环境pH感知:解析根癌土壤杆菌致病过程中VirA/VirG双组分系统的输入信号
Environmental pH sensing: resolving the VirA/VirG two-component system inputs for Agrobacterium pathogenesis.
作者信息
Gao Rong, Lynn David G
机构信息
Center for Fundamental and Applied Molecular Evolution, Department of Chemistry, Emory University, Atlanta, GA 30322, USA.
出版信息
J Bacteriol. 2005 Mar;187(6):2182-9. doi: 10.1128/JB.187.6.2182-2189.2005.
Abstract
Agrobacterium tumefaciens stands as one of biotechnology's greatest successes, with all plant genetic engineering building on the strategies of this pathogen. By integrating responses to external pHs, phenols, and monosaccharides, this organism mobilizes oncogenic elements to efficiently transform most dicotyledonous plants. We now show that the complex signaling network used to regulate lateral gene transfer can be resolved as individual signaling modules. While pH and sugar perception are coupled through a common pathway, requiring both low pH and sugar for maximal virulence gene expression, various VirA and ChvE alleles can decouple pH and monosaccharide perception. This VirA and ChvE system may represent a common mechanism that underpins external pH perception in prokaryotes, and the use of these simple genetic elements may now be extended to research on specific responses to changes in environmental pH.
摘要
根癌土壤杆菌是生物技术领域最成功的案例之一,所有植物基因工程都基于这种病原体的策略。通过整合对外部pH值、酚类和单糖的反应,这种生物体调动致癌元件以有效地转化大多数双子叶植物。我们现在表明,用于调节横向基因转移的复杂信号网络可以分解为单个信号模块。虽然pH值和糖的感知通过共同途径耦合,需要低pH值和糖才能实现最大毒力基因表达,但各种VirA和ChvE等位基因可以使pH值和单糖感知解耦。这种VirA和ChvE系统可能代表了原核生物中外部pH值感知的共同机制,现在这些简单遗传元件的应用可能会扩展到对环境pH值变化的特定反应的研究中。
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