Department of Biotechnology, Norwegian University of Science and Technology, Sem Sælands Vei 6/8, Trondheim N-7491, Norway.
BMC Microbiol. 2013 Nov 19;13:262. doi: 10.1186/1471-2180-13-262.
XylS is the positive regulator of the inducible Pm promoter, originating from Pseudomonas putida, where the system controls a biochemical pathway involved in degradation of aromatic hydrocarbons, which also act as inducers. The XylS/Pm positive regulator/promoter system is used for recombinant gene expression and the output from Pm is known to be sensitive to the intracellular XylS concentration.
By constructing a synthetic operon consisting of xylS and luc, the gene encoding luciferase, relative XylS expression levels could be monitored indirectly at physiological concentrations. Expression of XylS from inducible promoters allowed control over a more than 800-fold range, however, the corresponding output from Pm covered only an about five-fold range. The maximum output from Pm could not be increased by introducing more copies of the promoter in the cells. Interestingly, a previously reported XylS variant (StEP-13), known to strongly stimulate expression from Pm, caused the same maximum activity from Pm as wild-type XylS at high XylS expression levels. Under uninduced conditions expression from Pm also increased as a function of XylS expression levels, and at very high concentrations the maximum activity from Pm was the same as in the presence of inducer.
According to our proposed model, which is in agreement with current knowledge, the regulator, XylS, can exist in three states: monomers, dimers, and aggregates. Only the dimers are active and able to induce expression from Pm. Their maximum intracellular concentration and the corresponding output from Pm are limited by the concentration-dependent conversion into inactive aggregates. Maximization of the induction ratio at Pm can be obtained by expression of XylS at the level where aggregation occurs, which might be exploited for recombinant gene expression. The results described here also indicate that there might exist variants of XylS which can exist at higher active dimer concentrations and thus lead to increased expression levels from Pm.
XylS 是诱导型 Pm 启动子的正调控因子,来源于恶臭假单胞菌,该系统控制着参与降解芳香烃的生物化学途径,芳香烃也可作为诱导物。XylS/Pm 正调控因子/启动子系统用于重组基因表达,已知 Pm 的输出对细胞内 XylS 浓度敏感。
通过构建由 xylS 和 luc 基因编码荧光素酶的合成操纵子,可在生理浓度下间接监测相对 XylS 表达水平。诱导型启动子表达 XylS 可使表达水平控制在 800 倍以上,但 Pm 的相应输出仅覆盖约 5 倍的范围。在细胞中引入更多的启动子并不能增加 Pm 的最大输出。有趣的是,一种先前报道的 XylS 变体(StEP-13),已知可强烈刺激 Pm 的表达,在高 XylS 表达水平下,其 Pm 的最大活性与野生型 XylS 相同。在未诱导条件下,Pm 的表达也随 XylS 表达水平的增加而增加,在非常高的浓度下,Pm 的最大活性与诱导剂存在时相同。
根据我们提出的模型,与当前知识一致,该调节剂 XylS 可以存在于三种状态:单体、二聚体和聚集体。只有二聚体是活跃的,能够诱导 Pm 的表达。它们的最大细胞内浓度和 Pm 的相应输出受浓度依赖性转化为非活性聚集体的限制。通过在发生聚集的水平上表达 XylS,可以获得 Pm 的诱导比最大化,这可能被用于重组基因表达。这里描述的结果还表明,可能存在 XylS 的变体,其可以以更高的活性二聚体浓度存在,从而导致 Pm 的表达水平增加。