利用代谢途径结构揭示高阶上位性。

Exploiting the pathway structure of metabolism to reveal high-order epistasis.

作者信息

Imielinski Marcin, Belta Calin

机构信息

Center for Applied Genomics, Children's Hospital of Philadelphia, Philadelphia, USA.

出版信息

BMC Syst Biol. 2008 Apr 30;2:40. doi: 10.1186/1752-0509-2-40.

DOI:10.1186/1752-0509-2-40

PMID:18447928

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2390508/

Abstract

BACKGROUND

Biological robustness results from redundant pathways that achieve an essential objective, e.g. the production of biomass. As a consequence, the biological roles of many genes can only be revealed through multiple knockouts that identify a set of genes as essential for a given function. The identification of such "epistatic" essential relationships between network components is critical for the understanding and eventual manipulation of robust systems-level phenotypes.

RESULTS

We introduce and apply a network-based approach for genome-scale metabolic knockout design. We apply this method to uncover over 11,000 minimal knockouts for biomass production in an in silico genome-scale model of E. coli. A large majority of these "essential sets" contain 5 or more reactions, and thus represent complex epistatic relationships between components of the E. coli metabolic network.

CONCLUSION

The complex minimal biomass knockouts discovered with our approach illuminate robust essential systems-level roles for reactions in the E. coli metabolic network. Unlike previous approaches, our method yields results regarding high-order epistatic relationships and is applicable at the genome-scale.

摘要

背景

生物稳健性源于实现基本目标（如生物量产生）的冗余途径。因此，许多基因的生物学作用只能通过多重敲除来揭示，这些敲除将一组基因确定为特定功能所必需的。识别网络组件之间这种“上位性”必需关系对于理解和最终操纵稳健的系统水平表型至关重要。

结果

我们引入并应用了一种基于网络的方法进行全基因组规模的代谢敲除设计。我们将此方法应用于在大肠杆菌的计算机全基因组规模模型中发现超过11000个用于生物量产生的最小敲除。这些“必需集”中的绝大多数包含5个或更多反应，因此代表了大肠杆菌代谢网络组件之间复杂的上位性关系。

结论

我们的方法发现的复杂最小生物量敲除揭示了大肠杆菌代谢网络中反应的稳健必需系统水平作用。与以前的方法不同，我们的方法产生了关于高阶上位性关系的结果，并且适用于全基因组规模。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1c3f/2390508/fc11021136f2/1752-0509-2-40-1.jpg

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利用代谢途径结构揭示高阶上位性。

Exploiting the pathway structure of metabolism to reveal high-order epistasis.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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