Gregory W. Kyro, Matthew T. Martin, Eric D. Watt, Victor S. Batista
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引用次数: 0
Abstract
The link between in vitro hERG ion channel inhibition and subsequent in vivo QT interval prolongation, a critical risk factor for the development of arrythmias such as Torsade de Pointes, is so well established that in vitro hERG activity alone is often sufficient to end the development of an otherwise promising drug candidate. It is therefore of tremendous interest to develop advanced methods for identifying hERG-active compounds in the early stages of drug development, as well as for proposing redesigned compounds with reduced hERG liability and preserved primary pharmacology. In this work, we present CardioGenAI, a machine learning-based framework for re-engineering both developmental and commercially available drugs for reduced hERG activity while preserving their pharmacological activity. The framework incorporates novel state-of-the-art discriminative models for predicting hERG channel activity, as well as activity against the voltage-gated NaV1.5 and CaV1.2 channels due to their potential implications in modulating the arrhythmogenic potential induced by hERG channel blockade. We applied the complete framework to pimozide, an FDA-approved antipsychotic agent that demonstrates high affinity to the hERG channel, and generated 100 refined candidates. Remarkably, among the candidates is fluspirilene, a compound which is of the same class of drugs as pimozide (diphenylmethanes) and therefore has similar pharmacological activity, yet exhibits over 700-fold weaker binding to hERG. Furthermore, we demonstrated the framework's ability to optimize hERG, NaV1.5 and CaV1.2 profiles of multiple FDA-approved compounds while maintaining the physicochemical nature of the original drugs. We envision that this method can effectively be applied to developmental compounds exhibiting hERG liabilities to provide a means of rescuing drug development programs that have stalled due to hERG-related safety concerns. Additionally, the discriminative models can also serve independently as effective components of virtual screening pipelines. We have made all of our software open-source at https://github.com/gregory-kyro/CardioGenAI to facilitate integration of the CardioGenAI framework for molecular hypothesis generation into drug discovery workflows.
Scientific contribution
This work introduces CardioGenAI, an open-source machine learning-based framework designed to re-engineer drugs for reduced hERG liability while preserving their pharmacological activity. The complete CardioGenAI framework can be applied to developmental compounds exhibiting hERG liabilities to provide a means of rescuing drug discovery programs facing hERG-related challenges. In addition, the framework incorporates novel state-of-the-art discriminative models for predicting hERG, NaV1.5 and CaV1.2 channel activity, which can function independently as effective components of virtual screening pipelines.
体外hERG离子通道抑制与随后的体内QT间期延长之间的联系是心律失常(如Torsade de Pointes)发展的一个关键危险因素,因此,仅体外hERG活性通常足以终止其他有希望的候选药物的开发。因此,在药物开发的早期阶段,开发先进的方法来识别hERG活性化合物,以及提出重新设计的化合物,减少hERG的负荷并保留原始药理学,这是一个巨大的兴趣。在这项工作中,我们提出了CardioGenAI,这是一个基于机器学习的框架,用于重新设计开发和市售药物,以降低hERG活性,同时保持其药理活性。该框架结合了最新的判别模型,用于预测hERG通道的活性,以及电压门控的NaV1.5和CaV1.2通道的活性,因为它们在调节hERG通道阻断引起的心律失常电位方面具有潜在的意义。我们将完整的框架应用于pimozide,一种fda批准的抗精神病药物,显示出对hERG通道的高亲和力,并产生了100种精炼的候选药物。值得注意的是,在候选药物中,有一种与吡莫胺(二苯甲烷)属于同一类药物的化合物,因此具有相似的药理活性,但与hERG的结合弱700倍以上。此外,我们证明了该框架能够优化多种fda批准的化合物的hERG, NaV1.5和CaV1.2谱,同时保持原药的物理化学性质。我们设想这种方法可以有效地应用于具有hERG特性的开发化合物,为挽救因hERG相关安全问题而停滞的药物开发项目提供一种手段。此外,判别模型也可以独立作为虚拟筛选管道的有效组成部分。我们已经在https://github.com/gregory-kyro/CardioGenAI上开放了我们所有的软件,以促进将CardioGenAI框架用于分子假设生成到药物发现工作流程中的整合。这项工作介绍了CardioGenAI,这是一个基于开源机器学习的框架,旨在重新设计药物以减少hERG责任,同时保持其药理活性。完整的CardioGenAI框架可以应用于表现出hERG负性的开发化合物,为拯救面临hERG相关挑战的药物发现项目提供了一种手段。此外,该框架还结合了新的最先进的判别模型,用于预测hERG、NaV1.5和CaV1.2通道活性,这些通道可以作为虚拟筛选管道的有效组成部分独立发挥作用。
期刊介绍:
Journal of Cheminformatics is an open access journal publishing original peer-reviewed research in all aspects of cheminformatics and molecular modelling.
Coverage includes, but is not limited to:
chemical information systems, software and databases, and molecular modelling,
chemical structure representations and their use in structure, substructure, and similarity searching of chemical substance and chemical reaction databases,
computer and molecular graphics, computer-aided molecular design, expert systems, QSAR, and data mining techniques.
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