Recent advances in keratinase production via protein engineering, breeding, and fermentation

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Abstract

The gene editing and synthetic biological tools have led to the implementation of diverse metabolic engineering approaches to enhance the production of specific enzymes. Microbial keratinases can convert keratin wastes into valuable compounds for mankind. Since the market for keratinases cannot be satisfied by production from wild hosts, it is obligatory to develop hosts with high keratinase yields. The intention of this review is to evaluate microbial keratinase advancement through protein engineering, breeding techniques, and fermentation optimization. The main aim of protein engineering is to improve the heat resistance ability and catalytic activity of keratinases by employing mutagenesis methods. Moreover, modifying the expression elements and host engineering are also two unique ways to augment the keratinase yield. Intending to accelerate the production of modified keratinase, this review attempts to highlight the optimization of expression elements, such as promoter engineering, UTR, signal peptide, and codon optimization. Moreover, the approaches of host engineering including strengthening precursor supply, membrane surface engineering, and optimization of secretion pathways were also explained here. Furthermore, it is also essential to optimize the medium composition and fermentation condition for high keratinase yield. This review also addressed the present advancements, difficulties, and tendencies in the field of microbial keratinase production, along with its potential.

Abstract Image

通过蛋白质工程、育种和发酵生产角蛋白酶的最新进展
基因编辑和合成生物学工具促使人们采用多种代谢工程方法来提高特定酶的产量。微生物角蛋白酶可以将角蛋白废物转化为对人类有价值的化合物。由于野生宿主的生产无法满足角蛋白酶的市场需求,因此必须开发角蛋白酶产量高的宿主。本综述旨在评估通过蛋白质工程、育种技术和发酵优化提高微生物角蛋白酶产量的情况。蛋白质工程的主要目的是通过诱变方法提高角蛋白酶的耐热能力和催化活性。此外,修改表达元件和宿主工程也是提高角蛋白酶产量的两种独特方法。为了加速改良角蛋白酶的生产,本综述试图强调表达元件的优化,如启动子工程、UTR、信号肽和密码子优化。此外,本文还阐述了宿主工程的方法,包括加强前体供应、膜表面工程和分泌途径优化。此外,优化培养基成分和发酵条件对提高角蛋白酶产量也至关重要。本综述还探讨了微生物角蛋白酶生产领域目前的进展、困难和趋势及其潜力。
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