Gomal Center of Biochemistry and Biotechnology, Gomal University, Dera Ismail Khan 29111, Pakistan.
Basic Sciences Department, College of Applied Medical Sciences, King Saud Bin Abdulaziz University for Health Sciences, Al Ahsa 31982, Saudi Arabia.
Genes (Basel). 2022 Apr 11;13(4):672. doi: 10.3390/genes13040672.
Human DNA contains several variations, which can affect the structure and normal functioning of a protein. These variations could be single nucleotide polymorphisms (SNPs) or insertion-deletions (InDels). SNPs, as opposed to InDels, are more commonly present in DNA and may cause genetic disorders. In the current study, several bioinformatic tools were used to prioritize the pathogenic variants in the SLITRK1 gene. Out of all of the variants, 16 were commonly predicted to be pathogenic by these tools. All the variants had very low frequency, i.e., <0.0001 in the global population. The secondary structure of all filtered variants was predicted, but no structural change was observed at the site of variation in any variant. Protein stability analysis of these variants was then performed, which determined a decrease in protein stability of 10 of the variants. Amino acid conservation analysis revealed that all the amino acids were highly conserved, indicating their structural and functional importance. Protein 3D structure of wildtype SLITRK1 and all of its variants was predicted using I-TASSER, and the effect of variation on 3D structure of the protein was observed using the Missense3D tool, which presented the probable structural loss in three variants, i.e., Asn529Lys, Leu496Pro and Leu94Phe. The wildtype SLITRK1 protein and these three variants were independently docked with their close interactor protein PTPRD, and remarkable differences were observed in the docking sites of normal and variants, which will ultimately affect the functional activity of the SLITRK1 protein. Previous studies have shown that mutations in SLITRK1 are involved in Tourette syndrome. The present study may assist a molecular geneticist in interpreting the variant pathogenicity in research as well as diagnostic setup.
人类 DNA 含有多种变异,这些变异可能影响蛋白质的结构和正常功能。这些变异可能是单核苷酸多态性(SNPs)或插入缺失(InDels)。与 InDels 相比,SNP 在 DNA 中更为常见,并且可能导致遗传疾病。在当前的研究中,使用了几种生物信息学工具来优先考虑 SLITRK1 基因中的致病变异。在所有的变异中,有 16 个被这些工具普遍预测为致病性的。所有的变异都具有非常低的频率,即在全球人群中<0.0001。对所有过滤后的变异进行了二级结构预测,但在任何变异位点都没有观察到结构变化。然后对这些变异进行了蛋白质稳定性分析,结果表明 10 个变异的蛋白质稳定性降低。对这些变异进行的氨基酸保守性分析表明,所有的氨基酸都高度保守,这表明它们的结构和功能的重要性。使用 I-TASSER 预测了野生型 SLITRK1 及其所有变体的蛋白质 3D 结构,并使用 Missense3D 工具观察了变异对蛋白质 3D 结构的影响,该工具显示了三个变体,即 Asn529Lys、Leu496Pro 和 Leu94Phe,可能存在结构丢失。野生型 SLITRK1 蛋白及其三个变体分别与它们的紧密相互作用蛋白 PTPRD 进行独立对接,在正常和变体的对接位点观察到显著差异,这最终将影响 SLITRK1 蛋白的功能活性。先前的研究表明,SLITRK1 突变与图雷特综合征有关。本研究可以帮助分子遗传学家在研究和诊断设置中解释变异的致病性。
