The role of endoplasmic reticulum stress on reducing recombinant protein production in mammalian cells

IF 3.7 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biochemical Engineering Journal Pub Date : 2024-07-20 DOI:10.1016/j.bej.2024.109434

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Abstract

Therapeutic recombinant protein production relies on industrial scale culture of mammalian cells to produce active proteins in quantities sufficient for clinical use. The combination of stresses from industrial cell culture environment and recombinant protein production can overwhelm the protein synthesis machinery in the endoplasmic reticulum (ER). This leads to a buildup of improperly folded proteins which induces ER stress. Cells respond to ER stress by activating the Unfolded Protein Response (UPR). To restore proteostasis, ER sensor proteins reduce global protein synthesis and increase chaperone protein synthesis, and if that is insufficient the proteins are degraded. If proteostasis is still not restored, apoptosis is initiated. Increasing evidence suggests crosstalk between ER proteostasis and DNA damage repair (DDR) pathways. External factors (e.g., metabolites) from the cellular environment as well as internal factors (e.g., transgene copy number) can impact genome stability. Failure to maintain genome integrity reduces cell viability and in turn protein production. This review focuses on the association between ER stress and processes that affect protein production and secretion. The processes mediated by ER stress, including inhibition of global protein translation, chaperone protein production, degradation of misfolded proteins, DNA repair, and protein secretion, impact recombinant protein production. Recombinant protein production can be reduced by ER stress through increased autophagy and protein degradation, reduced protein secretion, and reduced DDR response.

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内质网应激对降低哺乳动物细胞重组蛋白产量的作用

治疗用重组蛋白的生产依赖于哺乳动物细胞的工业规模培养，以生产足够临床使用的活性蛋白。工业化细胞培养环境和重组蛋白质生产所产生的压力会使内质网（ER）中的蛋白质合成机制不堪重负。这导致折叠不当的蛋白质堆积，诱发 ER 应激。细胞通过激活未折叠蛋白反应（UPR）来应对 ER 压力。为了恢复蛋白稳态，ER 传感蛋白会减少整体蛋白质的合成，增加伴侣蛋白的合成，如果还不够，蛋白质就会被降解。如果蛋白稳态仍未恢复，就会启动细胞凋亡。越来越多的证据表明，ER 蛋白稳态与 DNA 损伤修复（DDR）途径之间存在相互影响。细胞环境中的外部因素（如代谢物）和内部因素（如转基因拷贝数）都会影响基因组的稳定性。如果不能保持基因组的完整性，就会降低细胞的活力，进而降低蛋白质的产量。本综述将重点讨论ER应激与影响蛋白质生产和分泌的过程之间的联系。ER应激介导的过程，包括抑制全局蛋白质翻译、伴侣蛋白生成、降解折叠错误的蛋白质、DNA修复和蛋白质分泌，都会影响重组蛋白质的生产。ER应激可通过增加自噬和蛋白质降解、减少蛋白质分泌和降低DDR反应来减少重组蛋白质的产生。

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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来源期刊

Biochemical Engineering Journal 工程技术-工程：化工

CiteScore

7.10

自引率

5.10%

发文量

380

审稿时长

34 days

期刊介绍： The Biochemical Engineering Journal aims to promote progress in the crucial chemical engineering aspects of the development of biological processes associated with everything from raw materials preparation to product recovery relevant to industries as diverse as medical/healthcare, industrial biotechnology, and environmental biotechnology. The Journal welcomes full length original research papers, short communications, and review papers* in the following research fields: Biocatalysis (enzyme or microbial) and biotransformations, including immobilized biocatalyst preparation and kinetics Biosensors and Biodevices including biofabrication and novel fuel cell development Bioseparations including scale-up and protein refolding/renaturation Environmental Bioengineering including bioconversion, bioremediation, and microbial fuel cells Bioreactor Systems including characterization, optimization and scale-up Bioresources and Biorefinery Engineering including biomass conversion, biofuels, bioenergy, and optimization Industrial Biotechnology including specialty chemicals, platform chemicals and neutraceuticals Biomaterials and Tissue Engineering including bioartificial organs, cell encapsulation, and controlled release Cell Culture Engineering (plant, animal or insect cells) including viral vectors, monoclonal antibodies, recombinant proteins, vaccines, and secondary metabolites Cell Therapies and Stem Cells including pluripotent, mesenchymal and hematopoietic stem cells; immunotherapies; tissue-specific differentiation; and cryopreservation Metabolic Engineering, Systems and Synthetic Biology including OMICS, bioinformatics, in silico biology, and metabolic flux analysis Protein Engineering including enzyme engineering and directed evolution.