确定跨Kemp消除酶变体的酶功能描述符的收敛性。

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Yaoyukun Jiang, Sebastian L Stull, Qianzhen Shao, Zhongyue J Yang
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引用次数: 1

摘要

分子模拟已被广泛用于加速生物催化的发现。从分子模拟得到的酶功能描述符已经被用来指导寻找有益的酶突变体。然而,计算多个酶变体描述符的理想活性位点区域大小仍未经过测试。在这里,我们对18个Kemp消去酶变体的动态衍生和静电描述子进行了收敛测试,这些变体跨越6个与底物边界距离不同的活性位点区域。测试的描述符包括活性位点区域的均方根偏差,底物与活性位点之间的溶剂可及表面积比,以及电场(EF)在断裂C-H键上的投影。使用分子力学方法评估所有描述符。为了了解电子结构的影响,还使用量子力学/分子力学方法对EF进行了评估。计算了18个Kemp消除酶变体的描述符值。使用Spearman相关矩阵来确定区域大小条件,在该条件下,区域边界的进一步扩展不会实质性地改变描述符值的排序。我们观察到蛋白质动力学衍生的描述符,包括RMSDactive_site和SASAratio,在距离底物5 Å处收敛。在截断酶模型的分子力学方法下,静电描述子EFC-H收敛于6 Å,在全酶模型的量子力学/分子力学方法下收敛于4 Å。本研究为今后确定酶工程预测建模的描述符提供了参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Convergence in determining enzyme functional descriptors across Kemp eliminase variants.

Molecular simulations have been extensively employed to accelerate biocatalytic discoveries. Enzyme functional descriptors derived from molecular simulations have been leveraged to guide the search for beneficial enzyme mutants. However, the ideal active-site region size for computing the descriptors over multiple enzyme variants remains untested. Here, we conducted convergence tests for dynamics-derived and electrostatic descriptors on 18 Kemp eliminase variants across six active-site regions with various boundary distances to the substrate. The tested descriptors include the root-mean-square deviation of the active-site region, the solvent accessible surface area ratio between the substrate and active site, and the projection of the electric field (EF) on the breaking C-H bond. All descriptors were evaluated using molecular mechanics methods. To understand the effects of electronic structure, the EF was also evaluated using quantum mechanics/molecular mechanics methods. The descriptor values were computed for 18 Kemp eliminase variants. Spearman correlation matrices were used to determine the region size condition under which further expansion of the region boundary does not substantially change the ranking of descriptor values. We observed that protein dynamics-derived descriptors, including RMSDactive_site and SASAratio, converge at a distance cutoff of 5 Å from the substrate. The electrostatic descriptor, EFC-H, converges at 6 Å using molecular mechanics methods with truncated enzyme models and 4 Å using quantum mechanics/molecular mechanics methods with whole enzyme model. This study serves as a future reference to determine descriptors for predictive modeling of enzyme engineering.

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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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