Salmonid Genome Duplication Drives Specialization and Adaptation

鲑鱼基因组复制推动专业化和适应

• 批准号: RGPIN-2017-03888
• 负责人: Koop, Ben
• 金额: $ 3.64万
• 依托单位: University of Victoria
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=745764
• 关键词: Salmonid; Genome; Duplication; Drives; Specialization

Whole genome duplications (WGD) very likely play one of the more significant roles in evolutionary innovation. Such expansive duplications are found in plants, animals, in basal vertebrates (~500MYA), fishes (~300MYA), and more recently in ancestral salmonids (~90MYA). These major genome expansions double the genetic raw material that has been associated with radically new adaptations to various environments and likely play a key role in the evolution of novel species and lineages. A connection between WGDs and major evolutionary events appears to be linked to seminal shifts in evolutionary history. Our specific objectives over the next 5 years are to: 1) build on our recent development of a high quality Atlantic salmon genome reference sequence to explore functional chromosomal structural and gene changes in Arctic charr, Coho and Chinook salmon, and further annotate duplicate genes within the Atlantic salmon, and 2) develop functional annotation for the salmonid outgroup Northern Pike genome and characterize its chromosome structure and a novel sex-determining system. Chromosome structural characteristics to be explored include DNA methylation, histone modification, and DNA openness and we will compare these potential epigenetic features with gene expression patterns. The subject of epigenetics is controversial and continues to evolve. Chromatin structure and DNA methylation patterns can be passed from one generation to the next and environmental factors can modify such patterns. Epigenetic changes can cause very rapid (and reversible) phenotypic changes and adaptation to a rapidly changing environment. This proposal explores this subject in salmonids and pike where we seek to annotate newly developed salmonid and pike genomes by mapping these sites and linking them to gene promoter and gene expression patterns. We will also explore a very recently evolved novel and possibly environmentally modified sex-determining pattern found in North American pike.

全基因组复制（WGD）很可能在进化创新中扮演着更重要的角色之一。在植物、动物、基础脊椎动物（~500MYA）、鱼类（~300MYA）以及最近的鲑鱼祖先（~90MYA）中都发现了这种广泛的重复。这些主要的基因组扩增使基因原料翻了一番，这些原料与对各种环境的全新适应有关，并可能在新物种和新谱系的进化中发挥关键作用。WGDs与主要进化事件之间的联系似乎与进化史上的重大转变有关。我们在未来5年的具体目标是：1)在我们最近开发的高质量大西洋鲑鱼基因组参考序列的基础上，探索北极鲑、银鲑和奇努克鲑鱼的功能染色体结构和基因变化，并进一步注释大西洋鲑鱼内的重复基因；2)开发鲑鱼外群北梭鱼基因组的功能注释，并表征其染色体结构和新的性别决定系统。待探索的染色体结构特征包括DNA甲基化、组蛋白修饰和DNA开放，我们将把这些潜在的表观遗传特征与基因表达模式进行比较。表观遗传学的主题是有争议的，并继续发展。染色质结构和DNA甲基化模式可以从一代传递到下一代，环境因素可以改变这种模式。表观遗传变化可以引起非常迅速（和可逆）的表型变化和适应快速变化的环境。本提案探讨了鲑科和梭鱼的这一主题，我们试图通过绘制这些位点并将它们与基因启动子和基因表达模式联系起来，来注释新开发的鲑科和梭鱼基因组。我们还将探索在北美梭子鱼中发现的一种最近进化的、可能是环境改变的性别决定模式。