A novel contractility pathway operating in Salmonella invasion.

S. typhimurium can infect host cells not only by the well-established "trigger"-mode of invasion, inducing the formation of prominent membrane ruffles e.g., as during macropinocytosis, but also independently of these processes. Recently, we have found that the novel, ruffling-independent entry mechanism usurps the host cell contraction machinery. This mode of entry involves formation of myosin II-rich stress fiber-like structures at invasion sites, likely through stimulation of a RhoA/Rho-kinase signaling pathway and mostly downstream of the Salmonella virulence factor SopB. Importantly, this pathway operates independently of Arp2/3 complex, a central regulator of the macropinocytic entry mode. Here, we will describe our current thinking of how the contraction-dependent uptake mechanism operates to promote Salmonella invasion, and which additional cellular or bacterial factors might get engaged in the process. Finally, we will speculate on the implications of these findings for invasion by other bacterial pathogens, and discuss their impact on the canonical trigger-vs.-zipper classification of entry mechanisms employed by distinct bacterial pathogens.

Host cell invasion mediated by Trypanosoma cruzi surface molecule gp82 is associated with F-actin disassembly and is inhibited by enteroinvasive Escherichia coli.

The target cell F-actin disassembly, induced by a Ca2+-signaling Trypanosoma cruzi factor of unknown molecular identity, has been reported to promote parasite invasion. We investigated whether the metacyclic trypomastigote stage-specific surface molecule gp82, a Ca2+-signal-inducing molecule implicated in host cell invasion, displayed the ability to induce actin cytoskeleton disruption, using a recombinant protein (J18) containing the full-length gp82 sequence fused to GST. J18, but not GST, induced F-actin disassembly in HeLa cells, significantly reducing the number as well as the length of stress fibers. The number of cells with typical stress fibers scored approximately 70% in untreated and GST-treated cells, as opposed to approximately 30% in J18-treated samples, which also showed decreased F-actin content. J18, but not GST, inhibited approximately 6-fold the HeLa cell entry of enteroinvasive Escherichia coli (EIEC), which depends on actin cytoskeleton. Not only were fewer cells infected with bacteria in the presence of J18, there were also fewer bacteria per cell. The inhibitory activity of J18 was Ca2+ dependent. In co-infection experiments, preincubation of HeLa cells with EIEC drastically reduced gp82-dependent internalization of T. cruzi metacyclic forms. All these data, plus the finding that gp82-mediated penetration of metacyclic forms was associated with disrupted HeLa cell cytoskeletal architecture, indicate that gp82 promotes parasite invasion by disassembling the cortical actin cytoskeleton.