FAME:基于片段的条件分子生成用于表型药物发现。

Thai-Hoang Pham, Lei Xie, Ping Zhang
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引用次数: 0

摘要

由于化学空间的复杂性,从头开始的分子设计是药物发现的一个关键挑战。随着分子数据集的可用性和机器学习的进步,许多深度生成模型被提出用于生成具有所需性质的新分子。然而,现有的大多数模型只关注分子分布学习和基于靶标的分子设计,从而阻碍了它们在实际应用中的潜力。在药物发现中,表型分子设计比基于靶标的分子设计具有优势,特别是在一类新药发现中。在这项工作中,我们提出了第一个针对表型分子设计的深度图生成模型(FAME),特别是基于基因表达的分子设计。FAME利用条件变分自编码器框架来学习从基因表达谱中生成分子的条件分布。然而,由于分子空间的复杂性和基因表达数据中的噪声现象,这种分布很难学习。为了解决这些问题,首先提出了一种采用对比目标函数的基因表达去噪(GED)模型来降低基因表达数据中的噪声。然后设计FAME将分子视为片段序列,并学习以自回归的方式生成这些片段。通过利用这种基于片段的生成策略和去噪的基因表达谱,FAME可以生成具有高效率和所需生物活性的新分子。实验结果表明,FAME优于现有的基于smiles和基于图的深度生成模型的表型分子设计方法。此外,我们研究中提出的降低基因表达数据噪声的有效机制可以应用于组学数据建模,以促进表型药物的发现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

FAME: Fragment-based Conditional Molecular Generation for Phenotypic Drug Discovery.

FAME: Fragment-based Conditional Molecular Generation for Phenotypic Drug Discovery.

De novo molecular design is a key challenge in drug discovery due to the complexity of chemical space. With the availability of molecular datasets and advances in machine learning, many deep generative models are proposed for generating novel molecules with desired properties. However, most of the existing models focus only on molecular distribution learning and target-based molecular design, thereby hindering their potentials in real-world applications. In drug discovery, phenotypic molecular design has advantages over target-based molecular design, especially in first-in-class drug discovery. In this work, we propose the first deep graph generative model (FAME) targeting phenotypic molecular design, in particular gene expression-based molecular design. FAME leverages a conditional variational autoencoder framework to learn the conditional distribution generating molecules from gene expression profiles. However, this distribution is difficult to learn due to the complexity of the molecular space and the noisy phenomenon in gene expression data. To tackle these issues, a gene expression denoising (GED) model that employs contrastive objective function is first proposed to reduce noise from gene expression data. FAME is then designed to treat molecules as the sequences of fragments and learn to generate these fragments in autoregressive manner. By leveraging this fragment-based generation strategy and the denoised gene expression profiles, FAME can generate novel molecules with a high validity rate and desired biological activity. The experimental results show that FAME outperforms existing methods including both SMILES-based and graph-based deep generative models for phenotypic molecular design. Furthermore, the effective mechanism for reducing noise in gene expression data proposed in our study can be applied to omics data modeling in general for facilitating phenotypic drug discovery.

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