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亚功能化的局限性。

The limits of subfunctionalization.

作者信息

MacCarthy Thomas, Bergman Aviv

机构信息

Department of Pathology, Albert Einstein College of Medicine, Bronx, NY 10461, USA.

出版信息

BMC Evol Biol. 2007 Nov 7;7:213. doi: 10.1186/1471-2148-7-213.

DOI:10.1186/1471-2148-7-213
PMID:17988397
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2213666/
Abstract

BACKGROUND

The duplication-degeneration-complementation (DDC) model has been proposed as an explanation for the unexpectedly high retention of duplicate genes. The hypothesis proposes that, following gene duplication, the two gene copies degenerate to perform complementary functions that jointly match that of the single ancestral gene, a process also known as subfunctionalization. We distinguish between subfunctionalization at the regulatory level and at the product level (e.g within temporal or spatial expression domains).

RESULTS

In contrast to what is expected under the DDC model, we use in silico modeling to show that regulatory subfunctionalization is expected to peak and then decrease significantly. At the same time, neofunctionalization (recruitment of novel interactions) increases monotonically, eventually affecting the regulatory elements of the majority of genes. Furthermore, since this process occurs under conditions of stabilizing selection, there is no need to invoke positive selection. At the product level, the frequency of subfunctionalization is no higher than would be expected by chance, a finding that was corroborated using yeast microarray time-course data. We also find that product subfunctionalization is not necessarily caused by regulatory subfunctionalization.

CONCLUSION

Our results suggest a more complex picture of post-duplication evolution in which subfunctionalization plays only a partial role in conjunction with redundancy and neofunctionalization. We argue that this behavior is a consequence of the high evolutionary plasticity in gene networks.

摘要

背景

复制-退化-互补(DDC)模型已被提出用于解释重复基因意外高保留率的现象。该假说认为,基因复制后,两个基因拷贝会发生退化以执行互补功能,共同匹配单一祖先基因的功能,这一过程也被称为亚功能化。我们区分了调控水平和产物水平的亚功能化(例如在时间或空间表达域内)。

结果

与DDC模型的预期相反,我们通过计算机模拟表明,调控亚功能化预计会达到峰值然后显著下降。与此同时,新功能化(新相互作用的招募)单调增加,最终影响大多数基因的调控元件。此外,由于这个过程是在稳定选择的条件下发生的,因此无需引入正选择。在产物水平上,亚功能化的频率并不高于偶然预期的频率,这一发现通过酵母微阵列时间进程数据得到了证实。我们还发现,产物亚功能化不一定由调控亚功能化引起。

结论

我们的结果表明,复制后进化的情况更为复杂,其中亚功能化仅与冗余和新功能化一起发挥部分作用。我们认为这种行为是基因网络中高进化可塑性的结果。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ee04/2213666/a94f6be0815d/1471-2148-7-213-6.jpg
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