Profiling Human Protein Degradome Delineates Cellular Responses to Proteasomal Inhibition and Reveals a Feedback Mechanism in Regulating Proteasome Homeostasis

Overview

Journal Cell Res

Specialty Cell Biology

Date 2014 Sep 17

PMID 25223703

Citations 8

Authors

Tao Yu

Yonghui Tao

Meiqiang Yang

Peng Chen

Xiaobo Gao

Yanbo Zhang

Tao Zhang

Zi Chen

Jian Hou

Yan Zhang

Kangcheng Ruan

Hongyan Wang

Ronggui Hu

Affiliations

Soon will be listed here.

Abstract

Global change in protein turnover (protein degradome) constitutes a central part of cellular responses to intrinsic or extrinsic stimuli. However, profiling protein degradome remains technically challenging. Recently, inhibition of the proteasome, e.g., by using bortezomib (BTZ), has emerged as a major chemotherapeutic strategy for treating multiple myeloma and other human malignancies, but systematic understanding of the mechanisms for BTZ drug action and tumor drug resistance is yet to be achieved. Here we developed and applied a dual-fluorescence-based Protein Turnover Assay (ProTA) to quantitatively profile global changes in human protein degradome upon BTZ-induced proteasomal inhibition. ProTA and subsequent network analyses delineate potential molecular basis for BTZ action and tumor drug resistance in BTZ chemotherapy. Finally, combined use of BTZ with drugs targeting the ProTA-identified key genes or pathways in BTZ action reduced BTZ resistance in multiple myeloma cells. Remarkably, BTZ stabilizes proteasome subunit PSMC1 and proteasome assembly factor PSMD10, suggesting a previously under-appreciated mechanism for regulating proteasome homeostasis. Therefore, ProTA is a novel tool for profiling human protein degradome to elucidate potential mechanisms of drug action and resistance, which might facilitate therapeutic development targeting proteostasis to treat human disorders.

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