Xiong Yuan-Ru, Fang Yuan-Chun, He Min, Li Ke-Jing, Qi Lei, Sui Yang, Zhang Ke, Wu Xue-Chang, Meng Liang, Li Ou, Zheng Dao-Qiong
College of Life Sciences and Medicine, Zhejiang Sci-Tech University, Hangzhou, China.
Ocean College, Zhejiang University, Zhoushan, China.
Appl Environ Microbiol. 2025 Jan 31;91(1):e0167824. doi: 10.1128/aem.01678-24. Epub 2024 Dec 23.
This study explored the genomic alterations in , a key yeast in industrial biotechnology, under both spontaneous and mutagen-induced conditions. Our findings reveal that spontaneous mutations occur at a rate of approximately 4 × 10 events per base pair per cell division, primarily manifesting as single-nucleotide variations (SNVs) and small insertions and deletions (InDels). Notably, C-to-T/G-to-A transitions and C-to-A/G-to-T transversions dominate the spontaneous SNVs, while 1 bp deletions, likely resulting from template slippage, are the most frequent InDels. Furthermore, chromosomal aneuploidy and rearrangements occur, albeit at a lower frequency. Exposure to ultraviolet (UV) light, methylmethane sulfonate (MMS), and Zeocin significantly enhances the rates of SNVs and alters their mutational spectra in distinct patterns. Notably, Zeocin-induced SNVs are predominantly T-to-A and T-to-G substitutions, often occurring within the 5'-TGT-3' motif ( denotes the mutated base). Additionally, Zeocin exhibits a higher potency in stimulating InDels compared to UV and MMS. Translesion DNA synthesis is implicated as the primary mechanism behind most Zeocin-induced SNVs and some InDels, whereas non-homologous end joining serves as the main pathway for Zeocin-mediated InDels. Intriguingly, the study identifies the gene , encoding a protein kinase, as negatively associated with Zeocin resistance. Overall, our results not only deepened our knowledge about the genome evolution in but also provided reference to develop innovative strategies to harness its genetic potential.IMPORTANCE exhibits high environmental stress tolerance and lipid metabolism capabilities, making it a microorganism with significant industrial application potential. In this study, we investigated the genomic variation and evolutionary patterns of this yeast under both spontaneous and induced mutation conditions. Our results reveal distinctive mutation spectra induced by different mutagenic conditions and elucidate the underlying genetic mechanisms. We further highlight the roles of non-homologous end joining and translesion synthesis pathways in Zeocin-induced mutations, demonstrating that such treatments can rapidly confer drug resistance to the cells. Overall, our research enhances the understanding of how yeast genomes evolve under various conditions and provides guidance for developing more effective mutagenesis and breeding techniques.
本研究探讨了工业生物技术中的关键酵母在自发和诱变条件下的基因组改变。我们的研究结果表明,自发突变的发生率约为每细胞分裂每碱基对4×10个事件,主要表现为单核苷酸变异(SNV)和小的插入和缺失(InDel)。值得注意的是,C到T/G到A的转换以及C到A/G到T的颠换在自发SNV中占主导地位,而可能由模板滑动导致的1 bp缺失是最常见的InDel。此外,染色体非整倍性和重排也会发生,尽管频率较低。暴露于紫外线(UV)、甲基磺酸甲酯(MMS)和博来霉素会显著提高SNV的发生率,并以不同模式改变其突变谱。值得注意的是,博来霉素诱导的SNV主要是T到A和T到G的替换,通常发生在5'-TGT-3'基序内(表示突变碱基)。此外,与UV和MMS相比,博来霉素在刺激InDel方面表现出更高的效力。跨损伤DNA合成被认为是大多数博来霉素诱导的SNV和一些InDel背后的主要机制,而非同源末端连接则是博来霉素介导的InDel的主要途径。有趣的是,该研究确定编码蛋白激酶的基因与博来霉素抗性呈负相关。总体而言,我们的结果不仅加深了我们对该酵母基因组进化的了解,还为开发利用其遗传潜力的创新策略提供了参考。重要性该酵母表现出高环境胁迫耐受性和脂质代谢能力,使其成为具有重大工业应用潜力的微生物。在本研究中,我们研究了这种酵母在自发和诱导突变条件下的基因组变异和进化模式。我们的结果揭示了不同诱变条件诱导的独特突变谱,并阐明了潜在的遗传机制。我们进一步强调了非同源末端连接和跨损伤合成途径在博来霉素诱导的突变中的作用,表明这种处理可以迅速赋予细胞耐药性。总体而言,我们的研究增强了对酵母基因组在各种条件下如何进化的理解,并为开发更有效的诱变和育种技术提供了指导。
