Design principles for robust oscillatory behavior.

Systems and Synthetic Biology Pub Date : 2015-09-01 Epub Date: 2015-08-05 DOI:10.1007/s11693-015-9178-6
Sebastian M Castillo-Hair, Elizabeth R Villota, Alberto M Coronado
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引用次数: 12

Abstract

Oscillatory responses are ubiquitous in regulatory networks of living organisms, a fact that has led to extensive efforts to study and replicate the circuits involved. However, to date, design principles that underlie the robustness of natural oscillators are not completely known. Here we study a three-component enzymatic network model in order to determine the topological requirements for robust oscillation. First, by simulating every possible topological arrangement and varying their parameter values, we demonstrate that robust oscillators can be obtained by augmenting the number of both negative feedback loops and positive autoregulations while maintaining an appropriate balance of positive and negative interactions. We then identify network motifs, whose presence in more complex topologies is a necessary condition for obtaining oscillatory responses. Finally, we pinpoint a series of simple architectural patterns that progressively render more robust oscillators. Together, these findings can help in the design of more reliable synthetic biomolecular networks and may also have implications in the understanding of other oscillatory systems.

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稳健振荡行为的设计原则。
振荡反应在生物体的调节网络中无处不在,这一事实导致了广泛的努力来研究和复制所涉及的电路。然而,到目前为止,自然振荡器稳健性的设计原理还不完全为人所知。在这里,我们研究了一个三组分的酶网络模型,以确定鲁棒振荡的拓扑要求。首先,通过模拟每一种可能的拓扑排列和改变它们的参数值,我们证明了鲁棒振荡器可以通过增加负反馈回路和正自调节的数量来获得,同时保持正负相互作用的适当平衡。然后我们确定网络基序,其存在于更复杂的拓扑结构中是获得振荡响应的必要条件。最后,我们指出了一系列简单的架构模式,这些模式逐渐呈现出更健壮的振荡器。总之,这些发现可以帮助设计更可靠的合成生物分子网络,也可能对理解其他振荡系统有启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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