DNA recognition by the helix-turn-helix motif: investigation by laser Raman spectroscopy of the phage lambda repressor and its interaction with operator sites OL1 and OR3.

The lambda repressor provides a model system for biophysical studies of DNA recognition by the helix-turn-helix motif. We describe laser Raman studies of the lambda operator sites OL1 and OR3 and their interaction with the DNA-binding domain of lambda repressor (residues 1-102). Raman spectra of the two DNA sites exhibit significant differences attributable to interstrand purine-purine steps that differ in the two oligonucleotides. Remarkably, the conformation of each operator is significantly and specifically altered by repressor binding. Protein recognition, which involves hydrogen-bond formation and hydrophobic contacts in the major groove, induces subtle changes in DNA Raman bands of interacting groups. These include (i) site-specific perturbations to backbone phosphodiester geometry at AT-rich domains, (ii) hydrophobic interaction at thymine 5CH3 groups, (iii) hydrogen bonding to guanine 7N and 6C = O acceptors, and (iv) alterations in sugar pucker within the C2'-endo (B-DNA) family. These perturbations differ between aqueous OL1 and OR3 complexes of repressor, indicating that protein binding in solution determines the precise DNA conformation. The overall structure of the lambda domain is not greatly perturbed by binding to either OL1 or OR3, in accord with X-ray studies of other complexes. However, Raman markers indicate a change in hydrogen bonding of the OH group of tyrosine-22, which is a hydrogen-bond acceptor in the absence of DNA but a combined donor and acceptor in the OL1 complex; yet, Y22 hydrogen bonding is not altered in forming the OR3 complex. The present results demonstrate qualitatively different and distinguishable modes of interaction of the lambda repressor DNA-binding domain with operators OL1 and OR3 in solution. This application of laser Raman spectroscopy to a well-characterized system provides a prototype for future Raman studies of other DNA-binding motifs under physiological conditions.     

Lac repressor with the helix-turn-helix motif of lambda cro binds to lac operator.

Lac repressor, lambda cro protein and their operator complexes are structurally, biochemically and genetically well analysed. Both proteins contain a helix-turn-helix (HTH) motif which they use to bind specifically to their operators. The DNA sequences 5'-GTGA-3' and 5'-TCAC-3' recognized in palindromic lac operator are the same as in lambda operator but their order is inverted form head to head to tail to tail. Different modes of aggregation of the monomers of the two proteins determine the different arrangements of the HTH motifs. Here we show that the HTH motif of lambda cro protein can replace the HTH motif of Lac repressor without changing its specificity. Such hybrid Lac repressor is unstable. It binds in vitro more weakly than Lac repressor but with the same specificity to ideal lac operator. It does not bind to consensus lambda operator.     

Design of the helix-turn-helix motif: nonlocal effects of quaternary structure in DNA recognition investigated by laser Raman spectroscopy

The operator-binding domain of phage lambda repressor provides a model for DNA recognition by the helix-turn-helix (HTH) motif. In the wild-type protein, dimerization is mediated by hydrophobic packing (of the dyad-related helix 5), which serves as an indirect determinant of operator affinity. The mutant repressor, Tyr88----Cys, forms an intersubunit disulfide linkage and exhibits enhancement of both structural stability and operator affinity. Yet the dimer-specific operator affinity of the mutant is 10-fold weaker than that of the wild-type (noncovalent) dimer, suggesting nonlocal effects of the intersubunit disulfide bond on HTH recognition (Sauer et al., 1986). To explore such nonlocal effects, we describe laser Raman studies of the Cys88 mutant repressor and its interaction with operator sites OL1 and OR3. The following results have been obtained: (i) Wild-type and mutant dimers exhibit similar secondary structures, indicated by quantitative comparison of Raman amide I and amide III bands. (ii) The engineered disulfide of the mutant lacks rigorous symmetry; we observe mainly the gauche/gauche/trans CC-S-S-CC rotamer. (iii) Remarkably, distinctive local and nonlocal differences are observed in the mechanisms of DNA recognition by wild-type and mutant repressors. These differences involve specific hydrogen-bonding interactions between the protein and DNA, including guanine N7 sites in the major groove of DNA, and alterations in DNA phosphodiester conformation induced by protein binding. We analyze these differences in relation to crystal structures of the wild-type dimer with and without bound DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Probing the structure of gal operator-repressor complexes. Conformation change in DNA

The gal operon is regulated by binding of Gal repressor to two operator loci, OE and OI, which are separated by 114 base pairs (bp). We have probed the actual operator DNA segments with and without Gal repressor occupation by characterizing the regions protected by repressor from DNase I digestion and dimethyl sulfate methylation. The segments which are protected from DNase I digestion in both OE and OI are about 22 bp long and seem to include 2-3 extra bp on either side of a 16-bp similar sequence containing an approximate dyad symmetry, with a consensus half-symmetry sequence GTG(G/T)AA-C. Repressor occupation hinders the reactivity of the consensus guanines in the four half-symmetry sequences, as shown by retardation of methylation at the N-7 positions by dimethyl sulfate owing to repressor binding. The protected guanines are symmetrically located. Since a dimeric Gal repressor affects symmetrically located bases, it is consistent with the notion that each half-operator is occupied by a repressor subunit. Because the N-7 positions of methylation of guanines lie in the major grooves and the protected guanines are located at positions 1, 3, 8 and the rotational 1', 3', and 8' in the 16-bp dyad symmetry, we suggest that Gal repressor establishes direct contacts with bases at 1, 3, 1', and 3' through two major grooves lying on one face of an operator helix and prevents reactivity of the guanines at 8 and 8' of a third major groove on the opposite face by changing the DNA helical structure at this position. Contacts at other positions are also discussed.     

lac operator DNA modification in the presence of proteolytic fragments of the repressor protein

Singly end-labeled DNA fragments containing the lactose operator were methylated in the presence of the lactose repressor and homogeneous preparations of its proteolytic fragments. Binding of core protein produced by mild trypsin digestion yielded a methylation perturbation pattern that differed significantly from that elicited by binding to intact repressor, although similarities in the patterns for these related proteins were noted in the central, asymmetric region of the operator. An NH2-terminal peptide (residues 1 to 56) from lac repressor bound operator fragments in a nitrocellulose filter assay, but failed to perturb DNA methylation significantly relative to the pattern in the absence of peptide. Binding of hybrid tetramers of core and intact repressor monomers produced related but unique methylation patterns for the purines on the operator fragment. The general pattern of perturbation observed suggests preferred binding of a single NH2 terminus to the promoter-distal region of the operator and asymmetric interaction of the core region with the operator sequence. Differences in purine methylation patterns produced by the presence of effector complexes of repressor and core protein suggest the possible nature of changes in protein topology that result in the affinity changes accompanying induction.     

Sequence dependence of purine C8H exchange kinetics in the dodecamer 5′-d(CGCGAATTCGCG)-3′

Proton nmr spectroscopy is used to measure the deuterium exchange rates of C8 protons in individual purines of the dodecamer 5′-d(CGCGAATTCGCG)-3′ and their temperature dependence. In perfect agreement with results from tritium labeling and laser Raman spectroscopy, we find that the DNA secondary structure retards the rates of purine C8H exchange. The largest effects are observed for the C8 protons of adenines whose rates of exchange at 40°C are 3-to 4-fold lower than that in 5′-adenosine monophosphate. Moreover, the retardation of exchange at the central adenine is greater than that at its 5′-neighbor. For the guanines, the exchange rates are up to 2-fold lower than that in 5′-guanosine monophosphate, and the largest retardation is observed for the bases at positions 10 and 12. A dependence on base sequence is also observed for the activation energy for exchange. The activation energy is largest for the adenines and its value is 4 kcal/mol higher than that in 5′-adenosine monophosphate. The lowest activation energy is observed for the guanine in position 4 and the value is the same as in 5′-guanosine monophosphate. These results demonstrate the sensitivity of the purine C8H exchange kinetics to sequence-dependent conformational features of B-DNA in solution state. © 1993 John Wiley & Sons, Inc.     

Sites of contact between lambda operators and lambda repressor.

DNA bearing lambda operator sequences was methylated by dimethyl sulfate (DMS) in the presence or absence of lambda repressor. Under the experimental conditions, DMS methylates only the purine residues. The presence of lambda repressor affects only the methylation of certain G residues in the operators. Repressor blocks the methylation of certain G's and enhances the methylation of other G's. Since the reactive ring-nitrogen of G lies in the major groove of double-stranded DNA, and the reactive ring-nitrogen of A lies in the minor groove, the above results imply that the repressor makes contacts in the major groove of the helix. The repressor effect on G-methylation is sharply confined to the three 17 base pair units within each lambda operator previously proposed as the repressor-binding sites.     

Functional roles of amino acid residues involved in forming the alpha-helix-turn-alpha-helix operator DNA binding motif of Tet repressor from Tn10.

The Tn10 derived Tet repressor contains an amino acid segment with high homology to the alpha-helix-turn-alpha-helix motif (HTH) of other DNA binding proteins. The five most conserved amino acids in HTH are probably involved in structural formation of the motif. Their functional role was probed by saturation mutagenesis yielding 95 single amino acid replacement mutants of Tet repressor. Their binding efficiencies to tet operator were quantitatively determined in vivo. All functional mutants contain amino acid substitutions consistent with their proposed role in a HTH. In particular, only the two smallest amino acids (serine, glycine) can substitute a conserved alanine in the proposed first alpha-helix without loss of activity. The last position of the first alpha-helix, the second position in the turn, and the fourth position in the second alpha-helix require mostly hydrophobic residues. The proposed C-terminus of the first alpha-helix is supported by a more active asparagine compared to glutamine replacement mutant of the wt leucine residue. The turn is located close to the protein surface as indicated by functional lysine and arginine replacements for valine. A glycine residue at the first position in the turn can be replaced by any amino acid yielding mutants with at least residual tet operator affinity. A structural model of the HTH of Tet repressor is presented.     

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.     

Effects of physical, ionic, and structural factors on the binding of repressor of mycobacteriophage L1 to its cognate operator DNA

To determine the factors influencing the binding of L1 repressor to its cognate operator DNA, several gel shift as well as bioinformatic analyses have been carried out. The data show that time, temperature, salt, and pH each greatly affect the binding. In order to achieve optimum operator binding of L1 repressor in Tris buffer, the minimum requirements of time, temperature, salt, and pH were estimated to be 1 min, 32 degrees C, NaCl (50 mM), and 7.9, respectively. Interestingly Na+ but not NH4+, K+, or Li+ was found to augment significantly the binding activity of CI protein above the basal level. Anions like Cl-, citrate-, acetate-, and H2PO4- do not alter the binding of L1 repressor to its operator. We also show that an in frame deletion mutant of L1 repressor which does not carry the putative HTH motif (at its N-terminal end) fails to bind to its cognate operator DNA even at very high concentrations. The putative HTH motif was found highly conserved and evolutionarily very close to that of regulatory proteins of Y. pestis, H. marismortui, A. tumefaciens, etc. Taken together we suggest that N-terminal end of L1 repressor carries a HTH motif. Further analysis of the putative secondary structures of mycobacteriophage repressors reveals that two common regions encompassing more than 90% of primary sequence are present in all the four repressor molecules studied here. The results suggest that these common regions are utilized for carrying out identical functions.     

Molecular dynamics simulation reveals sequence-intrinsic and protein-induced geometrical features of the OL1 DNA operator

We have carried out molecular dynamics simulation of the lambda OL1 DNA operator on the free and the protein-bound forms. Our results lead us to conclude that the binding of the repressor actually makes the N-7 atom of Gua8' more solvent exposed, thereby enhancing its reactivity to chemical methylation. This increase in solvent accessibility surface area occurs simultaneously with the formation of hydrogen bonds between Lys-4 of the nonconsensus flexible N-terminal arm and Gua6' of the nonconsensus half-site operator DNA. Calculations of protein--DNA interaction energies reveal that among the residues of the arm, Lys-4 contributes the most favorably to the interaction energies. This result is consistent with mutagenesis studies that established that lysine at position 4 is absolutely required for tight binding. We find that the nonconsensus arm and the nonconsensus monomer interacts less favorably with DNA than do their respective counterparts of the consensus monomer. Moreover, the six-residue flexible arm accounts for at least half the total protein--DNA interactions energy. These results are in agreement with previous experimental studies. In accord with the diffuse electron density map observed in crystallographic studies of the nonconsensus flexible arm, we find that our model built for this region is more flexible and exhibits more conformations than its consensus counterpart. The simulation also reveals that DNA bending observed near the outer edge of the operator site is an intrinsic sequence-dependent property. By contrast, the DNA-bending features observed toward the center of the operator are induced by the protein. On the whole, stepwise protein-induced bending is more pronounced in the consensus half-site operator. We also find that the unusually large helical twist (49 degrees ) observed in the protein-bound form near the center of the operator results from the binding of the protein at a base step with some propensity for high twists.     

Tet repressor-tet operator contacts probed by operator DNA-modification interference studies

Contacts between tet operator DNA and Tet repressor protein are characterized by modification interference studies. The modified DNA fragments are separated into fractions with high, intermediate and low affinities for Tet repressor by polyacrylamide gel electrophoresis. Ethylation of the phosphates with N-ethylnitrosourea reveals 12 contacts of a repressor dimer to tet operator. Eight of these contacts appear to be important for Tet repressor binding, as judged by the strong interference at these positions, while four contacts are probably less important. All of the phosphate contacts are located on the same side of the B-DNA structure. The sequences of tet operators proposed to interact with the recognition alpha-helix of Tet repressor are TCTATC in three cases and CCTATC in one case. After methylation of N-7 with dimethylsulfate, strong interference is observed at the guanine residues at positions +/- 2. None of the N-7 functions of other guanine residues seems to be involved in tight contacts to Tet repressor. Tet repressor subunits form identical phosphate and guanine N-7 contacts with each half side of the two tet operators indicating twofold dyad symmetry of the complexes. Attempts to analyze the methylation interference at the adenine N-3 sites reveal different results for the operators. Modification of DNA fragments with diethylpyrocarbonate yields hypersensitive sites in the tet operators, indicating different local DNA structures. Carbethoxylation interference studies confirm the contacts at the purines found by methylation interference. All of the sequence-specific protein-DNA contacts detected in this study are centered at the inside four base-pairs in each tet operator half side. The contacts are discussed with respect to the structure of the repressor-operator complex.     

The solution structure of Lac repressor headpiece 62 complexed to a symmetrical lac operator

BACKGROUND: Lactose repressor protein (Lac) controls the expression of the lactose metabolic genes in Escherichia coli by binding to an operator sequence in the promoter of the lac operon. Binding of inducer molecules to the Lac core domain induces changes in tertiary structure that are propagated to the DNA-binding domain through the connecting hinge region, thereby reducing the affinity for the operator. Protein-protein and protein-DNA interactions involving the hinge region play a crucial role in the allosteric changes occurring upon induction, but have not, as yet, been analyzed in atomic detail. RESULTS: We have used nuclear magnetic resonance (NMR) spectroscopy and restrained molecular dynamics (rMD) to determine the structure of the Lac repressor DNA-binding domain (headpeice 62; HP62) in complex with a symmetrized lac operator. Analysis of the structures reveals specific interactions between Lac repressor and DNA that were not found in previously investigated Lac repressor-DNA complexes. Important differences with the previously reported structures of the HP56-DNA complex were found in the loop following the helix-turn-helix (HTH) motif. The protein-protein and protein-DNA interactions involving the hinge region and the deformations in the DNA structure could be delineated in atomic detail. The structures were also used for comparison with the available crystallographic data on the Lac and Pur repressor-DNA complexes. CONCLUSIONS: The structures of the HP62-DNA complex provide the basis for a better understanding of the specific recognition in the Lac repressor-operator complex. In addition, the structural features of the hinge region provide detailed insight into the protein-protein and protein-DNA interactions responsible for the high affinity of the repressor for operator DNA.     

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.     

Tn10 tet operator mutations affecting Tet repressor recognition.

The effect of single base pair alterations of the Tn10 encoded tet operator on recognition of Tet repressor was studied in vivo using a repressor titration system and in vitro by dissociation rate determinations of the respective complexes. Both methods reveal that the two operators, O1 and O2, which are in a tandem arrangement in the wild type, are recognized with a two-fold different affinity when separated. Studies on synthetic operator sequences indicate that the Tet repressor binds with higher affinity to the non-palindromic O2 wildtype than to the respective palindromic sequences. The in vivo repressor titration system links the expression of lacZ to the affinity of tet operator to Tet repressor. It was used to isolate tet operator mutations with reduced affinity to the repressor. The in vivo and in vitro obtained results with these mutants agree quantitatively and indicate, that the GC base pairs at positions 2, 6, and 8 are involved in interaction with the Tet repressor. Their importance for recognition decreases in that order. Transitions at position 7 of the tet operator show smaller effects on recognition than transversions.     

How Lac repressor finds lac operator in vitro.

Filter-binding and gel mobility shift assays were used to analyse the kinetics of the interaction of Lac repressor with lac operator. A comparison of the two techniques reveals that filter-binding assays with tetrameric Lac repressor have often been misinterpreted. It has been assumed that all complexes of Lac repressor and lac operator DNA bind with equal affinity to nitrocellulose filters. This assumption is wrong. Sandwich or loop complexes where two lac operators bind to one tetrameric Lac repressor are not or are only badly retained on nitrocellulose filters under normal conditions. Taking this into account, dimeric and tetrameric Lac repressor do not show any DNA-length dependence of their association and dissociation rate constants when they bind to DNA fragments smaller than 2455 base-pairs carrying a single symmetric ideal lac operator. A ninefold increased association rate to ideal lac operator on lambda DNA is observed for tetrameric but not dimeric Lac repressor. It is presumably due to intersegment transfer involving lac operator-like sequences.     

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of β-galactosidase with symmetric variants of α- and β-centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the α-centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the α-centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. AI80, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for α-centered trp operator variants with exchanges in positions 3, 4 and 5.     

Adenine and guanine 8CH exchange in nucleic acids: resolution and measurement by Raman optical multichannel analysis

Deuterium exchange of 8C protons of adenine and guanine in nucleic acids is conveniently monitored by laser Raman spectrophotometry, and the average exchange rate so determined [kA + kG] can be exploited as a dynamic probe of the secondary structure of DNA or RNA [J. M. Benevides and G. J. Thomas, Jr. (1985) Biopolymers 24, 667-682]. The present work describes a rapid Raman procedure, based upon optical multichannel analysis, which permits discrimination of the different 8CH exchange rates, kA of adenine and kG of guanine, in a single experimental protocol. For this procedure, simultaneous measurements are made of the intensity decay or frequency shift in separately resolved Raman bands of adenine and guanine, each of which is sensitive only to 8C deuteration of its respective purine. Resolution of the rates kA and kG is demonstrated for the mononucleotide mixtures, 5'-rAMP + 5'-rGMP and 5'-dAMP + 5'-dGMP, for the polynucleotides poly(dA-dT).poly(dA-dT) and poly(dG-dC).poly(dG-dC), for calf thymus DNA, and for the 17 base-pair operator OR3. We show that the different exchange rates of adenine and guanine, in nucleotide mixtures and in DNA, may also be calculated independently from intensity decay of the composite 1481-cm-1 band, comprising overlapped adenine and guanine components, over a time domain that encompasses two distinct regimes: (1) a relatively more rapid exchange of guanine, and (2) a concurrent slower exchange of adenine. Both methods developed here yield consistent results. We find, first, that exchange of guanine is approximately twofold more rapid than that of adenine when both purines are present in the same structure and solvent environment, presumably a consequence of the greater basicity of the 7N site of guanine. Second, we find that adenine suffers greater retardation of exchange than guanine when both purines are incorporated into a "classical" B-DNA secondary structure, such as that of calf thymus DNA. This finding suggests different microenvironments at the 7N-8C loci of adenine and guanine in aqueous B-DNA. We also confirm that adenine residues of B-form poly(dA-dT).poly(dA-dT) exchange much more slowly than those of other B-DNA sequences, implying a secondary structure for the alternating-AT sequence with unusual stereochemistry in the major groove. The greater resistance of adenine than guanine to 8CH exchange in the B-DNA secondary structure is more evident in high molecular weight calf thymus DNA and in the alternating AT and GC copolymer duplexes than in the smaller 17 base-pair operator OR3.(ABSTRACT TRUNCATED AT 400 WORDS)