Uncoupled turnover disrupts mitochondrial quality control in diabetic retinopathy
Jose R. Hombrebueno, Lauren Cairns, Louise R. Dutton, Timothy J. Lyons, Derek P. Brazil, Paul Moynagh, Tim M. Curtis, Heping Xu
Jose R. Hombrebueno, Lauren Cairns, Louise R. Dutton, Timothy J. Lyons, Derek P. Brazil, Paul Moynagh, Tim M. Curtis, Heping Xu
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Research Article Neuroscience Ophthalmology

Uncoupled turnover disrupts mitochondrial quality control in diabetic retinopathy

Abstract

Mitochondrial quality control (MQC) is crucial for regulating CNS homeostasis, and its disruption has been implicated in the pathogenesis of some of the most common neurodegenerative diseases. In healthy tissues, the maintenance of MQC depends upon an exquisite balance between mitophagy (removal of damaged mitochondria by autophagy) and biogenesis (de novo synthesis of mitochondria). Here, we show that mitophagy is disrupted in diabetic retinopathy (DR) and decoupled from mitochondrial biogenesis during the progression of the disease. Diabetic retinas from human postmortem donors and experimental mice exhibit a net loss of mitochondrial contents during the early stages of the disease process. Using diabetic mitophagy-reporter mice (mitoQC-Ins2Akita) alongside pMitoTimer (a molecular clock to address mitochondrial age dynamics), we demonstrate that mitochondrial loss arose due to an inability of mitochondrial biogenesis to compensate for diabetes-exacerbated mitophagy. However, as diabetes duration increases, Pink1-dependent mitophagy deteriorates, leading to the build-up of mitochondria primed for degradation in DR. Impairment of mitophagy during prolonged diabetes is linked with the development of retinal senescence, a phenotype that blunted hyperglycemia-induced mitophagy in mitoQC primary Müller cells. Our findings suggest that normalizing mitochondrial turnover may preserve MQC and provide therapeutic options for the management of DR-associated complications.

Authors

Jose R. Hombrebueno, Lauren Cairns, Louise R. Dutton, Timothy J. Lyons, Derek P. Brazil, Paul Moynagh, Tim M. Curtis, Heping Xu

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Figure 2

Mitochondrial contents shift during the progression of diabetes in Ins2Akita/+ mouse retinas.

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Mitochondrial contents shift during the progression of diabetes in Ins2A...
(A) Example immunoblot and quantification of Cox4 in retinal lysates of 2-month and 8-month hyperglycemic Ins2Akita/+ and age-matched WT mice. Data were normalized to β-actin loading controls. (B and C) Retinal micrographs of 2-month (B) and 8-month (C) hyperglycemic Ins2Akita/+ and age-matched WT mice processed for Cox4 immunostaining. (D and E) The mean fluorescence intensities (MFI) of Cox4 at the IS-OPL and INL-GCL of 2-month (D) and 8-month (E) hyperglycemic Ins2Akita/+ and age-matched WT mice. (F and G) Retinal micrographs of 2-month (F) and 8-month (G) hyperglycemic Ins2Akita/+ and age-matched WT mice processed for TOMM20 immunostaining. (H and I) The densities of TOMM20+ mitochondria at the IS-OPL of 2-month (H) and 8-month (I) hyperglycemic Ins2Akita/+ and age-matched WT mice. WT (white bars), Ins2Akita/+ (gray bars); n = 5–8 eyes per strain. Results presented as mean ± SEM. *P < 0.05, **P < 0.01, 2-sided unpaired Student’s t test. IS, photoreceptor inner segments; ONL, outer nuclear layer; OPL, outer plexiform layer; IPL, inner plexiform layer; GCL, ganglion cell layer. Scale bar: 40 μm (B and C), 20 μm (G).