Enterohaemorrhagic Escherichia coli requires the spectrin cytoskeleton for efficient attachment and pedestal formation on host cells.

Recent work has demonstrated that the spectrin cytoskeleton is a host cell target, exploited during intestinal bacterial disease. Here we show that the highly virulent intestinal pathogen enterohaemorrhagic Escherichia coli (EHEC) is also reliant upon the spectrin cytoskeleton during key pathogenic events. Immunofluorescent microscopy demonstrated that the core components of the spectrin cytoskeleton (spectrin, adducin, and protein 4.1 [p4.1]) are recruited to sites of EHEC attachment and localized at pedestal structures along with the EHEC pedestal specific proteins IRSp53 and IRTKS. Further studies involving siRNA-mediated knockdowns of spectrin, adducin, or p4.1 revealed that those proteins are needed for efficient docking of EHEC to host cells, are involved in recruiting IRSp53 to the pedestal and are necessary for pedestal formation. These findings identify the spectrin cytoskeleton as a major host cell cytoskeletal network involved in critical EHEC pathogenic events.

Francisella tularensis uses cholesterol and clathrin-based endocytic mechanisms to invade hepatocytes.

Francisella tularensis are highly infectious microbes that cause the disease tularemia. Although much of the bacterial burden is carried in non-phagocytic cells, the strategies these pathogens use to invade these cells remains elusive. To examine these mechanisms we developed two in vitro Francisella-based infection models that recapitulate the non-phagocytic cell infections seen in livers of infected mice. Using these models we found that Francisella novicida exploit clathrin and cholesterol dependent mechanisms to gain entry into hepatocytes. We also found that the clathrin accessory proteins AP-2 and Eps15 co-localized with invading Francisella novicida as well as the Francisella Live Vaccine Strain (LVS) during hepatocyte infections. Interestingly, caveolin, a protein involved in the invasion of Francisella in phagocytic cells, was not required for non-phagocytic cell infections. These results demonstrate a novel endocytic mechanism adopted by Francisella and highlight the divergence in strategies these pathogens utilize between non-phagocytic and phagocytic cell invasion.

Hijacking the endocytic machinery by microbial pathogens.

Understanding the mechanisms that microbes exploit to invade host cells and cause disease is crucial if we are to eliminate their threat. Although pathogens use a variety of microbial factors to trigger entry into non-phagocytic cells, their targeting of the host cell process of endocytosis has emerged as a common theme. To accomplish this, microbes often rewire the normal course of particle internalization, frequently usurping theoretical maximal sizes to permit entry and reconfiguring molecular components that were once thought to be required for vesicle formation. Here, we discuss recent advances in our understanding of how toxins, viruses, bacteria, and fungi manipulate the host cell endocytic machinery to generate diseases. Additionally, we will reveal the advantages of using these organisms to expand our general knowledge of endocytic mechanisms in eukaryotic cells.

Gap junction hemichannels contribute to the generation of diarrhoea during infectious enteric disease.

OBJECTIVE: The attaching and effacing (A/E) pathogens enterohaemorrhagic Escherichia coli, enteropathogenic E coli and Citrobacter rodentium colonise intestinal tracts, attach to enterocytes, collapse infected cell microvilli and alter numerous host cell processes during infection. Enterocyte alterations result in numerous small molecules being released from host cells that likely contribute to diarrhoeal phenotypes observed during these infections. One possible route for small molecules to be released from intestinal cells may be through functional gap junction hemichannels. Here we examine the involvement of these hemichannels during the diarrhoeal disease caused by A/E pathogens in vivo. DESIGN: Mice were infected with the diarrhoea-causing murine A/E pathogen C rodentium for 7 days. Connexin43 (Cx43) protein levels and immunolocalization in the colon were initially used to determine alterations during A/E bacterial infections in vivo. Connexin mimetic peptides and connexin permeable tracer molecules were used to gage the presence and function of unpaired connexin hemichannels. The role of Cx43 in diarrhoea generation was assessed by comparing infections of wild-type mice to Cx43 mutant mice and determining the water abundance in the colonic luminal material. RESULTS: We demonstrate that Cx43 protein levels are increased in colonocytes during in vivo A/E bacterial infections, resulting in functionally open connexon hemichannels in apical membranes of infected cells. moreover, infected Cx43 +/- mice do not suffer from diarrhoeal disease. CONCLUSIONS: This study provides the first evidence that functional connexon hemichannels can occur in the intestine and are a novel molecular mechanism of water release during infectious diarrhoea.