Directed evolution driving the generation of an efficient keratinase variant to facilitate the feather degradation

Author:

Zhang Jing,Su Chang,Kong Xiao-Li,Gong Jin-Song,Liu Yan-Lin,Li Heng,Qin Jiufu,Xu Zheng-Hong,Shi Jin-Song

Abstract

AbstractKeratinases can specifically degrade keratins, which widely exist in hair, horns, claws and human skin. There is a great interest in developing keratinase to manage keratin waste generated by the poultry industry and reusing keratin products in agriculture, medical treatment and feed industries. Degradation of keratin waste by keratinase is more environmentally friendly and more sustainable compared with chemical and physical methods. However, the wild-type keratinase-producing strains usually cannot meet the requirements of industrial production, and some are pathogenic, limiting their development and utilization. The main purpose of this study is to improve the catalytic performance of keratinase via directed evolution technology for the degradation of feathers. We first constructed a mutant library through error-prone PCR and screened variants with enhanced enzyme activity. The keratinase activity was further improved through fermentation conditions optimization and fed-batch strategies in a 7-L bioreactor. As a result, nine mutants with enhanced activity were identified and the highest enzyme activity was improved from 1150 to 8448 U/mL finally. The mutant achieved efficient biodegradation of feathers, increasing the degradation rate from 49 to 88%. Moreover, a large number of amino acids and soluble peptides were obtained as degradation products, which were excellent protein resources to feed. Therefore, the study provided a keratinase mutant with application potential in the management of feather waste and preparation of protein feed additive. Graphical Abstract

Funder

National Key Research and Development Program of China

National Natural Science Foundation of China

Ningxia Hui Autonomous Region Key Research & Development Plan

Publisher

Springer Science and Business Media LLC

Subject

Renewable Energy, Sustainability and the Environment,Biomedical Engineering,Food Science,Biotechnology

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