Mutant CHCHD10 disrupts cytochrome c oxidation and activates mitochondrial retrograde signaling.

Abstract

Mutations in CHCHD10, a mitochondrial intermembrane space (IMS) protein implicated in proteostasis and cristae maintenance, cause mitochondrial disease. Knock-in mice modeling the human CHCHD10variant associated with ALS-FTD develop a mitochondrial cardiomyopathy driven by CHCHD10 aggregation and activation of the mitochondrial integrated stress response (mtISR). We show that cardiac dysfunction is associated with dual defects originating at the onset of disease: (1) bioenergetic failure linked to impaired mitochondrial copper homeostasis and cytochrome c oxidation, and (2) maladaptive mtISR signaling via the OMA1-DELE1-HRI axis. Using protease-inactive Oma1knock-in mice, we show that blunting mtISR in Chchd10mice delays cardiomyopathy onset without rescuing CHCHD10 insolubility, cristae defects or OXPHOS impairment. Proteomic profiling of insoluble mitochondrial proteins in Chchd10mice reveals widespread disruptions of mitochondrial proteostasis, including IMS proteins involved in cytochrome c biogenesis. Defective respiration in mutant mitochondria is rescued by the addition of cytochrome c, pinpointing IMS proteostasis disruption as a key pathogenic mechanism. Thus, mutant CHCHD10 insolubility compromises metabolic resilience by impairing bioenergetics and stress adaptation, offering new perspectives for the development of therapeutic targets.