XIAP-mediated targeting of endolysosomes to stressed mitochondria occurs in a switch-like, global manner and results in autophagy-independent, sub-organelle level mitochondrial degradation

Damaged mitochondria can be subject to lysosomal degradation via mitophagy. However, whole-organelle degradation exhibits relatively slow kinetics and thus its impact may be limited in response to acute, fast-acting cellular stress. We previously reported that in Parkin-deficient cells endolysosomes directly target mitochondria when subjected to bioenergetic stress. Here, using high-resolution live cell imaging we reveal a striking level of dynamic targeting of Rab5+ early endosomes to stressed mitochondria, culminating in a switch-like accumulation in the entire mitochondrial population, independently of canonical autophagy. This process of rapid, largescale Rab5+ vesicle trafficking to mitochondria coincides with, and is mediated by, XIAP E3 ligase activated mitochondrial ubiquitylation and results in ultrastructural changes to, and degradation of, intra-mitochondrial components. Mitochondria-targeting vesicles include early endosomal subpopulations marked by Rab5 effector APPL1 and ubiquitin-binding endocytic adaptors OPTN, TAX1BP1 and Tollip, and Rab7-positive late endosomes/lysosomes. In Parkin expressing cells, XIAP- and Parkin-dependent mitochondrial targeting and resulting processing modes are competitively regulated. Together, our data suggest that XIAP-mediated targeting of endolysosomes to mitochondria functions as a stress-responsive, sub-organelle level mitochondrial processing mode that is distinct from, and competitive to, Parkin-mediated mitophagy.