Freeman J A, Lilley B N, Bassler B L
Department of Molecular Biology, Princeton University, Princeton, NJ 08544-1014, USA.
Mol Microbiol. 2000 Jan;35(1):139-49. doi: 10.1046/j.1365-2958.2000.01684.x.
The bioluminescent marine bacterium Vibrio harveyi controls light production using two parallel quorum-sensing systems. V. harveyi produces two autoinducers (AI-1 and AI-2), which are recognized by cognate membrane-bound two-component hybrid sensor kinases called LuxN and LuxQ respectively. Under conditions of low cell density, in the absence of autoinducer, the hybrid sensors are kinases, and under conditions of high cell density, in the presence of autoinducer, the sensors are phosphatases. These activities allow LuxN and LuxQ to modulate the level of phosphorylation of the response regulator protein LuxO. LuxO, in turn, controls the transcription of the genes encoding luciferase. The phosphorelay protein LuxU is required for signalling to LuxO. In this report, we present a genetic analysis of the activities of the AI-1 sensor LuxN. Point mutations and in frame deletions were constructed in luxN and recombined onto the chromosome of V. harveyi for in vivo phenotypic analysis. We show that the conserved histidine (H471) in the sensor kinase domain of LuxN is required for kinase activity but not for phosphatase activity. In contrast, the conserved aspartate (D771) in the response regulator domain of LuxN is required for both activities. Furthermore, the LuxN phosphatase activity is localized to the response regulator domain. Our results indicate that the LuxN kinase activity is regulated by the presence of AI-1, whereas the LuxN phosphatase activity is constitutive. We also show that signalling from the two V. harveyi quorum-sensing systems is not equivalent. AI-1 and LuxN have a much greater effect on the level of LuxO phosphate and therefore Lux expression than do AI-2 and LuxQ.
发光海洋细菌哈氏弧菌利用两个平行的群体感应系统来控制发光。哈氏弧菌产生两种自诱导物(AI-1和AI-2),它们分别被同源的膜结合双组分杂交传感器激酶LuxN和LuxQ识别。在低细胞密度条件下,不存在自诱导物时,杂交传感器是激酶;在高细胞密度条件下,存在自诱导物时,传感器是磷酸酶。这些活性使LuxN和LuxQ能够调节反应调节蛋白LuxO的磷酸化水平。反过来,LuxO控制编码荧光素酶的基因的转录。磷传递蛋白LuxU是向LuxO发出信号所必需的。在本报告中,我们对AI-1传感器LuxN的活性进行了遗传分析。在luxN中构建了点突变和框内缺失,并将其重组到哈氏弧菌的染色体上进行体内表型分析。我们表明,LuxN传感器激酶结构域中保守的组氨酸(H471)是激酶活性所必需的,但不是磷酸酶活性所必需的。相反,LuxN反应调节结构域中保守的天冬氨酸(D771)是两种活性所必需的。此外,LuxN磷酸酶活性定位于反应调节结构域。我们的结果表明,LuxN激酶活性受AI-1的存在调节,而LuxN磷酸酶活性是组成型的。我们还表明,来自哈氏弧菌两个群体感应系统的信号并不等同。与AI-2和LuxQ相比,AI-1和LuxN对LuxO磷酸盐水平以及因此对Lux表达的影响要大得多。
