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基因组复制、基因成列与调控新特性的起源

Genomic duplication, fractionation and the origin of regulatory novelty.

作者信息

Langham Richard J, Walsh Justine, Dunn Molly, Ko Cynthia, Goff Stephen A, Freeling Michael

机构信息

Department of Plant and Microbial Biology, University of California, Berkeley 94720, USA.

出版信息

Genetics. 2004 Feb;166(2):935-45. doi: 10.1534/genetics.166.2.935.

DOI:10.1534/genetics.166.2.935
PMID:15020478
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1470742/
Abstract

Having diverged 50 MYA, rice remained diploid while the maize lineage became tetraploid and then fractionated by losing genes from one or the other duplicate region. We sequenced and annotated 13 maize genes (counting the duplicate gene as one gene) on one or the other of the pair of homeologous maize regions; 12 genes were present in one cluster in rice. Excellent maize-rice synteny was evident, but only after the fractionated maize regions were condensed onto a finished rice map. Excluding the gene we used to define homeologs, we found zero retention. Once retained, fractionation (loss of functioning DNA sequence) could occur within cis-acting gene space. We chose a retained duplicate basic leucine zipper transcription factor gene because it was well marked with big, exact phylogenetic footprints (CNSs). Detailed alignments of lg2 and retained duplicate lrs1 to their rice ortholog found that fractionation of conserved noncoding sequences (CNSs) was rare, as expected. Of 30 CNSs, 27 were conserved. The 3 unexpected, missing CNSs and a large insertion support subfunctionalization as a reflection of fractionation of cis-acting gene space and the recent evolution of lg2's novel maize leaf and shoot developmental functions. In general, the principles of fractionation and consolidation work well in making sense of maize gene and genomic sequence data.

摘要

在5000万年前分化后,水稻仍为二倍体,而玉米谱系则变成了四倍体,随后通过从一个或另一个重复区域丢失基因而发生了基因分馏。我们对一对同源玉米区域中的一个或另一个上的13个玉米基因(将重复基因计为一个基因)进行了测序和注释;12个基因在水稻中存在于一个簇中。玉米与水稻之间的良好共线性很明显,但只有在将分馏后的玉米区域浓缩到完整的水稻图谱上之后才明显。排除我们用于定义同源基因的那个基因,我们发现没有保留。一旦保留下来,分馏(功能性DNA序列的丢失)可能会在顺式作用基因空间内发生。我们选择了一个保留的重复碱性亮氨酸拉链转录因子基因,因为它带有大而精确的系统发育足迹(保守非编码序列)。对lg2和保留的重复基因lrs1与其水稻直系同源基因进行的详细比对发现,如预期的那样,保守非编码序列(CNSs)的分馏很少见。在30个CNSs中,27个是保守的。这3个意外缺失的CNSs和一个大的插入支持了亚功能化,这反映了顺式作用基因空间的分馏以及lg2在玉米叶片和茎发育新功能方面的近期进化。总的来说,分馏和整合的原理在理解玉米基因和基因组序列数据方面效果良好。

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