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黑腹果蝇中11个自发从头突变的分子性质

Molecular nature of 11 spontaneous de novo mutations in Drosophila melanogaster.

作者信息

Yang H P, Tanikawa A Y, Kondrashov A S

机构信息

Department of Ecology and Evolutionary Biology, Cornell University, Ithaca, New York 14853, USA.

出版信息

Genetics. 2001 Mar;157(3):1285-92. doi: 10.1093/genetics/157.3.1285.

DOI:10.1093/genetics/157.3.1285
PMID:11238412
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1461551/
Abstract

To investigate the molecular nature and rate of spontaneous mutation in Drosophila melanogaster, we screened 887,000 individuals for de novo recessive loss-of-function mutations at eight loci that affect eye color. In total, 28 mutants were found in 16 independent events (13 singletons and three clusters). The molecular nature of the 13 events was analyzed. Coding exons of the locus were affected by insertions or deletions >100 nucleotides long (6 events), short frameshift insertions or deletions (4 events), and replacement nucleotide substitutions (1 event). In the case of 2 mutant alleles, coding regions were not affected. Because approximately 70% of spontaneous de novo loss-of-function mutations in Homo sapiens are due to nucleotide substitutions within coding regions, insertions and deletions appear to play a much larger role in spontaneous mutation in D. melanogaster than in H. sapiens. If so, the per nucleotide mutation rate in D. melanogaster may be lower than in H. sapiens, even if their per locus mutation rates are similar.

摘要

为了研究黑腹果蝇自发突变的分子本质和速率,我们在影响眼睛颜色的八个基因座上筛选了887,000个个体,以寻找新生的隐性功能丧失突变。总共在16个独立事件中发现了28个突变体(13个单突变体和3个簇状突变体)。分析了13个事件的分子本质。该基因座的编码外显子受到长度大于100个核苷酸的插入或缺失(6个事件)、短移码插入或缺失(4个事件)以及替换核苷酸替换(1个事件)的影响。在2个突变等位基因的情况下,编码区未受影响。由于人类中约70%的新生自发功能丧失突变是由于编码区内的核苷酸替换,插入和缺失在黑腹果蝇的自发突变中似乎比在人类中发挥了更大的作用。如果是这样,即使黑腹果蝇和人类的每个基因座突变率相似,其每核苷酸突变率可能低于人类。

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