{"title":"枯草芽孢杆菌 YsxC 在 GDP 和 GTP-Mg 2+ 结合态下的分子动力学模拟研究和动态网络分析","authors":"Shuchika Devaraj Biligere, Kavya Kallahalli Mohankumar, Upendra Nagarajachari, Krishnaveni Sannathammegowda","doi":"10.34117/bjdv10n5-044","DOIUrl":null,"url":null,"abstract":"Ribosomes are essential cellular organelles made up of rRNA and rproteins found in both prokaryotic and eukaryotic cells, and play an important role in protein synthesis. The functional ribosomes are synthesized through the process called ribosome biogenesis, which proceeds with the help of certain factors such as chaperones, ribosomal proteins, and GTPases. GTPases bind to the premature ribosomal subunit and function as a checkpoint, ensuring the proper assembly of other proteins. To aid this process, GTPase undergoes conformational changes, alternating between an active GTP-bound state and an inactive GDP bound state. YsxC is a GTPase that functions this way, to help in the maturation of 50S subunit. Although YsxC plays an important role in ribosome biogenesis, a detailed knowledge of how the GDP and GTPMg2+ states of YsxC assist in the switching process is yet to be realized. Therefore, a study on the GDP and GTP-Mg2+ bound states is done for YsxC GTPase of Bacillus subtilis by all-atom molecular dynamics simulation for a period of 500 ns. The simulations aided the analysis of the RMSD from which it was noticed that both the GDP and GTP-Mg2+ states of YsxC attained equilibration after 200ns. The analysis of the Rg for the systems showed that the GTP-Mg2+ system showed higher values, in comparison to the GDP system, indicating conformational changes in the two systems. Thus, a residue-wise calculation for the difference in the SASA (solvent accessible surface area) of the GTP-Mg2+ and GDP system is done, and it is noticed that the GTP-Mg2+ system, especially in the regions recognized as Switch I and Switch II had a higher difference in SASA value. In which Switch I’s Lys55 (positive residue) and Switch II’s Arg89 (positive residue) showed a distinct difference, indicating that Switch I has more accessibility to solvent. Giving rise to a supposition that the residue Lys55 attracts the negative rRNA and aids in the binding of YsxC with the premature 50S subunit in the GTP-Mg2+ bound state by associating with the rRNA. To fathom the role of the GTP-Mg2+ bound state in increasing the SASA value of Switch I region, a community network is constructed to extract the shortest path. More number of paths are observed between the selected residue in the GTP-Mg2+ bound state inferring that the increased SASA in the Lys55 is due to the stronger connection with the nucleotide. Overall this study suggest that enhanced surface exposure of YsxC’s Sw-I in the GTP-Mg2+ bound state facilitate the GTP-Mg2+ bound system to involve in ribosome biogenesis by interacting with ribosomal constituents (rRNA and rproteins).","PeriodicalId":504671,"journal":{"name":"Brazilian Journal of Development","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-05-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Molecular dynamics simulation studies and dynamic network analysis of Bacillus subtilis YsxC in GDP and GTP-Mg 2+ bound states\",\"authors\":\"Shuchika Devaraj Biligere, Kavya Kallahalli Mohankumar, Upendra Nagarajachari, Krishnaveni Sannathammegowda\",\"doi\":\"10.34117/bjdv10n5-044\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Ribosomes are essential cellular organelles made up of rRNA and rproteins found in both prokaryotic and eukaryotic cells, and play an important role in protein synthesis. The functional ribosomes are synthesized through the process called ribosome biogenesis, which proceeds with the help of certain factors such as chaperones, ribosomal proteins, and GTPases. GTPases bind to the premature ribosomal subunit and function as a checkpoint, ensuring the proper assembly of other proteins. To aid this process, GTPase undergoes conformational changes, alternating between an active GTP-bound state and an inactive GDP bound state. YsxC is a GTPase that functions this way, to help in the maturation of 50S subunit. Although YsxC plays an important role in ribosome biogenesis, a detailed knowledge of how the GDP and GTPMg2+ states of YsxC assist in the switching process is yet to be realized. Therefore, a study on the GDP and GTP-Mg2+ bound states is done for YsxC GTPase of Bacillus subtilis by all-atom molecular dynamics simulation for a period of 500 ns. The simulations aided the analysis of the RMSD from which it was noticed that both the GDP and GTP-Mg2+ states of YsxC attained equilibration after 200ns. The analysis of the Rg for the systems showed that the GTP-Mg2+ system showed higher values, in comparison to the GDP system, indicating conformational changes in the two systems. Thus, a residue-wise calculation for the difference in the SASA (solvent accessible surface area) of the GTP-Mg2+ and GDP system is done, and it is noticed that the GTP-Mg2+ system, especially in the regions recognized as Switch I and Switch II had a higher difference in SASA value. In which Switch I’s Lys55 (positive residue) and Switch II’s Arg89 (positive residue) showed a distinct difference, indicating that Switch I has more accessibility to solvent. Giving rise to a supposition that the residue Lys55 attracts the negative rRNA and aids in the binding of YsxC with the premature 50S subunit in the GTP-Mg2+ bound state by associating with the rRNA. To fathom the role of the GTP-Mg2+ bound state in increasing the SASA value of Switch I region, a community network is constructed to extract the shortest path. More number of paths are observed between the selected residue in the GTP-Mg2+ bound state inferring that the increased SASA in the Lys55 is due to the stronger connection with the nucleotide. Overall this study suggest that enhanced surface exposure of YsxC’s Sw-I in the GTP-Mg2+ bound state facilitate the GTP-Mg2+ bound system to involve in ribosome biogenesis by interacting with ribosomal constituents (rRNA and rproteins).\",\"PeriodicalId\":504671,\"journal\":{\"name\":\"Brazilian Journal of Development\",\"volume\":null,\"pages\":null},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2024-05-16\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Brazilian Journal of Development\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.34117/bjdv10n5-044\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Brazilian Journal of Development","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.34117/bjdv10n5-044","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
摘要
核糖体是由原核细胞和真核细胞中的 rRNA 和 r 蛋白组成的重要细胞器,在蛋白质合成中发挥着重要作用。功能性核糖体是通过核糖体生物发生过程合成的,这一过程在某些因素(如伴侣蛋白、核糖体蛋白和 GTP 酶)的帮助下进行。GTPase 与未成熟的核糖体亚基结合,起着检查点的作用,确保其他蛋白质的正常组装。为了帮助这一过程,GTPase 会发生构象变化,在活跃的 GTP 结合态和不活跃的 GDP 结合态之间交替。YsxC 就是这样一种 GTPase,它有助于 50S 亚基的成熟。尽管 YsxC 在核糖体生物发生过程中发挥着重要作用,但人们对 YsxC 的 GDP 和 GTPMg2+ 状态如何帮助完成切换过程的详细了解仍有待实现。因此,我们通过 500 毫微秒的全原子分子动力学模拟,对枯草芽孢杆菌 YsxC GTPase 的 GDP 和 GTP-Mg2+ 结合态进行了研究。模拟有助于分析 RMSD,从中发现 YsxC 的 GDP 和 GTP-Mg2+ 状态都在 200 ns 后达到平衡。对这两个系统的 Rg 分析表明,与 GDP 系统相比,GTP-Mg2+ 系统的 Rg 值更高,这表明这两个系统的构象发生了变化。因此,对 GTP-Mg2+ 和 GDP 系统的 SASA(溶剂可及表面积)差异进行了残基计算,结果发现,GTP-Mg2+ 系统,尤其是开关 I 和开关 II 区域的 SASA 值差异较大。其中开关 I 的 Lys55(阳性残基)和开关 II 的 Arg89(阳性残基)显示出明显的差异,表明开关 I 对溶剂的可及性更高。由此推测,残基 Lys55 可吸引阴性 rRNA,并通过与 rRNA 结合,帮助 YsxC 与处于 GTP-Mg2+ 结合态的过早 50S 亚基结合。为了弄清 GTP-Mg2+ 结合状态在增加开关 I 区域 SASA 值中的作用,我们构建了一个群落网络来提取最短路径。在 GTP-Mg2+ 结合状态下,所选残基之间有更多的路径,推断 Lys55 的 SASA 值增加是由于与核苷酸的连接更强。总之,这项研究表明,在 GTP-Mg2+ 结合状态下,YsxC 的 Sw-I 表面暴露增强,有利于 GTP-Mg2+ 结合系统通过与核糖体成分(rRNA 和 r 蛋白)相互作用参与核糖体的生物生成。
Molecular dynamics simulation studies and dynamic network analysis of Bacillus subtilis YsxC in GDP and GTP-Mg 2+ bound states
Ribosomes are essential cellular organelles made up of rRNA and rproteins found in both prokaryotic and eukaryotic cells, and play an important role in protein synthesis. The functional ribosomes are synthesized through the process called ribosome biogenesis, which proceeds with the help of certain factors such as chaperones, ribosomal proteins, and GTPases. GTPases bind to the premature ribosomal subunit and function as a checkpoint, ensuring the proper assembly of other proteins. To aid this process, GTPase undergoes conformational changes, alternating between an active GTP-bound state and an inactive GDP bound state. YsxC is a GTPase that functions this way, to help in the maturation of 50S subunit. Although YsxC plays an important role in ribosome biogenesis, a detailed knowledge of how the GDP and GTPMg2+ states of YsxC assist in the switching process is yet to be realized. Therefore, a study on the GDP and GTP-Mg2+ bound states is done for YsxC GTPase of Bacillus subtilis by all-atom molecular dynamics simulation for a period of 500 ns. The simulations aided the analysis of the RMSD from which it was noticed that both the GDP and GTP-Mg2+ states of YsxC attained equilibration after 200ns. The analysis of the Rg for the systems showed that the GTP-Mg2+ system showed higher values, in comparison to the GDP system, indicating conformational changes in the two systems. Thus, a residue-wise calculation for the difference in the SASA (solvent accessible surface area) of the GTP-Mg2+ and GDP system is done, and it is noticed that the GTP-Mg2+ system, especially in the regions recognized as Switch I and Switch II had a higher difference in SASA value. In which Switch I’s Lys55 (positive residue) and Switch II’s Arg89 (positive residue) showed a distinct difference, indicating that Switch I has more accessibility to solvent. Giving rise to a supposition that the residue Lys55 attracts the negative rRNA and aids in the binding of YsxC with the premature 50S subunit in the GTP-Mg2+ bound state by associating with the rRNA. To fathom the role of the GTP-Mg2+ bound state in increasing the SASA value of Switch I region, a community network is constructed to extract the shortest path. More number of paths are observed between the selected residue in the GTP-Mg2+ bound state inferring that the increased SASA in the Lys55 is due to the stronger connection with the nucleotide. Overall this study suggest that enhanced surface exposure of YsxC’s Sw-I in the GTP-Mg2+ bound state facilitate the GTP-Mg2+ bound system to involve in ribosome biogenesis by interacting with ribosomal constituents (rRNA and rproteins).