Increased clusterin levels after myocardial infarction is due to a defect in protein degradation systems activity

Annie Turkieh,Jean-Luc Balligand,Philippe Amouyel,Maggy Chwastyniak,Florence Pinet,Sina Porouchani,Olivia Beseme,Christophe Bauters,Nicolas Lamblin

doi:10.1038/s41419-019-1857-x

Abstract

Clusterin (CLU) is induced in many organs after tissue injury or remodeling. Recently, we show that CLU levels are increased in plasma and left ventricle (LV) after MI, however, the mechanisms involved are not yet elucidated. On the other hand, it has been shown that the activity of the protein degradation systems (PDS) is affected after MI with a decrease in ubiquitin proteasome system (UPS) and an increase in macroautophagy. The aim of this study was to decipher if the increased CLU levels after MI are in part due to the alteration of PDS activity. Rat neonate cardiomyocytes (NCM) were treated with different modulators of UPS and macroautophagy in order to decipher their role in CLU expression, secretion, and degradation. We observed that inhibition of UPS activity in NCM increased CLU mRNA levels, its intracellular protein levels (p-CLU and m-CLU) and its secreted form (s-CLU). Macroautophagy was also induced after MG132 treatment but is not active. The inhibition of macroautophagy induction in MG132-treated NCM increased CLU mRNA and m-CLU levels, but not s-CLU compared to NCM only treated by MG132. We also demonstrate that CLU can be degraded in NCM through proteasome and lysosome by a macroautophagy independent pathway. In another hand, CLU silencing in NCM has no effect either on macroautophagy or apoptosis induced by MG132. However, the overexpression of CLU secreted isoform in H9c2 cells, but not in NCM decreased apoptosis after MG132 treatment. Finally, we observed that increased CLU levels in hypertrophied NCM and in failing human hearts are associated with proteasome inhibition and macroautophagy alteration. All these data suggest that increased CLU expression and secretion after MI is, in part, due to a defect of UPS and macroautophagy activities in the heart and may have a protective effect by decreasing apoptosis induced by proteasome inhibition.

Highlights

Clusterin (CLU) is a protein constitutively expressed in almost mammalian tissues and is highly conserved across species
We first studied the effect of protein degradation systems (PDS) alterations on CLU expression and secretion in neonate cardiomyocytes (NCM) treated with MG132 for 18 h in order to inhibit proteasome activity as verified by significant accumulation of ubiquitinated proteins (Fig. 1a)
We showed a significant increase of CLU mRNA levels, its intracellular proteins levels (precursor (p-CLU) and mature forms (m-CLU)) and its secreted form (s-CLU) in the culture media after MG132 treatment compared to control cells (Fig. 1b)

Summary

Introduction

Clusterin (CLU) is a protein constitutively expressed in almost mammalian tissues and is highly conserved across species. Other CLU species are detected in some stress conditions and are found in different cellular compartments (mitochondria, cytoplasm, and nucleus). The role of CLU is complex depending on the CLU isoforms, localization, and cellular types. Several functions have been proposed such as lipid transport, apoptosis regulation protein degradation, and epithelial-to-mesenchymal transition induction[1,2,3]. CLU is induced in many organs where tissue injury or remodeling occurs. Several studies have shown increased CLU levels in the heart and plasma at early stage after myocardial infarction (MI)[3,4,5]

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