Modulation of monomer conformation of the BglG transcriptional antiterminator from Escherichia coli.

Abstract

The BglG protein positively regulates expression of the bgl operon in Escherichia coli by binding as a dimer to the bgl transcript and preventing premature termination of transcription in the presence of beta-glucosides. BglG activity is negatively controlled by BglF, the beta-glucoside phosphotransferase, which reversibly phosphorylates BglG according to beta-glucoside availability, thus modulating its dimeric state. BglG consists of an RNA-binding domain and two homologous domains, PRD1 and PRD2. Based on structural studies of a BglG homologue, the two PRDs fold similarly, and the interactions within the dimer are PRD1-PRD1 and PRD2-PRD2. We have recently shown that the affinity between PRD1 and PRD2 of BglG is high, and a fraction of the BglG monomers folds in the cell into a compact conformation, in which PRD1 and PRD2 are in close proximity. We show here that both BglG forms, the compact and noncompact, bind to the active site-containing domain of BglF, IIB(bgl), in vitro. The interaction of BglG with IIB(bgl) or BglF is mediated by PRD2. Both BglG forms are detected as phosphorylated proteins after in vitro phosphorylation with IIB(bgl) and are dephosphorylated by BglF in vitro in the presence of beta-glucosides. Nevertheless, genetic evidence indicates that the interaction of IIB(bgl) and BglF with the compact form is seemingly less favorable. Using in vivo cross-linking, we show that BglF enhances folding of BglG into a compact conformation, whereas the addition of beta-glucosides reduces the amount of this form. Based on these results we suggest a model for the modulation of BglG conformation and activity by BglF.