Life in transition: the evolutionary consequences of ecological and habitat shifts

转型中的生命：生态和栖息地变化的进化后果

• 批准号: RGPIN-2016-06199
• 负责人: Adamowicz, Sarah
• 金额: $ 2.04万
• 依托单位: University of Guelph
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=616156
• 关键词: Life; transition; evolutionary; consequences; ecological

Major transitions in habitat and lifestyle traits have featured prominently in the history of life and have shaped the distribution of biodiversity on Earth. Some kinds of transitions have occurred numerous times independently, such as between marine and fresh waters and between predatory and herbivorous feeding modes. Such transitions that are represented by repeated, evolutionarily independent events provide valuable opportunities -- i.e. natural experiments -- to study the predictability of evolutionary responses. My overarching research objective is to elucidate the evolutionary causes and consequences of repeated transitions. Firstly, my students and I will assess the degree to which transitions impact rates of molecular evolutionary change through time, with a focus upon insects and aquatic invertebrates. We will quantify variability in rates of molecular evolution and test whether rates vary systematically in association with key habitat (e.g. marine/freshwater, benthic/planktonic, terrestrial/aquatic) and lifestyle (e.g. carnivorous/herbivorous, eusocial/solitary, parasitic/free-living) transitions in evolution. This work will represent a substantial step forward in molecular rates research by modeling rate variation across entire phylogenetic trees and by simultaneously investigating the strength of multiple factors in a multivariate context. Secondly, we will study molecular evolution associated with multiple types of aquatic habitat transitions, each representing a difference between a lower-extinction vs. a higher-extinction environment: ancient lakes vs. surrounding freshwaters, flowing vs. standing waters, and lakes vs. ponds. Using phylogenetically paired sister lineages differing in habitat occupancy, these various habitat regimes will be investigated for their potential association with elevated molecular diversity, population genetic structure, molecular evolutionary rate, and extent of genetic cohesion (vs. clustering into discrete groupings). The results of this work will contribute to understanding the impacts of habitat transitions upon molecular evolution within aquatic life. Furthermore, by explicitly investigating the hypothesis that extinction is important for generating discrete genetic groupings, this work also will contribute towards resolving a puzzle as to why so many taxa exhibit a "barcode gap", which is the disjunction often observed between intraspecific vs. interspecific pairwise DNA sequence divergences. The results of these studies will reveal whether these transitions provoke general molecular evolutionary responses. Moreover, understanding systematic rate variability is crucial for all who rely upon the molecular clock to provide a timescale for life, including researchers studying macroevolution, biogeography, and climate change impacts using historical reconstructions.

栖息地和生活方式特征的重大转变在生命史上占有突出地位，并塑造了地球上生物多样性的分布。有些种类的转变已经独立地发生了无数次，例如在海洋和淡水沃茨之间以及在捕食和草食模式之间。这种由重复的、进化上独立的事件所代表的转变提供了宝贵的机会--即自然实验--来研究进化反应的可预测性。我的首要研究目标是阐明重复转变的进化原因和后果。 首先，我和我的学生将评估过渡对分子进化速率的影响程度，重点是昆虫和水生无脊椎动物。我们将量化分子进化速率的变异性，并测试速率是否与关键栖息地（例如海洋/淡水，底栖/水生，陆地/水生）和生活方式（例如食肉/草食，真社会/独居，寄生/自由生活）进化过渡相关。这项工作将代表一个实质性的一步，在分子速率的研究，通过建模率变化在整个系统发育树，并同时调查多个因素的强度在一个多变量的情况下。 其次，我们将研究与多种类型的水生栖息地过渡相关的分子进化，每一种都代表了低灭绝与高灭绝环境之间的差异：古老的湖泊与周围的新鲜沃茨，流动与静止的沃茨，以及湖泊与池塘。使用不同的栖息地占用的遗传配对的姐妹谱系，这些不同的栖息地制度将调查其潜在的关联与升高的分子多样性，种群遗传结构，分子进化速率，遗传凝聚力的程度（与聚类成离散的分组）。这项工作的结果将有助于了解栖息地转变对水生生物分子进化的影响。此外，通过明确调查灭绝对于产生离散遗传分组很重要的假设，这项工作也将有助于解决为什么这么多分类群表现出“条形码间隙”的难题，这是种内与种间成对DNA序列分歧之间经常观察到的分离。 这些研究的结果将揭示这些转变是否会引起一般的分子进化反应。此外，了解系统速率变异性对于所有依赖分子钟提供生命时间尺度的人来说至关重要，包括研究宏观进化，地理学和使用历史重建的气候变化影响的研究人员。