Comprehensive Assessment of the Regulons Controlled by the FixLJ-FixK 2 -FixK 1 Cascade in Bradyrhizobium japonicum

Abstract

ABSTRACT Symbiotic N 2 fixation in Bradyrhizobium japonicum is controlled by a complex transcription factor network. Part of it is a hierarchically arranged cascade in which the two-component regulatory system FixLJ, in response to a moderate decrease in oxygen concentration, activates the fixK 2 gene. The FixK 2 protein then activates not only a number of genes essential for microoxic respiration in symbiosis ( fixNOQP and fixGHIS ) but also further regulatory genes ( rpoN 1 , nnrR , and fixK 1 ). The results of transcriptome analyses described here have led to a comprehensive and expanded definition of the FixJ, FixK 2 , and FixK 1 regulons, which, respectively, consist of 26, 204, and 29 genes specifically regulated in microoxically grown cells. Most of these genes are subject to positive control. Particular attention was addressed to the FixK 2 -dependent genes, which included a bioinformatics search for putative FixK 2 binding sites on DNA (FixK 2 boxes). Using an in vitro transcription assay with RNA polymerase holoenzyme and purified FixK 2 as the activator, we validated as direct targets eight new genes. Interestingly, the adjacent but divergently oriented fixK 1 and cycS genes shared the same FixK 2 box for the activation of transcription in both directions. This recognition site may also be a direct target for the FixK 1 protein, because activation of the cycS promoter required an intact fixK 1 gene and either microoxic or anoxic, denitrifying conditions. We present evidence that cycS codes for a c -type cytochrome which is important, but not essential, for nitrate respiration. Two other, unexpected results emerged from this study: (i) specifically FixK 1 seemed to exert a negative control on genes that are normally activated by the N 2 fixation-specific transcription factor NifA, and (ii) a larger number of genes are expressed in a FixK 2 -dependent manner in endosymbiotic bacteroids than in culture-grown cells, pointing to a possible symbiosis-specific control.