DOI: 10.1096/fj.202601561r ISSN: 0892-6638

Raptor and Drp1 Function Synthetically to Control Hypoxic Death and the Mitochondrial Network in Caenorhabditis elegans

Julien Goldstick, Diego Compte, Chun‐Ling Sun, Alison E. Ritter, C. Michael Crowder

ABSTRACT

Hypoxia induces mitochondrial fragmentation. Whether this fragmentation promotes or prevents cell death and whether the mitochondrial dynamics machinery plays a role are unresolved. To address these questions, we measured the effect of hypoxia on mitochondrial morphology in a Caenorhabditis elegans Raptor mutant resistant to hypoxic death and in mutants with disrupted mitochondrial fission and fusion. The Raptor loss‐of‐function mutant reduced hypoxia‐induced mitochondrial fragmentation and death. However, forcing mitochondrial fragmentation prior to hypoxia by combining the Raptor mutation with a loss‐of‐function mutation in mitofusin did not increase hypoxic death. A loss‐of‐function mutation in drp‐1 , which is required for mitochondrial fission, did not block hypoxia‐induced mitochondrial fragmentation nor enhance Raptor hypoxia resistance; rather, drp‐1 (lf) was surprisingly mildly hypoxia resistant and partially suppressed the high‐level hypoxia resistance of the Raptor mutant. Likewise, loss of DRP‐1 function interacted synthetically with the Raptor(lf) mutant to produce tangled mitochondria, demonstrating a role of Raptor in maintenance of the mitochondrial network. Vitamin B12 supplementation and feeding with a bacterial strain replete in vitamin B12 mitigated hypoxia‐induced mitochondrial fragmentation. Our results demonstrate that fragmented mitochondria do not necessarily promote hypoxic cell death, and hypoxia‐induced mitochondrial fragmentation is mechanistically distinct from physiological mitochondrial fission.

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