Ke-Jing Li , Lei Qi , Ying-Xuan Zhu , Min He , Qian Xiang , Dao-Qiong Zheng
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引用次数: 0
摘要
虽然基因组改变是生物进化的基础,能促进生物的适应性和多样性,但它们也可能导致有害的结果,如发展成包括癌症在内的遗传疾病。芽殖酵母是研究点突变、染色体重排和全染色体非整倍体等各种基因组改变背后机制的典范。在这篇综述中,我们重点介绍了基因筛选系统在有效评估物理和化学试剂诱变效应方面的应用。此外,我们还讨论了如何利用高通量测序技术来发现全面的基因组改变和罕见遗传事件。我们详细总结了基因组改变的特征,并讨论了在自发和应激诱导条件下驱动这些改变的遗传机制。鉴于不同生物的 DNA 复制和修复机制高度一致,从酵母研究中获得的见解为理解其他物种基因组可塑性和完整性之间的微妙平衡提供了宝贵的视角。
Spontaneous and environment induced genomic alterations in yeast model
While genomic alterations are fundamental to biological evolution, enabling adaptation and diversity, they can also result in detrimental outcomes, such as the development of genetic diseases including cancer. The budding yeast Saccharomyces cerevisiae serves as an exemplary model for investigating the mechanisms behind various genomic alterations, including point mutations, chromosomal rearrangements, and whole-chromosome aneuploidy. In this review, we highlight the application of genetic screening systems to assess the mutagenic effects of physical and chemical agents efficiently. Additionally, we discuss the utilization of high-throughput sequencing technologies to uncover comprehensive genomic alterations and rare genetic events. We provide a detailed summary of the features of genomic alterations and discuss the genetic mechanisms driving these changes under both spontaneous and stress-induced conditions. Given the high conservation of DNA replication and repair machinery across different organisms, the insights gained from studies on yeast offer valuable perspectives for understanding the delicate balance between genome plasticity and integrity in other species.
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