Over-expression of miR-486/miR-150 in sepsis: marker in myocardial depression function


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Robert Thron 1, Thomas Andersson, Kay Lee, Malloy Adrienne*
Author Affiliations
∗Correspondence author e-mail: WangF @nju.edu.cn: Nanjing University, 163 Xianlin Avenue, China

 

 

Abstract

Sepsis, the third most common cause of death worldwide, is associated with myocardial depression, one of the most common organ dysfunctions in sepsis. n this study, we found that miRNA-486 was significantly down-regulated in septic mice and miR-486 over-expression significantly up-regulated the IRE1/JNK pathway, resulting in increased autophagy and apoptosis. In our previous study, miR-486 has been shown to be a protective factor in sepsis overdose and the expression was significantly down-regulated, indicating that miR-486 is a sensitive responder in sepsis and may be an important indicator for the diagnosis and prognosis of sepsis. provided the first evidence that the expression of miR-486 in human macrophages (THP-1) was up-regulated after stimulation with lipopolysaccharide (LPS) (1 µg/mL). explored the expression profile of some miRNAs in bone marrow-derived macrophages (BMDMs) in LPS-induced sepsis mice using RT-PCR. The primary finding in our study is that in vivo over-expression of miR-486 depressed the myocardial function, and that miR-150 controlled the heart function in a constitutively negative manner. We had proved in SMs that miR-486 could repress Cav-1 expression, while miR-150 could inhibit calcineurin and l-type calcium channel. Calcium plays a fundamental role in the heart, and sepsis causing the imbalance of calcium ultimately leads to myocardial depression. Regulations of these related calcium signaling pathways also confirm and explain how miR-486 and miR-150 have a negative effect on myocardial function. These findings provide proof in mouse myocardial intramyocardial overexpression of miRs (miR-486, miR-150) in its decrease heart contractile function. Inconclusion, miR-486 and miR-150 play a protective role in sepsis-induced myocardial depression by inhibiting renin-angiotensin-aldosterone system dependent autophagy. This study may contribute to developing novel therapeutic strategies for favorably regulating miR-486 or miR-150 expression in sepsis-induced myocardial depression.

Keywords: Myocardial depression; Biomarkers; mRNA; Sepsis

Copyright © 2017 by The American Society for BioMedicine and BM-Publisher, Inc.

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Research Article

DOI: http://dx.doi.org/10.18081/2333-5106/015-06/313-324

Robert Thron, Thomas Andersson, Kay Lee, Malloy Adrienne
Received June 11, 2017; Accepted September 09, 2017; Published October 03, 2017

How to cite this article
Thron R, Andersson T,Lee K, Adrienne M. Critical role of microglia in the inflammatory response after spinal injury. American Journal of BioMedicine 2017;5(4):267–281
Research Article
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