A mitochondrial therapeutic reverses visual decline in mouse models of diabetes

ABSTRACT Diabetic retinopathy is characterized by progressive vision loss and the advancement of retinal micoraneurysms, edema and angiogenesis. Unfortunately, managing glycemia or targeting vascular complications with anti-vascular endothelial growth factor agents has shown only limited efficacy in treating the deterioration of vision in diabetic retinopathy. In light of growing evidence that mitochondrial dysfunction is an independent pathophysiology of diabetes and diabetic retinopathy, we investigated whether selectively targeting and improving mitochondrial dysfunction is a viable treatment for visual decline in diabetes. Measures of spatial visual behavior, blood glucose, bodyweight and optical clarity were made in mouse models of diabetes. Treatment groups were administered MTP-131, a water-soluble tetrapeptide that selectively targets mitochondrial cardiolipin and promotes efficient electron transfer, either systemically or in eye drops. Progressive visual decline emerged in untreated animals before the overt symptoms of metabolic and ophthalmic abnormalities were manifest, but with time, visual dysfunction was accompanied by compromised glucose clearance, and elevated blood glucose and bodyweight. MTP-131 treatment reversed the visual decline without improving glycemic control or reducing bodyweight. These data provide evidence that visuomotor decline is an early complication of diabetes. They also indicate that selectively treating mitochondrial dysfunction with MTP-131 has the potential to remediate the visual dysfunction and to complement existing treatments for diabetic retinopathy. Summary: Visual decline in mouse models of diabetes is reversed, independently of treating other disease symptoms, by treatment with MTP-131, a water-soluble peptide that selectively targets cardiolipin and improves mitochondrial bioenergetics.

[1]  G. Prusky,et al.  Rod photoreceptors drive circadian photoentrainment across a wide range of light intensities , 2010, Nature Neuroscience.

[2]  R. Douglas,et al.  Photoreceptor regulation of spatial visual behavior. , 2015, Investigative ophthalmology & visual science.

[3]  Y. Ho,et al.  Oxidative damage of mitochondrial DNA in diabetes and its protection by manganese superoxide dismutase , 2010, Free radical research.

[4]  M. Feinglos,et al.  Diet-Induced Type II Diabetes in C57BL/6J Mice , 1988, Diabetes.

[5]  G. Merriam,et al.  A clinical and experimental study of the effect of single and divided doses of radiation on cataract production. , 1962, Transactions of the American Ophthalmological Society.

[6]  H. Szeto,et al.  The mitochondrial-targeted compound SS-31 re-energizes ischemic mitochondria by interacting with cardiolipin. , 2013, Journal of the American Society of Nephrology : JASN.

[7]  D. Vohora,et al.  Characterisation of Streptozotocin Induced Diabetes Mellitus in Swiss Albino Mice , 2009 .

[8]  L. Belardinelli,et al.  Ranolazine Increases β-Cell Survival and Improves Glucose Homeostasis in Low-Dose Streptozotocin-Induced Diabetes in Mice , 2011, Journal of Pharmacology and Experimental Therapeutics.

[9]  X. Chen,et al.  Mitochondria-targeted antioxidant peptide SS31 protects the retinas of diabetic rats. , 2013, Current molecular medicine.

[10]  E. Meezan,et al.  Identification and characterization of the insulin receptor of bovine retinal microvessels. , 1984, Endocrinology.

[11]  Yuning Hong,et al.  Multifaceted effects of ATP on cardiolipin-bound cytochrome c. , 2013, Biochemistry.

[12]  H. Szeto First‐in‐class cardiolipin‐protective compound as a therapeutic agent to restore mitochondrial bioenergetics , 2014, British journal of pharmacology.

[13]  H. Szeto,et al.  Cell-permeable Peptide Antioxidants Targeted to Inner Mitochondrial Membrane inhibit Mitochondrial Swelling, Oxidative Cell Death, and Reperfusion Injury* , 2004, Journal of Biological Chemistry.

[14]  B. Worgul Accelerated Heavy Particles and the Lens , 1988 .

[15]  G. R. Jackson,et al.  Inner retinal visual dysfunction is a sensitive marker of non-proliferative diabetic retinopathy , 2011, British Journal of Ophthalmology.

[16]  J. Duarte,et al.  Lipidomic characterization of streptozotocin-induced heart mitochondrial dysfunction. , 2013, Mitochondrion.

[17]  M. Schlame,et al.  Barth syndrome, a human disorder of cardiolipin metabolism , 2006, FEBS letters.

[18]  E. Fletcher,et al.  Early inner retinal astrocyte dysfunction during diabetes and development of hypoxia, retinal stress, and neuronal functional loss. , 2011, Investigative ophthalmology & visual science.

[19]  Xiaoling Liang,et al.  Mitochondria-targeted antioxidant peptide SS31 attenuates high glucose-induced injury on human retinal endothelial cells. , 2011, Biochemical and biophysical research communications.

[20]  H. Khan,et al.  Novel drugs and their targets in the potential treatment of diabetic retinopathy , 2013, Medical science monitor : international medical journal of experimental and clinical research.

[21]  Lin Xie,et al.  Mitochondrial DNA oxidative damage triggering mitochondrial dysfunction and apoptosis in high glucose-induced HRECs. , 2008, Investigative ophthalmology & visual science.

[22]  H. Szeto,et al.  Serendipity and the Discovery of Novel Compounds That Restore Mitochondrial Plasticity , 2014, Clinical pharmacology and therapeutics.

[23]  H. Szeto,et al.  Mitochondria-targeted peptide prevents mitochondrial depolarization and apoptosis induced by tert-butyl hydroperoxide in neuronal cell lines. , 2005, Biochemical pharmacology.

[24]  S. Madsen-Bouterse,et al.  Role of mitochondrial DNA damage in the development of diabetic retinopathy, and the metabolic memory phenomenon associated with its progression. , 2010, Antioxidants & redox signaling.

[25]  Y. Kaneda,et al.  Normalizing mitochondrial superoxide production blocks three pathways of hyperglycaemic damage , 2000, Nature.

[26]  P. Thulé,et al.  Early visual deficits in streptozotocin-induced diabetic long evans rats. , 2013, Investigative ophthalmology & visual science.

[27]  P. Fort,et al.  Differential Roles of Hyperglycemia and Hypoinsulinemia in Diabetes Induced Retinal Cell Death: Evidence for Retinal Insulin Resistance , 2011, PloS one.

[28]  E. Leiter Multiple low-dose streptozotocin-induced hyperglycemia and insulitis in C57BL mice: influence of inbred background, sex, and thymus. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[29]  H. Szeto,et al.  Mitochondria-targeted peptide accelerates ATP recovery and reduces ischemic kidney injury. , 2011, Journal of the American Society of Nephrology : JASN.

[30]  T. Gardner,et al.  The Ins2Akita mouse as a model of early retinal complications in diabetes. , 2005, Investigative ophthalmology & visual science.

[31]  Kumar Sharma,et al.  Mitochondrial Hormesis and Diabetic Complications , 2015, Diabetes.

[32]  T. Sano,et al.  [Diabetic retinopathy]. , 2001, Nihon rinsho. Japanese journal of clinical medicine.

[33]  B. Rothermel,et al.  Unraveling the temporal pattern of diet-induced insulin resistance in individual organs and cardiac dysfunction in C57BL/6 mice. , 2005, Diabetes.

[34]  R. Rentería,et al.  Spatial frequency threshold and contrast sensitivity of an optomotor behavior are impaired in the Ins2Akita mouse model of diabetes , 2012, Behavioural Brain Research.

[35]  C. Kahn,et al.  Altered Insulin Signaling in Retinal Tissue in Diabetic States* , 2004, Journal of Biological Chemistry.

[36]  E. Gilbert,et al.  Development of a Nongenetic Mouse Model of Type 2 Diabetes , 2011, Experimental diabetes research.

[37]  Michael P. Siegel,et al.  Mitochondrial‐targeted peptide rapidly improves mitochondrial energetics and skeletal muscle performance in aged mice , 2013, Aging cell.

[38]  K. Oyanagi,et al.  Degeneration of retinal neuronal processes and pigment epithelium in the early stage of the streptozotocin‐diabetic rats , 2002, Neuropathology : official journal of the Japanese Society of Neuropathology.

[39]  S. Kanaly,et al.  Retinal gene expression and visually evoked behavior in diabetic long evans rats. , 2011, Investigative ophthalmology & visual science.

[40]  R. Kowluru,et al.  Diabetic retinopathy and damage to mitochondrial structure and transport machinery. , 2011, Investigative ophthalmology & visual science.

[41]  D. Foster,et al.  Detection of colour vision abnormalities in uncomplicated type 1 diabetic patients with angiographically normal retinas. , 1992, The British journal of ophthalmology.

[42]  Mao‐nian Zhang,et al.  The Morphological Features and Mitochondrial Oxidative Stress Mechanism of the Retinal Neurons Apoptosis in Early Diabetic Rats , 2014, Journal of diabetes research.

[43]  R. Douglas,et al.  Enhancement of Vision by Monocular Deprivation in Adult Mice , 2006, The Journal of Neuroscience.

[44]  T. Gardner,et al.  Characterization of insulin signaling in rat retina in vivo and ex vivo. , 2003, American journal of physiology. Endocrinology and metabolism.

[45]  Xianlin Han,et al.  Cardiolipin remodeling in diabetic heart. , 2014, Chemistry and physics of lipids.

[46]  J. Ge,et al.  Mitochondria impairment correlates with increased sensitivity of aging RPE cells to oxidative stress , 2010, Journal of ocular biology, diseases, and informatics.

[47]  M. Patti,et al.  The role of mitochondria in the pathogenesis of type 2 diabetes. , 2010, Endocrine reviews.

[48]  R M Douglas,et al.  Independent visual threshold measurements in the two eyes of freely moving rats and mice using a virtual-reality optokinetic system , 2005, Visual Neuroscience.

[49]  T. Kern,et al.  Hyperglycemia increases mitochondrial superoxide in retina and retinal cells. , 2003, Free radical biology & medicine.

[50]  M. Brownlee Biochemistry and molecular cell biology of diabetic complications , 2001, Nature.

[51]  Qing Zhao,et al.  Cytochrome c acts as a cardiolipin oxygenase required for release of proapoptotic factors , 2005, Nature chemical biology.

[52]  Nagahisa Yoshimura,et al.  Structural Changes in Individual Retinal Layers in Diabetic Macular Edema , 2013, Journal of diabetes research.

[53]  K. Hayashi,et al.  Strain differences in the diabetogenic activity of streptozotocin in mice. , 2006, Biological & pharmaceutical bulletin.

[54]  H. Szeto,et al.  Novel Cardiolipin Therapeutic Protects Endothelial Mitochondria 1 during Renal Ischemia and Mitigates Microvascular Rarefaction, 2 Inflammation and Fibrosis 3 4 , 2022 .

[55]  V. Ganapathy,et al.  Death of retinal neurons in streptozotocin-induced diabetic mice. , 2004, Investigative ophthalmology & visual science.

[56]  C. Bombelli,et al.  Extended cardiolipin anchorage to cytochrome c: a model for protein–mitochondrial membrane binding , 2010, JBIC Journal of Biological Inorganic Chemistry.

[57]  Milan Sonka,et al.  Selective loss of inner retinal layer thickness in type 1 diabetic patients with minimal diabetic retinopathy. , 2009, Investigative ophthalmology & visual science.

[58]  R. Kowluru,et al.  Beyond AREDS: is there a place for antioxidant therapy in the prevention/treatment of eye disease? , 2011, Investigative ophthalmology & visual science.

[59]  B. Ahrén,et al.  The high-fat diet-fed mouse: a model for studying mechanisms and treatment of impaired glucose tolerance and type 2 diabetes. , 2004, Diabetes.

[60]  D. Brenner,et al.  Accelerated heavy particles and the lens. VII: The cataractogenic potential of 450 MeV/amu iron ions. , 1993, Investigative ophthalmology & visual science.

[61]  A. Rossini,et al.  Streptozotocin-induced pancreatic insulitis: new model of diabetes mellitus. , 1976, Science.

[62]  M. Cooper,et al.  Mechanisms of diabetic complications. , 2013, Physiological reviews.

[63]  R. Douglas,et al.  Rapid quantification of adult and developing mouse spatial vision using a virtual optomotor system. , 2004, Investigative ophthalmology & visual science.

[64]  R. Kowluru,et al.  Impaired transport of mitochondrial transcription factor A (TFAM) and the metabolic memory phenomenon associated with the progression of diabetic retinopathy , 2013, Diabetes/metabolism research and reviews.

[65]  T. Kern,et al.  Oxidative damage in the retinal mitochondria of diabetic mice: possible protection by superoxide dismutase. , 2007, Investigative ophthalmology & visual science.

[66]  M. Maia,et al.  Anti-VEGF for the Management of Diabetic Macular Edema , 2014, Journal of immunology research.

[67]  C. Murphy,et al.  A quantitative rabbit model of vaccinia keratitis. , 2010, Investigative ophthalmology & visual science.

[68]  B. Viollet,et al.  AMPK dysregulation promotes diabetes-related reduction of superoxide and mitochondrial function. , 2013, The Journal of clinical investigation.