Physical Chemistry I-Biophysical Chemistry, Faculty of Chemistry, TU Dortmund University, Otto-Hahn-Strasse 6, D-44227 Dortmund, Germany.
Proc Natl Acad Sci U S A. 2012 Jan 10;109(2):460-5. doi: 10.1073/pnas.1110553109. Epub 2011 Dec 27.
Regulation of protein function is often linked to a conformational switch triggered by chemical or physical signals. To evaluate such conformational changes and to elucidate the underlying molecular mechanisms of subsequent protein function, experimental identification of conformational substates and characterization of conformational equilibria are mandatory. We apply pressure modulation in combination with FTIR spectroscopy to reveal equilibria between spectroscopically resolved substates of the lipidated signaling protein N-Ras. Pressure has the advantage that its thermodynamic conjugate is volume, a parameter that is directly related to structure. The conformational dynamics of N-Ras in its different nucleotide binding states in the absence and presence of a model biomembrane was probed by pressure perturbation. We show that not only nucleotide binding but also the presence of the membrane has a drastic effect on the conformational dynamics and selection of conformational substates of the protein, and a new substate appearing upon membrane binding could be uncovered. Population of this new substate is accompanied by structural reorientations of the G domain, as also indicated by complementary ATR-FTIR and IRRAS measurements. These findings thus illustrate that the membrane controls signaling conformations by acting as an effective interaction partner, which has consequences for the G-domain orientation of membrane-associated N-Ras, which in turn is known to be critical for its effector and modulator interactions. Finally, these results provide insights into the influence of pressure on Ras-controlled signaling events in organisms living under extreme environmental conditions as they are encountered in the deep sea where pressures reach the kbar range.
蛋白质功能的调节通常与化学或物理信号触发的构象转换有关。为了评估这种构象变化,并阐明随后蛋白质功能的潜在分子机制,必须对构象亚稳态进行实验鉴定和对构象平衡进行特征描述。我们应用压力调制与傅里叶变换红外光谱相结合,以揭示脂质化信号蛋白 N-Ras 的光谱可分辨亚稳态之间的平衡。压力的优点在于其热力学共轭是体积,而体积与结构直接相关。通过压力扰动探测 N-Ras 在不同核苷酸结合状态下在无模型生物膜和存在模型生物膜时的构象动力学。我们表明,不仅核苷酸结合,而且膜的存在对蛋白质构象动力学和构象亚稳态的选择有巨大影响,并且可以揭示出结合膜后出现的新亚稳态。这种新亚稳态的出现伴随着 G 结构域的结构重排,ATR-FTIR 和 IRRAS 测量也表明了这一点。因此,这些发现表明,膜通过充当有效的相互作用伴侣来控制信号构象,这对与膜相关的 N-Ras 的 G 结构域取向有影响,而 G 结构域取向又被认为对其效应物和调节剂相互作用至关重要。最后,这些结果为理解在深海等极端环境条件下生物体中 Ras 控制的信号事件提供了启示,深海中的压力可达千巴范围。