黑麦草/羊茅渐渗系与水稻之间的比较分析表明,功能注释基因模型的主要部分位于基因组中重组率低/极低的区域。
Comparative analyses between lolium/festuca introgression lines and rice reveal the major fraction of functionally annotated gene models is located in recombination-poor/very recombination-poor regions of the genome.
作者信息
King Julie, Armstead Ian P, Donnison S Iain, Roberts Luned A, Harper John A, Skøt Kirsten, Elborough Kieran, King Ian P
机构信息
Plant Genetics and Breeding Department, Institute of Grassland and Environmental Research, Aberystwyth, SY23 3EB, United Kingdom.
出版信息
Genetics. 2007 Sep;177(1):597-606. doi: 10.1534/genetics.107.075515. Epub 2007 Jul 1.
Abstract
Publication of the rice genome sequence has allowed an in-depth analysis of genome organization in a model monocot plant species. This has provided a powerful tool for genome analysis in large-genome unsequenced agriculturally important monocot species such as wheat, barley, rye, Lolium, etc. Previous data have indicated that the majority of genes in large-genome monocots are located toward the ends of chromosomes in gene-rich regions that undergo high frequencies of recombination. Here we demonstrate that a substantial component of the coding sequences in monocots is localized proximally in regions of very low and even negligible recombination frequencies. The implications of our findings are that during domestication of monocot plant species selection has concentrated on genes located in the terminal regions of chromosomes within areas of high recombination frequency. Thus a large proportion of the genetic variation available for selection of superior plant genotypes has not been exploited. In addition our findings raise the possibility of the evolutionary development of large supergene complexes that confer a selective advantage to the individual.
摘要
水稻基因组序列的公布使得对一种模式单子叶植物物种的基因组组织进行深入分析成为可能。这为诸如小麦、大麦、黑麦、黑麦草等尚未测序的大基因组且具有重要农业价值的单子叶物种的基因组分析提供了一个强大的工具。先前的数据表明,大基因组单子叶植物中的大多数基因位于染色体末端的富含基因区域,这些区域经历高频率的重组。在此我们证明,单子叶植物编码序列的很大一部分位于近端,处于重组频率极低甚至可忽略不计的区域。我们研究结果的意义在于,在单子叶植物物种驯化过程中,选择集中在染色体末端高重组频率区域内的基因上。因此,很大一部分可用于选择优良植物基因型的遗传变异尚未得到利用。此外,我们的研究结果还提出了大型超级基因复合体进化发展的可能性,这种复合体赋予个体选择优势。
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