Catabolite Repression of the TodS/TodT Two-Component System and Effector-Dependent Transphosphorylation of TodT as the Basis for Toluene Dioxygenase Catabolic Pathway Control

Abstract

ABSTRACT The TodS/TodT two-component system of Pseudomonas putida regulates the expression of the toluene dioxygenase ( tod ) operon for the metabolism of toluene, benzene, and ethylbenzene. The sensor kinase TodS has a complex domain arrangement containing two functional modules, each harboring a sensor and an autokinase domain separated by a receiver domain. The TodT protein is the cognate response regulator that activates transcription of the toluene dioxygenase (TOD) pathway genes at the P todX promoter. We report in this study that the todST operon is transcribed from a main promoter and that the +1 initiation point is located 31 nucleotides upstream from the A of the first ATG codon and is preceded by a −10/−35 canonical promoter. Expression from P todS is under catabolite control, and in cells growing with glucose, the level of expression from this promoter is reduced, which in turn translates to low levels of the TodS/TodT regulators and results in a decrease of transcription from the P todX promoter. Thus, the main underlying regulatory mechanisms of the tod structural genes are at the levels of catabolite repression control from P todS and transcription activation, mediated by the TodT response regulator through a regulatory cascade in which the effector enhances autophosphorylation of TodS by ATP, with subsequent transphosphorylation of TodT.