Operator DNA sequence variation enhances high affinity binding by hinge helix mutants of lactose repressor protein

The mechanism by which genetic regulatory proteins discern specific target DNA sequences remains a major area of inquiry. To explore in more detail the interplay between DNA and protein sequence, we have examined binding of variant lac operator DNA sequences to a series of mutant lactose repressor proteins (LacI). These proteins were altered in the C-terminus of the hinge region that links the N-terminal DNA binding and core sugar binding domains. Variant operators differed from the wild-type operator, O(1), in spacing and/or symmetry of the half-sites that contact the LacI N-terminal DNA binding domain. Binding of wild-type and mutant proteins was affected differentially by variations in operator sequence and symmetry. While the mutant series exhibits a 10(4)-fold range in binding affinity for O(1) operator, only a approximately 20-fold difference in affinity is observed for a completely symmetric operator, O(sym), used widely in studies of the LacI protein. Further, DNA sequence influenced allosteric response for these proteins. Binding of this LacI mutant series to other variant operator DNA sequences indicated the importance of symmetry-related bases, spacing, and the central base pair sequence in high affinity complex formation. Conformational flexibility in the DNA and other aspects of the structure influenced by the sequence may establish the binding environment for protein and determine both affinity and potential for allostery.     

The CTXphi repressor RstR binds DNA cooperatively to form tetrameric repressor-operator complexes

CTX is a filamentous bacteriophage that encodes cholera toxin and integrates into the Vibrio cholerae genome to form stable lysogens. In CTX lysogens, gene expression originating from the rstA phage promoter is repressed by the phage-encoded repressor RstR. The N-terminal region of RstR contains a helix-turn-helix DNA-binding element similar to the helix-turn-helix of the cI/Cro family of phage repressors, whereas the short C-terminal region is unrelated to the oligomerization domain of cI repressor. Purified His-tagged RstR bound to three extended 50-bp operator sites in the rstA promoter region. Each of the RstR footprints exhibited a characteristic staggered pattern of DNase I-accessible regions that suggested RstR binds DNA as a dimer-of-dimers. In gel permeation chromatography and cross-linking experiments, RstR oligomerized to form dimers and tetramers. RstR was shown to be tetrameric when bound to operator DNA by performing mobility shift experiments with mixtures of RstR and a lengthened active variant of RstR. Binding of RstR to the high affinity O1 site could be fit to a cooperative model of operator binding in which two RstR dimers associate to form tetrameric RstR-operator complexes. The binding of RstR dimers to the left or right halves of O1 operator DNA was not observed in mobility shift assays. These observations support a model in which protein-protein contacts between neighboring RstR dimers contribute to strong operator binding.     

Identification of functionally important residues in the DNA binding region of the mnt repressor

Single amino acid substitutions have been introduced throughout the N-terminal DNA binding region of the Mnt repressor, and the operator binding properties of the resulting mutant repressors have been assayed. These studies show that the side chains of Arg2, His6, Asn8, and Arg10 are critical for high affinity binding to operator DNA. Other side chains in the N-terminal region do not appear to play major roles in DNA recognition and binding. Specific alterations in the pattern of methylation protection afforded by the Arg2----Lys mutant protein suggest that Arg2 contacts the N7 groups of guanines 10 and 12 in the operator. In conjunction with previous results, these findings suggest that part of the N-terminal region of Mnt binds as an extended polypeptide strand within the major groove of the mnt operator.