Faas Guido C, Schwaller Beat, Vergara Julio L, Mody Istvan
Department of Neurology, University of California Los Angeles, Los Angeles, California, United States of America.
PLoS Biol. 2007 Nov;5(11):e311. doi: 10.1371/journal.pbio.0050311.
Cooperativity is one of the most important properties of molecular interactions in biological systems. It is the ability to influence ligand binding at one site of a macromolecule by previous ligand binding at another site of the same molecule. As a consequence, the affinity of the macromolecule for the ligand is either decreased (negative cooperativity) or increased (positive cooperativity). Over the last 100 years, O2 binding to hemoglobin has served as the paradigm for cooperative ligand binding and allosteric modulation, and four practical models were developed to quantitatively describe the mechanism: the Hill, the Adair-Klotz, the Monod-Wyman-Changeux, and the Koshland-Némethy-Filmer models. The predictions of these models apply under static conditions when the binding reactions are at equilibrium. However, in a physiological setting, e.g., inside a cell, the timing and dynamics of the binding events are essential. Hence, it is necessary to determine the dynamic properties of cooperative binding to fully understand the physiological implications of cooperativity. To date, the Monod-Wyman-Changeux model was applied to determine the kinetics of cooperative binding to biologically active molecules. In this model, cooperativity is established by postulating two allosteric isoforms with different binding properties. However, these studies were limited to special cases, where transition rates between allosteric isoforms are much slower than the binding rates or where binding and unbinding rates could be measured independently. For all other cases, the complex mathematical description precludes straightforward interpretations. Here, we report on calculating for the first time the fast dynamics of a cooperative binding process, the binding of Ca2+ to calretinin. Calretinin is a Ca2+-binding protein with four cooperative binding sites and one independent binding site. The Ca2+ binding to calretinin was assessed by measuring the decay of free Ca2+ using a fast fluorescent Ca2+ indicator following rapid (<50-mus rise time) Ca2+ concentration jumps induced by uncaging Ca2+ from DM-nitrophen. To unravel the kinetics of cooperative binding, we devised several approaches based on known cooperative binding models, resulting in a novel and relatively simple model. This model revealed unexpected and highly specific nonlinear properties of cellular Ca2+ regulation by calretinin. The association rate of Ca2+ with calretinin speeds up as the free Ca2+ concentration increases from cytoplasmic resting conditions ( approximately 100 nM) to approximately 1 muM. As a consequence, the Ca2+ buffering speed of calretinin highly depends on the prevailing Ca2+ concentration prior to a perturbation. In addition to providing a novel mode of action of cellular Ca2+ buffering, our model extends the analysis of cooperativity beyond the static steady-state condition, providing a powerful tool for the investigation of the dynamics and functional significance of cooperative binding in general.
协同性是生物系统中分子相互作用最重要的特性之一。它是指同一分子上一个位点先前的配体结合能够影响该分子另一位点的配体结合的能力。因此,大分子对配体的亲和力要么降低(负协同性),要么增加(正协同性)。在过去的100年里,氧气与血红蛋白的结合一直是协同配体结合和别构调节的范例,并且开发了四种实用模型来定量描述其机制:希尔模型、阿代尔 - 克洛茨模型、莫诺 - 怀曼 - 尚热模型和科什兰德 - 内梅蒂 - 菲尔默模型。这些模型的预测适用于结合反应处于平衡的静态条件。然而,在生理环境中,例如在细胞内,结合事件的时间和动力学至关重要。因此,有必要确定协同结合的动态特性,以充分理解协同性的生理意义。迄今为止,莫诺 - 怀曼 - 尚热模型已被用于确定与生物活性分子协同结合的动力学。在该模型中,通过假定具有不同结合特性的两种别构异构体来建立协同性。然而,这些研究仅限于特殊情况,即别构异构体之间的转变速率比结合速率慢得多,或者结合和解离速率可以独立测量的情况。对于所有其他情况,复杂的数学描述妨碍了直接的解释。在这里,我们首次报告了计算协同结合过程的快速动力学,即Ca2+与钙视网膜蛋白的结合。钙视网膜蛋白是一种具有四个协同结合位点和一个独立结合位点的Ca2+结合蛋白。通过使用快速荧光Ca2+指示剂测量在由DM - 硝基苯酚释放Ca2+引起的快速(<50微秒上升时间)Ca2+浓度跃升后游离Ca2+的衰减,来评估Ca2+与钙视网膜蛋白的结合。为了揭示协同结合的动力学,我们基于已知的协同结合模型设计了几种方法,从而得到了一个新颖且相对简单的模型。该模型揭示了钙视网膜蛋白对细胞Ca2+调节的意外且高度特异性的非线性特性。随着游离Ca2+浓度从细胞质静息状态(约100 nM)增加到约1 μM,Ca2+与钙视网膜蛋白的结合速率加快。因此,钙视网膜蛋白的Ca2+缓冲速度高度依赖于扰动前的Ca2+浓度。除了提供一种细胞Ca2+缓冲的新作用模式外,我们的模型还将协同性分析扩展到了静态稳态条件之外,为一般情况下协同结合的动力学和功能意义的研究提供了一个强大的工具。
