Kedrov Alexej, Wegmann Susanne, Smits Sander H J, Goswami Panchali, Baumann Hella, Muller Daniel J
Center of Biotechnology, TU Dresden, Dresden, Germany.
J Struct Biol. 2007 Aug;159(2):290-301. doi: 10.1016/j.jsb.2007.02.010. Epub 2007 Mar 12.
Integral membrane proteins are involved in virtually every cellular process. Precisely regulating these machineries would allow controlling many human and vertebrate diseases. Embedded into cellular membranes, membrane proteins establish molecular interactions that sensitively react to environmental changes and to molecular compounds, such as ligands or inhibitors. We applied atomic force microscopy (AFM) to image the Na(+)/H(+) antiporter MjNhaP1 from Methanococcus jannaschii, and single-molecule force spectroscopy (SMFS) to probe molecular interactions that drive the protein structure-function relationship. High-resolution AFM topographs showed the dimeric assembly of MjNhaP1 being reconstituted into a lipid bilayer. SMFS of MjNhaP1 unraveled molecular interactions stabilizing individual structural domains. Transmembrane domains exhibited certain probabilities to unfold individually or cooperatively with other domains resulting in different unfolding pathways. Helices VIII and X established pH sensitive interactions altering significantly upon MjNhaP1 activation, while removal of the ligand (Na(+)) destabilized the entire antiporter except helix VIII. It is assumed that Asp234/235 of helix VIII are involved in the ligand-binding site and that helix X plays a functional role in the activation of the transporter.
整合膜蛋白几乎参与了每一个细胞过程。精确调控这些机制将有助于控制许多人类和脊椎动物疾病。膜蛋白嵌入细胞膜中,建立起对环境变化以及配体或抑制剂等分子化合物敏感反应的分子相互作用。我们应用原子力显微镜(AFM)对詹氏甲烷球菌的Na(+)/H(+)反向转运蛋白MjNhaP1进行成像,并运用单分子力谱(SMFS)来探测驱动该蛋白质结构-功能关系的分子相互作用。高分辨率AFM形貌图显示MjNhaP1的二聚体组装体被重构到脂质双层中。MjNhaP1的SMFS揭示了稳定各个结构域的分子相互作用。跨膜结构域展现出单独展开或与其他结构域协同展开的特定概率,从而导致不同的展开途径。螺旋VIII和X建立了对pH敏感的相互作用,在MjNhaP1激活时会发生显著变化,而去除配体(Na(+))会使除螺旋VIII之外的整个反向转运蛋白不稳定。据推测,螺旋VIII的Asp234/235参与配体结合位点,并且螺旋X在转运蛋白的激活中发挥功能作用。
