PDIA6在错误折叠的胰岛素原加工过程中的重要作用。

A prominent role of PDIA6 in processing of misfolded proinsulin.

作者信息

Gorasia Dhana G, Dudek Nadine L, Safavi-Hemami Helena, Perez Rochelle Ayala, Schittenhelm Ralf B, Saunders Philippa M, Wee Sheena, Mangum Jon E, Hubbard Michael J, Purcell Anthony W

机构信息

Department of Biochemistry and Molecular Biology, The Bio21 Molecular Science and Biotechnology Institute, The University of Melbourne, Victoria, Australia.

Department of Biochemistry and Molecular Biology, The Bio21 Molecular Science and Biotechnology Institute, The University of Melbourne, Victoria, Australia; Infection and Immunity Program, Biomolecular Discovery Institute and Department of Biochemistry and Molecular Biology, School of Biomedical Sciences, Monash University, Clayton, Victoria, Australia.

出版信息

Biochim Biophys Acta. 2016 Jun;1864(6):715-723. doi: 10.1016/j.bbapap.2016.03.002. Epub 2016 Mar 3.

DOI:10.1016/j.bbapap.2016.03.002

PMID:26947243

Abstract

Despite its critical role in maintaining glucose homeostasis, surprisingly little is known about proinsulin folding in the endoplasmic reticulum. In this study we aimed to understand the chaperones involved in the maturation and degradation of proinsulin. We generated pancreatic beta cell lines expressing FLAG-tagged proinsulin. Several chaperones (including BiP, PDIA6, calnexin, calreticulin, GRP170, Erdj3 and ribophorin II) co-immunoprecipitated with proinsulin suggesting a role for these proteins in folding. To investigate the chaperones responsible for targeting misfolded proinsulin for degradation, we also created a beta cell line expressing FLAG-tagged proinsulin carrying the Akita mutation (Cys96Tyr). All chaperones found to be associated with wild type proinsulin also co-immunoprecipitated with Akita proinsulin. However, one additional protein, namely P58(IPK), specifically precipitated with Akita proinsulin and approximately ten fold more PDIA6, but not other PDI family members, was bound to Akita proinsulin. The latter suggests that PDIA6 may act as a key reductase and target misfolded proinsulin to the ER-degradation pathway. The preferential association of PDIA6 to Akita proinsulin was also confirmed in another beta cell line (βTC-6). Furthermore, for the first time, a physiologically relevant substrate for PDIA6 has been evidenced. Thus, this study has identified several chaperones/foldases that associated with wild type proinsulin and has also provided a comprehensive interactome for Akita misfolded proinsulin.

摘要

尽管胰岛素原在内质网中折叠对于维持葡萄糖稳态起着关键作用，但令人惊讶的是，目前我们对其了解甚少。在本研究中，我们旨在了解参与胰岛素原成熟和降解的分子伴侣。我们构建了表达FLAG标签胰岛素原的胰腺β细胞系。几种分子伴侣（包括BiP、PDIA6、钙联蛋白、钙网蛋白、GRP170、Erdj3和核糖体结合蛋白II）与胰岛素原共免疫沉淀，表明这些蛋白质在折叠过程中发挥作用。为了研究负责将错误折叠的胰岛素原靶向降解的分子伴侣，我们还构建了一个表达携带秋田突变（Cys96Tyr）FLAG标签胰岛素原的β细胞系。所有与野生型胰岛素原相关的分子伴侣也与秋田胰岛素原共免疫沉淀。然而，一种额外的蛋白质，即P58(IPK)，特异性地与秋田胰岛素原沉淀，并且与秋田胰岛素原结合的PDIA6比其他PDI家族成员多大约十倍。后者表明PDIA6可能作为关键的还原酶，将错误折叠的胰岛素原靶向内质网降解途径。在另一个β细胞系（βTC-6）中也证实了PDIA6与秋田胰岛素原的优先结合。此外，首次证明了PDIA6的生理相关底物。因此，本研究鉴定了几种与野生型胰岛素原相关的分子伴侣/折叠酶，也为秋田错误折叠胰岛素原提供了一个全面的相互作用组。

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PDIA6在错误折叠的胰岛素原加工过程中的重要作用。

A prominent role of PDIA6 in processing of misfolded proinsulin.

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