果蝇重复序列组在以色列进化峡谷的急剧小气候对比下的分歧。
Divergence of Drosophila melanogaster repeatomes in response to a sharp microclimate contrast in Evolution Canyon, Israel.
机构信息
Virginia Bioinformatics Institute and.
Department of Medical Physics, Memorial Sloan-Kettering Cancer Center, New York, NY 10065; and.
出版信息
Proc Natl Acad Sci U S A. 2014 Jul 22;111(29):10630-5. doi: 10.1073/pnas.1410372111. Epub 2014 Jul 8.
Abstract
Repeat sequences, especially mobile elements, make up large portions of most eukaryotic genomes and provide enormous, albeit commonly underappreciated, evolutionary potential. We analyzed repeatomes of Drosophila melanogaster that have been diverging in response to a microclimate contrast in Evolution Canyon (Mount Carmel, Israel), a natural evolutionary laboratory with two abutting slopes at an average distance of only 200 m, which pose a constant ecological challenge to their local biotas. Flies inhabiting the colder and more humid north-facing slope carried about 6% more transposable elements than those from the hot and dry south-facing slope, in parallel to a suite of other genetic and phenotypic differences between the two populations. Nearly 50% of all mobile element insertions were slope unique, with many of them disrupting coding sequences of genes critical for cognition, olfaction, and thermotolerance, consistent with the observed patterns of thermotolerance differences and assortative mating.
摘要
重复序列,尤其是移动元件,构成了大多数真核生物基因组的大部分,提供了巨大的、尽管通常未被充分认识的进化潜力。我们分析了在进化峡谷(以色列卡梅尔山)中因微气候差异而发生分歧的黑腹果蝇的重复序列组,这是一个自然进化实验室,两个相邻的斜坡之间的平均距离仅为 200 米,这对它们的当地生物群构成了持续的生态挑战。栖息在较冷、较潮湿的北坡的果蝇携带的转座元件比来自炎热、干燥的南坡的果蝇多约 6%,这与两个种群之间的一系列其他遗传和表型差异平行。几乎所有移动元件插入的 50%都是斜坡特有的,其中许多插入破坏了对认知、嗅觉和耐热性至关重要的基因的编码序列,与观察到的耐热性差异和选择性交配模式一致。
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