Autophagy is a highly conserved degradative process that breaks down cytosolic material inside double-membrane vesicles (called autophagosomes) by fusion with lysosomes. Selective autophagy is an important host defense mechanism that recognizes intracellular bacterial pathogens, such as Shigella flexneri, for targeting to degradation. To avoid autophagy, S. flexneri can polymerize host cell actin and form an actin tail that permits dissemination and cell-to-cell spread. Septins, a poorly understood component of the cytoskeleton that interacts with actin filaments and cellular membranes, entrap actin-polymerizing Shigella in cage-like structures for targeting to autophagy. However, the molecular determinants that underpin septin cage assembly are mostly unknown, and, the fate of septin cage-entrapped bacterium (replication, persistence, death) remains to be fully defined.
Hosted by the Mostowy lab my project entitled "In vitro reconstitution and single cell analysis of the Shigella-septin cage (INCAGE)", aims to study factors controlling septin cage assembly and bacterial metabolism inside septin cages. I am investigating septin cage biology using bottom-up (using purified septin complexes in vitro and cell-free extracts) and top-down (using epithelial cells and different types of cutting-edge microscopy) approaches. For my Marie Curie postdoctoral project, I propose that in depth investigation of the Shigella-septin cage can lead to new septin biology, and new roles for the cytoskeleton in cell-autonomous immunity.
INCAGE is an excellent platform to illuminate new concepts on the cell biology of Shigella that are difficult or impossible to address using whole cells or animal models. Understanding how our cells respond to bacterial infections can help to combat infectious diseases and control the spread of antibiotic resistance.