Activation of pro-matrix metalloproteinase-9 and degradation of gelatin by the surface protease PgtE of Salmonella enterica serovar Typhimurium.

Mammalian matrix metalloproteinases (MMPs) degrade collagen networks in extracellular matrices by cleaving collagen and its denatured form gelatin, and thus enhance migration of mammalian cells. The gastrointestinal pathogen Salmonella enterica survives and grows within host macrophages and dendritic cells, and can disseminate in the host by travelling within infected host cells. Here, we report that S. enterica serovar Typhimurium activates proMMP-9 (gelatinase B) secreted by human primary macrophages, and degrades gelatin after growth within J774A.1 murine macrophage-like cells. Both proMMP-9 activation and gelatin degradation were due to expression of the Salmonella surface protease PgtE. Following intraperitoneal infection in BALB/c mice, the amount of a pgtE deletion derivative was nearly ten-fold lower in the livers and spleens of mice than the amount of wild-type S. enterica, suggesting that PgtE contributes to dissemination of Salmonella in the host. PgtE belongs to the omptin family of bacterial beta-barrel transmembrane proteases. The ortholog of PgtE in Yersinia pestis, Pla, which is central for bacterial virulence in plague, was poor in proMMP-9 activation and in gelatin degradation. To model the evolution of these activities in the omptin barrel, we performed a substitution analysis in Pla and genetically modified it into a PgtE-like gelatinase. Our results indicate that PgtE and Pla have diverged in substrate specificity, and suggest that Salmonella PgtE has evolved to functionally mimic mammalian MMPs.

Using every trick in the book: the Pla surface protease of Yersinia pestis.

The Pla surface protease of Yersinia pestis, encoded by the Y. pestis-specific plasmid pPCP1, is a versatile virulence factor. In vivo studies have shown that Pla is essential in the establishment of bubonic plague, and in vitro studies have demonstrated various putative virulence functions for the Pla molecule. Pla is a surface protease of the omptin family, and its proteolytic targets include the abundant, circulating human zymogen plasminogen, which is activated by Pla to the serine protease plasmin. Plasmin is important in cell migration, and Pla also proteolytically inactivates the main circulating inhibitor of plasmin, alpha2-antiplasmin. Pla also is an adhesin with affinity for laminin, a major glycoprotein of mammalian basement membranes, which is degraded by plasmin but not by Pla. Together, these functions create uncontrolled plasmin proteolysis targeted at tissue barriers. Other proteolytic targets for Pla include complement proteins. Pla also mediates bacterial invasion into human endothelial cell lines; the adhesive and invasive charateristics of Pla can be genetically dissected from its proteolytic activity. Pla is a 10-stranded antiparallel beta-barrel with five surface-exposed short loops, where the catalytic residues are oriented inwards at the top of the beta-barrel. The sequence of Pla contains a three-dimensional motif for protein binding to lipid A of the lipopolysaccharide. Indeed, the proteolytic activity of Pla requires rough lipopolysaccharide but is sterically inhibited by the O antigen in smooth LPS, which may be the selective advantage of the loss of O antigen in Y. pestis. Members of the omptin family are highly similar in structure but differ in functions and virulence association. The catalytic residues of omptins are conserved, but the variable substrate specificities in proteolysis by Pla and other omptins are dictated by the amino acid sequences near or at the surface loops, and hence reflect differences in substrate binding. The closest orthologs of Pla are PgtE of Salmonella and Epo of Erwinia, which functionally differ from Pla. Pla gives a model of how a horizontally transferred protein fold can diverge into a powerful virulence factor through adaptive mutations.

The surface protease PgtE of Salmonella enterica affects complement activity by proteolytically cleaving C3b, C4b and C5.

Complement activity in mammalian serum is fundamentally based on three homologous components C3b, C4b and C5. During systemic infection, the gastrointestinal pathogen Salmonella enterica disseminates within host phagocytic cells but also extracellularly. Consequently, systemic Salmonella transiently confronts the complement system. We show here that the surface protease PgtE of S. enterica proteolytically cleaves C3b, C4b and C5 and that the expression of PgtE enhances bacterial resistance to human serum. Degradation of C3b was further enhanced by PgtE-mediated plasminogen activation.