Multi-bit Boolean model for chemotactic drift of Escherichia coli

IF 1.9 4区生物学 Q4 CELL BIOLOGY

IET Systems Biology Pub Date : 2020-10-16 DOI:10.1049/iet-syb.2020.0060

Anuj Deshpande, Sibendu Samanta, Sutharsan Govindarajan, Ritwik Kumar Layek

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Abstract

Dynamic biological systems can be modelled to an equivalent modular structure using Boolean networks (BNs) due to their simple construction and relative ease of integration. The chemotaxis network of the bacterium Escherichia coli (E. coli ) is one of the most investigated biological systems. In this study, the authors developed a multi-bit Boolean approach to model the drifting behaviour of the E. coli chemotaxis system. Their approach, which is slightly different than the conventional BNs, is designed to provide finer resolution to mimic high-level functional behaviour. Using this approach, they simulated the transient and steady-state responses of the chemoreceptor sensory module. Furthermore, they estimated the drift velocity under conditions of the exponential nutrient gradient. Their predictions on chemotactic drifting are in good agreement with the experimental measurements under similar input conditions. Taken together, by simulating chemotactic drifting, they propose that multi-bit Boolean methodology can be used for modelling complex biological networks. Application of the method towards designing bio-inspired systems such as nano-bots is discussed.

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大肠杆菌趋化漂移的多比特布尔模型

由于布尔网络结构简单，易于集成，动态生物系统可以用布尔网络(BNs)建模为等效的模块化结构。大肠杆菌(E. coli)的趋化网络是研究最多的生物系统之一。在这项研究中，作者开发了一种多比特布尔方法来模拟大肠杆菌趋化系统的漂移行为。他们的方法与传统的神经网络略有不同，旨在提供更精细的分辨率来模拟高级功能行为。利用这种方法，他们模拟了化学感受器感觉模块的瞬态和稳态反应。此外，他们估计了指数营养梯度条件下的漂移速度。在相似的输入条件下，他们对趋化漂移的预测与实验结果很好地吻合。总之，通过模拟趋化漂移，他们提出多比特布尔方法可用于模拟复杂的生物网络。讨论了该方法在设计纳米机器人等仿生系统中的应用。

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来源期刊

IET Systems Biology 生物-数学与计算生物学

CiteScore

4.20

自引率

4.30%

发文量

审稿时长

>12 weeks

期刊介绍： IET Systems Biology covers intra- and inter-cellular dynamics, using systems- and signal-oriented approaches. Papers that analyse genomic data in order to identify variables and basic relationships between them are considered if the results provide a basis for mathematical modelling and simulation of cellular dynamics. Manuscripts on molecular and cell biological studies are encouraged if the aim is a systems approach to dynamic interactions within and between cells. The scope includes the following topics: Genomics, transcriptomics, proteomics, metabolomics, cells, tissue and the physiome; molecular and cellular interaction, gene, cell and protein function; networks and pathways; metabolism and cell signalling; dynamics, regulation and control; systems, signals, and information; experimental data analysis; mathematical modelling, simulation and theoretical analysis; biological modelling, simulation, prediction and control; methodologies, databases, tools and algorithms for modelling and simulation; modelling, analysis and control of biological networks; synthetic biology and bioengineering based on systems biology.