Three-dimensional structure model and predicted ATP interaction rewiring of a deviant RNA ligase 2

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology

BMC Structural Biology Pub Date : 2015-10-09 DOI:10.1186/s12900-015-0046-0

Sandrine Moreira, Emmanuel Noutahi, Guillaume Lamoureux, Gertraud Burger

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引用次数: 4

Abstract

RNA ligases 2 are scarce and scattered across the tree of life. Two members of this family are well studied: the mitochondrial RNA editing ligase from the parasitic trypanosomes (Kinetoplastea), a promising drug target, and bacteriophage T4 RNA ligase 2, a workhorse in molecular biology. Here we report the identification of a divergent RNA ligase 2 (DpRNL) from Diplonema papillatum (Diplonemea), a member of the kinetoplastids’ sister group.

We identified DpRNL with methods based on sensitive hidden Markov Model. Then, using homology modeling and molecular dynamics simulations, we established a three dimensional structure model of DpRNL complexed with ATP and Mg2+.

The 3D model of Diplonema was compared with available crystal structures from Trypanosoma brucei, bacteriophage T4, and two archaeans. Interaction of DpRNL with ATP is predicted to involve double π-stacking, which has not been reported before in RNA ligases. This particular contact would shift the orientation of ATP and have considerable consequences on the interaction network of amino acids in the catalytic pocket. We postulate that certain canonical amino acids assume different functional roles in DpRNL compared to structurally homologous residues in other RNA ligases 2, a reassignment indicative of constructive neutral evolution. Finally, both structure comparison and phylogenetic analysis show that DpRNL is not specifically related to RNA ligases from trypanosomes, suggesting a unique adaptation of the latter for RNA editing, after the split of diplonemids and kinetoplastids.

Homology modeling and molecular dynamics simulations strongly suggest that DpRNL is an RNA ligase 2. The predicted innovative reshaping of DpRNL’s catalytic pocket is worthwhile to be tested experimentally.

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一个异常RNA连接酶的三维结构模型和预测ATP相互作用重布线2

RNA连接酶很少，而且分散在生命之树上。该家族的两个成员得到了很好的研究:来自寄生锥虫的线粒体RNA编辑连接酶(kinetoplasstea)，一个有前途的药物靶点，以及噬菌体T4 RNA连接酶2，一个分子生物学的主力。在这里，我们报道了一个分化的RNA连接酶2 (DpRNL)的鉴定，从乳头状蝶状体(Diplonema papillatum, Diplonemea)，一个动质体的姐妹组的成员。我们使用基于敏感隐马尔可夫模型的方法来识别DpRNL。然后，通过同源性建模和分子动力学模拟，建立了ATP和Mg2+配合的DpRNL的三维结构模型。将三维模型与布鲁氏锥虫、T4噬菌体和两种古生菌的晶体结构进行比较。预测DpRNL与ATP的相互作用涉及双π堆叠，这在RNA连接酶中尚未报道。这种特殊的接触会改变ATP的取向，并对催化口袋中氨基酸的相互作用网络产生相当大的影响。我们假设，与其他RNA连接酶中的结构同源残基相比，某些典型氨基酸在DpRNL中具有不同的功能作用2，这是建设性中性进化的重新分配指示。最后，结构比较和系统发育分析表明，DpRNL与锥虫的RNA连接酶没有特异性相关，这表明后者在双裂体和着丝质体分裂后对RNA编辑具有独特的适应性。同源性模型和分子动力学模拟有力地表明，DpRNL是RNA连接酶2。预测的催化袋的创新重塑值得实验验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Structural Biology 生物-生物物理

CiteScore

3.60

自引率

0.00%

发文量

期刊介绍： BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.