Mutation in MCL1 predicted loop to helix structural transition stabilizes MCL1–Bax binding interaction favoring cancer cell survival

D. Es, Beutline Malgija, Appadurai Muthamil Iniyan, S. Vincent
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Abstract

Myeloid cell leukemia‐1 (MCL1), an anti‐apoptotic BCL‐2 family protein plays a major role in the control of apoptosis as the regulator of mitochondrial permeability which is deregulated in various solid and hematological malignancies. Interaction of the executioner proteins Bak/Bax with anti‐apoptotic MCL1 and its cellular composition determines the apoptotic or survival pathway. Mutations act at various levels in the apoptotic process and can contribute to disease. Single nucleotide polymorphism (SNP) in MCL1 gene was focused as they result in changes in the amino acid sequence and have been associated with tumorigenesis. This study highlighted the deleterious MCL1‐Bax stabilizing effect of the mutation V220F on MCL1 structure through computational protein–protein interaction predictions and molecular dynamics simulations. The single point mutation at V220F was selected as it is residing at the hydrophobic core region of BH3 conserved domain, the site of Bax binding. The molecular dynamics simulation studies showed increase in stability of the mutated MCL1 before and after Bax binding comparable with the native MCL1. The clusters from free energy landscape found out structural variation in folding pattern with additional helix near the BH3 domain in the mutated structure. This loop to helix structural change in the mutated complex favored stable interaction of the complex and also induced Bax conformational change. Moreover, molecular mechanics‐based binding free energy calculations confirmed increased affinity of Bax toward mutated MCL1. Residue‐wise interaction network analysis showed the individual residues in Bax binding responsible for the change in stability and interaction due to the protein mutation. In conclusion, the overall findings from the study reveal that the presence of V220F mutation on MCL1 is responsible for the structural confirmational change leading to disruption of its biological functions which might be responsible for tumorigenesis. The mutation could possibly be used as future diagnostic markers in treating cancers.
MCL1突变预测环向螺旋结构转变,稳定MCL1 - bax结合相互作用,有利于癌细胞存活
髓系细胞白血病- 1 (MCL1)是一种抗凋亡的BCL - 2家族蛋白,作为线粒体通透性的调节因子,在多种实体和血液恶性肿瘤中发挥着重要的细胞凋亡控制作用。刽子手蛋白Bak/Bax与抗凋亡的MCL1及其细胞组成的相互作用决定了凋亡或存活途径。突变在细胞凋亡过程中起着不同程度的作用,并可能导致疾病。MCL1基因的单核苷酸多态性(SNP)引起了氨基酸序列的改变,并与肿瘤的发生有关。本研究通过计算蛋白-蛋白相互作用预测和分子动力学模拟强调了突变V220F对MCL1结构的有害MCL1‐Bax稳定作用。选择V220F的单点突变,是因为它位于BH3保守结构域的疏水核心区,即Bax结合位点。分子动力学模拟研究表明,与原生MCL1相比,突变MCL1在与Bax结合前后的稳定性有所提高。从自由能景观中发现,在突变结构中,BH3结构域附近有额外的螺旋,折叠模式发生了变化。这种环向螺旋结构的变化有利于复合物的稳定相互作用,也引起了Bax构象的变化。此外,基于分子力学的结合自由能计算证实了Bax对突变MCL1的亲和力增加。残基相互作用网络分析表明,由于蛋白质突变,Bax结合中的单个残基导致了稳定性和相互作用的变化。综上所述,本研究的总体结果表明,MCL1上V220F突变的存在导致了结构确认性改变,导致其生物学功能的破坏,这可能是肿瘤发生的原因。这种突变可能被用作未来治疗癌症的诊断标记。
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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