Department of Biochemistry, University of Illinois at Urbana-Champaign, Urbana, IL, USA.
Biophys J. 2013 Aug 20;105(4):993-1003. doi: 10.1016/j.bpj.2013.06.047.
During the fusion of the influenza virus to the host cell, bending of the HA2 chain of hemagglutinin into a hairpin-shaped structure in a pH-dependent manner facilitates the fusion of the viral envelope and the endosomal membrane. To characterize the structural and dynamical responses of the hinge region of HA2 to pH changes and examine the role of a conserved histidine in this region (the hinge histidine), we have performed an extensive set of molecular dynamics (MD) simulations of 26-residue peptides encompassing the hinge regions of several hemagglutinin subtypes under both neutral and low pH conditions, modeled by the change of the protonation state of the hinge histidine. More than 70 sets of MD simulations (collectively amounting to 25.1 μs) were performed in both implicit and explicit solvents to study the effect of histidine protonation on structural dynamics of the hinge region. In both explicit and implicit solvent simulations, hinge bending was consistently observed upon the protonation of the histidine in all the simulations starting with an initial straight helical conformation, whereas the systems with a neutral histidine retained their primarily straight conformation throughout the simulations. Conversely, the MD simulations starting from an initially bent conformation resulted in the formation of a straight helical structure upon the neutralization of the hinge histidine, whereas the bent structure was maintained when the hinge histidine remained protonated. Finally, mutation of the hinge histidine to alanine abolishes the bending response of the peptide altogether. A molecular mechanism based on the interaction of the hinge histidine with neighboring acidic residues is proposed to be responsible for its role in controlling the conformation of the hinge. We propose that this might present a common mechanism for pH-controlled structural changes in helical structures when histidines act as the pH sensor.
在流感病毒与宿主细胞融合的过程中,血凝素(HA)的 HA2 链在 pH 依赖性的方式下发生弯曲,形成发夹状结构,从而促进病毒包膜和内体膜的融合。为了描述 HA2 铰链区域对 pH 变化的结构和动力学响应,并研究该区域中一个保守组氨酸(铰链组氨酸)的作用,我们对几种血凝素亚型的铰链区域进行了广泛的分子动力学(MD)模拟,这些模拟涵盖了 26 个残基的肽,在中性和低 pH 条件下,通过改变铰链组氨酸的质子化状态来模拟。在两种溶剂(包括隐式溶剂和显式溶剂)中进行了超过 70 组 MD 模拟(总共 25.1 μs),以研究组氨酸质子化对铰链区域结构动力学的影响。在显式和隐式溶剂模拟中,在所有模拟中,当铰链组氨酸质子化时,铰链弯曲都被一致观察到,所有模拟都从初始的直螺旋构象开始,而带有中性组氨酸的系统在整个模拟过程中都保持其主要的直构象。相反,从初始弯曲构象开始的 MD 模拟在铰链组氨酸中和时导致形成直螺旋结构,而当铰链组氨酸保持质子化时,弯曲结构得以维持。最后,将铰链组氨酸突变为丙氨酸会完全消除肽的弯曲响应。提出了一种基于铰链组氨酸与相邻酸性残基相互作用的分子机制,认为其负责控制铰链构象。我们提出,当组氨酸作为 pH 传感器时,这可能是螺旋结构中 pH 控制的结构变化的一种常见机制。