An integrated docking and molecular dynamics simulation approach to discover potential inhibitors of activin receptor-like kinase 1

IF 2.3 4区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Deeba Shamim Jairajpuri, Taj Mohammad, Afzal Hussain, Samira Amir, Urooj Fatima, Mohamed F. AlAjmi, Dharmendra Kumar Yadav, Md. Imtaiyaz Hassan
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引用次数: 0

Abstract

Activin receptor-like kinase 1 (ALK1) is a transmembrane receptor involved in crucial signaling pathways associated with angiogenesis and vascular development. Inhibition of ALK1 signaling has emerged as a promising therapeutic strategy for various angiogenesis-related diseases, including cancer and hereditary hemorrhagic telangiectasia. This study aimed to investigate the potential of phytoconstituents as inhibitors of ALK1 using a combined approach of virtual screening and molecular dynamics (MDs) simulations. Phytoconstituents from the IMPPAT 2.0 database underwent virtual screening to identify potential inhibitors of ALK1. The compounds were initially filtered based on physicochemical parameters, following Lipinski's rules and the PAINS filter. Subsequently, compounds demonstrating high binding affinities in docking analysis were further analyzed. Additional assessments, including ADMET, PAINS, and PASS evaluations, were conducted to identify more potent hits. Through interaction analysis, a phytoconstituent, Candidine, exhibited appreciable affinity and specific interactions with the ALK1 active site. To validate the results, MD simulations and principal components analysis were performed. The MD simulations demonstrated that Candidine stabilized the ALK1 structure and reduced conformational fluctuations. In conclusion, Candidine shows promising potential as binding partners of ALK1. These findings provide a foundation for further exploration and development of Candidine as a lead molecule for therapeutic interventions targeting ALK1-associated diseases.

发现活化素受体样激酶 1 潜在抑制剂的综合对接和分子动力学模拟方法。
激肽受体样激酶 1(ALK1)是一种跨膜受体,参与了与血管生成和血管发育相关的重要信号通路。抑制 ALK1 信号传导已成为治疗各种血管生成相关疾病(包括癌症和遗传性出血性毛细血管扩张症)的一种有前景的治疗策略。本研究旨在采用虚拟筛选和分子动力学(MDs)模拟相结合的方法,研究植物成分作为 ALK1 抑制剂的潜力。对 IMPPAT 2.0 数据库中的植物成分进行了虚拟筛选,以确定 ALK1 的潜在抑制剂。根据理化参数,按照利宾斯基规则和 PAINS 过滤器对化合物进行了初步筛选。随后,进一步分析了在对接分析中表现出高结合亲和力的化合物。此外,还进行了其他评估,包括 ADMET、PAINS 和 PASS 评估,以确定更多的强效化合物。通过相互作用分析,一种植物成分 Candidine 与 ALK1 活性位点表现出明显的亲和力和特异性相互作用。为了验证结果,我们进行了 MD 模拟和主成分分析。MD 模拟结果表明,Candidine 稳定了 ALK1 的结构,减少了构象波动。总之,Candidine 显示出作为 ALK1 结合伙伴的巨大潜力。这些发现为进一步探索和开发 Candidine 作为针对 ALK1 相关疾病的治疗干预先导分子奠定了基础。
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来源期刊
Journal of Molecular Recognition
Journal of Molecular Recognition 生物-生化与分子生物学
CiteScore
4.60
自引率
3.70%
发文量
68
审稿时长
2.7 months
期刊介绍: Journal of Molecular Recognition (JMR) publishes original research papers and reviews describing substantial advances in our understanding of molecular recognition phenomena in life sciences, covering all aspects from biochemistry, molecular biology, medicine, and biophysics. The research may employ experimental, theoretical and/or computational approaches. The focus of the journal is on recognition phenomena involving biomolecules and their biological / biochemical partners rather than on the recognition of metal ions or inorganic compounds. Molecular recognition involves non-covalent specific interactions between two or more biological molecules, molecular aggregates, cellular modules or organelles, as exemplified by receptor-ligand, antigen-antibody, nucleic acid-protein, sugar-lectin, to mention just a few of the possible interactions. The journal invites manuscripts that aim to achieve a complete description of molecular recognition mechanisms between well-characterized biomolecules in terms of structure, dynamics and biological activity. Such studies may help the future development of new drugs and vaccines, although the experimental testing of new drugs and vaccines falls outside the scope of the journal. Manuscripts that describe the application of standard approaches and techniques to design or model new molecular entities or to describe interactions between biomolecules, but do not provide new insights into molecular recognition processes will not be considered. Similarly, manuscripts involving biomolecules uncharacterized at the sequence level (e.g. calf thymus DNA) will not be considered.
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