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The genomic basis of adaptation and species divergence in Senecio

千里光适应和物种分化的基因组基础

基本信息

批准号：
NE/G018448/1
负责人：
Simon Hiscock
金额：
$ 48.7万
依托单位：
University of Bristol
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2010
资助国家：
英国
起止时间：
2010 至无数据
项目状态：
已结题

来源：
https://gtr.ukri.org/projects?ref=NE%2FG018448%2F1
关键词：
genomic basis adaptation species divergence

项目摘要

This project will exploit the latest developments in DNA sequencing and analysis technologies to study the genomic bases of adaptation and speciation in the plant genus Senecio (ragworts). The principal aim of this work is to determine the relative importance of differences in the coding and regulatory regions of genes in adaptation of species to contrasting environments, our null hypothesis being that these genomic regions contribute equally to adaptation and species divergence. To do this we will compare the nucleotide sequences of protein-coding and regulatory regions of the genomes of Senecio aethnensis and S. chrysanthemifolius, adapted to high and low altitudes, respectively, on Mt. Etna, Sicily, and a hybrid formed between them, S. squalidus (Oxford ragwort), which evolved in Britain following introduction of plants to Oxford from a hybrid zone on Mt. Etna 300 years ago. All 3 Senecio species are adapted to very different habitats and these phenotypic differences will be reflected by genotypic differences detectable by new comparative genomic technologies. Indeed, our previous NERC-funded research has revealed differences in gene expression between the 3 species correlated with phenotypic adaptation. This project will analyse these genetic differences further, and expand genomic comparison through an analysis of the entire gene-rich portion (protein-coding and regulatory sequences) of the genomes of the 3 species. To do this we will establish a partial reference genome by sequencing the gene-space, the non-repetitive fraction of the genome, of Senecio squalidus. This will allow identification of protein-coding and regulatory regions (e.g. promoters and microRNA binding sites). Protein-coding regions of genes can be identified relatively easily using bioinformatic approaches, but identification of regulatory regions requires additional analyses using new technologies designed to identify: i) RNA polymerase- and transcription factor-binding sites (chromatin immunoprecipitation [ChIP-] sequencing), ii) microRNAs (recently discovered ubiquitous gene-regulatory factors) and their binding sites. Once identified, these regions can then be sequenced extensively in multiple individuals of all 3 species to identify differences between them. Evolutionary genetic analysis will then be used to compare patterns of DNA polymorphism to detect 'footprints' of natural selection in protein-coding and regulatory regions that may have been involved in local adaptation and speciation, and also to further investigate the evolutionary history of the 3 Senecio species. In addition, we will investigate changes to promoter binding, DNA methylation (gene silencing) and microRNA expression/targeting between the 3 Senecio species that may be involved in adaptation. Finally, we will test (using plants grown at different UV-regimes) whether altered expression/regulation of candidate genes for local adaptation to high UV light (in high altitude S. aethnensis) is determined by species divergence or phenotypic plasticity. This project will break new ground in evolutionary genomics by being the first to: 1) use functional and evolutionary genetic analyses to analyse the entire gene-space of a plant to detect 'footprints' of selection correlated with adaptation and speciation; 2) explore the role of microRNAs in adaptation and speciation; 3) use large-scale ChIP-sequencing in a plant species. This work will therefore provide unprecedented advances in our current understanding of the role of genomic change in adaptation and speciation.

这个项目将利用DNA测序和分析技术的最新发展来研究千里光(千里光)植物适应和物种形成的基因组基础。这项工作的主要目的是确定基因编码和调节区的差异在物种对对比环境的适应中的相对重要性，我们的零假设是这些基因组区域对适应和物种分化同等重要。为此，我们将比较分别适应高海拔和低海拔的千里光和菊花基因组蛋白质编码区和调控区的核苷酸序列。Etna，西西里岛，和他们之间形成的杂交，方子草(牛津草)，它是在英国从山上的杂交区引进植物到牛津后进化的。300年前的埃特纳。所有3个千里光物种都适应了非常不同的生境，这些表型差异将通过新的比较基因组技术检测到的基因差异来反映。事实上，我们之前由NERC资助的研究已经揭示了与表型适应相关的3个物种之间的基因表达差异。该项目将进一步分析这些遗传差异，并通过分析这3个物种基因组的整个富含基因的部分(蛋白质编码和调控序列)来扩大基因组比较。为了做到这一点，我们将通过对千里光基因组的非重复部分基因空间进行测序来建立部分参考基因组。这将有助于确定蛋白质编码和调节区(例如启动子和microRNA结合位点)。使用生物信息学方法可以相对容易地识别基因的蛋白质编码区，但识别调节区需要使用新技术的额外分析，这些新技术旨在识别：i)RNA聚合酶和转录因子结合部位(染色质免疫沉淀[芯片-]测序)，ii)microRNAs(最近发现的普遍存在的基因调节因子)及其结合部位。一旦确定，这些区域就可以在所有3个物种的多个个体中广泛测序，以确定它们之间的差异。然后将使用进化遗传分析来比较DNA多态模式，以检测可能参与局部适应和物种形成的蛋白质编码和调节区的自然选择的‘足迹’，并进一步调查3个千里光物种的进化史。此外，我们还将调查可能参与适应的3个千里光物种之间启动子结合、DNA甲基化(基因沉默)和microRNA表达/靶向的变化。最后，我们将测试(使用生长在不同紫外线条件下的植物)局部适应高紫外线的候选基因的表达/调节变化是否由物种差异或表型可塑性决定。该项目将在进化基因组学方面开辟新的天地，它将率先：1)使用功能和进化遗传分析来分析植物的整个基因空间，以检测与适应和物种形成相关的选择的‘足迹’；2)探索microRNAs在适应和物种形成中的作用；3)在植物物种中使用大规模芯片测序。因此，这项工作将为我们目前对基因组变化在适应和物种形成中的作用的理解提供前所未有的进步。