Yeh Iwei, Hanekamp Theodor, Tsoka Sophia, Karp Peter D, Altman Russ B
Department of Genetics, Stanford University, Stanford, California 94305, USA.
Genome Res. 2004 May;14(5):917-24. doi: 10.1101/gr.2050304. Epub 2004 Apr 12.
Identification of novel targets for the development of more effective antimalarial drugs and vaccines is a primary goal of the Plasmodium genome project. However, deciding which gene products are ideal drug/vaccine targets remains a difficult task. Currently, a systematic disruption of every single gene in Plasmodium is technically challenging. Hence, we have developed a computational approach to prioritize potential targets. A pathway/genome database (PGDB) integrates pathway information with information about the complete genome of an organism. We have constructed PlasmoCyc, a PGDB for Plasmodium falciparum 3D7, using its annotated genomic sequence. In addition to the annotations provided in the genome database, we add 956 additional annotations to proteins annotated as "hypothetical" using the GeneQuiz annotation system. We apply a novel computational algorithm to PlasmoCyc to identify 216 "chokepoint enzymes." All three clinically validated drug targets are chokepoint enzymes. A total of 87.5% of proposed drug targets with biological evidence in the literature are chokepoint reactions. Therefore, identifying chokepoint enzymes represents one systematic way to identify potential metabolic drug targets.
鉴定新型靶点以开发更有效的抗疟药物和疫苗是疟原虫基因组计划的主要目标。然而,确定哪些基因产物是理想的药物/疫苗靶点仍然是一项艰巨的任务。目前,对疟原虫中的每一个基因进行系统性破坏在技术上具有挑战性。因此,我们开发了一种计算方法来对潜在靶点进行优先级排序。通路/基因组数据库(PGDB)将通路信息与有关生物体完整基因组的信息整合在一起。我们利用恶性疟原虫3D7的注释基因组序列构建了PlasmoCyc,这是一个针对恶性疟原虫3D7的PGDB。除了基因组数据库中提供的注释外,我们还使用GeneQuiz注释系统为注释为“假设的”蛋白质添加了956条额外注释。我们将一种新颖的计算算法应用于PlasmoCyc,以识别216种“关键酶”。所有三个经过临床验证的药物靶点都是关键酶。文献中有生物学证据的拟议药物靶点中,共有87.5%是关键反应。因此,识别关键酶是识别潜在代谢药物靶点的一种系统性方法。