Pathway-selective mitophagy regulates retinal physiology and neurogenic transitions in Muller glia

Mitochondrial quality control (MQC) is essential for retinal homeostasis, yet how distinct mitophagy pathways are coordinated within specialized retinal cell types remains poorly understood. Here, we show that Muller glia engage distinct mitophagy programmes that are differentially activated across physiological, metabolic stress, and differentiation contexts. Using pathway-resolved analyses supported by mouse and human single-cell transcriptomic datasets, we demonstrate that PINK1-dependent and receptor-mediated mitophagy pathways coexist within Muller glia and exhibit distinct functional and spatial regulation. To enable precise, time-resolved interrogation of these processes, we developed MQ-MG2, a spontaneously immortalised Muller glial model stably expressing the Mito-QC reporter while preserving endogenous mitophagy adaptors and metabolic features of primary Muller cells. Using this system, we identify context-dependent activation of mitophagy pathways with spatial relevance in vivo and reveal transient coordination of PINK1-dependent and receptor-associated mitophagy during Muller glial neurogenic differentiation. Suppression of fission-dependent mitophagy impaired the acquisition of complex neurite features in MQ-MG2, with a comparable phenotype observed following targeted PINK1 deletion in human neurogenic cells. Together, these findings position Muller glia as active integrators of mitochondrial quality control, capable of engaging distinct mitophagy programmes according to cellular context.