K84s和K102s多肽与α-突触核蛋白相互作用位点的研究及其抗聚集机制

V. S. Mattaparthi, P. Borah
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Using the PatchDock web server, the two peptides were docked to the α-Synuclein molecule. After that, 50 ns of Molecular Dynamics (MD) simulations using the Amberff99SBildn force field were performed on the two resulting docked complexes. The two complexes' structure, dynamics, energy profiles, and binding modes were identified through analysis of the respective MD simulation trajectories. By submitting the two complexes' lowest energy structure to the PDBsum website, the interface residues in the two complexes were identified. The per residue energy decomposition (PRED) analysis using the MM-GBSA technique was used to calculate the contributions of each residue in the α-Synuclein of (α-Synuclein-K84s/K102s) complexes to the total binding free energy.\n\n\n\n\nThe binding of the two peptides with the α-Synuclein was demonstrated to have high binding free energy. 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The PRED analysis revealed that the residues PHE 1, LEU 7, ILE 12, LEU 2, VAL 3, GLY 5, and PRO 21 of the K84s peptide and residues VAL 48, ALA 29, VAL 40, TYR 39, VAL 49, VAL 26 and GLY 36 of α-Synuclein in the (α-Synuclein-K84s) complex are responsible for the intermolecular interaction. The residues ARG 4, ARG 10, TRP 11, ALA 14, SER 15, CYS 16 and SER 19 of the K102s peptide and residues GLU 46, LYS 45, VAL 49, GLU 35, VAL 48, TYR 39, and VAL 40 of α-Synuclein are responsible for the intermolecular interaction in the instance of the (α-Synuclein-K102s) complex. 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引用次数: 0

摘要

自从20年前α-Synuclein与帕金森病风险的遗传关联以及聚集性α-Synuclein作为Lewy病理的主要蛋白成分被发现以来,α-Synuclein已成为帕金森病及相关突触核蛋白病的主要治疗靶点。两种新肽K84s (FLVWGCLRGSAIGECVVHGGPPSRH)和K102s (FLKRWARSTRWGTASCGGS)最近被发现可以显著降低α-Synuclein的寡聚和聚集。然而,目前尚不清楚这些肽在哪里与α-Synuclein相互作用。研究K84s和K102s与α-Synuclein相互作用的位置。在本研究中,使用PEPFOLD3服务器生成K84s和K102s肽的三维结构。利用PatchDock web服务器,将这两个肽对接到α-Synuclein分子上。然后,利用Amberff99SBildn力场对两种对接物进行了50 ns的分子动力学(MD)模拟。通过MD模拟轨迹分析,确定了两种配合物的结构、动力学、能量分布和结合模式。通过将这两个配合物的最低能结构提交到PDBsum网站,确定了这两个配合物的界面残基。采用MM-GBSA技术进行单残基能量分解(PRED)分析,计算(α-Synuclein- k84s /K102s)配合物中α-Synuclein各残基对总结合自由能的贡献。结果表明,这两种多肽与α-Synuclein的结合具有较高的结合自由能。配合物(α-Synuclein-K84s)和(α-Synuclein-K102s)的结合自由能分别为-33.61 kcal/mol和-40.88 kcal/mol。通过PDBsum服务器分析,在(α-Synuclein-K84s)络合物中,鉴定出残基GLY 25、ALA 29、VAL 49、LEU 38、VAL 40、GLU 28、GLY 47、LYS 32、GLU 35、GLY 36、TYR 39、VAL 48和VAL 26(来自α-Synuclein)和SER 23、LEU 7、ILE 12、HIS 25、PHE 1、HIS 18、CYS 6、ARG 24、PRO 21和ARG 8(来自K84s肽)存在于界面上。在(α-Synuclein-K102s)配合物中,鉴定出残基VAL 40、GLY 36、GLU 35、TYR 39、LYS 45、LEU 38、LYS 43、VAL 37、THR 44、VAL 49、VAL 48和GLU 46(来自α-Synuclein)以及ARG 10、GLY 12、GLY 18、SER 15、THR 13、SER 19、TRP 11、ALA 14、CYS 16、ARG 7、ARG 4和GLY 17(来自K102s肽)存在于界面上。PRED分析表明,K84s肽的PHE 1、LEU 7、LEU 12、LEU 2、VAL 3、GLY 5和PRO 21残基以及(α-Synuclein-K84s)复合物中α-Synuclein的VAL 48、ALA 29、VAL 40、TYR 39、VAL 49、VAL 26和GLY 36残基参与了分子间相互作用。K102s肽的arg4、arg10、TRP 11、ALA 14、SER 15、CYS 16和SER 19残基以及α-Synuclein的GLU 46、LYS 45、VAL 49、GLU 35、VAL 48、tyr39和VAL 40残基参与了(α-Synuclein-K102s)复合物的分子间相互作用。此外,当α-Synuclein与K84s和K102s肽形成复合物时,相当一部分螺旋结构得以保留。综上所述,这些数据表明,本文研究的两种新肽可能是未来治疗α-突触核蛋白聚集的合适候选物。
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Investigation into the Interaction Sites of the K84s and K102s Peptides with α-Synuclein for Understanding the Anti-Aggregation Mechanism: an in silico study
α-Synuclein has become the main therapeutic target in Parkinson's disease and related Synucleinopathies since the discovery of genetic associations between α-Synuclein and Parkinson's disease risk and the identification of aggregated α-Synuclein as the primary protein constituent of Lewy pathology two decades ago. The two new peptides K84s (FLVWGCLRGSAIGECVVHGGPPSRH) and K102s (FLKRWARSTRWGTASCGGS) have recently been found to significantly reduce the oligomerization and aggregation of α-Synuclein. However, it is still unclear where these peptides interact with α-Synuclein at the moment. To examine the locations where K84s and K102s interact with α-Synuclein. In this investigation, the PEPFOLD3 server was used to generate the 3-D structures of the K84s and K102s peptides. Using the PatchDock web server, the two peptides were docked to the α-Synuclein molecule. After that, 50 ns of Molecular Dynamics (MD) simulations using the Amberff99SBildn force field were performed on the two resulting docked complexes. The two complexes' structure, dynamics, energy profiles, and binding modes were identified through analysis of the respective MD simulation trajectories. By submitting the two complexes' lowest energy structure to the PDBsum website, the interface residues in the two complexes were identified. The per residue energy decomposition (PRED) analysis using the MM-GBSA technique was used to calculate the contributions of each residue in the α-Synuclein of (α-Synuclein-K84s/K102s) complexes to the total binding free energy. The binding of the two peptides with the α-Synuclein was demonstrated to have high binding free energy. The binding free energies of the (α-Synuclein-K84s) and (α-Synuclein-K102s) complexes are -33.61 kcal/mol and -40.88 kcal/mol respectively. Using PDBsum server analysis, it was determined that in the (α-Synuclein-K84s) complex, the residues GLY 25, ALA 29, VAL 49, LEU 38, VAL 40, GLU 28, GLY 47, LYS 32, GLU 35, GLY 36, TYR 39, VAL 48 and VAL 26 (from α-Synuclein) and SER 23, LEU 7, ILE 12, HIS 25, PHE 1, HIS 18, CYS 6, ARG 24, PRO 21 and ARG 8 (from K84s peptide) were identified to be present at the interface. In the (α-Synuclein-K102s) complex, the residues VAL 40, GLY 36, GLU 35, TYR 39, LYS 45, LEU 38, LYS 43, VAL 37, THR 44, VAL 49, VAL 48, and GLU 46 (from α-Synuclein) and ARG 10, GLY 12, GLY 18, SER 15, THR 13, SER 19, TRP 11, ALA 14, CYS 16, ARG 7, ARG 4 and GLY 17 (from K102s peptide) were identified to be present at the interface. The PRED analysis revealed that the residues PHE 1, LEU 7, ILE 12, LEU 2, VAL 3, GLY 5, and PRO 21 of the K84s peptide and residues VAL 48, ALA 29, VAL 40, TYR 39, VAL 49, VAL 26 and GLY 36 of α-Synuclein in the (α-Synuclein-K84s) complex are responsible for the intermolecular interaction. The residues ARG 4, ARG 10, TRP 11, ALA 14, SER 15, CYS 16 and SER 19 of the K102s peptide and residues GLU 46, LYS 45, VAL 49, GLU 35, VAL 48, TYR 39, and VAL 40 of α-Synuclein are responsible for the intermolecular interaction in the instance of the (α-Synuclein-K102s) complex. Additionally, it has been found that a sizable portion of the helical structure is preserved when α-Synuclein is in a complex form with the K84s and K102s peptides. Taken together the data implies that the two new peptides investigated here could be suitable candidates for future therapeutic development against α-Synuclein aggregation.
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