强有力的合作伙伴:拟南芥和化学基因组学。

The arabidopsis book Pub Date : 2009-01-01 Epub Date: 2009-01-21 DOI:10.1199/tab.0109
Stéphanie Robert, Natasha V Raikhel, Glenn R Hicks
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引用次数: 60

摘要

化学基因组学(即基因组学规模化学遗传学)方法利用低分子质量分子的能力来修改生物过程。这些分子被用来以一种可调节和可逆的方式修改蛋白质或途径的活性。由于化学空间中固有的结构和活动的本质上无限的变化,由正向或反向化学筛选产生的生物活性化学物质可以用于理解和剖析复杂的生物过程。作为传统植物遗传学的强大补充,这种方法的一个主要优势是化学基因组学可以解决功能丧失的致命性和冗余性。此外,化学物质的随意添加和迅速作用的能力,可以使人们研究高度动态的过程,如膜运输。有效利用小分子的一个重要方面是详细表征生物活性化学物质,包括对结构-活性关系的理解以及活性和非活性类似物的鉴定。生物活性化学物质可以作为试剂直接探测生物途径。然而,同源靶点及其途径的鉴定也提供了信息,可以通过筛选拟南芥或其他生物的遗传抗性或超敏性来实现,这些结果可以转化为植物。此外,还有利用“标记”化学文库的方法,这些化学文库具有允许固定活性化合物的活性部分。这为假定同源目标的生化纯化提供了可能。我们将回顾筛选影响拟南芥生物过程的生物活性化学物质的方法,并提供几个例子,说明这种新方法在植物生物学中的力量和固有的挑战。
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Powerful partners: Arabidopsis and chemical genomics.

Chemical genomics (i.e. genomics scale chemical genetics) approaches capitalize on the ability of low molecular mass molecules to modify biological processes. Such molecules are used to modify the activity of a protein or a pathway in a manner that it is tunable and reversible. Bioactive chemicals resulting from forward or reverse chemical screens can be useful in understanding and dissecting complex biological processes due to the essentially limitless variation in structure and activities inherent in chemical space. A major advantage of this approach as a powerful addition to conventional plant genetics is the fact that chemical genomics can address loss-of-function lethality and redundancy. Furthermore, the ability of chemicals to be added at will and to act quickly can permit the study of processes that are highly dynamic such as endomembrane trafficking. An important aspect of utilizing small molecules effectively is to characterize bioactive chemicals in detail including an understanding of structure-activity relationships and the identification of active and inactive analogs. Bioactive chemicals can be useful as reagents to probe biological pathways directly. However, the identification of cognate targets and their pathways is also informative and can be achieved by screens for genetic resistance or hypersensitivity in Arabidopsis thaliana or other organisms from which the results can be translated to plants. In addition, there are approaches utilizing "tagged" chemical libraries that possess reactive moieties permitting the immobilization of active compounds. This opens the possibility for biochemical purification of putative cognate targets. We will review approaches to screen for bioactive chemicals that affect biological processes in Arabidopsis and provide several examples of the power and challenges inherent in this new approach in plant biology.

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