Regulation of the gltBDF operon of Escherichia coli: how is a leucine-insensitive operon regulated by the leucine-responsive regulatory protein?

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J Bacteriol. 1993 November; 175(22): 7160-7169

research-article

Regulation of the gltBDF operon of Escherichia coli: how is a leucine-insensitive operon regulated by the leucine-responsive regulatory protein?

B R Ernsting, J W Denninger, R M Blumenthal and R G Matthews

Biophysics Research Division, University of Michigan, Ann Arbor 48109.

ABSTRACT

The regulon controlled by the leucine-responsive regulatoryprotein (Lrp) of Escherichia coli consists of over 40 genesand proteins whose expression is regulated, either positivelyor negatively, by Lrp. The gltBDF operon, encoding glutamatesynthase, was originally identified as a member of the Lrp regulonthrough a two-dimensional electrophoretic analysis of polypeptidesfrom isogenic strains containing or lacking a functional Lrpprotein. We have now demonstrated that Lrp regulates the transcriptionof gltBDF::lacZ operon fusions. Relative to expression in glucoseminimal 3-(N-morpholino)propanesulfonic acid (MOPS) medium,gltBDF::lacZ expression in an lrp+ strain is repressed 2.2-foldin the presence of 10 mM exogenous leucine and 16-fold in Luriabroth. Repression of gltBDF::lacZ expression by leucine or Luriabroth is not seen for an isogenic strain containing a Tn10 insertionin lrp, and expression of gltBDF::lacZ is 44-fold lower thanin the lrp+ strain when both are grown in glucose minimal MOPSmedium. Lrp binds specifically to DNA fragments containing thegltBDF promoter region. Saturating levels of leucine do notabolish binding of Lrp upstream of gltBDF but merely increaseits apparent dissociation constant from 2.0 to 6.9 nM. Electrophoreticanalysis of the Lrp regulon established that target proteinsdiffer greatly in the degree to which the effect of Lrp on theirexpression is antagonized by leucine. On the basis of our presentresults, we present a model for positive regulation of targetgenes by Lrp. Insensitivity to leucine would be expected whenthe effective intracellular concentration of Lrp is high relativeto the affinity of Lrp binding sites required for transcriptionof the target gene. At lower concentrations of Lrp, transcriptionof the target gene should be sensitive to leucine. This modelsuggests that regulation of the concentration of active Lrpis critical to control of the Lrp regulon.

J Bacteriol. 1993 November; 175(22): 7160-7169

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