An efficient platform for markerless large-scale genomic deletions in Lactococcus lactis

IF 4.8 1区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

Food Bioscience Pub Date : 2025-06-12 DOI:10.1016/j.fbio.2025.107057

Yongping Xin , Dingyi Guo , Yuhang Nan , Pu Yang , Mingqiang Qiao

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Abstract

The strain fitness and stress resistance of the starters, which are important to industrial applications, can be enhanced by large-scale genomic deletions. However, the low efficiency of large-scale genomic deletions has limited the efforts to improve the Lactococcus lactis fermentation performance through this method. In this study, we developed an efficient and time-saving platform for markerless large-scale genomic deletions in L. lactis by integrating temperature-sensitive plasmids, the SacB/pG15A counterselection system, and the Cre/loxP site-specific recombination system. First, the p15A origin, upstream and downstream homologies flanking the galK gene from MG1363 were integrated into the temperature-sensitive pG⁺Host9 plasmid, enabling the resulting plasmid pG15A-UD to replicate in Escherichia coli. The SacB gene from Bacillus subtilis, which encodes levansucrase, was then expressed from the plasmid pG15A-UD to establish the SacB/pG15A counterselection system. Furthermore, the SacB/pG15A counterselection system was demonstrated to be functional in L. lactis MG1363 and N8, achieving 40 %–60 % efficiency for markerless gene deletion and insertion. Finally, by combining the temperature-sensitive plasmid, SacB/pG15A and Cre/loxP system, we successfully deleted the 14,646 bp nisin biosynthetic gene cluster and a ∼58.5 kb nonessential genomic region in L. lactis N8. Our results provide an effective, rapid platform for large-scale genomic deletion in L. lactis to enhance the strain fitness and stress resistance and investigate their mechanisms.

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乳酸乳球菌无标记大规模基因组缺失的有效平台

大规模的基因组缺失可以提高发酵剂的菌株适应度和抗逆性，这对工业应用具有重要意义。然而，大规模基因组缺失的低效率限制了通过这种方法提高乳酸乳球菌发酵性能的努力。在这项研究中，我们通过整合温度敏感质粒、SacB/pG15A反选择系统和Cre/loxP位点特异性重组系统，开发了一个高效、省时的乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸乳酸。首先，将来自MG1363的p15A起源和galK基因两侧的上下游同源物整合到温度敏感的pG+Host9质粒中，使所得到的质粒pG15A-UD在大肠杆菌中复制。将枯草芽孢杆菌中编码左旋蔗糖酶的SacB基因在质粒pG15A- ud上表达，建立SacB/pG15A反选择体系。此外，SacB/pG15A反选择系统被证明在l.l lactis MG1363和N8中起作用，对无标记基因的删除和插入效率达到40% - 60%。最后，通过结合温度敏感质粒、SacB/pG15A和Cre/loxP系统，我们成功地删除了L. lactis N8中14,646 bp的nisin生物合成基因簇和约58.5 kb的非必需基因组区域。本研究结果为乳酸菌的大规模基因组缺失提供了一个有效、快速的平台，以增强菌株适应性和抗逆性，并探讨其机制。

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来源期刊

Food Bioscience Biochemistry, Genetics and Molecular Biology-Biochemistry

CiteScore

6.40

自引率

5.80%

发文量

671

审稿时长

27 days

期刊介绍： Food Bioscience is a peer-reviewed journal that aims to provide a forum for recent developments in the field of bio-related food research. The journal focuses on both fundamental and applied research worldwide, with special attention to ethnic and cultural aspects of food bioresearch.