Generation of Anti-Mastitis Gene-Edited Dairy Goats with Enhancing Lysozyme Expression by Inflammatory Regulatory Sequence Using ISDra2-TnpB System

Overview

Journal Adv Sci (Weinh)

Specialty Biomedical Engineering

Date 2024 Aug 5

PMID 39099401

Authors

Rui Feng

Jianglin Zhao

Qian Zhang

Zhenliang Zhu

Junyu Zhang

Chengyuan Liu

Xiaoman Zheng

Fan Wang

Jie Su

Xianghai Ma

Xiaoyu Mi

Lin Guo

Xiaoxue Yan

Yayi Liu

Huijia Li

Xu Chen

Yi Deng

Guoyan Wang

Yong Zhang

Xu Liu

Jun Liu

Affiliations

Soon will be listed here.

Abstract

Gene-editing technology has become a transformative tool for the precise manipulation of biological genomes and holds great significance in the field of animal disease-resistant breeding. Mastitis, a prevalent disease in animal husbandry, imposes a substantial economic burden on the global dairy industry. In this study, a regulatory sequence gene editing breeding strategy for the successful creation of a gene-edited dairy (GED) goats with enhanced mastitis resistance using the ISDra2-TnpB system and dairy goats as the model animal is proposed. This included the targeted integration of an innate inflammatory regulatory sequence (IRS) into the promoter region of the lysozyme (LYZ) gene. Upon Escherichia Coli (E. coli) mammary gland infection, GED goats exhibited increased LYZ expression, showing robust anti-mastitis capabilities, mitigating PANoptosis activation, and alleviating blood-milk-barrier (BMB) damage. Notably, LYZ is highly expressed only in E. coli infection. This study marks the advent of anti-mastitis gene-edited animals with exogenous-free gene expression and demonstrates the feasibility of the gene-editing strategy proposed in this study. In addition, it provides a novel gene-editing blueprint for developing disease-resistant strains, focusing on disease specificity and biosafety while providing a research basis for the widespread application of the ISDra2-TnpB system.

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Generation of Anti-Mastitis Gene-Edited Dairy Goats with Enhancing Lysozyme Expression by Inflammatory Regulatory Sequence using ISDra2-TnpB System.

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PMID: 39099401 PMC: 11481229. DOI: 10.1002/advs.202404408.

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