer membrane proteins (YOPs). The parent Y. pestis showed net growth in the spleen by 2 h and in the liver after 7 h; exponential growth in both the liver and spleen culminated in death of the mice starting on day 4, with total bacterial numbers of less than 10(8) in the blood, liver, and spleen together. The histopathology progressed from microabscesses to extensive coagulative necrosis unaccompanied by further immigration of inflammatory cells. This, together with the relatively low bacterial numbers, suggests a toxigenic mechanism. YopE- or YopK- YopL- yersiniae were cleared from the spleen but grew in the liver after an initial lag. Their growth was curbed after 1 to 2 days and entered a plateau that lasted 5 to 6 days; viable numbers then decline rapidly. This suggests that these Yop- mutations distinguish, at least kinetically, between host responses in liver and spleen. Both strains caused acute inflammation in liver that evolved into structured lesions surrounded by progressively mononuclear inflammation suggestive of a granulomatous response. Accordingly, YOP E and YOPs K and L are necessary in the early days of the infection for net growth in spleen and prolonged growth in the liver; their absence is reflected morphologically by the emergence of cell-mediated immunity in the liver. The YopE- and YopK- YopL- mutants bound only slightly increased amounts of C3, suggesting that YOPs E, K, and L are protective through mechanisms other than interfering with the binding of complement.

Expression of the low calcium response in Yersinia pestis

Pathogenic yersiniae undergo an established low calcium response (LCR) at 37 degrees C in Ca2+-deficient media characterized by restricted growth with synthesis of Lcr plasmid-encoded virulence functions. The latter include outer membrane peptides (Yops) known to undergo Pst plasmid-mediated post-translational degradation in Yersinia pestis but not in enteropathogenic yersiniae lacking this plasmid. Salient Yops of Y. pestis are shown here to be either maintained in the steady state or to exist as a stable degradation product (p24 of Yop E). Processing of plague plasminogen activator (p36 to p33), responsible for hydrolysis of Yops, required 2 h. Avirulence of mutants with inserted Mu dl1 (Apr lac) in yopE was verified and shown to occur independently of introduced fusion-dependent peptides. However, avirulence of such yopE mutants but not that of isolates lacking the Lcr plasmid was phenotypically suppressed in mice injected with iron. Appearance of 20,500 and 40,500 Da heat-shock peptides preceded onset of the LCR. Lcr plasmid mediated V antigen (p38) and p20, Pst plasmid-encoded p36, and chromosomally promoted p56 and p70 were synthesized throughout the LCR. Classical antigen 5 was equated with p70 which was shared by Yersinia pseudotuberculosis but not Yersinia enterocolitica.

Homology between virF, the transcriptional activator of the Yersinia virulence regulon, and AraC, the Escherichia coli arabinose operon regulator

Virulent yersiniae (Yersinia pestis, Y. pseudotuberculosis, and Y. enterocolitica) restrict their growth at 37 degrees C in rich medium deprived of calcium. This property, called calcium dependency, correlates with the secretion of Yersinia outer membrane proteins (Yops) and with pathogenicity. It is mediated by a 70-kilobase plasmid called pYV. The structural genes of the Yops (yop genes), as well as genes involved in the control of their expression (vir genes), have been localized on pYV. In this communication we show that virF encodes a transcriptional activator controlling the yop regulon. This activator is a 30,879-dalton protein related to AraC, the regulator of the Escherichia coli and Salmonella typhimurium arabinose operons. We also show in this paper that transcription of virF is thermodependent and presumably autoregulated. virF is thus responsible for the effect of temperature on the production of the Yops. Finally, we show that virF activates transcription of the yop genes independently of the presence of calcium ions. The role of calcium therefore remains unaccounted for.

Nucleotide sequence and transcription analysis of yop51 from Yersinia enterocolitica W22703

Virulent strains of Yersinia enterocolitica, pseudotuberculosis and pestis secrete large amounts of plasmid-encoded proteins involved in virulence and called Yops. A 2 kb fragment of the pYVe227 plasmid from Yersinia enterocolitica 0:9 encoding Yop51 was sequenced. Gene yop51 was found to encode a 50,882 Da protein consisting of 468 amino acids. This protein shows 99% identity with Yop2b, its counterpart from Y. pseudotuberculosis YPIII (pIB1), confirming that the virulence machinery is highly conserved among Yersinia spp. The homology stops abruptly 240 bp upstream and 175 bp downstream of the structural yop51 gene suggesting that all the sequences involved in the regulation of yop51 are located within the conserved region and confirming that the homology between the plasmids of Yersinia enterocolitica and Yersinia pseudotuberculosis is made up of boxes of high homology. Gene yop51 is only transcribed at 37 degrees C from a VirF-regulated promoter. This promoter was tentatively identified by determining the messenger transcriptional startpoint. The putative yop51 promoter resembles E. coli promoters despite the fact that it is not active in that species in the absence of VirF. A transcription terminator was found at the end of the gene while a second terminator was detected within the structural gene leading to premature termination of some of the messenger molecules.

Inhibition of phagocytosis in Yersinia pseudotuberculosis: a virulence plasmid-encoded ability involving the Yop2b protein

Virulence plasmid-containing cells of Yersinia pseudotuberculosis had the ability to inhibit phagocytosis by mouse peritoneal macrophages cultured in vitro, but cells of its plasmid-cured derivative did not. Inhibition was most pronounced when the pathogen was incubated under Ca2+-deficient conditions, which allowed a high level of expression of outer membrane proteins (Yops). The addition of 2.5 mM Ca2+ to the growth medium reduced the degree of inhibition by the pathogen, but it was still significantly higher than that of the plasmid-cured strain. An avirulent mutant strain, from which the entire yopH gene was deleted, was impaired in its phagocytosis inhibition ability. This mutant could be trans-complemented by the yopH+ gene back to the wild-type phenotype with respect to virulence, as well as the ability to inhibit phagocytosis, demonstrating that the ability to inhibit phagocytosis is an important virulence function. The mutant strain was still cytotoxic for HeLa cells, indicating that inhibition of phagocytosis can be genetically separated from the ability to cause a cytotoxic effect.

Role of antibodies in the opsonization of Yersinia spp

We have determined the opsonic capacity of specific antibodies in patient sera obtained after Yersinia infection. The results indicate that Yersinia antibodies lead to complement activation through the classical pathway, thus overcoming the inhibition of complement-mediated opsonization in the absence of specific antibodies provided by the virulence plasmid in Yersinia enterocolitica and Yersinia pseudotuberculosis. Further, antibodies against plasmid-encoded structures, the Yersinia outer membrane proteins (YOPs), are not necessary in this effect. This is indicated by two facts. (i) Monoclonal antibodies directed against the O polysaccharide of Y. enterocolitica O:3 are capable of opsonizing the plasmid-containing bacteria through C1q binding. (ii) Rabbit antisera show opsonic activity when obtained by immunization both with plasmid-containing Y. enterocolitica expressing the YOPs and a plasmid-cured variant not expressing these proteins.

The plasmid-encoded Yop2b protein of Yersinia pseudotuberculosis is a virulence determinant regulated by calcium and temperature at the level of transcription

The basic Yop2b protein, encoded by the virulence plasmid pIBI of Yersinia pseudotuberculosis, is produced under Ca2+-deficient conditions. A mutant deleted for the entire yopH gene, which encodes the Yop2b protein, was found to be avirulent. Virulence could be restored by trans-complementation. The DNA-sequence of yopH predicted a 50 737 D polypeptide lacking a typical signal peptide. Transcription of yopH is regulated by both temperature and Ca2+-concentration. Mutations within the region of the virulence plasmid known to be involved in regulating gene expression in response to Ca2+ abolished transcription of yopH. Other temperature-sensitive mutations in the Ca2+-regulatory locus showed a high level of transcription regardless of Ca2+-concentration. These responses were similar to those of the yopE gene. The promoter region of the yopE and yopH genes were compared and four conserved motifs identified.

Identification and mapping of the temperature-inducible, plasmid-encoded proteins of Yersinia spp

The structural genes of the outer membrane polypeptides of Yersinia spp. (YOPs) and the V antigen of plasmid pIB1 of Yersinia pseudotuberculosis were recently cloned and mapped (A. Forsberg, I. Bölin, L. Norlander, and H. Wolf-Watz, Microb. Pathogen. 2:123-137, 1987). The corresponding genes were localized on pYV019 and pYV8081 of Yersinia pestis and Yersinia enterocolitica, respectively. No obvious differences were observed on comparison of pIB1 and pYV019, whereas pYV8081 showed intragenic as well as extragenic changes. However, one region of plasmid pYV8081, which coded for the V antigen, YOP3, and YOP4a, was essentially conserved among the three plasmids. Since this region is connected with the Ca2+ region, we suggest that the conserved region of the virulence plasmids of Yersinia spp. be extended to include both of these regions. Low amounts of the YOPs were detected in the membrane fraction at 37 degrees C in the presence of 2.5 mM calcium. Only minor differences were noticed when the individual YOPs of Y. pestis and Y. pseudotuberculosis were compared. Several differences were observed when the YOPs of Y. enterocolitica were included for comparison. All Y. enterocolitica proteins, except YOP1, YOP4b, and the V antigen, exhibited changes in their characteristic molecular sizes. Although these differences were within a range of +/- 2 kilodaltons, the isoelectric point was retained for each protein type.

Post-translational regulation of Lcr plasmid-mediated peptides in pesticinogenic Yersinia pestis

The low calcium response of wild type Yersinia pestis, the causative agent of bubonic plague, and of enteropathogenic Yersinia pseudotuberculosis and Yersinia enterocolitica is known to be mediated by a shared Lcr plasmid of about 70 kb. At 37 degrees C in Ca2+-deficient medium, this element promotes restriction of growth with concomitant production of virulence functions including the common V antigen and a set of yersiniae outer membrane peptides termed YOPs (Lcr+). The latter are expressed by the enteropathogenic species but not by wild type Y. pestis which possesses a unique 10 kb Pst plasmid associated with pesticinogeny (Pst+). We show in this report that, after pulse with 35S-methionine, peptides with molecular weights corresponding to YOPs of 78, 47, 45, 44, 36, and 26 kDa are synthesized during the low calcium response by both Lcr+, Pst+ and Lcr+, Pst- cells of Y. pestis. Although stable in the latter, radioactivity in YOPs of wild type was rapidly chased into lower molecular weight degradation products. At least four soluble peptides, including V, were also labeled during starvation for Ca2+; these structures were stable in both Lcr+, Pst+ and Lcr+, Pst- yersiniae. These findings suggest that a product encoded by the Pst plasmid of Y. pestis is required for post-translational regulation of outer membrane but not soluble peptides mediated by a second unrelated Lcr plasmid.