Genomewide architecture of adaptation in experimentally evolved Drosophila characterized by widespread pleiotropy

IF 2.9 4区生物学 Q1 EDUCATION & EDUCATIONAL RESEARCH

Journal of Genetics Pub Date : 2024-01-17 DOI:10.1007/s12041-023-01460-8

Zachary S. Greenspan, Thomas T. Barter, Mark A. Phillips, José M. Ranz, Michael R. Rose, Laurence D. Mueller

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引用次数: 0

Abstract

Dissecting the molecular basis of adaptation remains elusive despite our ability to sequence genomes and transcriptomes. At present, most genomic research on selection focusses on signatures of selective sweeps in patterns of heterozygosity. Other research has studied changes in patterns of gene expression in evolving populations but has not usually identified the genetic changes causing these shifts in expression. Here we attempt to go beyond these approaches by using machine learning tools to explore interactions between the genome, transcriptome, and life-history phenotypes in two groups of 10 experimentally evolved Drosophila populations subjected to selection for opposing life history patterns. Our findings indicate that genomic and transcriptomic data have comparable power for predicting phenotypic characters. Looking at the relationships between the genome and the transcriptome, we find that the expression of individual transcripts is influenced by many sites across the genome that are differentiated between the two types of populations. We find that single-nucleotide polymorphisms (SNPs), transposable elements, and indels are powerful predictors of gene expression. Collectively, our results suggest that the genomic architecture of adaptation is highly polygenic with extensive pleiotropy.

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实验进化果蝇适应性的全基因组结构以广泛的多义性为特征

尽管我们有能力对基因组和转录组进行测序，但对适应的分子基础进行剖析仍是一个难题。目前，有关选择的基因组研究大多集中于杂合度模式中选择性扫描的特征。其他研究则对进化种群中基因表达模式的变化进行了研究，但通常无法确定导致这些表达变化的基因变化。在这里，我们尝试超越这些方法，使用机器学习工具来探索基因组、转录组和生活史表型之间的相互作用，这些基因组、转录组和生活史表型在两组 10 个实验进化果蝇种群中受到对立生活史模式的选择。我们的研究结果表明，基因组和转录组数据在预测表型特征方面的能力相当。通过观察基因组和转录组之间的关系，我们发现单个转录本的表达受整个基因组中许多位点的影响，而这些位点在两类种群中是不同的。我们发现，单核苷酸多态性（SNP）、可转座元素和嵌合体是预测基因表达的有力因素。总之，我们的研究结果表明，适应的基因组结构是高度多基因的，具有广泛的多义性。

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来源期刊

Journal of Genetics 生物-遗传学

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The journal retains its traditional interest in evolutionary research that is of relevance to geneticists, even if this is not explicitly genetical in nature. The journal covers all areas of genetics and evolution,including molecular genetics and molecular evolution.It publishes papers and review articles on current topics, commentaries and essayson ideas and trends in genetics and evolutionary biology, historical developments, debates and book reviews. From 2010 onwards, the journal has published a special category of papers termed ‘Online Resources’. These are brief reports on the development and the routine use of molecular markers for assessing genetic variability within and among species. Also published are reports outlining pedagogical approaches in genetics teaching.