Aptamers are emerging as powerful synthetic bioreceptors for fundamental research, diagnostics, and therapeutics. For further advances, it is important to gain a better understanding of how aptamers interact with their targets. In this work, we have used magnetic force-induced dissociation experiments to study the dissociation process of two different aptamer-protein complexes, namely for hIgE and Ara h 1. The measurements show that both complexes exhibit dissociation with two distinct regimes: the dissociation rate depends weakly on the applied force at high forces but depends stronger on force at low forces. We attribute these observations to the existence of at least one intermediate state and at least two energy barriers in the aptamer-protein interaction. The measured spontaneous dissociation rate constants were validated with SPR using both Biacore and fiber optic technology. This work demonstrates the potential of the magnetic force-induced dissociation approach for an in-depth study of the dissociation kinetics of aptamer-protein bonds, which is not possible with SPR technologies. The results will help in the development and expansion of aptamers as bioaffinity probes.
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机译:适体正在成为强大的合成生物受体,可用于基础研究,诊断和治疗。对于进一步的进步,重要的是要更好地了解适体如何与其靶标相互作用。在这项工作中,我们已经使用磁力诱导的解离实验研究了两种不同的适体-蛋白复合物,即hIgE和Ara h 1的解离过程。测量结果表明,两种复合物都表现出两种不同的解离状态:解离速率在较高的力下微弱地依赖于所施加的力,而在较低的力下微弱地依赖于力。我们将这些观察结果归因于在适体-蛋白质相互作用中存在至少一种中间状态和至少两个能垒。使用Biacore和光纤技术,通过SPR验证了测得的自发解离速率常数。这项工作证明了磁力诱导解离方法对于深入研究适体-蛋白质键解离动力学的潜力,这是SPR技术无法实现的。该结果将有助于开发和扩展作为生物亲和探针的适体。
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