In vitro reconstitution and characterization of the Rhodobacter capsulatus NtrB and NtrC two-component system.

Enhancer-dependent transcription in enteric bacteria depends upon an activator protein that binds DNA far upstream from the promoter and an alternative sigma factor (sigma 54) that binds with the core RNA polymerase at the promoter. In the photosynthetic bacterium Rhodobacter capsulatus, the NtrB and NtrC proteins (RcNtrB and RcNtrC) are putative members of a two-component system that is novel because the enhancer-binding RcNtrC protein activates transcription of sigma 54-independent promoters. To reconstitute this putative two-component system in vitro, the ReNtrB protein was overexpressed in Escherichia coli and purified as a maltose-binding protein fusion (MBP-RcNtrB). MBP-RcNtrB autophosphorylates in vitro to the same steady state level and with the same stability as the Salmonella typhimurium NtrB (StNtrB) protein but at a lower initial rate. MBP-RcNtrB autophosphorylates the S.typhimurium NtrC (St-NtrC) and RcNtrC proteins in vitro. The enteric NtrC protein is also phosphorylated in vivo by RcNtrB because plasmids that encode either RcNtrB or MBP-Rc-NtrB activate transcription of an NtrC-dependent nifL-lacZ fusion. The rate of phosphotransfer to RcNtrC and autophosphatase activity of phosphorylated RcNtrC (RcNtrC---P) are comparable to the StNtrC protein. However, the RcNtrC protein appears to be a specific RcNtrB P phosphatase since RcNtrC is not phosphorylated by small molecular weight phosphate compounds or by the StNtrB protein. RcNtrC forms a dimer in solution, and RcNtrC - P binds the upstream tandem binding sites of the g1nB promoter 4-fold better than the unphos-phorylated RcNtrC protein, presumably due to oligomerization of RcNtrC -P. Therefore, the R. capsulatus NtrB and NtrC proteins form a two-component system similar to other NtrC-like systems, where specific Rc- NtrB phosphotransfer to the RcNtrC protein results in increased oligoinerization at the enhancer but with subsequent activation of a sigma 54-independent promoter.