Deuterium exchange of operator 8CH groups as a Raman probe of repressor recognition: interactions of wild-type and mutant lambda repressors with operator OL1.

The rate of deuterium exchange of a purine 8CH group in DNA is highly sensitive to both macromolecular secondary structure and intermolecular interactions which restrict solvent access to the major groove [Lamba, O.P., Becka, R., & Thomas, G.J., Jr. (1990) Biopolymers 29, 1465-1477]. We have exploited the sensitivity of the 8CH----8CD reaction to probe DNA recognition by the helix-turn-helix (HTH) motif of phage lambda cI repressor. We find that purine exchanges in the 19-base-pair OL1 operator are strongly and specifically restricted by binding of the HTH N-terminal domain of the repressor fragment (RF) comprising residues 1-102. The kinetics indicate large-scale obstruction of solvent access to operator 7N-8C purine sites. Interpretation of the exchange kinetics using a simple model suggests that only 7 purine residues (5 of 10 adenines and 2 of 9 guanines) remain unrestricted with respect to 8CH exchange in complexes of OL1 with the wild-type repressor. On the other hand, the 8CH exchange profile for the complex of OL1 with the Tyr88----Cys mutant repressor indicates that 9 purines (7 adenines and 2 guanines) are exchangeable. These results suggest important differences in major groove recognition in the two complexes. The proposed 8CH labeling profiles are consistent with molecular models of related complexes determined by X-ray crystallography [Jordan, S.R., & Pabo, C.O. (1988) Science 242, 893-899] and indicate that the structures observed in the crystal are largely maintained in solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Preferential protection of the minor groove of non-operator DNA by lac repressor against methylation by dimethyl sulphate.

The binding of lactose repressor to non-operator DNA was studied by the modification of several DNA's, including glycosylated DNA, with dimethyl sulphate, which affects the minor and major grooves of DNA and single stranded DNA regions. The non-specific binding of the repressor to DNA protected the minor groove but apparently not the major groove of the DNA double helix against methylation and did not increase the content of single stranded DNA regions. This suggests that the repressor on binding to non-operator DNA makes contacts mainly in the minor groove of DNA and does not uncoil the DNA double helix. This is different from the interaction of the repressor with lactose operator DNA which occurs, as shown by Gilbert et al. (1), along both the major and the minor groove.     

Crystal structure of the lambda repressor C-terminal domain octamer.

The three-dimensional structure of the lambda repressor C-terminal domain (CTD) has been determined at atomic resolution. In the crystal, the CTD forms a 2-fold symmetric tetramer that mediates cooperative binding of two repressor dimers to pairs of operator sites. Based upon this structure, a model was proposed for the structure of an octameric repressor that forms both in the presence and absence of DNA. Here, we have determined the structure of the lambda repressor CTD in three new crystal forms, under a wide variety of conditions. All crystals have essentially the same tetramer, confirming the results of the earlier study. One crystal form has two tetramers bound to form an octamer, which has the same overall architecture as the previously proposed model. An unexpected feature of the octamer in the crystal structure is a unique interaction at the tetramer-tetramer interface, formed by residues Gln209, Tyr210 and Pro211, which contact symmetry-equivalent residues from other subunits of the octamer. Interestingly, these residues are also located at the dimer-dimer interface, where the specific interactions are different. The structures thus indicate specific amino acid residues that, at least in principle, when altered could result in repressors that form tetramers but not octamers.     

1H-NMR study of the lambda operator site OL1: assignment of the imino and adenine H2 resonances.

One- and two-dimensional proton NMR methods are being used to study the synthetic lambda operator site O-L1, a 17 base-pair DNA duplex recognized by lambda repressor and Cro protein. The complete assignment of the 17 imino protons, which participate in Watson-Crick hydrogen bonding, and of the eight adenine H2 protons, which lie in the minor groove of the double helix, is presented.     

Comparison of the structures of operator DNA free and in complex with lambda repressor

The structures of operator DNA unbound and in complex with lambda repressor protein are compared. The conformation of the left 10 base pairs of a lambda right regulatory operator DNA sequence has been previously determined in solution using nuclear magnetic resonance techniques and the structure of a homologous left regulatory operator DNA bound to lambda repressor N-terminal domain had been previously solved using X-ray crystallography. The DNA adopts an overall linear B-form DNA both in the absence and presence of lambda repressor. Superimpositioning of the DNA structures reveals small differences between them that are due to the binding of protein and not to the different techniques used for their determination.     

Interaction of mutant lambda repressors with operator and non-operator DNA

We have described a set of mutations that alter side-chains on the operator binding surface of lambda repressor. In this paper, we study the interactions of 12 purified mutant repressors with operator and non-operator DNA. The mutant proteins have operator affinities that are reduced from tenfold to greater than 10,000-fold compared to wild-type. Nine of the mutants have affinities for non-operator DNA that are similar to wild-type, two mutants show decreased non-specific binding, and one mutant has increased affinity for non-operator DNA. We discuss these findings in terms of the structural and energetic contributions of side-chain--DNA interactions, and show that certain contacts between the repressor and the operator backbone contribute both energy and specificity to the interaction.     

How lambda repressor and lambda Cro distinguish between OR1 and OR3

Although lambda repressor and lambda Cro bind to the same six operators on the phage chromosome, the fine specificities of the two proteins differ: repressor binds more tightly to OR1 than to OR3, and vice versa for Cro. In this paper, we change base pairs in the operators and amino acids in the proteins to analyze the basis for these preferences. We find that these preferences are determined by residues 5 and 6 of the recognition helices of the two proteins and by the amino-terminal arm, in the case of repressor. We also find that the most important base pairs in the operator which enable repressor and Cro to discriminate between OR1 and OR3 are position 3 (for Cro) and positions 5 and 8 (for repressor). These and previous results show how repressor and Cro recognize and distinguish between two related operator sequences.     

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.     

Localization of chromatin proteins within DNA grooves by methylation of chromatin with dimethyl sulphate

The use of the comparative modification with ³H-dimethyl sulphate (DMS) of free DNA and DNA in different complexes is proposed to evaluate the shielding of the minor and major grooves of the DNA double helix and to determine the presence of single-stranded DNA in the complexes.Glucosyl groups in DNA of T6 phage protect, as expected, the major groove, and actinomycin d in its complex with DNA shields the minor groove against methylation with DMS.The data obtained suggest that histones and protamine in reconstituted nucleohistone and nucleoprotamine are allocated within partly the major groove leaving the minor groove open, while polylysine does not seem to be buried within either of the grooves, and cations of cetyltrimethylammonium lie within the minor groove of DNA.     

Interaction of lambda cro repressor with synthetic operator OR3 studied by competition binding with minor groove binders.

In the present work, we employ a combination of CD spectroscopy and gel retardation technique to characterize thermodynamically the binding of lambda phage cro repressor to a 17 base pair operator OR3. We have found that three minor groove-binding antibiotics, distamycin A, netropsin and sibiromycin, compete effectively with the cro for binding to the operator OR3. Among these antibiotics, sibiromycin binds covalently to DNA in the minor groove at the NH2 of guanine, whereas distamycin A and netropsin interact preferentially with runs of AT base pairs and avoid DNA regions containing guanine bases in the two polynucleotide strands. Only subtle DNA conformation changes are known to take place upon binding of these antibiotics. Both the CD spectral profiles and the results of the gel retardation experiments indicate that distamycin A and netropsin can displace cro repressor from the operator OR3. The binding of cro repressor to the OR3 is accompanied by considerable changes in CD in the far-UV region which appear to be attributed to a DNA-dependent structural transition in the protein. Spectral changes are also induced in the wavelength region of 270-290 nm. The CD spectral profile of the cro-OR3 mixture in the presence of distamycin A can be represented as a sum of the CD spectrum of the repressor-operator complex and spectrum of distamycin-DNA complex at the appropriate molar ratio of the bound antibiotic to the operator DNA (r). When r tends to the saturation level of binding the CD spectrum in the region of 270-360 nm approaches a CD pattern typical of complexes of the antibiotic with the free DNA oligomer. This suggests that simultaneous binding of cro repressor and distamycin A to the same DNA oligomer is not possible and that distamycin A and netropsin can be used to determine the equilibrium affinity constant of cro repressor to the synthetic operator from competition-type experiments. The binding constant of cro repressor to the OR3 is found to be (6 +/- 1).10(6)M-1 at 20 degrees C in 10 mM sodium cacodylate buffer (pH 7.0) in the presence of 0.1 M NH4F.     

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.     

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.     

Binding and bending of the lambda replication origin by the phage O protein.

We have characterized the binding of lambda phage replication initiation protein O to the phage origin of replication. The minimal DNA segment required for O binding is the single iteron, a 19-bp sequence of hyphenated dyad symmetry that is repeated with variations four times in the origin. The isolated amino terminus of O protein is also sufficient to bind DNA. Electrophoretic studies show that the amino terminus of O protein induces bending of a single iteron. The DNA-protein interaction was characterized by ethylation interference, dimethyl sulfate protection and neocarzinostatin footprinting. Points of DNA-protein contact are largely concentrated in two areas symmetrically disposed with respect to the dyad symmetry of the iteron. This suggests the protein interacts as a dimer with half sites in the DNA. However, a few non-symmetrical contacts are found, indicating that O protein may distort the helix. This may correlate with the bending effects demonstrated electrophoretically. Cylindrical DNA projections were used to model O protein binding to the lambda origin and compare it with the lambda repressor-operator interaction. Whereas bound repressor nearly encircles the DNA in the major groove, O protein leaves the major groove on the opposite side exposed.     

Dimerization of the operator binding domain of phage lambda repressor

Dimerization of lambda repressor is required for its binding to operator DNA. As part of a continuing study of the structural basis of the coupling between dimer formation and operator binding, we have undertaken 1H NMR and gel filtration studies of the dimerization of the N-terminal domain of lambda repressor. Five protein fragments have been studied: three are wild-type fragments of different length (1-102, 1-92, and 1-90), and two are fragments bearing single amino acid substitutions in residues involved in the dimer interface (1-102, Tyr-88----Cys; 1-92, Ile-84----Ser). The tertiary structure of each species is essentially the same, as monitored by the 1H NMR resonances of internal aromatic groups. However, significant differences are observed in their dimerization properties. 1H NMR resonances of aromatic residues that are involved in the dimer contact allow the monomer-dimer equilibrium to be monitored in solution. The structure of the wild-type dimer contact appears to be similar to that deduced from X-ray crystallography and involves the hydrophobic packing of symmetry-related helices (helix 5) from each monomer. Removal of two contact residues, Val-91 and Ser-92, by limited proteolysis disrupts this interaction and also prevents crystallization. The Ile-84----Ser substitution also disrupts this interaction, which accounts for the severely reduced operator affinity of this mutant protein.     

Refined 1.8 A crystal structure of the lambda repressor-operator complex.

The crystal structure of the lambda repressor-operator complex has been refined to an R-factor of 18.9% at 1.8 A resolution. This refinement, using data collected at low temperature, has revealed the structure of the N-terminal arm and shows that the interactions of repressor with the two halves of the pseudo-symmetric operator site are significantly different. The two halves of the complex are most similar near the outer edge of the operator site (in a region where the lambda and 434 repressors make similar contacts), but they become increasingly different toward the center of the operator. There are striking differences near the center of the site where it appears that the arm makes significant contacts to only one half of the DNA site. This suggested a new way of aligning the operator sites in phage lambda. The high resolution structure confirms many of the previously noted features of the complex, but also reveals a number of new protein-DNA contacts. It also gives a better view of the extensive H-bonding networks that couple contacts made by different residues and different regions of the protein, and reveals important new details about the helix-turn-helix (HTH) region, and the positions of many water molecules in the complex.