果蝇中的两个 frequenins：揭示一种不寻常的神经元钙传感器 (NCS) 重复的进化历史。

Two frequenins in Drosophila: unveiling the evolutionary history of an unusual neuronal calcium sensor (NCS) duplication.

机构信息

Instituto Cajal, CSIC, Ave, Dr, Arce 37, Madrid 28002, Spain.

出版信息

BMC Evol Biol. 2010 Feb 19;10:54. doi: 10.1186/1471-2148-10-54.

DOI:10.1186/1471-2148-10-54

PMID:20170488

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2837045/

Abstract

BACKGROUND

Drosophila frequenin (Frq), the homolog of the mammalian neuronal calcium sensor-1 (NCS-1), is a high affinity calcium-binding protein with ubiquitous expression in the nervous system. This protein has an important role in the regulation of neurotransmitter release per synapse, axonal growth and bouton formation. In D. melanogaster, frequenin is encoded by two genes (frq1 and frq2), a very unexpected feature in the Frq/NCS-1 subfamily. These genes are located in tandem in the same genomic region, and their products are 95% identical in their amino acid sequence, clearly indicating their recent origin by gene duplication. Here, we have investigated the factors involved in this unusual feature by examining the molecular evolution of the two frq genes in Drosophila and the evolutionary dynamics of NCS family in a large set of bilaterian species.

RESULTS

Surprisingly, we have found no amino acid replacements fixed across the twelve Drosophila species surveyed. In contrast, synonymous substitutions have been prevalent in the evolution of the coding region of frq1 and frq2, indicating the presence of strong functional constraints following gene duplication. Despite that, we have detected that significant evolutionary rate acceleration had occurred in Frq1 in early times from the duplication, in which positive selection (likely promoting functional diversification) had probably an important role. The analysis of sequence conservation and DNA topology at the non-coding regions of both genes has allowed the identification of DNA regions candidates to be cis-regulatory elements. The results reveal a possible mechanism of regulatory diversification between frq1 and frq2.

CONCLUSIONS

The presence of two frequenins in Drosophila and the rapid accumulation of amino acid substitutions after gene duplication are very unusual features in the evolution of the Frq/NCS-1 subfamily. Here we show that the action of positive selection in concordance with some extent of regulatory diversification might explain these findings. Selected amino acid substitutions in Frq1 likely contributed to the functional divergence between the two duplicates, which, in turn, should have diverged in their regulation by ecdysone-induced early genes.

摘要

背景

果蝇 frequenin（Frq）是哺乳动物神经元钙传感器-1（NCS-1）的同源物，是一种在神经系统中广泛表达的高亲和力钙结合蛋白。这种蛋白质在调节每个突触的神经递质释放、轴突生长和末梢形成方面起着重要作用。在黑腹果蝇中，frequenin 由两个基因（frq1 和 frq2）编码，这在 Frq/NCS-1 亚家族中是一个非常意外的特征。这两个基因在同一基因组区域中串联排列，其产物在氨基酸序列上 95%相同，显然表明它们是最近由基因复制产生的。在这里，我们通过研究果蝇中两个 frq 基因的分子进化以及在大量的两侧对称物种中 NCS 家族的进化动态，研究了导致这一不寻常特征的因素。

结果

令人惊讶的是，我们在调查的 12 个果蝇物种中没有发现固定的氨基酸替换。相比之下，frq1 和 frq2 编码区的同义替换普遍存在，表明基因复制后存在强烈的功能约束。尽管如此，我们发现 Frq1 在复制后的早期就发生了显著的进化速率加速，其中正选择（可能促进功能多样化）可能起了重要作用。对两个基因非编码区的序列保守性和 DNA 拓扑结构的分析，允许鉴定候选顺式调控元件的 DNA 区域。结果揭示了 frq1 和 frq2 之间可能的调控多样化机制。

结论

果蝇中存在两种 frequenins，以及基因复制后氨基酸替换的快速积累，是 Frq/NCS-1 亚家族进化中的非常不寻常的特征。在这里，我们表明，正选择的作用与一定程度的调控多样化相协调，可能解释了这些发现。Frq1 中的选择氨基酸替换可能有助于两个副本之间的功能分化，而这反过来又应该通过蜕皮激素诱导的早期基因的调控而分化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/64db/2837045/763d74ca2aa8/1471-2148-10-54-1.jpg

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果蝇中的两个 frequenins：揭示一种不寻常的神经元钙传感器 (NCS) 重复的进化历史。

Two frequenins in Drosophila: unveiling the evolutionary history of an unusual neuronal calcium sensor (NCS) duplication.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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