Aakanksha Singh, Bidisha Acharya, Beas Mukherjee, Veda Sheersh Boorla , Soumendu Boral , Snigdha Maiti , Soumya De
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Also, NMR dynamics and MD simulation show that dynamic motions present in the wild-type protein are quenched in the mutant. This in turn resulted in increased stability of the entire homeodomain (ΔΔG<sub>G→A</sub> of −2.6 kcal/mol). Increased protein stability resulted in three-fold better DNA-binding affinity of the mutant as compared to the wild-type protein. Molecular mechanics with generalized Born and surface area solvation (MMGBSA) analysis of our MD simulation on DNA-bound models of both wild-type and mutant proteins shows that the contribution to binding is enhanced for most of the interface residues in the mutant compared to the wild-type. Interestingly, the flexible N-terminal arm makes more stable contact with the DNA minor groove in the mutant. We found that the two interaction sites i.e. the DNA-binding helix and the unstructured N-terminal arm influence each other via the bound DNA. These results provide an interesting conundrum: alanine at position 290 enhances both the stability and the DNA-binding affinity of the protein, however, evolution prefers glycine at this position. We have provided several plausible explanations for this apparent conundrum. 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引用次数: 0
摘要
Extradenticle(EXD)是HOX转录因子的伙伴蛋白,在果蝇的发育过程中发挥着重要作用。它增加了与 HOX 蛋白的 DNA 结合亲和力和特异性。然而,与 HOX 同源域相比,EXD 的 DNA 结合同源域对 DNA 的亲和力要弱得多。在这里,我们发现 EXD DNA 结合螺旋中间的甘氨酸残基(G290)是导致这种较弱结合力的主要原因。甘氨酸会破坏螺旋的稳定性。为了探究其在蛋白质稳定性和功能中的作用,G290 被突变为丙氨酸。通过核磁共振研究和分子动力学(MD)模拟观察到,G290A 突变体中 DNA 结合螺旋的内在稳定性增加了。核磁共振动力学和分子动力学模拟还表明,野生型蛋白质中的动态运动在突变体中被淬灭。这反过来又增加了整个同源结构域的稳定性(ΔΔGG→A 为-2.6 kcal/mol)。蛋白质稳定性的提高使突变体的 DNA 结合亲和力比野生型蛋白质高出三倍。我们对野生型和突变体蛋白质的 DNA 结合模型进行了分子力学与广义玻恩和表面积溶解(MMGBSA)模拟分析,结果表明,与野生型相比,突变体中大部分界面残基对结合的贡献率都有所提高。有趣的是,在突变体中,灵活的 N 端臂与 DNA 小沟的接触更加稳定。我们发现,DNA 结合螺旋和非结构化 N 端臂这两个相互作用位点通过结合 DNA 相互影响。这些结果提供了一个有趣的难题:位于 290 位的丙氨酸能增强蛋白质的稳定性和 DNA 结合亲和力,但进化却偏好位于该位置的甘氨酸。我们为这一明显的难题提供了几种似是而非的解释。EXD作为HOX辅助因子的功能要求其具有分辨相似DNA序列的能力,而这很有可能会影响EXD的功能。
Stability and dynamics of extradenticle modulates its function
Extradenticle (EXD) is a partner protein of the HOX transcription factors and plays an important role in the development of Drosophila. It confers increased affinity and specificity of DNA-binding to the HOX proteins. However, the DNA-binding homeodomain of EXD has a significantly weaker affinity to DNA compared to the HOX homeodomains. Here, we show that a glycine residue (G290) in the middle of the EXD DNA-binding helix primarily results in this weaker binding. Glycine destabilizes helices. To probe its role in the stability and function of the protein, G290 was mutated to alanine. The intrinsic stability of the DNA-binding helix increased in the G290A mutant as observed by NMR studies and molecular dynamics (MD) simulation. Also, NMR dynamics and MD simulation show that dynamic motions present in the wild-type protein are quenched in the mutant. This in turn resulted in increased stability of the entire homeodomain (ΔΔGG→A of −2.6 kcal/mol). Increased protein stability resulted in three-fold better DNA-binding affinity of the mutant as compared to the wild-type protein. Molecular mechanics with generalized Born and surface area solvation (MMGBSA) analysis of our MD simulation on DNA-bound models of both wild-type and mutant proteins shows that the contribution to binding is enhanced for most of the interface residues in the mutant compared to the wild-type. Interestingly, the flexible N-terminal arm makes more stable contact with the DNA minor groove in the mutant. We found that the two interaction sites i.e. the DNA-binding helix and the unstructured N-terminal arm influence each other via the bound DNA. These results provide an interesting conundrum: alanine at position 290 enhances both the stability and the DNA-binding affinity of the protein, however, evolution prefers glycine at this position. We have provided several plausible explanations for this apparent conundrum. The function of the EXD as a HOX co-factor requires its ability to discriminate similar DNA sequences, which is most likely comprom
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