Abstract
Abstract Objective: Increased fatty acids in the circulation and their accumulation in non-adipose tissues play a significant role in the development of obesity related metabolic and inflammatory disorders such as insulin resistance, diabetes and atherosclerosis. While fat tissue has the ability to store excess fatty acids, uptake of excess fatty acids to other tissues burdens intracellular metabolic organelles such as mitochondria and endoplasmic reticulum (ER), leading to stress response and lipotoxic cell death. Unfolded protein response (UPR) is a key adaptation of the ER to stress. It is still not completely clear how lipids engage the UPR and how UPR manages both the adaptive and destructive consequences under its control. Increasing evidence point to the importance of miRNA regulation of the UPR as well as UPR’s role in miRNA biogenesis. In order to understand how lipids engage the UPR, we set forth to identify microRNAs regulated by lipotoxic ER stress in macrophages. Methods: We stressed the mouse macrophage cell line (RAW 264.7) with a saturated fatty acid, 500μM palmitate, reflecting the levels found in the circulation of obese patients. We analyzed the microRNAome profiles of this cell line using QRT-PCR based miScript miRNA PCR array which contained all known mouse microRNAs in miRBase release16 and performed pathway analysis for potential targets. Results: 227 microRNAs showed altered expression levels; 43 microRNAs above 2 fold difference and 13 microRNAs 3-24 fold difference. Pathway analysis enriched the target mRNAs of these lipotoxic ER stress associated miRNAs. Conclusion: When exposed to high concentrations of saturated fatty acids that can induce ER stress, macrophages display a dynamic range of changes in their microRNAome profiles. Our findings reflect the consequences of lipotoxic stress on circulating monocytes and tissue-associated macrophages in obesity. Further studies are needed to deliniate which UPR arm is reponsible for the microRNA changes reported here.
Highlights
Endoplasmic Reticulum (ER) functions as a critical metabolic hub for protein, lipid and calcium metabolism [1]
When exposed to high concentrations of saturated fatty acids that can induce ER stress, macrophages display a dynamic range of changes in their microRNAome profiles
Further studies are needed to deliniate which unfolded protein response (UPR) arm is reponsible for the microRNA changes reported here
Summary
Endoplasmic Reticulum (ER) functions as a critical metabolic hub for protein, lipid and calcium metabolism [1]. Upon ER stress, UPR functions as a switch between the adaptation of the cell against stress and the decision for apoptosis. Chronic ER stress is harmful for cells and tissues and may lead to development of many metabolic diseases such as obesity, diabetes and atherosclerosis. The chronic inflammation observed in obesity can arise from malfunctioning ER as UPR and the organelle itself is intricately linked to many immunological conditions [1]. UPR is an essential homeostatic mechanism for the management of stress associated with the accumulation of unfolded proteins in the ER [5]. The unfolded or misfolded proteins can be destined to ER-associated degradation pathways. If the ER cannot restore homeostasis in irremediable ER stress, UPR activates apoptotic pathways to initiate cell death [7]
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