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用于配体-靶点相互作用的计算分子生物学方法。

Computational molecular biology approaches to ligand-target interactions.

作者信息

Lupieri Paola, Nguyen Chuong Ha Hung, Bafghi Zhaleh Ghaemi, Giorgetti Alejandro, Carloni Paolo

出版信息

HFSP J. 2009 Aug;3(4):228-39. doi: 10.2976/1.3092784. Epub 2009 Mar 10.

DOI:10.2976/1.3092784
PMID:20119480
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2799985/
Abstract

Binding of small molecules to their targets triggers complex pathways. Computational approaches are keys for predictions of the molecular events involved in such cascades. Here we review current efforts at characterizing the molecular determinants in the largest membrane-bound receptor family, the G-protein-coupled receptors (GPCRs). We focus on odorant receptors, which constitute more than half GPCRs. The work presented in this review uncovers structural and energetic aspects of components of the cellular cascade. Finally, a computational approach in the context of radioactive boron-based antitumoral therapies is briefly described.

摘要

小分子与其靶标的结合会触发复杂的信号通路。计算方法是预测此类级联反应中涉及的分子事件的关键。在此,我们综述了目前在最大的膜结合受体家族——G蛋白偶联受体(GPCRs)中表征分子决定因素的研究进展。我们重点关注嗅觉受体,其占GPCRs总数的一半以上。本综述中介绍的工作揭示了细胞级联反应各组分的结构和能量方面的信息。最后,简要描述了基于放射性硼的抗肿瘤治疗背景下的一种计算方法。

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