miR-26a Limits Muscle Wasting and Cardiac Fibrosis through Exosome-Mediated microRNA Transfer in Chronic Kidney Disease

Uremic cardiomyopathy and muscle atrophy are associated with insulin resistance and contribute to chronic kidney disease (CKD)-induced morbidity and mortality. We hypothesized that restoration of miR-26a levels would enhance exosome-mediated microRNA transfer to improve muscle wasting and cardiomyopathy that occur in CKD. Methods: Using next generation sequencing and qPCR, we found that CKD mice had a decreased level of miR-26a in heart and skeletal muscle. We engineered an exosome vector that contained Lamp2b, an exosomal membrane protein gene fused with a muscle-specific surface peptide that targets muscle delivery. We transfected this vector into muscle satellite cells and then transduced these cells with adenovirus that expresses miR-26a to produce exosomes encapsulated miR-26a (Exo/miR-26a). Exo/miR-26a was injected once per week for 8 weeks into the tibialis anterior (TA) muscle of 5/6 nephrectomized CKD mice. Results: Treatment with Exo/miR-26a resulted in increased expression of miR-26a in skeletal muscle and heart. Overexpression of miR-26a increased the skeletal muscle cross-sectional area, decreased the upregulation of FBXO32/atrogin-1 and TRIM63/MuRF1 and depressed cardiac fibrosis lesions. In the hearts of CKD mice, FoxO1 was activated, and connective tissue growth factor, fibronectin and collagen type I alpha 1 were increased. These responses were blunted by injection of Exo/miR-26a. Echocardiograms showed that cardiac function was improved in CKD mice treated with Exo/miR-26a. Conclusion: Overexpression of miR-26a in muscle prevented CKD-induced muscle wasting and attenuated cardiomyopathy via exosome-mediated miR-26a transfer. These results suggest possible therapeutic strategies for using exosome delivery of miR-26a to treat complications of CKD.

[1]  T. Anchordoquy,et al.  Biodistribution and delivery efficiency of unmodified tumor-derived exosomes. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[2]  R. Foley,et al.  Clinical epidemiology of cardiac disease in dialysis patients: left ventricular hypertrophy, ischemic heart disease and cardiac failure. Semin Dial 2003 , 2022 .

[3]  Anutosh Chakraborty,et al.  Inositol Pyrophosphates Inhibit Akt Signaling, Thereby Regulating Insulin Sensitivity and Weight Gain , 2010, Cell.

[4]  R. Graham,et al.  A Proliferative Burst during Preadolescence Establishes the Final Cardiomyocyte Number , 2014, Cell.

[5]  Michael A Lopez,et al.  Mechanical Stretch Up-regulates MicroRNA-26a and Induces Human Airway Smooth Muscle Hypertrophy by Suppressing Glycogen Synthase Kinase-3β* , 2010, The Journal of Biological Chemistry.

[6]  Zhaoyong Hu,et al.  Evidence for adipose-muscle cross talk: opposing regulation of muscle proteolysis by adiponectin and Fatty acids. , 2007, Endocrinology.

[7]  Xiaonan H. Wang,et al.  Acupuncture plus low-frequency electrical stimulation (Acu-LFES) attenuates denervation-induced muscle atrophy. , 2016, Journal of applied physiology.

[8]  P. Netti,et al.  Metformin Prevents the Development of Chronic Heart Failure in the SHHF Rat Model , 2012, Diabetes.

[9]  A. Molinari,et al.  Microenvironmental pH Is a Key Factor for Exosome Traffic in Tumor Cells* , 2009, The Journal of Biological Chemistry.

[10]  Yangxin Li,et al.  Transport of microRNAs via exosomes , 2015, Nature Reviews Cardiology.

[11]  M. Rambausek,et al.  Myocardial interstitial fibrosis in experimental uremia--implications for cardiac compliance. , 1988, Kidney international.

[12]  Zhaoyong Hu,et al.  Transcription factor FoxO1, the dominant mediator of muscle wasting in chronic kidney disease, is inhibited by microRNA-486 , 2012, Kidney international.

[13]  Xiaonan H. Wang MicroRNA in myogenesis and muscle atrophy , 2013, Current opinion in clinical nutrition and metabolic care.

[14]  Pranav Dorbala,et al.  An emerging role for the miR-26 family in cardiovascular disease. , 2014, Trends in cardiovascular medicine.

[15]  N. Vaziri,et al.  Effects of chronic renal failure on caveolin-1, guanylate cyclase and AKT protein expression. , 2004, Biochimica et biophysica acta.

[16]  Rajesh Kumar,et al.  Intracellular Angiotensin II Production in Diabetic Rats Is Correlated With Cardiomyocyte Apoptosis, Oxidative Stress, and Cardiac Fibrosis , 2008, Diabetes.

[17]  R. Jove,et al.  MicroRNA-26a regulates insulin sensitivity and metabolism of glucose and lipids. , 2015, The Journal of clinical investigation.

[18]  W. Mitch,et al.  Decreased miR-29 suppresses myogenesis in CKD. , 2011, Journal of the American Society of Nephrology : JASN.

[19]  D. Catalucci,et al.  NF‐κB mediated miR‐26a regulation in cardiac fibrosis , 2013, Journal of cellular physiology.

[20]  S. Price,et al.  Acidification and glucocorticoids independently regulate branched-chain alpha-ketoacid dehydrogenase subunit genes. , 2001, American journal of physiology. Cell physiology.

[21]  Patient mortality and survival. United States Renal Data System. , 1998, American journal of kidney diseases : the official journal of the National Kidney Foundation.

[22]  W. Mitch,et al.  Exercise ameliorates chronic kidney disease-induced defects in muscle protein metabolism and progenitor cell function. , 2009, Kidney international.

[23]  Lei Yuan,et al.  FOXO1-Mediated Activation of Akt Plays a Critical Role in Vascular Homeostasis , 2014, Circulation research.

[24]  M. Wood,et al.  Exosomes and the emerging field of exosome-based gene therapy. , 2012, Current gene therapy.

[25]  A. Depaoli-Roach,et al.  Glycogen synthase kinase-3 beta is a dual specificity kinase differentially regulated by tyrosine and serine/threonine phosphorylation. , 1994, The Journal of biological chemistry.

[26]  Xiaonan H. Wang,et al.  Chronic kidney disease induces autophagy leading to dysfunction of mitochondria in skeletal muscle. , 2017, American journal of physiology. Renal physiology.

[27]  N. Mittman,et al.  Malnutrition in uremia. , 1994, Seminars in Nephrology.

[28]  S. Raptis,et al.  Insulin effects in muscle and adipose tissue. , 2011, Diabetes research and clinical practice.

[29]  M. Wood,et al.  Identification of a novel muscle targeting peptide in mdx mice , 2010, Peptides.

[30]  K. Nakao,et al.  MicroRNA-26a inhibits TGF-β-induced extracellular matrix protein expression in podocytes by targeting CTGF and is downregulated in diabetic nephropathy , 2015, Diabetologia.

[31]  Xiaonan H. Wang,et al.  Low-frequency electrical stimulation attenuates muscle atrophy in CKD--a potential treatment strategy. , 2015, Journal of the American Society of Nephrology : JASN.

[32]  S. Yusuf,et al.  Glucose and insulin abnormalities relate to functional capacity in patients with congestive heart failure. , 2000, European heart journal.

[33]  Reuven Agami,et al.  The PTEN-regulating microRNA miR-26a is amplified in high-grade glioma and facilitates gliomagenesis in vivo. , 2009, Genes & development.

[34]  S. Russell,et al.  Reduced kidney function as a risk factor for incident heart failure: the atherosclerosis risk in communities (ARIC) study. , 2007, Journal of the American Society of Nephrology : JASN.

[35]  R. Liao,et al.  MicroRNA-26a Regulates Pathological and Physiological Angiogenesis by Targeting BMP/SMAD1 Signaling , 2013, Circulation research.

[36]  S. Bhandari,et al.  Uremic cardiomyopathy and insulin resistance: a critical role for akt? , 2011, Journal of the American Society of Nephrology : JASN.

[37]  Olivier Lantz,et al.  Vaccination of metastatic melanoma patients with autologous dendritic cell (DC) derived-exosomes: results of thefirst phase I clinical trial , 2005, Journal of Translational Medicine.

[38]  S. Houser,et al.  Nuclear Targeting of Akt Enhances Ventricular Function and Myocyte Contractility , 2005, Circulation research.

[39]  H. Koyama,et al.  Insulin resistance as an independent predictor of cardiovascular mortality in patients with end-stage renal disease. , 2002, Journal of the American Society of Nephrology : JASN.

[40]  W. Mitch,et al.  Muscle wasting from kidney failure-a model for catabolic conditions. , 2013, The international journal of biochemistry & cell biology.

[41]  S. Rostand,et al.  Dialysis-associated ischemic heart disease: insights from coronary angiography. , 1984, Kidney international.

[42]  Michelle E. Hung,et al.  Stabilization of Exosome-targeting Peptides via Engineered Glycosylation* , 2015, The Journal of Biological Chemistry.

[43]  Yun‐Sil Lee,et al.  MicroRNA-26a/-26b-COX-2-MIP-2 Loop Regulates Allergic Inflammation and Allergic Inflammation-promoted Enhanced Tumorigenic and Metastatic Potential of Cancer Cells* , 2015, The Journal of Biological Chemistry.

[44]  Muneesh Tewari,et al.  Quantitative and stoichiometric analysis of the microRNA content of exosomes , 2014, Proceedings of the National Academy of Sciences.

[45]  W. Mitch,et al.  Mechanisms of muscle wasting in chronic kidney disease , 2014, Nature Reviews Nephrology.

[46]  Xiaonan H. Wang,et al.  miRNA‐23a/27a attenuates muscle atrophy and renal fibrosis through muscle‐kidney crosstalk , 2018, Journal of cachexia, sarcopenia and muscle.

[47]  Xiaonan H. Wang,et al.  MicroRNA-23a and MicroRNA-27a Mimic Exercise by Ameliorating CKD-Induced Muscle Atrophy. , 2017, Journal of the American Society of Nephrology : JASN.

[48]  H. Krumholz,et al.  Thiazolidinediones, Metformin, and Outcomes in Older Patients With Diabetes and Heart Failure: An Observational Study , 2005, Circulation.

[49]  Ping Liu,et al.  TGF-β2 induces proliferation and inhibits apoptosis of human Tenon capsule fibroblast by miR-26 and its targeting of CTGF. , 2018, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[50]  W. Mitch,et al.  Insulin resistance accelerates muscle protein degradation: Activation of the ubiquitin-proteasome pathway by defects in muscle cell signaling. , 2006, Endocrinology.