A fragment activity assay reveals the key residues of TBC1D15 GTPase-activating protein (GAP) in Chiloscyllium plagiosum

IF 2.946 Q3 Biochemistry, Genetics and Molecular Biology

BMC Molecular Biology Pub Date : 2019-02-12 DOI:10.1186/s12867-019-0122-2

Yangyang Jin, Guodong Lin, Yanna Chen, Yinghua Ge, Ruofeng Liang, Jia Wu, Jianqing Chen, Dan Wang, Hengbo Shi, Hui Fei, Zhengbing Lv

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引用次数: 2

Abstract

GTPase-activating proteins (GAPs) with a TBC (Tre-2/Bub2/Cdc16) domain architecture serve as negative regulators of Rab GTPases. The related crystal structure has been studied and reported by other members of our research group in 2017 (Chen et al. in Protein Sci 26(4):834–846, 2017). The protein crystal structure and sequencing data accession numbers in Protein structure database (PDB) are 5TUB (Shark TBC1D15 GAP) and 5TUC (Sus TBC1D15 GAP), respectively. In this paper, we analyzed the Rab-GAP specificity of TBC1D15 in the evolution and influence of key amino acid residue mutations on Rab-GAP activity.

Sequence alignment showed that five arginine residues of the TBC1D15-GAP domain are conserved among the species Sus/Mus/Homo but have been replaced by glycine or lysine in Shark. A fragment activity assay was conducted by altering the five residues of Shark TBC1D15-GAP to arginine, and the corresponding arginine in TBC1D15 GAP domains from Sus and Homo species were mutated to resemble Shark TBC1D15-GAP. Our data revealed that the residues of G28, K45, K119, K122 and K221 in the Shark TBC1D15-GAP domain had a key role in determining the specificity for Rab7 and Rab11. Mutation of the five residues significantly altered the Shark TBC1D15-GAP activity.

These results revealed that the substrate specificity of TBC1D15 has had different mechanisms across the evolution of species from lower-cartilaginous fish to higher mammals. Collectively, the data support a different mechanism of Shark TBC1D15-GAP in substrate selection, which provides a new idea for the development of Marine drugs.

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片段活性分析揭示了白桦TBC1D15 gtpase激活蛋白(GAP)的关键残基

具有TBC (tre2 /Bub2/Cdc16)结构域结构的gtpase激活蛋白(GAPs)作为兔gtpase的负调控因子。相关晶体结构已于2017年由课题组其他成员研究并报道(Chen et al. in Protein Sci 26(4): 834-846, 2017)。蛋白结构数据库(protein structure database, PDB)的蛋白晶体结构和测序数据登录号分别为5TUB (Shark TBC1D15 GAP)和5TUC (Sus TBC1D15 GAP)。本文分析了TBC1D15在进化过程中的lab - gap特异性，以及关键氨基酸残基突变对lab - gap活性的影响。序列比对表明，TBC1D15-GAP结构域的5个精氨酸残基在Sus/Mus/Homo中是保守的，但在Shark中被甘氨酸或赖氨酸所取代。通过将鲨鱼TBC1D15-GAP的5个残基改变为精氨酸，进行了片段活性测定，结果表明，在Sus和Homo物种中，TBC1D15-GAP结构域中相应的精氨酸突变为与鲨鱼TBC1D15-GAP相似。我们的数据显示，鲨鱼TBC1D15-GAP结构域中G28、K45、K119、K122和K221的残基在决定Rab7和Rab11的特异性中起关键作用。这5个残基的突变显著改变了鲨鱼TBC1D15-GAP活性。这些结果表明，从低软骨鱼类到高等哺乳动物，TBC1D15的底物特异性在物种进化过程中具有不同的机制。综上所述，这些数据支持了鲨鱼TBC1D15-GAP在底物选择中的不同机制，为海洋药物的开发提供了新的思路。

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 Molecular Biology 生物-生化与分子生物学

CiteScore

4.80

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： BMC Molecular Biology is an open access journal publishing original peer-reviewed research articles in all aspects of DNA and RNA in a cellular context, encompassing investigations of chromatin, replication, recombination, mutation, repair, transcription, translation and RNA processing and function.