New frontiers in type III secretion biology: the Chlamydia perspective.

Members of the order Chlamydiales comprise a group of exquisitely evolved parasites of eukaryotic hosts that extends from single-celled amoeba to mammals. The most notable are human pathogens and include the agent of oculogenital disease Chlamydia trachomatis, the respiratory pathogen C. pneumoniae, and the zoonotic agent C. psittaci. All of these species are obligate intracellular bacteria that develop within parasitophorous vesicles termed inclusions. This demanding lifestyle necessitates orchestrated entry into nonphagocytic cells, creation of a privileged intracellular niche, and subversion of potent host defenses. All chlamydial genomes contain the coding capacity for a nonflagellar type III secretion system, and this mechanism has arisen as an essential contributor to chlamydial virulence. The emergence of tractable approaches to the genetic manipulation of chlamydiae raises the possibility of explosive progress in understanding this important contributor to chlamydial pathogenesis. This minireview considers challenges and recent advances that have revealed how chlamydiae have maintained conserved aspects of T3S while exploiting diversification to yield a system that exerts a fundamental role in the unique biology of Chlamydia species.

Type III export: new uses for an old pathway.

Gram-negative bacteria use type III secretion (TTS) systems to translocate proteins into the extracellular environment or directly into eukaryotic cells. These complex secretory systems are assembled from over 20 different structural proteins, including 10 that have counterparts in the flagellar export pathway. Secretion substrates are directed to the TTS machinery via mRNA and/or amino acid secretion signals. TTS chaperones bind to select secretion substrates and assist in the export process. Recent progress in the understanding of TTS is reviewed.

Yersinia pestis YscG protein is a Syc-like chaperone that directly binds yscE.

Pathogenic Yersinia species secrete virulence proteins, termed Yersinia outer proteins (Yops), upon contact with a eukaryotic cell. The secretion machinery is composed of 21 Yersinia secretion (Ysc) proteins. Yersinia pestis mutants defective in expression of YscG or YscE were unable to export the Yops. YscG showed structural and limited amino-acid-sequence similarities to members of the specific Yop chaperone (Syc) family of proteins. YscG specifically recognized and bound YscE; however, unlike previously characterized Syc substrates, YscE was not exported from the cell. These data suggest that YscG functions as a chaperone for YscE.

Interactions between type III secretion apparatus components from Yersinia pestis detected using the yeast two-hybrid system.

Interactions among the Yersinia secretion (Ysc) proteins of Yersinia pestis were explored using the yeast two-hybrid system. Various pairwise combinations of the yscEFGHIKLN and Q genes fused to the DNA-binding or activation domain of the yeast GAL4 gene were introduced into yeast, and expression of a reporter gene encoding beta-galactosidase was detected. Combinations of yscN and yscL, yscL and yscQ, and yscQ and yscK resulted in high levels of reporter gene activation. These results suggest that YscL interacts with both YscN and YscQ, and that YscQ interacts with both YscL and YscK. Three-hybrid analyses using plasmid pDELA to target a third hybrid protein to the yeast nucleus was used to detect the formation of ternary protein complexes. Using the three-hybrid system, YscQ expressed from plasmid pDELA was able to bring together the YscK and YscL fusion proteins. In a similar manner, YscL expressed from plasmid pDELA was able to bring together the YscN and YscQ fusion proteins. Together, these results suggest that a complex composed of YscN, YscQ, YscK and YscL is involved in the assembly and/or function of the Y. pestis type III secretion apparatus.

The Yersinia pestis YscY protein directly binds YscX, a secreted component of the type III secretion machinery.

Human pathogenic yersiniae organisms export and translocate the Yop virulence proteins and V antigen upon contact with a eukaryotic cell. Yersinia pestis mutants defective for production of YscX or YscY were unable to export the Yops and V antigen. YscX and YscY were both present in the Y. pestis cell pellet fraction; however, YscX was also found in the culture supernatant. YscY showed structural and amino acid sequence similarities to the Syc family of proteins. YscY specifically recognized and bound to a region of YscX that included a predicted coiled-coil region. These data suggest that YscY may function as a chaperone for YscX in Y. pestis.

DsbA is required for stable expression of outer membrane protein YscC and for efficient Yop secretion in Yersinia pestis.

The role of the periplasmic disulfide oxidoreductase DsbA in Yop secretion was investigated in Yersinia pestis. A Y. pestis dsbA mutant secreted reduced amounts of the V antigen and Yops and expressed reduced amounts of the full-sized YscC protein. Site-directed mutagenesis of the four cysteine residues present in the YscC protein resulted in defects similar to those found in the dsbA mutant. These results suggest that YscC contains at least one disulfide bond that is essential for the function of this protein in Yop secretion.

Complete DNA sequence and detailed analysis of the Yersinia pestis KIM5 plasmid encoding murine toxin and capsular antigen.

Yersinia pestis, the causative agent of plague, harbors at least three plasmids necessary for full virulence of the organism, two of which are species specific. One of the Y. pestis-specific plasmids, pMT1, is thought to promote deep tissue invasion, resulting in more acute onset of symptoms and death. We determined the entire nucleotide sequence of Y. pestis KIM5 pMT1 and identified potential open reading frames (ORFs) encoded by the 100,990-bp molecule. Based on codon usage for known yersinial genes, homology with known proteins in the databases, and potential ribosome binding sites, we determined that 115 of the potential ORFs which we considered could encode polypeptides in Y. pestis. Five of these ORFs were genes previously identified as being necessary for production of the classic virulence factors, murine toxin (MT), and the fraction 1 (F1) capsule antigen. The regions of pMT1 encoding MT and F1 were surrounded by remnants of multiple transposition events and bacteriophage, respectively, suggesting horizontal gene transfer of these virulence factors. We identified seven new potential virulence factors that might interact with the mammalian host or flea vector. Forty-three of the remaining 115 putative ORFs did not display any significant homology with proteins in the current databases. Furthermore, DNA sequence analysis allowed the determination of the putative replication and partitioning regions of pMT1. We identified a single 2,450-bp region within pMT1 that could function as the origin of replication, including a RepA-like protein similar to RepFIB, RepHI1B, and P1 and P7 replicons. Plasmid partitioning function was located ca. 36 kb from the putative origin of replication and was most similar to the parABS bacteriophage P1 and P7 system. Y. pestis pMT1 encoded potential genes with a high degree of similarity to a wide variety of organisms, plasmids, and bacteriophage. Accordingly, our analysis of the pMT1 DNA sequence emphasized the mosaic nature of this large bacterial virulence plasmid and provided implications as to its evolution.

YscB of Yersinia pestis functions as a specific chaperone for YopN.

Following contact with a eucaryotic cell, Yersinia species pathogenic for humans (Y. pestis, Y. pseudotuberculosis, and Y. enterocolitica) export and translocate a distinct set of virulence proteins (YopE, YopH, YopJ, YopM, and YpkA) from the bacterium into the eucaryotic cell. During in vitro growth at 37 degrees C in the presence of calcium, Yop secretion is blocked; however, in the absence of calcium, Yop secretion is triggered. Yop secretion occurs via a plasmid-encoded type III, or "contact-dependent," secretion system. The secreted YopN (also known as LcrE), TyeA, and LcrG proteins are necessary to prevent Yop secretion in the presence of calcium and prior to contact with a eucaryotic cell. In this paper we characterize the role of the yscB gene product in the regulation of Yop secretion in Y. pestis. A yscB deletion mutant secreted YopM and V antigen both in the presence and in the absence of calcium; however, the export of YopN was specifically reduced in this strain. Complementation with a functional copy of yscB in trans completely restored the wild-type secretion phenotype for YopM, YopN, and V antigen. The YscB amino acid sequence showed significant similarities to those of SycE and SycH, the specific Yop chaperones for YopE and YopH, respectively. Protein cross-linking and immunoprecipitation studies demonstrated a specific interaction between YscB and YopN. In-frame deletions in yopN eliminating the coding region for amino acids 51 to 85 or 6 to 100 prevented the interaction of YopN with YscB. Taken together, these results indicate that YscB functions as a specific chaperone for YopN in Y. pestis.

A complex composed of SycN and YscB functions as a specific chaperone for YopN in Yersinia pestis.

Human pathogenic Yersinia resist host defences, in part through the expression and delivery of a set of plasmid-encoded virulence proteins termed Yops. A number of these Yops are exported from the bacteria directly into the cytoplasm of their eukaryotic host's cells upon contact with these cells. The secreted YopN protein (also known as LcrE) is required to block Yop secretion in the presence of calcium in vitro or before contact with a eukaryotic cell in vivo. In this study, we characterize the role of the tyeA, sycN and yscB gene products in the regulation of Yop secretion in Yersinia pestis. Mutants specifically defective in the expression of TyeA, SycN or YscB were no longer able to block Yop secretion in the presence of calcium. In addition, the secretion of YopN was specifically reduced in both the sycN and the yscB deletion mutants. Protein cross-linking and immunoprecipitation studies in conjunction with yeast two-hybrid analyses showed that SycN and YscB interact with one another to form a SycN/YscB complex. Yeast three-hybrid analyses demonstrated that the SycN/YscB complex, but not SycN or YscB alone, specifically associates with YopN. SycN and YscB share amino acid sequence similarity and structural similarities with the specific Yop chaperones SycE and SycH. Together, these results indicate that a complex composed of SycN and YscB functions as a specific chaperone for YopN in Y. pestis.

Mutations in yscC, yscD, and yscG prevent high-level expression and secretion of V antigen and Yops in Yersinia pestis.

The Yersinia pestis low-Ca2+ response stimulon is responsible for the temperature- and Ca(2+)-regulated expression and secretion of plasmid pCD1-encoded antihost proteins (V antigen and Yops). We have previously shown that lcrD and yscR encode proteins that are essential for high-level expression and secretion of V antigen and Yops at 37 degrees C in the absence of Ca2+. In this study, we constructed and characterized mutants with in-frame deletions in yscC, yscD, and yscG of the ysc operon that contains yscA through yscM. All three mutants lost the Ca2+ requirement for growth at 37 degrees c, expressed only basal levels of V antigen and YopM in the presence or absence of Ca2+, and failed to secrete these proteins to the culture supernatant. Overproduction of YopM in these mutants failed to restore YopM export, showing that the mutations had a direct effect on secretion. The protein products of yscC, yscD, and yscG were identified and localized by immunoblot analysis. YscC was localized to the outer membrane of Y. pestis, while YscD was found in the inner membrane. YscG was distributed equally between the soluble and total membrane fractions. Double mutants were characterized to assess where YscC and YscD act in low-Ca2+ response (LCR) regulation. lcrH::cat-yscC and lcrH::cat-yscD double mutants were constitutively induced for expression of V antigen and YopM; however, these proteins were not exported. This finding showed that the ysc mutations did not directly decrease induction of LCR stimulon genes. In contrast, lcrE-yscC, lcrG-yscC, lcrE-yscD, and lcrG-yscD double mutants as well as an lcrE-lcrD double mutant expressed only basal levels of V antigen and YopM and also failed to secrete these proteins to the culture supernatant. These results indicated that a functional LCR secretion system was necessary for high-level expression of LCR stimulon proteins in the lcrE and lcrG mutants but not in an lcrH::cat mutant. Possible models of regulation which incorporate these results are discussed.

A low-Ca2+ response (LCR) secretion (ysc) locus lies within the lcrB region of the LCR plasmid in Yersinia pestis.

The causative agent of plague, Yersinia pestis, contains a 75-kb plasmid, pCD1, which carries a virulence-related stimulon called the low-Ca2+ response stimulon (LCRS). LCRS operons are regulated by the environmental signals of temperature and Ca2+. This study characterized a portion of the lcrB region of pCD1, known to contain at least one gene necessary for the regulation of LCRS operons by Ca2+. The sequence of a 2-kb region revealed three open reading frames, designated yscQ, yscR, and yscS, predicted to encode acidic proteins of 34.4, 24.4, and 8.5 kDa. All three proteins were homologous to proteins involved in flagellar function or virulence. An antipeptide antibody specific for YscR was used to localize YscR to the inner membrane of Y. pestis. Analysis of yscR-phoA fusions supported a model for yscR which predicts four transmembrane regions and a large, central hydrophilic domain. In-frame deletion mutations of yscQ and yscR were constructed and moved into Y. pestis. Both mutants failed to show the restriction of growth that normally accompanies maximal LCRS induction. Unlike the parent Y. pestis, the yscR mutant did not respond to the absence of Ca2+ by increasing the net transcription or translation of the LCRS-encoded V antigen, YopM, or LcrG. The yscR mutant also was defective for secretion of V antigen, YopM, and LcrG. These findings implicate a dual role for YscR in regulation of LCRS operons and secretion of LCRS proteins and add to the developing picture of how secretion of virulence proteins may be coupled to transcriptional regulation in yersiniae.

Regulation by Ca2+ in the Yersinia low-Ca2+ response.

The Yersinia low-Ca2+ response (LCR) is a regulatory response in which a set of plasmid-borne operons is transcriptionally regulated at 37 degrees C in response to the presence or absence of mM concentrations of Ca2+. LCR-regulated operons encode secreted proteins with regulatory and virulence roles as well as non-secreted regulatory proteins and components of the secretion machinery. Downregulation by Ca2+ is imposed by a signalling cascade that includes secreted proteins and possibly also components of the secretion system and is hypothesized to act on membrane-bound inductive components. An important role in LCR induction is played by LcrD, an inner-membrane protein with homologues in several virulence-associated and flagella assembly-related systems in diverse bacterial species. The mechanism of signal transduction in response to Ca2+ is not known, and the proteins that bind DNA to downregulate transcription have not been identified.

Multiple effects of lcrD mutations in Yersinia pestis.

Plasmid pCD1 of Yersinia pestis contains a low-calcium response stimulon responsible for the temperature- and calcium-regulated expression and secretion of proteins involved in virulence, which include the V antigen and Yops. We have previously shown that insertional inactivation of the bicistronic lcrDR operon abolished the calcium requirement for growth at 37 degrees C and reduced expression of the V antigen and Yops. In this study, we constructed and characterized three mutants having nonpolar lcrD deletions. All three mutants lost the two main low-calcium response properties: a calcium requirement for growth at 37 degrees C and strong expression of the V antigen and Yops. The effects on virulence gene expression occurred at both the levels of transcription and secretion. The growth, transcription, and secretion defects could be at least partially complemented for two of the lcrD mutants by providing lcrD in trans. A third mutant could not be complemented, and a plasmid carrying this mutation had a dominant negative effect over normal LcrD function. In the three mutants, the amount of mutant LcrD protein detectable in immunoblots was inversely related to the amount of complementation. Taken together, these data indicate that LcrD function involves the interaction of LcrD with another molecule.

New suicide vector for gene replacement in yersiniae and other gram-negative bacteria.

A suicide vector named pUK4134 was constructed to enlarge the repertoire of vectors available for allelic exchange of mutated sequences in gram-negative bacteria. This plasmid combines the properties of two previously described plasmid vectors, pJM703.1 and pRTP1. pUK4134 is a suicide vector, carrying the origin of replication of the plasmid R6K and thus requiring the product of the pir gene for its stable maintenance. The rpsL gene encoding Escherichia coli ribosomal protein S12 confers streptomycin sensitivity on streptomycin-resistant strains and provides a positive selection for bacteria that have lost the plasmid following allelic exchange. The bla gene provides for selection by Apr. Other features are a unique EcoRV cloning site, oriT of plasmid RK2, and the bacteriophage lambda cos sequence. This vector was successfully used several times to carry out allelic exchange in Yersinia pestis.

LcrD, a membrane-bound regulator of the Yersinia pestis low-calcium response.

Yersinia pestis, the etiologic agent of bubonic plague, contains a 75-kb virulence plasmid, called pCD1 in Y. pestis KIM. The low-Ca(2+)-response genes of Y. pestis regulate both bacterial growth and the expression of pCD1-encoded virulence determinants in response to temperature and the presence of Ca2+ or nucleotides. This study characterizes the nucleotide sequence and protein product of the lcrD locus. An lcrD mutant, in contrast to the parent Y. pestis, did not undergo growth restriction or induce strong expression of the V antigen when grown under conditions (37 degrees C, no Ca2+) expected to elicit maximal expression of pCD1 genes. DNA sequence analysis of the cloned lcrD locus showed a single open reading frame that could encode a protein with a molecular weight of 77,804 and a pI of 4.88. LcrD was identified as a 70-kDa inner membrane protein by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblot analysis. LcrD membrane topology was investigated by using lcrD-phoA translational fusions generated with the transposon TnphoA. The alkaline phosphatase activities of the resultant hybrid proteins were consistent with a model predicting eight amino-terminal transmembrane segments that anchor a large cytoplasmic carboxyl-terminal domain to the inner membrane.

Identification and initial topological analysis of the Rickettsia prowazekii ATP/ADP translocase.

The Rickettsia prowazekii ATP/ADP translocase was identified by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and immunoblot analysis using antibodies raised against a synthetic peptide corresponding in sequence to the carboxyl-terminal 17 amino acids of the carrier. Both the translocase of R. prowazekii and that expressed by Escherichia coli transformants containing the rickettsial gene had an apparent molecular mass of 36,500 Da by SDS-PAGE analysis, a mass considerably less than that deduced from the sequence of the gene. The SDS-solubilized translocase aggregated upon heating at 100 degrees C in the presence of disulfide bond-reducing agents. Similar concentrations of disulfide bond-reducing agents inhibited the exchange transport of adenine nucleotides by both R. prowazekii and translocase-expressing E. coli. These data suggested that an intramolecular disulfide bond in the translocase was essential for transport activity. The antipeptide antibodies used for identification of the translocase bound preferentially to inside-out membrane vesicles of translocase-expressing E. coli relative to right-side-out spheroplasts, thus indicating that the carboxyl terminus of the carrier is located on the cytoplasmic side of the bacterial inner membrane. Protease studies were unable to localize the carboxyl terminus because of the resistance of this region of the native translocase to proteolytic cleavage. These data in conjunction with hydrophobicity analysis were used to construct an initial topological model of the translocase within the cell membrane.

Solubilization and reconstitution of the Rickettsia prowazekii ATP/ADP translocase.

The ATP/ADP translocase protein of Rickettsia prowazekii, an obligate intracellular parasite that had been grown in the chick yolk sac, was solubilized and reconstituted into liposomes composed of Escherichia coli phospholipid by an octylglucoside dilution procedure. Proteoliposomes prepared from membranes of Renografin-purified R. prowazekii translocated ATP by an obligate exchange mechanism. Influx of extravesicular ATP required intravesicular transportable nucleotide and efflux of intravesicular ATP required transportable extravesicular nucleotide in the medium. The transport activity was insensitive to carboxyatractyloside and bongkrekic acid, inhibitors of mitochondrial ADP/ATP translocation. Proteoliposomes prepared from membranes of standard (non-Renografin-purified) R. prowazekii exhibited both an inhibitor-sensitive mitochondrial translocase activity and an inhibitor-resistant rickettsial translocase activity. Proteoliposomes prepared from uninoculated yolk sac membranes exhibited only the inhibitor-sensitive mitochondrial translocase activity. The substrate specificity of each reconstituted translocase was determined and shown to correspond with that reported for intact mitochondria or rickettsiae. Following influx of ATP the steady-state value for intravesicular labeled ATP was dependent on the concentration of intravesicular nucleotide available for exchange.

Nucleotide sequence of the Rickettsia prowazekii ATP/ADP translocase-encoding gene.

The Rickettsia prowazekii ATP/ADP translocase (Tlc) gene (tlc), previously cloned in Escherichia coli was localized to a 1.6-kb chromosomal fragment. Nucleotide sequence analysis of this fragment revealed an open reading frame of 1494 bp that could encode a hydrophobic protein of 497 amino acids (aa) with an Mr of 56,668. Analysis of the deduced aa sequence revealed that it contained twelve potential membrane-spanning regions. Comparisons between the deduced aa sequence of the R. prowazekii ATP/ADP Tlc and the sequences of mitochondrial (mt) Tlc revealed no detectable homologies between the rickettsial and mt sequences. The major protein synthesized in E. coli minicells containing the rickettsial gene exhibited and Mr of approx. 34,000.