用于药物发现的生成网络复合体(GNC)。

IF 0.6 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS Communications in Information and Systems Pub Date : 2019-01-01 DOI:10.4310/cis.2019.v19.n3.a2
Christopher Grow, Kaifu Gao, Duc Duy Nguyen, Guo-Wei Wei
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引用次数: 0

摘要

要生成大量具有理想药理特性的新型化合物,仍然是一项具有挑战性的任务。在这项工作中,我们提出了一种生成网络复合体(GNC),作为设计新型化合物、预测其物理和化学性质以及选择符合各种可药用标准(如结合亲和力、溶解度、分配系数等)的潜在候选药物的新平台。我们将 SMILES 字符串生成器(由编码器、药物特性控制或调节潜空间和解码器组成)与验证深度神经网络、目标特定三维(3D)姿态生成器和数学深度学习网络相结合,分别生成新化合物、预测其药物特性、构建与目标蛋白质相关的三维姿态以及重新评估可药用性。新化合物通过随机输出、控制输出或优化输出在潜空间生成。在我们的演示中,针对 Cathepsin S 和 BACE 目标分别生成了 208 万和 280 万种新型化合物。这些新化合物与种子化合物截然不同,涵盖了更大的化学空间。对于具有潜在活性的化合物,我们采用最先进的方法生成了它们的三维姿态。基于代数拓扑学、微分几何学和代数图理论的深度学习算法将进一步评估生成的三维复合物的可药性。整个过程在超级计算机上完成,耗时不到一周。因此,我们的 GNC 是发现候选新药的高效新范例。
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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Generative network complex (GNC) for drug discovery.

It remains a challenging task to generate a vast variety of novel compounds with desirable pharmacological properties. In this work, a generative network complex (GNC) is proposed as a new platform for designing novel compounds, predicting their physical and chemical properties, and selecting potential drug candidates that fulfill various druggable criteria such as binding affinity, solubility, partition coefficient, etc. We combine a SMILES string generator, which consists of an encoder, a drug-property controlled or regulated latent space, and a decoder, with verification deep neural networks, a target-specific three-dimensional (3D) pose generator, and mathematical deep learning networks to generate new compounds, predict their drug properties, construct 3D poses associated with target proteins, and reevaluate druggability, respectively. New compounds were generated in the latent space by either randomized output, controlled output, or optimized output. In our demonstration, 2.08 million and 2.8 million novel compounds are generated respectively for Cathepsin S and BACE targets. These new compounds are very different from the seeds and cover a larger chemical space. For potentially active compounds, their 3D poses are generated using a state-of-the-art method. The resulting 3D complexes are further evaluated for druggability by a championing deep learning algorithm based on algebraic topology, differential geometry, and algebraic graph theories. Performed on supercomputers, the whole process took less than one week. Therefore, our GNC is an efficient new paradigm for discovering new drug candidates.

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来源期刊
Communications in Information and Systems
Communications in Information and Systems COMPUTER SCIENCE, INFORMATION SYSTEMS-
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