与GENEMDM 2相关的人类疾病基因组变异的计算检测、分析和解释

M. Baksh, Farkhanda Yasmin, Majeeda Rasheed, Waqas, Farooq, M. S. Iqbal, U. Ashfaq
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摘要

在人类MDM2中描述的大多数突变都是耐受的,而不会显著破坏相应的结构或分子功能。然而,其中一些与包括癌症在内的各种人类疾病有关。许多计算方法已经发展到预测错义单核苷酸变异(snv)的影响。非同义单核苷酸多态性影响XRCC1的功能,从而损害修复DNA的能力,从而增加癌症等疾病的风险。本研究使用基于序列和结构的计算工具筛选MDM2基因的编码snp,以识别和描述它们。利用计算工具PolyPhen 2、SIFT、PANTHER和cSNP进行一致性分析,从29 ns SNP中鉴定出MDM2潜在的6 ns SNP。计算方法用于系统地分类调节区和编码区改变MDM2酶的表达和功能的功能突变。HOPE项目还使阐明氨基酸取代的结构效应成为可能。硅分析预测rs759244097是有害的。这项研究的结论是,识别这种SNP将有助于确定个体的癌症易感性、预后和进一步的治疗。此外,目前的高通量测序工作和对蛋白质序列变异的广泛解释需要在未来几年更有效和准确的计算方法。
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Computational detection, analysis and interpretations of genomic variants in human diseases associated GENEMDM 2
Most of the mutations described in human MDM2 are tolerated without significantly disrupting the corresponding structural or molecular function. However, some of them are associated with a variety of human diseases, including cancer. Numerous computational methods have been developed to predict the effects of missense single nucleotide variants (SNVs). The non-synonymous single nucleotide polymorphisms affect the function of XRCC1, which impairs the ability to repair DNA and therefore increases the risk of diseases such as cancer. In this study, sequence and structure-based computational tools were used to screen the total listed coding SNPs of the MDM2 gene in order to recognize and describe them. The potential 6 ns SNP of MDM2 were identified from 29 ns SNP by consistent analysis using computational tools PolyPhen 2, SIFT, PANTHER and cSNP. The computational methods were used to systematically classify functional mutations in the regulatory and coding regions that modify the expression and function of the MDM2 enzyme. The HOPE project also made it possible to elaborate the structural effects of the substitutions of amino acids. In silico analysis predicted that rs759244097 is harmful. This study concluded that identifying this SNP will help to determine an individual's cancer susceptibility, prognosis and further treatment. Furthermore, current high-throughput sequencing efforts and the need for extensive interpretation of protein sequence variants requires more efficient and accurate computational methods in the coming years.
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