Identification of Pathogenic Missense Mutations of NF1 Using Computational Approaches

IF 2.8 4区 医学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Jie Chen, Ziqiao Li, Yiheng Wu, Xiang Li, Zipei Chen, Pan Chen, Yuhan Ding, Chengpeng Wu, Lidan Hu
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Abstract

Neurofibromatosis type 1 (NF1) is a prevalent autosomal dominant disorder caused by mutations in the NF1 gene, leading to multisystem disorders. Given the critical role of cysteine residues in protein stability and function, we aimed to identify key NF1 mutations affecting cysteine residues that significantly contribute to neurofibromatosis pathology. To identify the most critical mutations in the NF1 gene that contribute to the pathology of neurofibromatosis, we employed a sophisticated computational pipeline specifically designed to detect significant mutations affecting the NF1 gene. Our approach involved an exhaustive search of databases such as the Human Gene Mutation Database (HGMD), UniProt, and ClinVar for information on missense mutations associated with NF1. Our search yielded a total of 204 unique cysteine missense mutations. We then employed in silico prediction tools, including PredictSNP, iStable, and Align GVGD, to assess the impact of these mutations. Among the mutations, C379R, R1000C, and C1016Y stood out due to their deleterious effects on the biophysical properties of the neurofibromin protein, significantly destabilizing its structure. These mutations were subjected to further phenotyping analysis using SNPeffect 4.0, which predicted disturbances in the protein’s chaperone binding sites and overall structural stability. Furthermore, to directly visualize the impact of these mutations on protein structure, we utilized AlphaFold3 to simulate both the wild-type and mutant NF1 structures, revealing the significant effects of the R1000C mutation on the protein’s conformation. In conclusion, the identification of these mutations can play a pivotal role in advancing the field of precision medicine and aid in the development of effective drugs for associated diseases.

利用计算方法鉴定 NF1 的致病性错义突变
神经纤维瘤病 1 型(NF1)是一种常见的常染色体显性遗传疾病,由 NF1 基因突变引起,可导致多系统疾病。鉴于半胱氨酸残基在蛋白质稳定性和功能中的关键作用,我们的目标是找出影响半胱氨酸残基并对神经纤维瘤病病理起重要作用的关键 NF1 基因突变。为了确定NF1基因中导致神经纤维瘤病病理的最关键突变,我们采用了一种复杂的计算管道,专门用于检测影响NF1基因的重大突变。我们的方法包括对人类基因突变数据库(HGMD)、UniProt 和 ClinVar 等数据库进行详尽搜索,以获取与 NF1 相关的错义突变信息。我们的搜索共获得了 204 个独特的半胱氨酸错义突变。然后,我们采用了包括 PredictSNP、iStable 和 Align GVGD 在内的硅预测工具来评估这些突变的影响。在这些突变中,C379R、R1000C 和 C1016Y 因其对神经纤维瘤蛋白生物物理特性的有害影响而脱颖而出,大大破坏了其结构的稳定性。利用 SNPeffect 4.0 对这些突变进行了进一步的表型分析,预测了蛋白质伴侣结合位点和整体结构稳定性的紊乱。此外,为了直接观察这些突变对蛋白质结构的影响,我们利用 AlphaFold3 模拟了野生型和突变型 NF1 的结构,结果显示 R1000C 突变对蛋白质的构象有显著影响。总之,这些突变的鉴定可在推动精准医学领域的发展方面发挥关键作用,并有助于开发治疗相关疾病的有效药物。
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来源期刊
Journal of Molecular Neuroscience
Journal of Molecular Neuroscience 医学-神经科学
CiteScore
6.60
自引率
3.20%
发文量
142
审稿时长
1 months
期刊介绍: The Journal of Molecular Neuroscience is committed to the rapid publication of original findings that increase our understanding of the molecular structure, function, and development of the nervous system. The criteria for acceptance of manuscripts will be scientific excellence, originality, and relevance to the field of molecular neuroscience. Manuscripts with clinical relevance are especially encouraged since the journal seeks to provide a means for accelerating the progression of basic research findings toward clinical utilization. All experiments described in the Journal of Molecular Neuroscience that involve the use of animal or human subjects must have been approved by the appropriate institutional review committee and conform to accepted ethical standards.
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