Polverini Eugenia, Coll Eoin P, Tieleman D Peter, Harauz George
Dipartimento di Fisica, Università di Parma, V. le Usberti, 7/A, 43100 Parma, Italy.
Biochim Biophys Acta. 2011 Mar;1808(3):674-83. doi: 10.1016/j.bbamem.2010.11.030. Epub 2010 Dec 3.
The 18.5 kDa isoform of myelin basic protein is essential to maintaining the close apposition of myelin membranes in central nervous system myelin, but its intrinsic disorder (conformational dependence on environment), a variety of post-translational modifications, and a diversity of protein ligands (e.g., actin and tubulin) all indicate it to be multifunctional. We have performed molecular dynamics simulations of a conserved central segment of 18.5 kDa myelin basic protein (residues Glu80-Gly103, murine sequence numbering) in aqueous and membrane-associated environments to ascertain the stability of constituent secondary structure elements (α-helix from Glu80-Val91 and extended poly-proline type II from Thr92-Gly103) and the effects of phosphorylation of residues Thr92 and Thr95, individually and together. In aqueous solution, all four forms of the peptide bent in the middle to form a hydrophobic cluster. The phosphorylated variants were stabilized further by electrostatic interactions and formation of β-structures, in agreement with previous spectroscopic data. In simulations performed with the peptide in association with a dimyristoylphosphatidylcholine bilayer, the amphipathic α-helical segment remained stable and membrane-associated, although the degree of penetration was less in the phosphorylated variants, and the tilt of the α-helix with respect to the plane of the membrane also changed significantly with the modifications. The extended segment adjacent to this α-helix represents a putative SH3-ligand and remained exposed to the cytoplasm (and thus accessible to binding partners). The results of these simulations demonstrate how this segment of the protein can act as a molecular switch: an amphipathic α-helical segment of the protein is membrane-associated and presents a subsequent proline-rich segment to the cytoplasm for interaction with other proteins. Phosphorylation of threonyl residues alters the degree of membrane penetration of the α-helix and the accessibility of the proline-rich ligand and can stabilize a β-bend. A bend in this region of 18.5 kDa myelin basic protein suggests that the N- and C-termini of the proteins can interact with different leaflets of the myelin membrane and explain how a single protein can bring them close together.
髓鞘碱性蛋白的18.5 kDa异构体对于维持中枢神经系统髓鞘中髓鞘膜的紧密并置至关重要,但其内在无序性(构象对环境的依赖性)、多种翻译后修饰以及多种蛋白质配体(如肌动蛋白和微管蛋白)均表明它具有多种功能。我们对18.5 kDa髓鞘碱性蛋白的一个保守中央片段(残基Glu80 - Gly103,小鼠序列编号)在水性和膜相关环境中进行了分子动力学模拟,以确定组成二级结构元件(Glu80 - Val91的α - 螺旋和Thr92 - Gly103的延伸聚脯氨酸II型)的稳定性以及Thr92和Thr95残基单独和一起磷酸化的影响。在水溶液中,肽的所有四种形式在中间弯曲形成疏水簇。与先前的光谱数据一致,磷酸化变体通过静电相互作用和β - 结构的形成进一步稳定。在用该肽与二肉豆蔻酰磷脂酰胆碱双层结合进行的模拟中,两亲性α - 螺旋片段保持稳定并与膜相关,尽管磷酸化变体中的穿透程度较小,并且α - 螺旋相对于膜平面的倾斜也随着修饰而显著变化。与该α - 螺旋相邻的延伸片段代表一个假定的SH3配体,并保持暴露于细胞质(因此可与结合伴侣接触)。这些模拟结果表明该蛋白质片段如何作为分子开关起作用:蛋白质的两亲性α - 螺旋片段与膜相关,并向细胞质呈现随后富含脯氨酸的片段以与其他蛋白质相互作用。苏氨酰残基的磷酸化改变了α - 螺旋的膜穿透程度和富含脯氨酸配体的可及性,并可稳定β - 弯曲。18.5 kDa髓鞘碱性蛋白该区域的弯曲表明蛋白质的N端和C端可与髓鞘膜的不同小叶相互作用,并解释了单个蛋白质如何使它们紧密靠近。
