Tollip coordinates Parkin-dependent trafficking of mitochondrial-derived vesicles.

Multiple mitochondrial quality control pathways exist to maintain the health of mitochondria and ensure cell homeostasis. Here, we investigate the role of the endosomal adaptor Tollip during the mitochondrial stress response and identify its interaction and colocalisation with the Parkinson's disease-associated E3 ubiquitin ligase Parkin. The interaction between Tollip and Parkin is dependent on the ubiquitin-binding CUE domain of Tollip, but independent of Tom1 and mitophagy. Interestingly, this interaction is independent of Parkin mitochondrial recruitment and ligase activity but requires an intact ubiquitin-like (UBL) domain. Importantly, Tollip regulates Parkin-dependent endosomal trafficking of a discrete subset of mitochondrial-derived vesicles (MDVs) to facilitate delivery to lysosomes. Retromer function and an interaction with Tom1 allow Tollip to facilitate late endosome/lysosome trafficking in response to mitochondrial stress. We find that upregulation of TOM20-positive MDVs upon mitochondrial stress requires Tollip interaction with ubiquitin, endosomal membranes and Tom1 to ensure their trafficking to the lysosomes. Thus, we conclude that Tollip, via an association with Parkin, is an essential coordinator to sort damaged mitochondrial-derived cargo to the lysosomes.

Legionella longbeachae Is Immunologically Silent and Highly Virulent In Vivo.

BACKGROUND: Legionella longbeachae (Llo) and Legionella pneumophila (Lpn) are the most common pneumonia-causing agents of the genus. Although both species can be lethal to humans and are highly prevalent, little is known about the molecular pathogenesis of Llo infections. In murine models of infection, Lpn infection is self-limited, whereas Llo infection is lethal. METHODS: We used mouse macrophages, human macrophages, human epithelial cells, and mouse infections in vivo to evaluate multiple parameters of the infection. RESULTS: We determined that the Llo Dot/Icm secretion system is critical for virulence. Different than Lpn, Llo disseminates and the animals develop a severe pulmonary failure, as demonstrated by lung mechanics and blood oxygenation assays. As compared to Lpn, Llo is immunologically silent and fails to trigger the production of cytokines in human pulmonary epithelial cells and in mouse and human macrophages. Infections in Tnfr1-/-, Ifng-/-, and Il12p40-/- mice supported the participation of cytokines for the resistance phenotype. CONCLUSIONS: Both Lpn and Llo require the Dot/Icm system for pathogenesis, but the infection outcome is strikingly different. Llo is immunologically silent, highly virulent, and lethal. The differences reported herein may reflect unappreciated clinical differences in patients infected with Lpn or Llo.

Dot/Icm Effector Translocation by Legionella longbeachae Creates a Replicative Vacuole Similar to That of Legionella pneumophila despite Translocation of Distinct Effector Repertoires.

Legionella organisms are environmental bacteria and accidental human pathogens that can cause severe pneumonia, termed Legionnaires' disease. These bacteria replicate within a pathogen-derived vacuole termed the Legionella-containing vacuole (LCV). Our understanding of the development and dynamics of this vacuole is based on extensive analysis of Legionella pneumophila. Here, we have characterized the Legionella longbeachae replicative vacuole (longbeachae-LCV) and demonstrated that, despite important genomic differences, key features of the replicative LCV are comparable to those of the LCV of L. pneumophila (pneumophila-LCV). We constructed a Dot/Icm-deficient strain by deleting dotB and demonstrated the inability of this mutant to replicate inside THP-1 cells. L. longbeachae does not enter THP-1 cells as efficiently as L. pneumophila, and this is reflected in the observation that translocation of BlaM-RalFLLO (where RalFLLO is the L. longbeachae homologue of RalF) into THP-1 cells by the L. longbeachae Dot/Icm system is less efficient than that by L. pneumophila. This difference is negated in A549 cells where L. longbeachae and L. pneumophila infect with similar entry dynamics. A ß-lactamase assay was employed to demonstrate the translocation of a novel family of proteins, the Rab-like effector (Rle) proteins. Immunofluorescence analysis confirmed that these proteins enter the host cell during infection and display distinct subcellular localizations, with RleA and RleC present on the longbeachae-LCV. We observed that the host Rab GTPase, Rab1, and the v-SNARE Sec22b are also recruited to the longbeachae-LCV during the early stages of infection, coinciding with the LCV avoiding endocytic maturation. These studies further our understanding of the L. longbeachae replicative vacuole, highlighting phenotypic similarities to the vacuole of L. pneumophila as well as unique aspects of LCV biology.