Chandra Devi, Prashant Ranjan, Sonam Raj, Parimal Das
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Molecular dynamics (MD) simulation of PC1 wild-type and mutant protein regions were performed using GROMACS 2018 (GROMOS96 54a7 force field). Findings revealed that five variants including c.8809G > A (p.E2937K), c.11249G > C (p.R3750P), c.3101A > G (p.N1034S), c.6928G > A (p.G2310R), c.6644G > A (p.R2215Q) exhibited major alterations in RNA structures and thereby their interactions with other proteins or RNAs affecting protein structure dynamics. While certain variants have minimal impact on RNA conformations, their observed alterations in MD simulations indicate impact on protein structure dynamics highlighting the importance of evaluating the functional consequences of genetic variants by considering both RNA and protein levels. The study also emphasizes that each missense variant exerts a unique impact on RNA stability, and protein structure dynamics, potentially contributing to the heterogeneous clinical manifestations and progression observed in Autosomal Dominant Polycystic Kidney Disease (ADPKD) patients offering a novel perspective in this direction. 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引用次数: 0
摘要
我们分析了之前研究中发现的 9 个 PKD1 错义变异的影响,包括 c.6928G > A p.G2310R、c.8809G > A p.E2937K、c.2899 T > C p.W967R、c.6284A > G p.D2095G、c.6644G > A p.R2215Q、c.7810G > A p.D2604N、c.11249G > C p.R3750P、c.1001C > T p.T334M,以及 c.3101A > G p.N1034S。RNA 结构分析使用的是 41 个核苷酸的短 RNA 片段,变异位置位于第 21 个核苷酸,确保两侧各有 20 个碱基。使用 RNAstructure 预测了这些 RNA 片段的二级结构。利用 MutaRNA 网络服务器分析了突变体与野生型相比的结构变化。使用 GROMACS 2018(GROMOS96 54a7 力场)对 PC1 野生型和突变体蛋白质区域进行了分子动力学(MD)模拟。研究结果显示,包括 c.8809G > A (p.E2937K), c.11249G > C (p.R3750P), c.3101A > G (p.N1034S), c.6928G > A (p.G2310R), c.6644G > A (p.R2215Q) 在内的五个变异体的 RNA 结构发生了重大改变,从而影响了它们与其他蛋白质或 RNA 的相互作用,进而影响了蛋白质结构动力学。虽然某些变体对 RNA 构象的影响微乎其微,但在 MD 模拟中观察到的变化表明它们对蛋白质结构动态产生了影响,这突出了通过考虑 RNA 和蛋白质水平来评估基因变体功能后果的重要性。该研究还强调,每种错义变体都对 RNA 稳定性和蛋白质结构动态产生独特的影响,这可能是导致常染色体显性多囊肾(ADPKD)患者出现不同临床表现和病情进展的原因之一,为研究提供了一个新的视角。因此,通过计算工具研究结构动态有助于确定变异的优先次序,了解ADPKD表现变异的分子机制,并开发有针对性的治疗干预措施:在线版本包含补充材料,可查阅 10.1007/s13205-024-04057-9。
Computational exploration of protein structure dynamics and RNA structural consequences of PKD1 missense variants: implications in ADPKD pathogenesis.
We analyzed the impact of nine previously identified missense PKD1 variants from our studies, including c.6928G > A p.G2310R, c.8809G > A p.E2937K, c.2899 T > C p.W967R, c.6284A > G p.D2095G, c.6644G > A p.R2215Q, c.7810G > A p.D2604N, c.11249G > C p.R3750P, c.1001C > T p.T334M, and c.3101A > G p.N1034S on RNA structures and PC1 protein structure dynamics utilizing computational tools. RNA structure analysis was done using short RNA snippets of 41 nucleotides with the variant position at the 21st nucleotide, ensuring 20 bases on both sides. The secondary structures of these RNA snippets were predicted using RNAstructure. Structural changes of the mutants compared to the wild type were analyzed using the MutaRNA webserver. Molecular dynamics (MD) simulation of PC1 wild-type and mutant protein regions were performed using GROMACS 2018 (GROMOS96 54a7 force field). Findings revealed that five variants including c.8809G > A (p.E2937K), c.11249G > C (p.R3750P), c.3101A > G (p.N1034S), c.6928G > A (p.G2310R), c.6644G > A (p.R2215Q) exhibited major alterations in RNA structures and thereby their interactions with other proteins or RNAs affecting protein structure dynamics. While certain variants have minimal impact on RNA conformations, their observed alterations in MD simulations indicate impact on protein structure dynamics highlighting the importance of evaluating the functional consequences of genetic variants by considering both RNA and protein levels. The study also emphasizes that each missense variant exerts a unique impact on RNA stability, and protein structure dynamics, potentially contributing to the heterogeneous clinical manifestations and progression observed in Autosomal Dominant Polycystic Kidney Disease (ADPKD) patients offering a novel perspective in this direction. Thus, the utility of studying the structure dynamics through computational tools can help in prioritizing the variants for their functional implications, understanding the molecular mechanisms underlying variability in ADPKD presentation and developing targeted therapeutic interventions.
Supplementary information: The online version contains supplementary material available at 10.1007/s13205-024-04057-9.
3 BiotechAgricultural and Biological Sciences-Agricultural and Biological Sciences (miscellaneous)
CiteScore
6.00
自引率
0.00%
发文量
314
期刊介绍:
3 Biotech publishes the results of the latest research related to the study and application of biotechnology to:
- Medicine and Biomedical Sciences
- Agriculture
- The Environment
The focus on these three technology sectors recognizes that complete Biotechnology applications often require a combination of techniques. 3 Biotech not only presents the latest developments in biotechnology but also addresses the problems and benefits of integrating a variety of techniques for a particular application. 3 Biotech will appeal to scientists and engineers in both academia and industry focused on the safe and efficient application of Biotechnology to Medicine, Agriculture and the Environment.