Department of Chemistry and Chemical Biology, Cornell University, Ithaca, New York 14853, United States.
J Phys Chem A. 2020 May 21;124(20):4128-4140. doi: 10.1021/acs.jpca.0c02766. Epub 2020 May 7.
Ion-π interactions between the face of a molecular π-system and a cation or anion are among the strongest noncovalent interactions known, with applications throughout biochemistry and structural biology, molecular recognition and host-guest chemistry, as well as enzyme kinetics and organocatalysis. In this work, we examine the competing notions of selectivity and flexibility in this class of noncovalent interactions by investigating how certain π-systems can be promiscuous ion-π binders with the versatility to form favorable cation- and anion-π complexes. We focus our efforts on a detailed theoretical case study of the DNA/RNA nucleobases by first demonstrating that these π-systems are promiscuous ion-π binders with the biologically relevant Li/Na cations and F/Cl anions via benchmark-quality quantum-mechanical binding energy curves computed at the CCSD(T)/CBS level of theory. Using a symmetry-adapted perturbation theory (SAPT)-based energy decomposition analysis, we explore the different physicochemical driving forces underlying the formation of cation- and anion-π complexes, as well as the crucial role played by charge penetration effects in determining the nontrivial (and often counterintuitive) electrostatics in anion-π systems. In doing so, a unified view of these rather distinct noncovalent binding motifs emerges with the finding that both cation- and anion-π complexes are strongly stabilized by an essentially ring-independent potential that can only be overcome by substantially unfavorable electrostatics. This work furnishes a more comprehensive explanation for decades of observed correlations between the equilibrium binding energy and the electrostatic potential above the ring and provides new insight into the nature of selectivity and flexibility in this important class of noncovalent interactions. Quite interestingly, the analysis presented herein demonstrates that π-systems have an inherent propensity to bind both cations and anions, thereby implying that promiscuous ion-π binding is not an exotic property of the nucleobases and should be common in nature.
离子-π 相互作用是分子π 体系的面与阳离子或阴离子之间最强的非共价相互作用之一,在生物化学和结构生物学、分子识别和主体-客体化学、以及酶动力学和有机催化等领域都有应用。在这项工作中,我们通过研究某些π 体系如何成为具有多功能性的混杂离子-π 结合物,能够形成有利的阳离子和阴离子-π 配合物,来考察这类非共价相互作用中选择性和灵活性的竞争概念。我们通过对 DNA/RNA 碱基的详细理论案例研究来集中精力,首先通过计算 CCSD(T)/CBS 理论水平的基准质量量子力学结合能曲线,证明这些π 体系是具有混杂性的离子-π 结合物,能够与生物相关的 Li/Na 阳离子和 F/Cl 阴离子结合。通过基于对称自适应微扰理论 (SAPT)的能量分解分析,我们探索了形成阳离子和阴离子-π 配合物的不同物理化学驱动力,以及电荷穿透效应在确定阴离子-π 体系中复杂(且常常违反直觉)的静电作用方面所起的关键作用。通过这样做,我们对这些相当不同的非共价结合基序形成了一个统一的观点,发现阳离子和阴离子-π 配合物都强烈地被一个本质上与环无关的势所稳定,只有通过显著不利的静电作用才能克服。这项工作为几十年来观察到的平衡结合能与环上方静电势之间的相关性提供了更全面的解释,并为这种重要的非共价相互作用中的选择性和灵活性的本质提供了新的见解。非常有趣的是,本文的分析表明,π 体系具有结合阳离子和阴离子的固有倾向,这意味着混杂离子-π 结合不是碱基的奇特性质,在自然界中应该很常见。
