Mechanism and evolutionary analysis of Yarrowia lipolytica CA20 capable of producing erythritol with a high yield based on comparative genomics.

Q3 Medicine 遗传 Pub Date : 2023-10-20 DOI:10.16288/j.yczz.23-139
Kai Xia, Fang-Mei Liu, Yu-Qing Chen, Shan-Shan Chen, Chun-Ying Huang, Xue-Qun Zhao, Ru-Yi Sha, Jun Huang
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Abstract

Combined mutagenesis is widely applied for the breeding of robust Yarrowia lipolytica used in the production of erythritol. However, the changes of genome after mutagenesis remains unclear. This study aimed to unravel the mechanism involved in the improved erythritol synthesis of CA20 and the evolutionary relationship between different Y. lipolytica by comparative genomics analysis. The results showed that the genome size of Y. lipolytica CA20 was 20,420,510 bp, with a GC content of 48.97%. There were 6330 CDS and 649 ncRNA (non-coding RNA) in CA20 genome. Average nucleotide identity (ANI) analysis showed that CA20 genome possessed high similarity (ANI > 99.50%) with other Y. lipolytica strains, while phylogenetic analysis displayed that CA20 was classified together with Y. lipolytica IBT 446 and Y. lipolytica H222. CA20 shared 5342 core orthologous genes with the 8 strains while harbored 65 specific genes that mainly participated in the substrate and protein transport processes. CA20 contained 166 genes coding for carbohydrate-active enzymes (CAZymes), which was more than that found in other strains (108-137). Notably, 4, 2, and 13 different enzymes belonging to glycoside hydrolases (GHs), glycosyltransferases (GTs), and carbohydrate esterases (CEs), respectively, were only found in CA20. The enzymes involved in the metabolic pathway of erythritol were highly conserved in Y. lipolytica, except for transaldolase (TAL1). In addition, the titer and productivity of erythritol by CA20 were 190.97 g/L and 1.33 g/L/h, respectively, which were significantly higher than that of WT5 wherein 128.61 g/L and 0.92 g/L/h were obtained (P< 0.001). Five frameshift mutation genes and 15 genes harboring nonsynonymous mutation were found in CA20 compared with that of WT5. Most of these genes were involved in the cell division, cell wall synthesis, protein synthesis, and protein homeostasis maintenance. These findings suggested that the genome of Y. lipolytica is conserved during evolution, and the variance of living environment is one important factor leading to genome divergence. The varied number of CAZymes existed in Y. lipolytica is one factor that contributes to the performance difference. The increased synthesis of erythritol by Y. lipolytica CA20 is correlated with the improvement of the stability of cell structure and internal environment. The results of this study provide a basis for the directional breeding of robust strains used in erythritol production.

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基于比较基因组学的解脂亚罗花CA20高产赤藓糖醇的机制及进化分析。
联合诱变广泛应用于生产赤藓醇的健壮解脂亚罗维菌的选育。然而,突变后基因组的变化仍不清楚。本研究旨在通过比较基因组学分析,揭示CA20赤藓糖醇合成改善的机制以及不同溶脂酵母之间的进化关系。结果表明,溶脂酵母CA20的基因组大小为20420510bp,GC含量为48.97%,共有6330个CDS和649个ncRNA(非编码RNA)。平均核苷酸同一性(ANI)分析表明,CA20基因组与其他溶脂乳杆菌菌株具有较高的相似性(ANI>99.50%),而系统发育分析表明CA20与溶脂乳球菌IBT446和溶脂乳链球菌H222分为一类。CA20与8个菌株共有5342个核心直向同源基因,同时携带65个主要参与底物和蛋白质转运过程的特异基因。CA20含有166个编码碳水化合物活性酶(CAZymes)的基因,比其他菌株(108-137)多。值得注意的是,分别属于糖苷水解酶(GHs)、糖基转移酶(GTs)和碳水化合物酯酶(CE)的4种、2种和13种不同的酶仅在CA20中发现。除转醛酶(TAL1)外,参与赤藓糖醇代谢途径的酶在溶脂酵母中高度保守。此外,CA20对赤藓糖醇的效价和产率分别为190.97g/L和1.33g/L,显著高于WT5(分别为128.61g/L和0.92g/L)(P<0.001)。这些基因大多参与细胞分裂、细胞壁合成、蛋白质合成和蛋白质稳态维持。这些发现表明,溶脂酵母的基因组在进化过程中是保守的,生活环境的变化是导致基因组分化的重要因素之一。溶脂Y.中存在的CAZymes数量不同是导致性能差异的一个因素。Y.lipolytica CA20对赤藓糖醇的合成增加与细胞结构和内部环境稳定性的改善有关。该研究结果为赤藓糖醇生产中使用的健壮菌株的定向育种提供了基础。
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遗传
遗传 Medicine-Medicine (all)
CiteScore
2.50
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0.00%
发文量
6699
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