Upon invasion of a host cell, intracellular pathogens must actively ensure their survival in an immediately hostile environment. One such survival tactic of some pathogenic bacteria is through the subversion of host membrane fusion machinery, thereby inhibiting phagolysosomal fusion and subsequent delivery of the bacterium to the host degradative lysosome. The foodborne pathogen, Salmonella enterica, and the causative agent of Legionnaire’s disease, Legionella pneumophila, are examples of such bacterial pathogens that utilize this particular survival tactic. While evading host cell defenses in this manner is key to the organism’s ability to cause infection and disease, the mechanisms underlying these evasion pathways remain poorly understood. Many studies have tentatively identified bacterial factors thought to be important for the disruption of normal host membrane dynamics, but the biochemical analysis of these factors remains lacking. By employing a powerful in vivo and in vitro model system of eukaryotic membrane fusion, my laboratory will investigate the biochemistry of eukaryotic membrane fusion, identify and biochemically characterize bacterial effectors capable of modulating membrane fusion, and finally analyze these activities within the context of pathogenesis
