控制细菌生理以实现基因报告构建体的最佳表达。

Controlling bacterial physiology for optimal expression of gene reporter constructs.

作者信息

Marqués Silvia, Aranda-Olmedo Isabel, Ramos Juan L

机构信息

Department of Biochemistry and Molecular and Cellular Biology of Plants, Estación Experimental del Zaidín, Consejo Superior de Investigaciones Científicas, Apartado de Correos 419, E-18008, Granada, Spain.

出版信息

Curr Opin Biotechnol. 2006 Feb;17(1):50-6. doi: 10.1016/j.copbio.2005.12.001. Epub 2005 Dec 15.

DOI:10.1016/j.copbio.2005.12.001

PMID:16359853

Abstract

Bacterial biosensors for the detection of pollutants are based on the regulatory elements that control the corresponding degradation pathways. An increasing number of catabolic pathways under the control of specific regulators are now known to be influenced by the presence of alternative carbon sources, which to different extents repress expression of the pathway despite the presence of the inducer. The molecular basis underlying the control of each catabolic pathway is different, although all sense a high energy state of the cell resulting from the presence of more favourable carbon sources. Biosensor tests mimicking field conditions point to global regulation being relevant for biosensor performance; thus, this global regulation must be taken into account when designing whole-cell biosensors.

摘要

用于检测污染物的细菌生物传感器基于控制相应降解途径的调控元件。现在已知越来越多受特定调控因子控制的分解代谢途径会受到替代碳源的影响，尽管存在诱导物，但这些替代碳源在不同程度上会抑制该途径的表达。尽管所有分解代谢途径都能感知到由于存在更有利的碳源而导致的细胞高能状态，但每条途径控制的分子基础是不同的。模拟现场条件的生物传感器测试表明，全局调控与生物传感器性能相关；因此，在设计全细胞生物传感器时必须考虑这种全局调控。

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控制细菌生理以实现基因报告构建体的最佳表达。

Controlling bacterial physiology for optimal expression of gene reporter constructs.

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