Shibayama Naoya, Ohki Mio, Tame Jeremy R H, Park Sam-Yong
From the Department of Physiology, Division of Biophysics, Jichi Medical University, 3311-1 Yakushiji, Shimotsuke, Tochigi 329-0498 and
the Drug Design Laboratory, Graduate School of Medical Life Science, Yokohama City University, 1-7-29 Suehiro, Tsurumi, Yokohama 230-0045, Japan.
J Biol Chem. 2017 Nov 3;292(44):18258-18269. doi: 10.1074/jbc.M117.781146. Epub 2017 Sep 20.
Although X-ray crystallography is the most commonly used technique for studying the molecular structure of proteins, it is not generally able to monitor the dynamic changes or global domain motions that often underlie allostery. These motions often prevent crystal growth or reduce crystal order. We have recently discovered a crystal form of human hemoglobin that contains three protein molecules allowed to express a full range of quaternary structures, whereas maintaining strong X-ray diffraction. Here we use this crystal form to investigate the effects of two allosteric effectors, phosphate and bezafibrate, by tracking the structures and functions of the three hemoglobin molecules following the addition of each effector. The X-ray analysis shows that the addition of either phosphate or bezafibrate not only induces conformational changes in a direction from a relaxed-state to a tense-state, but also within relaxed-state populations. The microspectrophotometric O equilibrium measurements on the crystals demonstrate that the binding of each effector energetically stabilizes the lowest affinity conformer more strongly than the intermediate affinity one, thereby reducing the O affinity of tense-state populations, and that the addition of bezafibrate causes an ∼5-fold decrease in the O affinity of relaxed-state populations. These results show that the allosteric pathway of hemoglobin involves shifts of populations rather than a unidirectional conversion of one quaternary structure to another, and that minor conformers of hemoglobin may have a disproportionate effect on the overall O affinity.
尽管X射线晶体学是研究蛋白质分子结构最常用的技术,但它通常无法监测变构作用背后常见的动态变化或全局结构域运动。这些运动往往会阻碍晶体生长或降低晶体有序性。我们最近发现了一种人血红蛋白的晶体形式,其中包含三个能够呈现完整四级结构范围的蛋白质分子,同时保持强烈的X射线衍射。在这里,我们利用这种晶体形式,通过追踪添加每种效应物后三个血红蛋白分子的结构和功能,来研究两种变构效应物——磷酸盐和苯扎贝特的作用。X射线分析表明,添加磷酸盐或苯扎贝特不仅会诱导构象从松弛态向紧张态转变,而且在松弛态群体内部也会发生变化。对晶体进行的显微分光光度法氧平衡测量表明,每种效应物的结合在能量上更强烈地稳定了最低亲和力构象体,而不是中间亲和力构象体,从而降低了紧张态群体的氧亲和力,并且添加苯扎贝特会使松弛态群体的氧亲和力降低约5倍。这些结果表明,血红蛋白的变构途径涉及群体的转变,而不是一种四级结构向另一种四级结构的单向转化,并且血红蛋白的次要构象体可能对整体氧亲和力有不成比例的影响。