Impaired Renal Mitochondria and Bioenergetics During Obesity-Associated NAFLD

Background/Objectives: Obesity-associated non-alcoholic fatty liver disease (NAFLD) drives systemic metabolic stress and accelerates chronic kidney disease, yet the mechanistic links remain unclear. Mitochondrial dysfunction has emerged as a central mediator of obesity-induced organ injury. Here, we investigated renal mitochondrial remodeling in a rat model of obesity-associated NAFLD (Ob-NAFLD) and examined the effects of metformin. Methods: Female Zucker rats (obese fa/fa and lean Fa/Fa) were fed an AIN-93G diet for eight weeks, followed by 10 weeks of metformin treatment in designated groups. Kidney tissues were analyzed using biochemical assays, immunoblotting, blue native PAGE, in-gel activity assays, and histological evaluation. Results: In Ob-NAFLD rats, renal ATP levels were elevated despite reduced electron transport chain (ETC) Complex III and increased Complex V expression, reflecting compensatory ATP synthase hyperactivity uncoupled from efficient oxidative phosphorylation. Mitochondrial dynamics were disrupted such that inhibitory phosphorylation of DRP1 was reduced, promoting fission, and total OPA1 expression was decreased with a shift in short-to-long isoform balance, indicating impaired fusion and cristae remodeling. Notably, ATPase inhibitory factor 1 (IF1), a checkpoint that limits ATP synthase overdrive, remained stably expressed, suggesting an adaptive ceiling or failed protective control under chronic metabolic stress. Metformin partially alleviated bioenergetic stress by lowering ATP and modestly restoring Complex III, yet ETC imbalance and structural remodeling persisted, revealing the limitations of metabolic modulation alone. Conclusions: These findings position entrenched mitochondrial dysregulation as a mechanistic bridge linking obesity-driven liver disease to kidney injury. Therapeutic strategies combining metabolic interventions with targeted restoration of ETC coordination, mitochondrial dynamics, and regulatory checkpoints such as IF1 may be required to fully restore renal mitochondrial health and prevent the progression of metabolic kidney disease.