ExoU expression by Pseudomonas aeruginosa correlates with acute cytotoxicity and epithelial injury
SummaryThe production of exoenzyme S is correlated with the ability of Pseudomonas aeruginosa to disseminate from epithelial colonization sites and cause a fatal sepsis in burn injury and acute lung infection models. Exoenzyme S is purified from culture supernatants as a non-covalent aggregate of two polypeptides, ExoS and ExoT. ExoS and ExoT are encoded by separate but highly similar genes, exoS and exoT. Clinical isolates that injure lung epithelium in vivo and that are cytotoxic in vitro possess exoT but lack exoS, suggesting that ExoS is not the cytotoxin responsible for the pathology and cell death measured in these assays. We constructed a specific mutation in exoT and showed that this strain, PA103 exoT::Tc, was cytotoxic in vitro and caused epithelial injury in vivo, indicating that another cytotoxin was responsible for the observed pathology. To identify the protein associated with acute cytotoxicity, we compared extracellular protein profiles of PA103, its isogenic non-cytotoxic derivative PA103 exsA::⍀ and several cytotoxic and non-cytotoxic P. aeruginosa clinical isolates. This analysis indicated that, in addition to expression of ExoT, expression of a 70-kDa protein correlated with the cytotoxic phenotype. Specific antibodies to the 70-kDa protein bound to extracellular proteins from cytotoxic isolates but failed to bind to similar antigen preparations from non-cytotoxic strains or PA103 exsA::⍀. To clone the gene encoding this potential cytotoxin we used Tn5 Tc mutagenesis and immunoblot screening to isolate an insertional mutant, PA103exoU :: Tn5 Tc, which no longer expressed the 70-kDa extracellular protein but maintained expression of ExoT. PA103 exoU ::Tn5 Tc was non-cytotoxic and failed to injure the epithelium in an acute lung infection model. Complementation of PA103exoU ::Tn5 Tc with exoU restored cytotoxicity and epithelial injury. ExoU, ExoS and ExoT share similar promoter structures and an identical binding site for the transcriptional activator, ExsA, data consistent with their co-ordinate regulation. In addition, all three proteins are nearly identical in the first six amino acids, suggesting a common amino terminal motif that may be involved in the recognition of the type III secretory apparatus of P. aeruginosa.
Exoenzyme S is an extracellular ADP-ribosyltransferase of Pseudomonas aeruginosa. Transposon mutagenesis of P. aeruginosa 388 was used to identify genes required for exoenzyme S production. Five Tn5Tc insertion mutants were isolated which exhibited an exoenzyme S-deficient phenotype (388::Tn5Tc 469, 550, 3453, 4885, and 5590). Mapping experiments demonstrated that 388::Tn5Tc 3453, 4885, and 5590 possessed insertions within a 5.0 kb EcoRI fragment that is not contiguous with the exoenzyme S trans-regulatory operon. 388::Tn5Tc 469 and 550 mapped to a region downstream of the trans-regulatory operon which has been previously shown to contain a promoter region that is co-ordinately regulated with exoenzyme S synthesis. Nucleotide sequence analysis of a 7.2 kb region flanking the 388::Tn5Tc 469 and 550 insertions, identified 12 contiguous open reading frames (ORFs). Database searches indicated that the first ORF, ExsD, is unique. The other 11 ORFs demonstrated high homology to the YscB-L proteins of the yersiniae Yop type III export apparatus. RNase-protection analysis of wild-type and mutant strains indicated that exsD and pscB-L form an operon. To determine whether ExoS was exported by a type III mechanism, derivatives consisting of internal deletions or lacking amino- or carboxy-terminal residues were expressed in P. aeruginosa. Deletion analyses indicated that the amino-terminal nine residues are required for ExoS export. Combined data from mutagenesis, regulatory, expression, and sequence analyses provide strong evidence that P. aeruginosa possesses a type III secretion apparatus which is required for the export of exoenzyme S and potentially other co-ordinately regulated proteins.
The ferric enterobactin receptor (FepA) is a high-affinity ligand-specific transport protein in the outer membrane of Gram-negative bacteria. Deletion of the cell-surface ligand-binding peptides of FepA generated mutant proteins that were incapable of high-affinity uptake but that instead formed nonspecific, passive channels in the outer membrane. Unlike native FepA, these pores acted independently of the accessory protein TonB, which suggests that FepA is a gated porin and that TonB acts as its gatekeeper by facilitating the entry of ligands into the FepA channel. The sequence homology among TonB-dependent proteins suggests that all ligand-specific outer membrane receptors may function by this gated-porin mechanism.
The dissemination of Pseudomonas aeruginosa to the bloodstream increases the likelihood of developing fatal sepsis. In experimental models, the ability to disseminate is linked to expression of the exoenzyme S pathway. Genetic and biochemical analysis of the pathway has led to the identification of the two structural genes encoding exoenzyme S, exoS and exoT. A key regulator of several loci of the pathway has been identified as a DNA-binding protein with transcriptional activation properties. Preliminary evidence suggests that exoenzyme S and the Yop virulence determinants of yersiniae share homology among proteins involved in their synthesis and secretion. With the addition of exoS and exoT to the molecular arsenal, questions concerning in vivo toxicity and target specificities of exoenzyme S can be directly addressed.
Expression of ExsC, ExsB, and ExsA (the exoenzyme S trans-regulatory locus) of Pseudomonas aeruginosa was analyzed by using complementation, RNase protection, translational fusion, and T7-directed protein expression analyses. T7 expression analyses in E. coli hosts demonstrated that ExsC, ExsA, and a truncated form of ExsD (a partial open reading frame located 3 of ExsA) were translated; however, a product corresponding to ExsB was undetectable. T7-mediated transcription and translation of the antisense strand resulted in production of a 18.5-kDa product, termed ExsB, which overlapped the predicted ExsB product. In complementation experiments, deletion of the region encoding ExsB and most of ExsB severely reduced exoenzyme S production. Site-specific mutagenesis of the start codons for ExsB and ExsB, however, did not affect exoenzyme S production. RNase protection studies were initiated to examine the hypothesis that RNA encoded within the ExsB/ExsB region exerted a regulatory effect. RNA encoding ExsB was not detectable from chromosomal genes or complementation constructs, indicating that ExsB was not expressed in P. aeruginosa. To determine the pattern of translation, a chloramphenicol acetyltransferase gene (cat) reporter was fused in frame with ExsB and with ExsA in the context of the entire locus or in the absence of the exsB region. These experiments indicated that exsB was not translated but that deletion of the exsB region affected the translation of ExsA-CAT. RNase protection assays further suggested that deletion of exsB resulted in a processing of ExsA mRNA. Our data indicate that the untranslated exsB region of the trans-regulatory locus mRNA mediates either the stability or the translation of exsA. Complementation analysis further suggests that ExsC may play a role in the translation or stability of ExoS.Exoenzyme S is an ADP-ribosyltransferase produced and secreted by the opportunistic pathogen Pseudomonas aeruginosa (3,5,22,34,42). Two immunologically related forms of exoenzyme S with molecular masses of 49 and 53 kDa have been identified (22). The two forms are encoded by separate but coordinately regulated genes (48). Exoenzyme S-mediated ADP-ribosyltransferase activity requires the participation of a eukaryotic protein termed FAS (Factor activating exoenzyme S) (5,8). FAS is a member of the 14-3-3 family of proteins, which regulate the activity and interaction of several eukaryotic proteins (15). Exoenzyme S covalently modifies monomeric vimentin (5, 6) and a variety of small (21-to 25-kDa) GTP-binding proteins of the H-and K-Ras families (5, 7). In burn wound and lung infection models, exoenzyme S production correlates with the dissemination of P. aeruginosa from epithelial colonization sites to the bloodstream (34,35,36). An attractive model that fits these data suggests that exoenzyme S ADP-ribosyltransferase activity disrupts epithelial cell signal transduction pathways, resulting in a breakdown of the epithelial barrier.Genetic studies and complementation analysis of the exoenzyme S-defici...
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