Mapping of microbial pathways through constrained mapping of orthologous genes.

Victor Olman, Hanchuan Peng, Zhengchang Su, Ying Xu
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Abstract

We present a novel computer algorithm for mapping biological pathways from one prokaryotic genome to another. The algorithm maps genes in a known pathway to their homologous genes (if any) in a target genome that is most consistent with (a) predicted orthologous gene relationship, (b) predicted operon structures, and (c) predicted co-regulation relationship of operons. Mathematically, we have formulated this problem as a constrained minimum spanning tree problem (called a Steiner network problem), and demonstrated that this formulation has the desired property through applications. We have solved this mapping problem using a combinatorial optimization algorithm, with guaranteed global optimality. We have implemented this algorithm as a computer program, called PMAP. Our test results on pathway mapping are highly encouraging -- we have mapped a number of pathways of H. influenzae, B. subtilis, H. pylori, and M. tuberculosis to E. coli using P-MAP, whose homologous pathways in E coli. are known and hence the mapping accuracy could be checked. We have then mapped known E. coli pathways in the EcoCyc database to the newly sequenced organism Synechococcus sp WH8102, and predicted 158 Synechococcus pathways. Detailed analyses on the predicted pathways indicate that P-MAP's mapping results are consistent with our general knowledge about (local) pathways. We believe that P-MAP will be a useful tool for microbial genome annotation projects and inference of individual microbial pathways.

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通过限制同源基因的定位来定位微生物途径。
我们提出了一种新的计算机算法来绘制从一个原核生物基因组到另一个原核生物基因组的生物路径。该算法将已知途径中的基因映射到目标基因组中的同源基因(如果有的话),这些基因与(a)预测的同源基因关系,(b)预测的操纵子结构,以及(c)预测的操纵子共调控关系最一致。在数学上,我们将这个问题表述为一个约束最小生成树问题(称为Steiner网络问题),并通过应用证明了这个表述具有期望的性质。我们用组合优化算法解决了这个映射问题,保证了全局最优性。我们已经将这个算法实现为一个计算机程序,称为PMAP。我们在路径绘制方面的测试结果非常鼓舞人心——我们使用P-MAP绘制了流感嗜血杆菌、枯草芽孢杆菌、幽门螺杆菌和结核分枝杆菌到大肠杆菌的许多路径,而P-MAP在大肠杆菌中的同源路径。是已知的,因此可以检查映射的准确性。然后,我们将EcoCyc数据库中已知的大肠杆菌途径映射到新测序的生物体粘球菌sp WH8102,并预测了158种粘球菌途径。对预测路径的详细分析表明,P-MAP的映射结果与我们对(局部)路径的一般认识一致。我们相信P-MAP将成为微生物基因组注释项目和个体微生物途径推断的有用工具。
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