Breeding of Fructilactobacillus sanfranciscensis with excellent ethanol tolerance based on adaptive evolution technology

Yan Liu, Muhammad Danial, Huixin Dong, Min Zhang, Ru Jia, Guohua Zhang
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Abstract

Fructilactobacillus (F.) sanfranciscensis LS1 is one of the dominant strains in sourdough. Ethanol produced during fermentation is an inevitable stress factor for this stain. At present, the research on the mechanism of ethanol stress in lactic acid bacteria is limited compared to yeast species (particularly Saccharomyces (S.) cerevisiae). In this study microbial physiology and protein expression analysis technology was used. F. sanfranciscensis LS1 served as the original bacteria, and evolutionary bacteria LS1-1 were obtained by adaptive evolution. The comparison of the two strains' growth, survival rate, morphology, hydrophobicity, cohesive force and protein expression revealed that the evolved bacteria had a significantly higher ethanol tolerance than the original bacteria. Similarly, the hydrophobicity of evolved bacteria was increased about 6.6 times than that of the original bacteria. With an increase in ethanol concentration, the level of damage on evolved bacteria was less, and the total proportion of damaged cells decreased. After 8 h of culturing, the self-cohesion of the evolved strain was 1.29 times more than the original strain. Sodium dodecyl-sulfate polyacrylamide gel electrophoresis analysis has shown that the number of protein bands of the evolved bacteria LS1-1 increased significantly, indicating that the associated proteins were expressed more and the strain's ability to resist environmental pressure was improved.

Abstract Image

基于适应性进化技术的三方果乳杆菌的选育
桑弗朗西斯果乳杆菌LS1是酸面团中的优势菌株之一。发酵过程中产生的乙醇是这种污渍不可避免的压力因素。目前,与酵母(特别是酿酒酵母)相比,对乳酸菌乙醇胁迫机制的研究有限。本研究采用微生物生理学和蛋白质表达分析技术。桑弗朗西斯氏F.sanfranciscensis LS1为原始菌,进化菌LS1-1为适应性进化菌。通过对两个菌株的生长、存活率、形态、疏水性、内聚力和蛋白质表达的比较,发现进化细菌的乙醇耐受性明显高于原始细菌。同样,进化细菌的疏水性比原始细菌增加了约6.6倍。随着乙醇浓度的增加,对进化细菌的损伤程度降低,损伤细胞的总比例降低。8点之后 培养h,进化菌株的自内聚力是原始菌株的1.29倍。十二烷基硫酸钠-聚丙烯酰胺凝胶电泳分析表明,进化细菌LS1-1的蛋白带数量显著增加,表明相关蛋白表达增加,菌株抵抗环境压力的能力提高。
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