Assembly and beyond – The structure and functions of chaperones of the proteasome

Prasanna Venkatraman
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Abstract

The 26S proteasome is the major protease machinery in eukaryotic cells responsible for spatio-temporally regulated turnover of the proteome and therefore critical to the maintenance of homeostasis. These act not only as efficient garbage disposal units for abnormal/misfolded, denatured and oxidised proteins, but, are crucial for irreversible termination of key cellular process regulation of various check points. Replication, transcription, translation, antigen processing, maintenance of stemness, development and differentiation are several of the functions and processes regulated by the proteasomes. The 2.5-megadalton structure of the eukaryotic proteasome is very complex and is assembled from 66 polypeptides with 33 structurally unique. The biogenesis of the multi subunit architecture is regulated by dedicated chaperones which orchestrate the assembly of intricate and complex structure. The current review focuses on four chaperones PSMD9 (Nas2), PSMD10 (Nas6), PAAF1 (Rpn14) and S5B (Hsm3) responsible for the assembly. The structure of the chaperones, molecular details of interaction of the individual chaperones with subunits of the proteasome during the process of assembly, role in hierarchical steps leading to assembly, recent evidences for the unprecedented role of some of these proteins (PSMD9 and PSMD10) in other physiological processes will be summarized. In addition, potential of two chaperones as targets for development of inhibitors of proteasome function will be explored.
组装和超越-蛋白酶体伴侣的结构和功能
26S蛋白酶体是真核细胞中主要的蛋白酶机制,负责蛋白质组的时空调节周转,因此对维持体内平衡至关重要。它们不仅作为异常/错误折叠、变性和氧化蛋白质的有效垃圾处理单元,而且对于各种检查点的关键细胞过程调节的不可逆终止至关重要。复制、转录、翻译、抗原加工、维持茎性、发育和分化是蛋白酶体调节的几个功能和过程。真核蛋白酶体的2.5兆道尔顿结构非常复杂,由66个多肽组成,其中33个结构独特。多亚基结构的生物发生是由专门的伴侣调节的,这些伴侣协调了复杂结构的组装。目前综述的重点是4种伴侣蛋白PSMD9 (Nas2)、PSMD10 (Nas6)、PAAF1 (Rpn14)和S5B (Hsm3)。本文将对这些蛋白的结构、在组装过程中单个伴侣蛋白与蛋白酶体亚基相互作用的分子细节、在导致组装的分层步骤中的作用以及这些蛋白(PSMD9和PSMD10)在其他生理过程中前所未有的作用的最新证据进行综述。此外,还将探讨两种伴侣蛋白作为蛋白酶体功能抑制剂开发靶点的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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