Interaction of the bacteriophage P22 Arc repressor with operator DNA

Are repressor binds to a single, partially symmetric, 21 base-pair operator site that is centered between the -10 and -35 regions of the Pant promoter. Protection and interference experiments show that Arc makes contacts with the operator on one side of the DNA helix. Although Arc is a small protein (53 residues/subunit), it makes contacts that are farther from the center of the operator than those made by many larger repressors. These extended contacts include the phosphate groups at the ends of the 21 base-pair site. Under standard conditions (pH 7.5, 100 mM-KCl, 3 mM-MgCl2, 22 degrees C) half-maximal operator binding is observed at an Arc concentration of 2.5 X 10(-9) M and the protein-DNA complex is very stable (t1/2 approximately equal to 80 min).     

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.     

The Arc and Mnt repressors. A new class of sequence-specific DNA-binding protein

Genetic, biochemical, and biophysical studies have begun to reveal details of the structures of Arc and Mnt and show that these repressors use residues at their N-terminal ends for operator recognition and binding. Some of the DNA contacts made by these residues have been identified, and this information together with NMR studies has permitted the construction of models of the DNA binding region. Although the accuracy of these models remains to be determined, it seems clear that Arc and Mnt are members of a new class of DNA-binding proteins.     

Biochemical and genetic analysis of operator contacts made by residues within the beta-sheet DNA binding motif of Mnt repressor.

Residues 2, 6, 8 and 10 of Mnt repressor are the major determinants of operator DNA binding and recognition. Here, we investigate the interaction of wild-type Mnt and mutants bearing the Arg2----Lys, His6----Ala, Asn8----Ala and Arg10----Lys mutations with operator DNA modified by methylation or by symmetric base substitutions. The wild-type pattern of methylation interference is altered in specific ways for each of the mutant proteins. In addition, some of the mutant proteins show a 'loss of contact' phenotype with specific mutant operators. Taken together, these and previous results predict the following contacts between side chains in the Mnt tetramer and operator DNA: Arg2 recognizes the guanines at operator positions 10 and 12; His6 contacts the guanines at operator positions 5 and 17; Asn8 contacts operator positions 4, 7, 15 and 18; Arg10 contacts the guanines at operator positions 8 and 14. The proposed contacts can be accommodated in a structural model in which the anti-parallel beta-sheet motifs of Mnt dimers lie in the major grooves of each operator half-site, centered over pseudo-symmetry axes that are 5.5 bp from the central dyad axis of the operator.     

Influence of DNA stiffness in protein-DNA recognition

Protein-DNA recognition plays an essential role in the regulation of gene expression. The protein-DNA binding specificity is based on direct atomic contacts between protein and DNA and/or the conformational properties of DNA. In this work, we have analyzed the influence of DNA stiffness (E) to the specificity of protein-DNA complexes. The average DNA stiffness parameters for several protein-DNA complexes have been computed using the structure based sequence dependent stiffness scale. The relationship between DNA stiffness and experimental protein-DNA binding specificity has been brought out. We have investigated the importance of DNA stiffness with the aid of experimental free energy changes (DeltaDeltaG) due to binding in several protein-DNA complexes, such as, ETS proteins, 434, lambda, Mnt and trp repressors, 434 cro protein, EcoRV endonuclease V and zinc fingers. We found a correlation in the range 0.65-0.97 between DeltaDeltaG and E in these examples. Further, we have qualitatively analyzed the effect of mutations in the target sequence of lambda repressor and we observed that the DNA stiffness could correctly identify 70% of the correct bases among the considered nine positions.     

Interaction of the Mnt repressor with 37-base pair synthetic operator DNA fragments. Importance of symmetric GC pairs

Mnt repressor is indirectly responsible for the maintenance of lysogeny of the phage P22. This repressor interacts with a 21-base pair operator DNA constituting within it a 17-base pair perfect 2-fold symmetric sequence whose bases make a direct contact with the protein. We have synthesized six 37-base pair DNAs consisting of 21 base pair natural operator and its modifications in which certain symmetrically situated GC base pairs were replaced systematically with ATs to understand their importance. The binding interaction studies of Mnt repressor to such natural and modified operator DNAs reported here indicate that the GCs close to the center of symmetry make major contacts with the protein whereas, GCs nearer to the periphery form weak contacts. Methylation protection experiments indicated that when the GCs near the center of symmetry were replaced with AT, the central GC became more accessible for dimethyl sulfate methylation with possible conformational change in DNA. The circular dichroism studies indicated that upon repressor binding conformational changes in DNA takes place with a possible increase in helicity of the repressor protein.     

Site-specific enthalpic regulation of DNA transcription at bacteriophage lambda OR.

Binding of cI repressor to DNA fragments containing the three specific binding sites of the right operator (OR) of bacteriophage lambda was studied in vitro over the temperature range 5-37 degrees C by quantitative footprint titration. The individual-site isotherms, obtained for binding repressor dimers to each site of wild-type OR and to appropriate mutant operator templates, were analyzed for the Gibbs energies of intrinsic binding and pairwise cooperative interactions. It is found that dimer affinity for each of the three sites varies inversely with temperature, i.e., the binding reactions are enthalpy driven, unlike many protein-DNA reactions. By contrast, the magnitude of the pairwise cooperativity terms describing interaction between adjacently site-bound repressor dimers is quite small. This result in combination with the recent finding that repressor monomer-dimer assembly is highly enthalpy driven (with delta H degrees = -16 kcal mol-1) [Koblan, K. S., & Ackers, G. K. (1991) Biochemistry 30, 7817-7821] indicates that the associative contacts between site-bound repressors that mediate cooperativity are unlikely to be the same as those responsible for dimerization. The intrinsic binding enthalpies for all three sites are negative (exothermic) and nearly temperature-invariant, indicating no heat capacity changes on the scale of those inferred in other protein-DNA systems. However, the three operator sites are affected differentially by temperature: the intrinsic binding free energies for sites OR1 and OR3 change in parallel over the entire range, delta H0OR1 = -23.3 +/- 4.0 kcal mol-1 and delta H0OR3 = -22.7 +/- 1.2 kcal mol-1.(ABSTRACT TRUNCATED AT 250 WORDS)