MiR 208a Regulates Mitochondrial Biogenesis in Metabolically Challenged Cardiomyocytes

MiR 208a Regulates Mitochondrial Biogenesis in Metabolically Challenged Cardiomyocytes

Metabolic syndrome increases the risk for cardiovascular disease including metabolic cardiomyopathy that may progress to heart failure. The decline in mitochondrial metabolism is considered a critical pathogenic mechanism that drives this progression. Considering its cardiac specificity, we hypothes...

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Bibliographic Details
Published in:Cells (Basel, Switzerland) Vol. 10; no. 11; p. 3152
Main Authors: Mekala, Naveen, Kurdys, Jacob, Vicenzi, Alexis Paige, Weiler, Leana Rose, Avramut, Carmen, Vazquez, Edwin J, Ragina, Neli, Rosca, Mariana G
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 13-11-2021
MDPI
Subjects:
Acidification
Adult
Apoptosis
Bioenergetics
Biomarkers - metabolism
Biosynthesis
Cardiomyocytes
Cardiomyopathy
Cardiovascular diseases
Congestive heart failure
CRISPR
Diabetes
Diabetes mellitus
Diabetes Mellitus - genetics
Experiments
Fatty acids
Gene expression
Glucose
Heart failure
Humans
Metabolic syndrome
MicroRNAs
MicroRNAs - genetics
MicroRNAs - metabolism
miR 208a
Mitochondria
mitochondrial biogenesis
Mitochondrial DNA
Models, Biological
Muscle contraction
Myocytes, Cardiac - metabolism
Myosin
Myosins - metabolism
Nexin
Organelle Biogenesis
Oxidation
Oxidative stress
Palmitic acid
Penicillin
Protein Isoforms - metabolism
Protein transport
Proteins
Signal transduction
Stanniocalcin
Stress, Physiological - genetics
Transcription
United States > US
cardiomyocytes
metabolic syndrome
bioenergetics
mitochondrial biogenesis
miR 208a
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Summary:Metabolic syndrome increases the risk for cardiovascular disease including metabolic cardiomyopathy that may progress to heart failure. The decline in mitochondrial metabolism is considered a critical pathogenic mechanism that drives this progression. Considering its cardiac specificity, we hypothesized that miR 208a regulates the bioenergetic metabolism in human cardiomyocytes exposed to metabolic challenges. We screened in silico for potential miR 208a targets focusing on mitochondrial outcomes, and we found that mRNA species for mediator complex subunit 7, mitochondrial ribosomal protein 28, stanniocalcin 1, and Sortin nexin 10 are rescued by the CRISPR deletion of miR 208a in human SV40 cardiomyocytes exposed to metabolic challenges (high glucose and high albumin-bound palmitate). These mRNAs translate into proteins that are involved in nuclear transcription, mitochondrial translation, mitochondrial integrity, and protein trafficking. MiR 208a suppression prevented the decrease in myosin heavy chain α isoform induced by the metabolic stress suggesting protection against a decrease in cardiac contractility. MiR 208a deficiency opposed the decrease in the mitochondrial biogenesis signaling pathway, mtDNA, mitochondrial markers, and respiratory properties induced by metabolic challenges. The benefit of miR 208a suppression on mitochondrial function was canceled by the reinsertion of miR 208a. In summary, miR 208a regulates mitochondrial biogenesis and function in cardiomyocytes exposed to diabetic conditions. MiR 208a may be a therapeutic target to promote mitochondrial biogenesis in chronic diseases associated with mitochondrial defects.
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Current address: School of Medicine, International University of the Health Sciences, Saint Kitts, West Indies, USA.
Current address: Lewis Katz School of Medicine, Temple University, Philadelphia, PA 19122, USA.
ISSN:2073-4409
2073-4409
DOI:10.3390/cells10113152