人FOLH1基因非同义单核苷酸多态性的芯片结构和功能分析。

In silico pharmacology Pub Date : 2025-02-25 eCollection Date: 2025-01-01 DOI:10.1007/s40203-025-00319-3

Abtin Tondar, Muhammad Irfan, Sergio Sánchez-Herrero, Hafsa Athar, Aleena Haqqi, Asim Kumar Bepari, Laura Calvet Liñán, David Hervás Marin

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摘要

非同义单核苷酸多态性（nssnp），也被称为错义snp，可以严重影响个体对许多疾病的易感性，包括癌症。在这项研究中，我们进行了全面的计算机分析，以研究叶酸水解酶1（FOLH1）基因中nssnp的结构和功能意义，该基因编码前列腺特异性膜抗原（PSMA）。共检索到504个snp，经过筛选，使用5种不同的计算机工具鉴定出15个致病性nssnp。其中三个snp - r255h (rs375565491), R255C （rs201789325）和G168E (rs267602926)-被一致预测在所有硅工具中具有致病性。MutPred2用于预测所鉴定突变的结构和功能后果。分析揭示了PSMA蛋白的多种变化，包括螺旋构象、糖基化模式、跨膜性质和溶剂可及性的变化。此外，I-Mutant 2.0分析显示，除了rs267602926 （G168E）外，大多数nssnp的蛋白质稳定性都有所下降，而rs267602926 （G168E）预计会增加稳定性。ConSurf保守分析显示，R255H和R255C为高度保守的氨基酸残基，具有潜在的功能和结构意义。此外，翻译后修饰（PTM）分析表明，虽然磷酸化和甲基化位点保持不变，但特异性糖基化位点在两种致病突变变体（R255H和R255C）中丢失，可能影响PSMA功能并对前列腺癌产生不利影响。我们的研究结果强调了研究FOLH1非单核苷酸多态性对PSMA蛋白的结构和功能影响的计算机研究的重要性。这样的计算机研究可以加深我们对nssnp在前列腺癌发病、进展和耐药中的作用的理解。补充信息：在线版本包含补充资料，提供地址为10.1007/s40203-025-00319-3。

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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In-silico structural and functional analysis of nonsynonymous single nucleotide polymorphisms in human FOLH1 gene.

Non-synonymous single nucleotide polymorphisms (nsSNPs), also known as missense SNPs, can seriously affect an individual's vulnerability to numerous diseases, including cancer. In this study, we conducted a comprehensive in-silico analysis to examine the structural and functional implications of nsSNPs within the Folate Hydrolase 1(FOLH1) gene, which encodes the Prostate-Specific Membrane Antigen (PSMA). A total of 504 SNPs were retrieved, and after filtering, 15 pathogenic nsSNPs were identified using five different in-silico tools. Three of these SNPs-R255H (rs375565491), R255C (rs201789325), and G168E (rs267602926)-were consistently predicted to be pathogenic across all in-silico tools. MutPred2 was used to predict the structural and functional consequences of the identified mutations. The analysis revealed multiple alterations in the PSMA protein, including changes in helical conformations, glycosylation patterns, transmembrane properties, and solvent accessibility. Furthermore, I-Mutant 2.0 analysis demonstrated a decrease in protein stability for most nsSNPs, except for rs267602926 (G168E), which was predicted to increase stability. Conservation analysis using ConSurf revealed varying degrees of amino acid conservation, with R255H and R255C identified as highly conserved residues, indicating their potential functional and structural significance. Additionally, post-translational modification (PTM) analysis indicated that while phosphorylation and methylation sites remained unchanged, specific glycosylation sites were lost in two pathogenic mutant variants (R255H and R255C), potentially affecting PSMA function and adversely impacting prostate cancer. Our findings highlight the importance of in silico studies to investigate the structural and functional impacts of FOLH1 nsSNPs on the PSMA protein. Such in silico studies can deepen our understanding of the roles of nsSNPs in prostate cancer onset, progression, and drug resistance.

Supplementary information: The online version contains supplementary material available at 10.1007/s40203-025-00319-3.

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In silico pharmacology

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