A TRAF-like E3 ubiquitin ligase TrafE coordinates ESCRT and autophagy in endolysosomal damage response and cell-autonomous immunity to Mycobacterium marinum.

Cells are perpetually challenged by pathogens, protein aggregates or chemicals, that induce plasma membrane or endolysosomal compartments damage. This severe stress is recognised and controlled by the endosomal sorting complex required for transport (ESCRT) and the autophagy machineries, which are recruited to damaged membranes to either repair or to remove membrane remnants. Yet, insight is limited about how damage is sensed and which effectors lead to extensive tagging of the damaged organelles with signals, such as K63-polyubiquitin, required for the recruitment of membrane repair or removal machineries. To explore the key factors responsible for detection and marking of damaged compartments, we use the professional phagocyte Dictyostelium discoideum. We found an evolutionary conserved E3-ligase, TrafE, that is robustly recruited to intracellular compartments disrupted after infection with Mycobacterium marinum or after sterile damage caused by chemical compounds. TrafE acts at the intersection of ESCRT and autophagy pathways and plays a key role in functional recruitment of the ESCRT subunits ALIX, Vps32 and Vps4 to damage sites. Importantly, we show that the absence of TrafE severely compromises the xenophagy restriction of mycobacteria as well as ESCRT-mediated and autophagy-mediated endolysosomal membrane damage repair, resulting in early cell death.

Novel Single-Cell and High-Throughput Microscopy Techniques to Monitor Dictyostelium discoideum-Mycobacterium marinum Infection Dynamics.

The Dictyostelium discoideum-Mycobacterium marinum host-pathogen system is a well-established and powerful alternative model system to study mycobacterial infections. In this chapter, we will describe three microscopy methods that allow the precise identification and quantification of very diverse phenotypes arising during infection of D. discoideum with M. marinum. First, at the lowest end of the scale, we use the InfectChip, a microfluidic device that enables the long-term monitoring of the integrated history of the infection course at the single-cell level. We use single-cell analysis to precisely map and quantitate the various fates of the host and the pathogen during infection. Second, a high-content microscopy setup was established to study the infection dynamics with high-throughput imaging of a large number of cells at the different critical stages of infection. The large datasets are then fed into a deep image analysis pipeline allowing the development of complex phenotypic analyses. Finally, as part of its life cycle, single D. discoideum amoebae aggregate by chemotaxis to form multicellular structures, which represent ordered assemblies of hundreds of thousands of cells. This transition represents a challenge for the monitoring of infection at multiple scales, from single cells to a true multicellular organism. In order to visualize and quantitate the fates of host cells and bacteria during the developmental cycle in a controlled manner, we can adjust the proportion of infected cells using live FAC-sorting. Then, cells are plated in defined humidity conditions on optical glass plates in order to image large fields, using tile scans, with the help of a spinning disc confocal microscope.

Mapping of Adenovirus of serotype 3 fibre interaction to desmoglein 2 revealed a novel 'non-classical' mechanism of viral receptor engagement.

High-affinity binding of the trimeric fibre protein to a cell surface primary receptor is a common feature shared by all adenovirus serotypes. Recently, a long elusive species B adenovirus receptor has been identified. Desmoglein 2 (DSG2) a component of desmosomal junction, has been reported to interact at high affinity with Human adenoviruses HAd3, HAd7, HAd11 and HAd14. Little is known with respect to the molecular interactions of adenovirus fibre with the DSG2 ectodomain. By using different DSG2 ectodomain constructs and biochemical and biophysical experiments, we report that the third extracellular cadherin domain (EC3) of DSG2 is critical for HAd3 fibre binding. Unexpectedly, stoichiometry studies using multi-angle laser light scattering (MALLS) and analytical ultra-centrifugation (AUC) revealed a non-classical 1:1 interaction (one DSG2 per trimeric fibre), thus differentiating 'DSG2-interacting' adenoviruses from other protein receptor interacting adenoviruses in their infection strategy.