QSAR and its Role in Target-Ligand Interaction

Q3 Computer Science

Open Bioinformatics Journal Pub Date : 2013-12-27 DOI:10.2174/1875036201307010063

Anamika Singh, Rajeev Singh

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引用次数: 7

Abstract

Each molecule has its own specialty, structure and function and when these molecules are combined together they form a compound. Structure and function of a molecule are related to each other and QSARs (Quantitative Structure- Activity relationships) are based on the criteria that the structure of a molecule must contain the features responsible for its physical, chemical, and biological properties, and on the ability to represent the chemical by one, or more, numerical descriptor(s). By QSAR models, the biological activity of a new or untested chemical can be inferred from the molecular structure of similar compounds whose activities have already been assessed. QSARs attempt to relate physical and chemical properties of molecules to their biological activities. For this there are so many descriptors (for example, molecular weight, number of rotatable bonds, Log P) and simple statistical methods such as Multiple Linear Regression (MLR) are used to predict a model. These models describe the activity of the data set and can predict activities for further sets of (untested) compounds. These types of descriptors are simple to calculate and allow for a relatively fast analysis. 3D-QSAR uses probe-based sampling within a molecular lattice to determine three-dimensional properties of molecules (particularly steric and electrostatic values) and can then correlate these 3D descriptors with biological activity. Physicochemical descriptors, include hydrophobicity, topology, electronic properties, and steric effects etc. These descriptors can be calculated empirically, statistically or through more recent computational methods. QSARs are currently being applied in many disciplines, with many pertaining to drug design and environmental risk assessment. Key word: QSAR, Ligand Designing, LogP, Cheminformatics, Docking.

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QSAR及其在靶配体相互作用中的作用

每个分子都有自己的特点、结构和功能，当这些分子结合在一起就形成了一种化合物。分子的结构和功能是相互关联的，qsar(定量结构-活性关系)是基于分子的结构必须包含负责其物理，化学和生物特性的特征的标准，以及用一个或多个数字描述符表示化学物质的能力。通过QSAR模型，可以从已经评估过活性的类似化合物的分子结构推断出新的或未经测试的化学物质的生物活性。qsar试图将分子的物理和化学性质与其生物活性联系起来。为此，有许多描述符(例如，分子量，可旋转键数，Log P)和简单的统计方法，如多元线性回归(MLR)用于预测模型。这些模型描述了数据集的活性，并可以预测进一步的(未经测试的)化合物的活性。这些类型的描述符计算起来很简单，并且允许相对快速的分析。3D- qsar在分子晶格内使用基于探针的采样来确定分子的三维特性(特别是空间和静电值)，然后可以将这些3D描述符与生物活性相关联。物理化学描述，包括疏水性，拓扑结构，电子性质和空间效应等。这些描述符可以通过经验、统计或最新的计算方法来计算。qsar目前应用于许多学科，其中许多与药物设计和环境风险评估有关。关键词:QSAR，配体设计，LogP，化学信息学，对接

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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来源期刊

Open Bioinformatics Journal Computer Science-Computer Science (miscellaneous)

CiteScore

2.40

自引率

0.00%

发文量

期刊介绍： The Open Bioinformatics Journal is an Open Access online journal, which publishes research articles, reviews/mini-reviews, letters, clinical trial studies and guest edited single topic issues in all areas of bioinformatics and computational biology. The coverage includes biomedicine, focusing on large data acquisition, analysis and curation, computational and statistical methods for the modeling and analysis of biological data, and descriptions of new algorithms and databases. The Open Bioinformatics Journal, a peer reviewed journal, is an important and reliable source of current information on the developments in the field. The emphasis will be on publishing quality articles rapidly and freely available worldwide.