Identification of Diagnostic SNPs in Exon 28 of the Von Willebrand Factor Gene for Diagnosis of VWD Type 2B in Patients Referred to IBTO Coagulation Lab: In-silico Approach

International Journal of Medical Laboratory Pub Date : 2023-06-20 DOI:10.18502/ijml.v10i2.12946

Roshanak Shamriz, K. Atarodi, M. Ahmadinejad, N. Ghasemi

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Abstract

Background and Aims: von Willebrand disease (VWD) is brought on by hereditary impairments in the von Willebrand factor (VWF). It has been determined that most of the molecular abnormalities are present in exon 28 of the VWF gene qualitative variations. In this regard, investigating mutations in exon 28 of the VWF coding gene can help identify the VWD type and can be used to manage patients by using appropriate strategies. Materials and Methods: 10 suspected VWD type 2B patients were investigated for the genotype of exon 28. Routine coagulation tests were performed for the patients. Molecular sequencing was also used for the evaluation of mutations in exon 28. Determining the tertiary structure of VWF can aid in understanding its functional residues and interactions. The nsSNVs’ pathogenicity was examined utilizing potent bioinformatics methods. Step-by-step testing of the high-risk mutations was done using SIFT, PolyPhen-2, I-Mutant 2.0, PHD-SNPg, and SNPs&GO. Then, the secondary structure, amino acid conservation, and feature of amino acids were investigated via Protparam, Cofactor, Interprosurf, ConSurf, NetSurfP-2.0, and HOPE. Results: N1231T, V1229G, V1316M, and P1266Q missense mutations in VWF were detected. 3D structure of VWF predicted and evaluated. Putative conserved domains were identified. P1266Q and V1316M amino acid substitutions are predicted as “Not tolerated substitution” damaging and Disease, while V1229G and N1231T amino acid substitutions are predicted as “tolerated substitution” benign and Neutral. Conclusion: V1316M and P1266Q amino acid substitutions were determined as high-risk mutations using powerful bioinformatics tools in VWD patients.

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用于IBTO凝血实验室诊断VWD 2B型患者的Von Willebrand因子基因28外显子诊断snp的鉴定:计算机方法

背景与目的:血管性血友病(VWD)是由血管性血友病因子(VWF)的遗传性损伤引起的疾病。已经确定，大多数分子异常存在于VWF基因的28外显子的定性变异。在这方面，研究VWF编码基因外显子28的突变可以帮助确定VWD类型，并可以通过使用适当的策略来管理患者。材料与方法:对10例疑似VWD 2B型患者进行28外显子基因型分析。对患者进行常规凝血检查。分子测序也用于评估外显子28的突变。确定VWF的三级结构有助于了解其功能残基和相互作用。利用有效的生物信息学方法研究了nssnv的致病性。使用SIFT、polyphen2、I-Mutant 2.0、PHD-SNPg和SNPs&GO逐步检测高危突变。然后通过Protparam、Cofactor、Interprosurf、ConSurf、NetSurfP-2.0和HOPE等软件对其二级结构、氨基酸保守性和氨基酸特征进行了研究。结果:在VWF中检测到N1231T、V1229G、V1316M、P1266Q错义突变。VWF三维结构预测与评价。确定了假定的保守结构域。预测P1266Q和V1316M氨基酸取代为“不耐受取代”损害和疾病，预测V1229G和N1231T氨基酸取代为“耐受取代”良性和中性。结论:利用强大的生物信息学工具确定V1316M和P1266Q氨基酸替换为VWD患者的高危突变。

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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International Journal of Medical Laboratory

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