mdCATH: A Large-Scale MD Dataset for Data-Driven Computational Biophysics

arXiv - QuanBio - Biomolecules Pub Date : 2024-07-20 DOI:arxiv-2407.14794

Antonio Mirarchi, Toni Giorgino, Gianni De Fabritiis

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Abstract

Recent advancements in protein structure determination are revolutionizing our understanding of proteins. Still, a significant gap remains in the availability of comprehensive datasets that focus on the dynamics of proteins, which are crucial for understanding protein function, folding, and interactions. To address this critical gap, we introduce mdCATH, a dataset generated through an extensive set of all-atom molecular dynamics simulations of a diverse and representative collection of protein domains. This dataset comprises all-atom systems for 5,398 domains, modeled with a state-of-the-art classical force field, and simulated in five replicates each at five temperatures from 320 K to 413 K. The mdCATH dataset records coordinates and forces every 1 ns, for over 62 ms of accumulated simulation time, effectively capturing the dynamics of the various classes of domains and providing a unique resource for proteome-wide statistical analyses of protein unfolding thermodynamics and kinetics. We outline the dataset structure and showcase its potential through four easily reproducible case studies, highlighting its capabilities in advancing protein science.

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mdCATH：用于数据驱动计算生物物理学的大规模 MD 数据集

蛋白质结构测定领域的最新进展正在彻底改变我们对蛋白质的认识。然而，在提供侧重于蛋白质动力学的综合数据集方面仍然存在巨大差距，而蛋白质动力学对于理解蛋白质的功能、折叠和相互作用至关重要。为了填补这一空白，我们引入了 mdCATH，这是一个通过对具有代表性的各种蛋白质结构域进行大量全原子分子动力学模拟而生成的数据集。mdCATH 数据集每 1 毫微秒记录一次坐标和力，累计模拟时间超过 62 毫秒，有效地捕捉了各类结构域的动态，为蛋白质组范围内的蛋白质展开热力学和动力学统计分析提供了独特的资源。我们概述了数据集的结构，并通过四个易于重复的案例研究展示了它的潜力，突出了它在推动蛋白质科学发展方面的能力。

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arXiv - QuanBio - Biomolecules

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