Multiscale molecular simulations to investigate adenylyl cyclase-based signaling in the brain

IF 16.8 2区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY Wiley Interdisciplinary Reviews: Computational Molecular Science Pub Date : 2022-06-14 DOI:10.1002/wcms.1623
Siri C. van Keulen, Juliette Martin, Francesco Colizzi, Elisa Frezza, Daniel Trpevski, Nuria Cirauqui Diaz, Pietro Vidossich, Ursula Rothlisberger, Jeanette Hellgren Kotaleski, Rebecca C. Wade, Paolo Carloni
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引用次数: 2

Abstract

Adenylyl cyclases (ACs) play a key role in many signaling cascades. ACs catalyze the production of cyclic AMP from ATP and this function is stimulated or inhibited by the binding of their cognate stimulatory or inhibitory Gα subunits, respectively. Here we used simulation tools to uncover the molecular and subcellular mechanisms of AC function, with a focus on the AC5 isoform, extensively studied experimentally. First, quantum mechanical/molecular mechanical free energy simulations were used to investigate the enzymatic reaction and its changes upon point mutations. Next, molecular dynamics simulations were employed to assess the catalytic state in the presence or absence of Gα subunits. This led to the identification of an inactive state of the enzyme that is present whenever an inhibitory Gα is associated, independent of the presence of a stimulatory Gα. In addition, the use of coevolution-guided multiscale simulations revealed that the binding of Gα subunits reshapes the free-energy landscape of the AC5 enzyme by following the classical population-shift paradigm. Finally, Brownian dynamics simulations provided forward rate constants for the binding of Gα subunits to AC5, consistent with the ability of the protein to perform coincidence detection effectively. Our calculations also pointed to strong similarities between AC5 and other AC isoforms, including AC1 and AC6. Findings from the molecular simulations were used along with experimental data as constraints for systems biology modeling of a specific AC5-triggered neuronal cascade to investigate how the dynamics of downstream signaling depend on initial receptor activation.

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多尺度分子模拟研究脑内腺苷基环化酶信号
腺苷酸环化酶(ACs)在许多信号级联反应中起关键作用。ac催化ATP生成环状AMP,其功能分别受其同源刺激或抑制Gα亚基的刺激或抑制。在这里,我们使用模拟工具揭示了AC功能的分子和亚细胞机制,重点是AC5异构体,广泛的实验研究。首先,利用量子力学/分子力学自由能模拟研究酶促反应及其在点突变时的变化。接下来,采用分子动力学模拟来评估Gα亚基存在或不存在时的催化状态。这导致了酶的失活状态的鉴定,无论何时抑制Gα相关,独立于刺激Gα的存在。此外,利用协同进化引导的多尺度模拟显示,Gα亚基的结合遵循经典的种群转移范式,重塑了AC5酶的自由能格局。最后,布朗动力学模拟提供了Gα亚基与AC5结合的正向速率常数,这与该蛋白有效进行重合检测的能力相一致。我们的计算还指出AC5和其他AC异构体(包括AC1和AC6)之间有很强的相似性。分子模拟的结果与实验数据一起被用作特定ac5触发的神经元级联的系统生物学建模的约束,以研究下游信号传导的动力学如何依赖于初始受体激活。本文分类如下:
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来源期刊
Wiley Interdisciplinary Reviews: Computational Molecular Science
Wiley Interdisciplinary Reviews: Computational Molecular Science CHEMISTRY, MULTIDISCIPLINARY-MATHEMATICAL & COMPUTATIONAL BIOLOGY
CiteScore
28.90
自引率
1.80%
发文量
52
审稿时长
6-12 weeks
期刊介绍: Computational molecular sciences harness the power of rigorous chemical and physical theories, employing computer-based modeling, specialized hardware, software development, algorithm design, and database management to explore and illuminate every facet of molecular sciences. These interdisciplinary approaches form a bridge between chemistry, biology, and materials sciences, establishing connections with adjacent application-driven fields in both chemistry and biology. WIREs Computational Molecular Science stands as a platform to comprehensively review and spotlight research from these dynamic and interconnected fields.
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