Abstract
The beta-glucoside (bgl) operon of Escherichia coli is subject to both positive control by transcriptional termination/antitermination and negative control by the beta-glucoside-specific transport protein, an integral membrane protein known as enzyme IIBgl. Previous results led us to speculate that enzyme IIBgl exerts its negative control by phosphorylating and thereby inactivating the antiterminator protein, BglG. Specifically, our model postulated that the transport protein enzyme IIBgl exhibits protein-phosphotransferase activity in the absence of beta-glucosides. We now present biochemical evidence that the phosphorylation of protein BglG does indeed occur in vivo and that it is accompanied by the loss of antitermination activity. BglG persists in the phosphorylated state in the absence of beta-glucosides but is rapidly dephosphorylated when beta-glucosides become available for transport. Our data also suggested specific interactions between the beta-glucoside transport protein and the glucose-specific enzyme III (enzyme IIIGlc), a component of glucose transport and a key element in regulation of catabolite repression. These observations indicate that enzyme IIIGlc may, in conjunction with enzyme IIBgl, modulate the transport of beta-glucosides and the phosphorylation of the antiterminator protein. In the absence of both sugars, when the catabolite-controlled promoter of the operon is derepressed, enzyme IIIGlc may mediate tight repression of antitermination.
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