大肠杆菌基因调控网络的表征及其边缘重布线的拓扑增强

International Conference on Bio-inspired Information and Communications Technologies Pub Date : 2016-05-24 DOI:10.4108/EAI.3-12-2015.2262418

Satyaki Roy, V. Shah, Sajal K. Das

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引用次数: 16

摘要

长期以来，生物有机体与生俱来的弹性激发了稳健系统的设计。基因调控网络(GRN)就是这样一个生物网络，它具有一系列的拓扑特性，有助于其鲁棒性。在这项工作中，我们将大肠杆菌GRN作为三层拓扑进行研究，以表征这些特性，并解释为什么GRN特别容易受到集线器节点故障的影响。我们还在现有的大肠杆菌GRN拓扑上提出了一种边缘重布线机制，以增强其对轮毂故障的鲁棒性。通过对大肠杆菌GRN的大量实验，我们发现在边缘重新布线后，其拓扑性质得到了显著改善。最后，我们使用原始和重新布线的大肠杆菌GRN拓扑设计无线传感器网络。仿真结果表明，与原来的GRN相比，重新布线后的GRN具有更高的数据包投递率和更低的延迟。

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Characterization of E. coli Gene Regulatory Network and its Topological Enhancement by Edge Rewiring

The innate resilience of biological organisms have long inspired the design of robust systems. Gene regulatory network (GRN) is one such biological network which possesses a gamut of topological properties that contribute to its robustness. In this work, we study E. coli GRN as a three-tier topology to characterize such properties and explain why GRN is particularly vulnerable to failure of hub nodes. We also propose an edge rewiring mechanism on existing E. coli GRN topology to strengthen its robustness against hub failure. With extensive experiments on E. coli GRN, we show that its topological properties improve significantly after applying edge rewiring. Finally, we design wireless sensor networks using original and rewired E. coli GRN topologies. Simulation results indicate that rewired GRN has higher packet delivery and lower latency than original GRN.

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International Conference on Bio-inspired Information and Communications Technologies

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