Two helix DNA binding motif of CAP found in lac repressor and gal repressor.

Comparison of both the DNA and protein sequences of catabolite gene activator protein (CAP) with the sequences of lac and gal repressors shows significant homologies between a sequence that forms a two alpha-helix motif in CAP and sequences near the amino terminus of both repressors. This two-helix motif is thought to be involved in specific DNA sequence recognition by CAP. The region in lac repressor to which CAP is homologous contains many i-d mutations that are defective in DNA binding. Less significant sequence homologies between CAP and phage repressors and activators are also shown. The amino acid residues that are critical to the formation of the two-helix motif are conserved, while those residues expected to interact with DNA are variable. These observations suggest the lac and gal repressors also have a two alpha-helix structural motif which is involved in DNA binding and that this two helix motif may be generally found in many bacterial and phage repressors. We conclude that one major mechanism by which proteins can recognize specific base sequences in double stranded DNA is via the amino acid side chains of alpha-helices fitting into the major groove of B-DNA.     

Mutants of the lac promoter with large insertions and deletions between the CAP binding site and the -35 region

A set of the lac promoter mutants that have varying lengths of the spacer between the CAP binding site and the -35 region was constructed. The mutants have the spacer length increased by five (I5 mutant), or eleven (I11) residues or decreased by eleven residues (D11). We also present a construction of the hybrid between the gal and lac promoters in which the CAP binding site and the -35 region of the gal promoter are fused to the lac -10 region. The promoter fragments were assembled through ligations of chemically synthesized oligodeoxynucleotides and cloned into a pBR322-derivative vector. The results of the in vivo assays of promoter activity show that the I11 mutation results in an active but weak promoter that can be stimulated by CAP, though to a lesser degree than the wild-type lac promoter. The other mutants exhibit no promoter activity. Since the insertion of 11-bp preserves the location of the CAP binding site on the same side on the DNA helix, the data demonstrate the importance of spatial alignment between the CAP binding site and the promoter. The fact that the gal::lac hybrid is inactive as a promoter indicates also that catabolite activation is a highly complex process in which the -35 and -10 regions cannot be easily exchanged between promoters.     

Regulation of open complex formation at the Escherichia coli galactose operon promoters. Simultaneous interaction of RNA polymerase, gal repressor and CAP/cAMP.

The regulation of open complex formation at the Escherichia coli galactose operon promoters by galactose repressor and catabolite activator protein/cyclic AMP (CAP/cAMP) was investigated in DNA-binding and kinetic experiments performed in vitro. We found that gal repressor and CAP/cAMP bind to the gal regulatory region independently, resulting in simultaneous occupancy of the two gal operators and the CAP/cAMP binding site. Both CAP/cAMP and gal repressor altered the partitioning of RNA polymerase between the two overlapping gal promoters. Open complexes formed in the absence of added regulatory proteins were partitioned between gal P1 and P2 with occupancies of 25% and 75%, respectively. CAP/cAMP caused open complexes to be formed nearly exclusively at P1 (98% occupancy). gal repressor caused a co-ordinated, but incomplete, switch in promoter partitioning from P1 to P2 in both the absence and presence of CAP/cAMP. We measured the kinetic constants governing open complex formation and decay at the gal promoters in the absence and presence of gal repressor and CAP/cAMP. CAP/cAMP had the largest effect on the kinetics of open complex formation, resulting in a 30-fold increase in the apparent binding constant. We conclude that the regulation of open complex formation at the gal promoters does not result from competition between gal repressor, CAP/cAMP and RNA polymerase for binding at the gal operon regulatory region, but instead results from the interactions of the three proteins during the formation of a nucleoprotein complex on the gal DNA fragment. Finally, we present a kinetic model for the regulation of open complex formation at the gal operon.     

Comparison of the binding sites for the Escherichia coli cAMP receptor protein at the lactose and galactose promoters

Polyacrylamide gel electrophoresis has been used to visualise and quantitate complexes between the Escherichia coli cyclic AMP receptor protein (CRP) and DNA fragments containing the promoter region of either the E. coli galactose or lactose operons. We show that, although CRP binding to the gal fragment is weaker than binding to the lac fragment, in each case, stable complexes are formed between one dimer of CRP and one molecule of DNA. We have examined the effects of a series of deletions and point mutations in the gal promoter region on CRP binding. From the position of deletions and mutations which prevent the formation of stable complexes, we deduce the location and extent of the sequence at the CRP binding site. We show that it covers approximately the same length of sequence as the binding site at the lac promoter. Unlike the lac site, the gal site contains no palindromic sequence. We discuss the importance of symmetry in the sequence at CRP binding sites and the validity of CRP binding consensus sequences which have been proposed.     

NMR study of the structural changes induced in the E. coli lac promoter by the specific binding of the CAP protein.

We have studied the binding of the CAP protein to an 18 base pair lac promoter sequence comprising the core of the CAP recognition sequence. Specific binding of this sequence was established by competition binding assays and comparison of the relative affinities of a number of lac promoter, lac operator, and unspecific sequences of different lengths. The effect of the binding of CAP to the 18 base pair promoter sequence and, for comparison, to an 18 base pair symmetric operator and an oligonucleotide of unrelated sequence have been studied by 1H NMR. Binding of CAP does not bring about any changes in the chemical shift values of the imino proton resonances of the DNA, but causes the selective line broadening of two of the resonances. The comparison of these data with results of gel retardation assays published previously (1) allows the identification and localization of a kink induced in the DNA by the CAP binding to its specific site on the lac promoter.     

CAP binding sites reveal pyrimidine-purine pattern characteristic of DNA bending

To investigate the intrinsic bending of DNA at sites where proteins bind, we analyzed catabolite gene activator protein (CAP) binding sites and various operators from the viewpoint of DNA bending flexibility. Theoretical conformational analysis. DNase I digestion and x-ray crystallography data indicate that bending of B-DNA is highly anisotropic and sequence-dependent. Certain dimers prefer to bend into the major groove ("major-philic") and others prefer to bend into the minor groove ("minor-philic" dimers). From these data we considered TA, CG, CA:TG and GG:CC as major-philic dimers and AT,AA:TT and GT:AC as minor-philic ones. Analysis of 31 CAP binding sites has identified strong major-philic tendencies 5-7 base pairs (bp) away from the center. In addition, we found minor-philic poly-A tracts extending 4-5 bp away from the proposed major-philic bends. Finally, to analyze the central regions we followed the lead of Shumilov and classified the DNA sites by their spacer lengths [V.Y. Shumilov, Mol. Biol. (Mosk) 21, 168-187 (1987)]. In this way, we identified two subsets of CAP binding sites: one with 6 bp between the TGTGA:TCACA consensus boxes (N6-set) and one with 8 central bp (N8-set). We discovered that the dimer at the center of an N6-set site was usually major-philic, whereas at the center of an N8-set site more often minor-philic. Analysis of phages 434, P22 lambda and trp operators revealed similar results. In conclusion, our data show that CAP binding sites have major-philic and minor-philic dimers at specific positions; the location of these dimers may facilitate wrapping of DNA around CAP. A similar pattern is seen in nucleosomes.     

The catabolite activator protein stabilizes its binding site in the E. coli lactose promoter.

The effect of catabolite activator protein, CAP, on the thermal stability of DNA was examined. Site specific binding was studied with a 62 bp DNA restriction fragment containing the primary CAP site of the E. coli lactose (lac) promoter. A 144 bp DNA containing the lac promoter region and a 234 bp DNA from the pBR322 plasmid provided other DNA sites. Thermal denaturation of protein-DNA complexes was carried out in a low ionic strength solvent with 40% dimethyl sulfoxide, DMSO. In this solvent free DNA denatured below the denaturation temperature of CAP. The temperature stability of CAP for site specific binding was monitored using an acrylamide gel electrophoresis assay. Results show that both specific and non-specific CAP binding stabilize duplex DNA. Site specific binding to the 62 bp DNA produced a 13.3 degrees C increase in the transition under conditions where non-specific binding stabilized this DNA by 2-3 degrees C.     

CAP Binding Sites Reveal Pyrimidine-Purine Pattern Characteristic of DNA Bending

Abstract

To investigate the intrinsic bending of DNA at sites where proteins bind, we analyzed catabolite gene activator protein (CAP) binding sites and various operators from the viewpoint of DNA bending flexibility. Theoretical conformational analysis, DNase I digestion and x-ray crystallography data indicate that bending of B-DNA is highly anisotropic and sequence-dependent. Certain dimers prefer to bend into the major groove (“major-philic”) and others prefer to bend into the minor groove (“minor-philic” dimers). From these data we considered TA CG, CA:TG and GG:CC as major-philic dimers and AT, AA:TT and GT:AC as minor-philic ones.

Analysis of 31 CAP binding sites has identified strong major-philic tendencies 5–7 base pairs (bp) away from the center. In addition, we found minor-philic poly-A tracts extending 4–5 bp away from the proposed major-philic bends. Finally, to analyze the central regions we followed the lead of Shumilov and classified the DNA sites by their spacer lengths [V.Y. Shumilov, Mol. Biol. (Mosk) 21, 168–187 (1987)]. In this way, we identified two subsets of CAP binding sites: one with 6 bp between the TGTGA:TCACA consensus boxes (N6-set) and one with 8 central bp (N8-set). We discovered that the dimer at the center of an N6-set site was usually major-philic, whereas at the center of an N8-set site more often minor-philic. Analysis of phages 434, P22, λ and trp operators revealed similar results.

In conclusion, our data show that CAP binding sites have major-philic and minor-philic dimers at specific positions; the location of these dimers may facilitate wrapping of DNA around CAP. A similar pattern is seen in nucleosomes.