Mitochondrial quality control in diabetes mellitus and complications: molecular mechanisms and therapeutic strategies

Abstract

Diabetes mellitus (DM), a metabolic disease of globally health concern, is pathologically attributed to mitochondrial dysfunction, an essential component in disease progression. Mitochondrial quality control (MQC) acts as a critical defense mechanism for metabolic homeostasis, yet its implications in DM and its complications remain incompletely understood. This study thoroughly summarizes emerging evidence that delineates the molecular processes of MQC, with an emphasis on effector protein post-translational regulation, upstream signaling hubs, and interactions with other metabolic processes including ferroptosis and lipid metabolism. We highlight newly discovered processes involving mitochondrial-derived vesicles, licensed mitophagy, and mitocytosis that broaden the regulatory landscape of MQC, going beyond the traditionally recognized process including biogenesis, dynamics and mitophagy. MQC imbalance exacerbates insulin resistance, while impaired insulin signaling reciprocally compromises mitochondrial function, creating a vicious cycle of metabolic deterioration. Despite tissue-specific pathophysiology, diabetic complications exhibit identical MQC impairment including suppressed biogenesis, fission-fusion imbalance, and deficient mitophagy. Emerging therapies including clinical hypoglycemic agents and bioactive phytochemicals demonstrate therapeutic potential by restoring MQC. However, current strategies remain anchored to classical pathways, neglecting novel MQC mechanisms such as mitocytosis. Addressing this gap demands integration of cutting-edge MQC insights into drug discovery, particularly for compounds modulating upstream regulators. Future studies must prioritize mechanistic dissection of MQC novel targets and their translational relevance in halting metabolic collapse of diabetes progression. Since mitochondrial function is a cornerstone of metabolic restoration, synergizing precision MQC modulation with multi-target interventions, holds transformative potential for refine diabetic complications therapeutics.