Nuclear magnetic resonance free ligand conformations and atomic resolution dynamics.

Q3 Physics and Astronomy

Magnetic resonance (Gottingen, Germany) Pub Date : 2021-06-23 eCollection Date: 2021-01-01 DOI:10.5194/mr-2-489-2021

Amber Y S Balazs, Nichola L Davies, David Longmire, Martin J Packer, Elisabetta Chiarparin

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Abstract

Knowledge of free ligand conformational preferences (energy minima) and conformational dynamics (rotational energy barriers) of small molecules in solution can guide drug design hypotheses and help rank ideas to bias syntheses towards more active compounds. Visualization of conformational exchange dynamics around torsion angles, by replica exchange with solute tempering molecular dynamics (REST-MD), gives results in agreement with high-resolution $^{1}$ H nuclear magnetic resonance (NMR) spectra and complements free ligand conformational analyses. Rotational energy barriers around individual bonds are comparable between calculated and experimental values, making the in-silico method relevant to ranking prospective design ideas in drug discovery programs, particularly across a series of analogs. Prioritizing design ideas, based on calculations and analysis of measurements across a series, efficiently guides rational discovery towards the "right molecules" for effective medicines.

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无核磁共振配体构象和原子分辨率动力学。

溶液中小分子的自由配体构象偏好（能量最小值）和构象动力学（旋转能垒）的知识可以指导药物设计假设，并有助于对合成偏向更活性化合物的想法进行排序。通过与溶质回火分子动力学（REST-MD）的复制交换，对扭转角周围的构象交换动力学进行可视化，给出了与高分辨率1H核磁共振（NMR）光谱一致的结果，并补充了自由配体构象分析。单个键周围的旋转能垒在计算值和实验值之间具有可比性，这使得在药物发现项目中，特别是在一系列类似物中，计算机方法与潜在设计想法的排名相关。基于一系列测量的计算和分析，对设计思想进行优先排序，有效地引导理性发现有效药物的“正确分子”。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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