School of Biosciences and Technology, Vellore Institute of Technology, Vellore, India.
Department of Biomedical Sciences, College of Health Sciences, Qatar University, Doha, Qatar.
J Cell Biochem. 2018 Sep;119(9):7585-7598. doi: 10.1002/jcb.27097. Epub 2018 Jun 12.
Galactosemia type 2 is an autosomal recessive disorder characterized by the deficiency of galactokinase (GALK) enzyme due to missense mutations in GALK1 gene, which is associated with various manifestations such as hyper galactosemia and formation of cataracts. GALK enzyme catalyzes the adenosine triphosphate (ATP)-dependent phosphorylation of α-d-galactose to galactose-1-phosphate. We searched 4 different literature databases (Google Scholar, PubMed, PubMed Central, and Science Direct) and 3 gene-variant databases (Online Mendelian Inheritance in Man, Human Gene Mutation Database, and UniProt) to collect all the reported missense mutations associated with GALK deficiency. Our search strategy yielded 32 missense mutations. We used several computational tools (pathogenicity and stability, biophysical characterization, and physiochemical analyses) to prioritize the most significant mutations for further analyses. On the basis of the pathogenicity and stability predictions, 3 mutations (P28T, A198V, and L139P) were chosen to be tested further for physicochemical characterization, molecular docking, and simulation analyses. Molecular docking analysis revealed a decrease in interaction between the protein and ATP in all the 3 mutations, and molecular dynamic simulations of 50 ns showed a loss of stability and compactness in the mutant proteins. As the next step, comparative physicochemical changes of the native and the mutant proteins were carried out using essential dynamics. Overall, P28T and A198V were predicted to alter the structure and function of GALK protein when compared to the mutant L139P. This study demonstrates the power of computational analysis in variant classification and interpretation and provides a platform for developing targeted therapeutics.
半乳糖血症 2 型是一种常染色体隐性疾病,其特征是由于 GALK1 基因中的错义突变导致半乳糖激酶(GALK)酶缺乏,与高半乳糖血症和白内障形成等多种表现相关。GALK 酶催化三磷酸腺苷(ATP)依赖性磷酸化α-d-半乳糖为半乳糖-1-磷酸。我们搜索了 4 个不同的文献数据库(Google Scholar、PubMed、PubMed Central 和 Science Direct)和 3 个基因变异数据库(在线孟德尔遗传数据库、人类基因突变数据库和 UniProt),以收集与 GALK 缺乏相关的所有报道的错义突变。我们的搜索策略产生了 32 个错义突变。我们使用了几种计算工具(致病性和稳定性、生物物理特性和物理化学分析)来优先考虑最重要的突变进行进一步分析。根据致病性和稳定性预测,选择了 3 个突变(P28T、A198V 和 L139P)进行进一步的物理化学特性、分子对接和模拟分析测试。分子对接分析显示,所有 3 个突变均导致蛋白质与 ATP 的相互作用减少,50ns 的分子动力学模拟显示突变蛋白的稳定性和紧凑性丧失。下一步,使用基本动力学对天然和突变蛋白进行了比较物理化学变化。总体而言,与突变体 L139P 相比,P28T 和 A198V 被预测会改变 GALK 蛋白的结构和功能。本研究证明了计算分析在变异分类和解释中的强大功能,并为开发靶向治疗提供了一个平台。
