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Modeling suggests that gene circuit architecture controls phenotypic variability in a bacterial persistence network

机译：建模表明基因电路架构可控制细菌持久性网络中的表型变异

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BackgroundBacterial persistence is a non-inherited bet-hedging mechanism where a subpopulation of cells enters a dormant state, allowing those cells to survive environmental stress such as treatment with antibiotics. Persister cells are not mutants; they are formed by natural stochastic variation in gene expression. Understanding how regulatory architecture influences the level of phenotypic variability can help us explain how the frequency of persistence events can be tuned.

机译：背景技术细菌持久性是一种非继承性的对冲机制，其中一部分细胞进入休眠状态，从而使这些细胞能够在环境压力下生存，例如使用抗生素进行处理。持久性细胞不是突变体。它们是由基因表达的自然随机变化形成的。了解调节体系结构如何影响表型变异性的水平可以帮助我们解释如何调整持续事件的频率。

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期刊名称 BMC Systems Biology
作者
Rachel S Koh; Mary J Dunlop;
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作者单位

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年(卷),期 2012(6),-1
年度 2012
页码 47
总页数 9
原文格式 PDF
正文语种
中图分类生物学;
关键词
Persister Toxin-antitoxin Gene regulatory network Feedback;

机译：顾问;毒素-抗毒素;基因调控网络;反馈;

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1. Modeling suggests that gene circuit architecture controls phenotypic variability in a bacterial persistence network [J] . Rachel S Koh, Mary J Dunlop BMC Systems Biology . 2012,第1期

机译：建模表明基因电路架构可控制细菌持久性网络中的表型变异
2. Modelling the effects of cell-to-cell variability on the output of interconnected gene networks in bacterial populations [J] . Nicolò Politi, Lorenzo Pasotti, Susanna Zucca, BMC Systems Biology . 2015,第SUPPLEMENTa3期

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3. A Domain-specific Rule Generation Using Model-Driven Architecture in Controlled Variability Model [J] . Neel Mani, Markus Helfert, Claus Pahl Procedia Computer Science . 2017,第1期

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7. Modeling suggests that gene circuit architecture controls phenotypic variability in a bacterial persistence network [O] . Rachel S Koh, Mary J Dunlop 2012

机译：建模表明基因电路架构可控制细菌持久性网络中的表型变异

Modeling suggests that gene circuit architecture controls phenotypic variability in a bacterial persistence network

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