Lambda phage cro repressor interaction with its operator DNA: 2'-deoxy-5-fluorouracil OR3 analogues

The experiments here show that chemically synthesized DNA containing fluorine at selected sites can be used to test specific predictions of a model for cro repressor--operator interaction. This is done by observation of the perturbation to the fluorine-19 NMR spectra of analogues of OR3 synthesized with 2'-deoxy-5-fluorouracil at specific positions in the DNA helix. Although the three-dimensional structure of the cro repressor from phage lambda has been determined by Matthews and co-workers [Anderson, W., Ohlendorf, D., Takeda, Y., & Matthews, B. (1981) Nature (London) 290, 754-758], direct structural observations on the complex of the protein with its specific DNA recognition sequence, OR3, are limited. From that structure of the protein, alone, a model of its complex to DNA was built by fitting B-form DNA, with some distortion [Ohlendorf, D., Anderson, W., Fisher, R., Takeda, Y., & Matthews, B. (1982) Nature (London) 298, 718-723]. That model proposes that the cro repressor contacts only one side of this DNA double helix and a number of specific protein--DNA contacts. To test the model, 2'-deoxy-5-fluorouracil was used to place the fluorine-19 nuclear spin-label on the side of the DNA contacting the cro repressor and on the opposite side facing away from the cro repressor. The results presented here are consistent with the prediction that lambda phage cro repressor contacts only one side of the DNA double helix.     

Design and synthesis of sequence-specific DNA-binding peptides

Design, synthesis and DNA binding activities of two peptides containing 32 and 102 residues are reported. A nonlinear 102-residue peptide contains four modified alpha helix-turn-alpha helix motifs of 434 cro protein. These four units are linked covalently to a carboxyterminal crosslinker containing four arms each ending with an aliphatic amino group. From CD studies we have found that in aqueous buffer in the presence of 20% trifluoroethanol the peptide residues assume alpha-helical, beta-sheet and random-coiled conformations with the alpha-helical content of about 16% at room temperature. Upon complex formation between peptide and DNA, a change in the peptide conformation takes place which is consistent with an alpha - beta transition in the DNA binding alpha helix-turn-alpha helix units of the peptide. Similar conformation changes are observed upon complex formation with the synthetic operator of a linear peptide containing residues 7-37 of 434 cro repressor. Evidently, in the complex, residues present in helices alpha 2 and alpha 3 of the two helix motif form a beta-hairpin which is inserted in the minor DNA groove. The last inference is supported by our observations that the two peptides can displace the minor groove-binding antibiotic distamycin A from poly(dA).poly(dT) and synthetic operator DNA. As revealed from DNase digestion studies, the nonlinear peptide binds more strongly to a pseudooperator Op1, located in the cro gene, than to the operator OR3. A difference in the specificity shown by the non-linear peptide and wild-type cro could be attributed to a flexibility of the linker chains between the DNA-binding domains in the peptide molecule as well as to a replacement of Thr-Ala in the peptide alpha 2-helices. Removal of two residues from the N-terminus of helix alpha 2 in each of the four DNA-binding domains of the peptide leads to a loss of binding specificity.     

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.     

Monovalent cations regulate DNA sequence recognition by 434 repressor

The bacteriophage 434 repressor distinguishes between its six naturally occurring binding sites using indirect readout. In indirect readout, sequence-dependent differences in the structure and flexibility of non-contacted bases in a protein's DNA-binding site modulate the affinity of DNA for protein. The conformation and flexibility of a DNA sequence can be influenced by the interaction of the DNA bases or backbone with solution components. We examined the effect of changing the cation-type present in solution on the stability and structure of 434 repressor complexes with wild-type and mutant OR1 and OR3, binding sites that differ in their contacted and non-contacted base sequences. We find that the affinity of repressor for OR1, but not for OR3, depends remarkably on the type and concentration of monovalent cation. Moreover, the formation of a stable, specific repressor-OR1 complex requires the presence of monovalent cations; however, repressor-OR3 complex formation has no such requirement. Changing monovalent cation type alters the ability of repressor to protect OR1, but not OR3, from *OH radical cleavage. Altering the relative length of the poly(dA) x poly(dT) tract in the non-contacted regions of the OR1 and OR3 can reverse the cation sensitivity of repressor's affinities for these two sites. Taken together these findings show that cation-dependent alterations in DNA structure underlies indirect readout of DNA sequence by 434 repressor and perhaps other proteins.     

The missing nucleoside experiment: a new technique to study recognition of DNA by protein

We report a new technique for quickly determining which nucleosides in a DNA molecule are contacted by a sequence-specific DNA-binding protein. Our method is related to the recently reported "missing contact" experiment [Brunelle, A., & Schleif, R. F. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 6673-6679]. We treat the DNA molecule with the hydroxyl radical to randomly remove nucleosides. The ability of protein to bind to gapped DNA is assayed by gel mobility shift. Nucleosides important to protein binding are identified by sequencing gel electrophoresis. The missing nucleoside experiment can be used to scan a DNA molecule at single-nucleotide resolution in one experiment. The bacteriophage lambda repressor-OR1 and cro-OR1 complexes were analyzed to evaluate the method. For both proteins, the most important contacts are located in the protein monomer that binds to the consensus half of the operator. These contacts correspond well to those found by mutational studies, and in the cocrystal structure of the lambda repressor-operator. The missing nucleoside data show that the amino-terminal arms of lambda repressor make energetically important contacts with positions 7 and 8 and the central dyad base pair of the operator. The amino-terminal arm that makes the most extensive contacts to DNA appears to be the one that emanates from the repressor monomer that binds to the consensus half of the operator, in agreement with the cocrystal structure. The lambda cro protein does not have an amino-terminal arm, and the missing nucleoside experiment clearly shows a lack of contacts to DNA in the central region of the operator in this complex.     

Base sequence-specific interactions of operator DNA fragments with the lambda-cro repressor coupled with changes in their conformations.

The mechanism of interaction of the operator DNA with the lambda-cro repressor protein was investigated using proton n.m.r. and photo CIDNP. Three kinds of DNA duplexes, the lambda-OR3 17-mer, phi80-OR2 19-mer and CRP binding site 22-mer, were prepared, and all of their imino proton resonances of the complexes with lambda-cro were assigned to individual base pairs. By monitoring the assigned signals of the DNA fragments and lambda-cro, it was found that in the complex of lambda-cro with lambda-OR3, two subunits of the cro dimer bind to the right and left halves of the OR3, respectively, and the bidentate binding induces a structural distortion in the middle of the 17-mer. lambda-cro itself also undergoes a conformational change including loosening of the dimeric form. In the complex of lambda-cro with phi 80-OR2, which has a 6-bp sequence common to that of lambda-OR3, one subunit of the cro dimer seems to bind specifically to the common part. However, there is only a slight conformational change in the cro dimer. In the mixture of the CRP binding site 22-mer and lambda-cro, soft contact without any conformational change was observed between them.     

Comparison of the structures of cro and lambda repressor proteins from bacteriophage lambda

The three-dimensional structures of cro repressor protein and of the amino-terminal domain of lambda repressor protein, both from bacteriophage lambda, are compared. The second and third alpha-helices, alpha 2 and alpha 3, are shown to have essentially identical conformations in the two proteins, confirming the significance of the amino acid sequence homology previously noted between these and other DNA binding proteins in the region corresponding to these helices. The correspondence between the two-helical units in cro and lambda repressor protein is better than the striking agreement noted previously between two-helical units in cro and catabolite gene-activator protein. Parts of the first alpha-helices of repressor and cro show a structural correspondence that suggests a revised sequence homology between the two proteins in their extreme amino-terminal regions. In particular, there is a short loop between the alpha 1 and alpha 2 helices of lambda repressor that is missing from cro. This structural difference may account for the observed differences found with different cros and repressors in the pattern of phosphates whose ethylation prevents the binding of these proteins to their specific recognition sites. Although the two proteins have strikingly similar alpha 2-alpha 3 helical units that are presumed to bind to DNA in an essentially similar manner, stereochemical restrictions prevent the alpha 2-alpha 3 units of the respective proteins aligning on the DNA in exactly the same way.     

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.     

Spatial structure of the cro-repressor in a solution. I. Identification of interaction in a hydrophobic cluster using the nuclear Overhauser effect

The structure of a bacteriophage lambda cro repressor hydrophobic globule was studied by the technique of 1H NMR spectroscopy at 500 MHz. The analysis of NOE difference spectra and building of the molecular models for the most probable fragments of the secondary structure allowed us to assign many signals in the protein spectrum and to identify the intramolecular interactions which stabilized the hydrophobic globule and the tertiary structure of the molecule. The results suggest that the structure of the cro repressor hydrophobic globule in solution coincides with the crystal one, although there are some differences in the mutual arrangement of the alpha 1 helix and the three-fold beta-sheet. Resonance assignment has made it possible to study conformational changes and specific interactions of the cro repressor by using suitable reporter groups.     

Orientation of the Lac repressor DNA binding domain in complex with the left lac operator half site characterized by affinity cleaving.

Lac repressor (LacR) is a helix-turn-helix motif sequence-specific DNA binding protein. Based on proton NMR spectroscopic investigations, Kaptein and co-workers have proposed that the helix-turn-helix motif of LacR binds to DNA in an orientation opposite to that of the helix-turn-helix motifs of lambda repressor, lambda cro, 434 repressor, 434 cro, and CAP [Boelens, R., Scheek, R., van Boom, J. and Kaptein, R., J. Mol. Biol. 193, 1987, 213-216]. In the present work, we have determined the orientation of the helix-turn-helix motif of LacR in the LacR-DNA complex by the affinity cleaving method. The DNA cleaving moiety EDTA.Fe was attached to the N-terminus of a 56-residue synthetic protein corresponding to the DNA binding domain of LacR. We have formed the complex between the modified protein and the left DNA half site for LacR. The locations of the resulting DNA cleavage positions relative to the left DNA half site provide strong support for the proposal of Kaptein and co-workers.     

Coupled energetics of lambda cro repressor self-assembly and site-specific DNA operator binding II: cooperative interactions of cro dimers

The bacteriophage lambda relies on interactions of the cI and cro repressors which self assemble and bind the two operators (O(R) and O(L)) of the phage genome to control the lysogenic to lytic switch. While the self assembly and O(R) binding of cI have been investigated in detail, a more complete understanding of gene regulation by phage lambda also requires detailed knowledge of the role of cro repressor as it dimerizes and binds at O(R) sites. Since dimerization and operator binding are coupled processes, a full elucidation of the regulatory energetics in this system requires that the equilibrium constants for dimerization and cooperative binding be determined. The dimerization constant for cro has been measured as a prelude to these binding studies. Here, the energetics of cro binding to O(R) are evaluated using quantitative DNaseI footprint titration techniques. Binding data for wild-type and modified O(R) site combinations have been simultaneously analyzed in concert with the dimerization energetics to obtain both the intrinsic and cooperative DNA binding energies for cro with the three O(R) sites. Binding of cro dimers is strongest to O(R)3, then O(R)1 and lastly, O(R)2. Adjacently bound repressors exhibit positive cooperativity ranging from -0.6 to -1.0 kcal/mol. Implications of these, newly resolved, energetics are discussed in the framework of a dynamic model for gene regulation. This characterization of the DNA-binding properties of cro repressor establishes the foundation on which the system can be explored for other, more complex, regulatory elements such as cI-cro cooperativity.     

The roles of residues 5 and 9 of the recognition helix of Lac repressor in lac operator binding

We constructed expression libraries for Lac repressor mutants with amino acid exchanges in positions 1, 2, 5 and 9 of the recognition helix. We then analysed the interactions of residues 5 and 9 with operator variants bearing single or multiple symmetric base-pair exchanges in positions 3, 4 and 5 of the ideal fully symmetric lac operator. We isolated 37 independent Lac repressor mutants with five different amino acids in position 5 of the recognition helix that exhibit a strong preference for particular residues in position 2 and, to a lesser extent, in position 1 of the recognition helix. Our results suggest that residue 5 of the recognition helix (serine 21) contributes to the specific recognition of base-pair 4 of the lac operator. They further suggest that residue 9 of the recognition helix (asparagine 25) interacts non-specifically with a phosphate of the DNA backbone, possibly between base-pairs 2 and 3.     

Structural basis of gene regulation by the tetracycline inducible Tet repressor-operator system

The tetracycline repressor (TetR) regulates the most abundant resistance mechanism against the antibiotic tetracycline in grain-negative bacteria. The TetR protein and its mutants are commonly used as control elements to regulate gene expression in higher eukaryotes. We present the crystal structure of the TetR homodimer in complex with its palindromic DNA operator at 2.5 A resolution. Comparison to the structure of TetR in complex with the inducer tetracycline-Mg2+ allows the mechanism of induction to be deduced. Inducer binding in the repressor core initiates conformational changes starting with C-terminal unwinding and shifting of the short helix a6 in each monomer. This forces a pendulum-like motion of helix a4, which increases the separation of the attached DNA binding domains by 3 A, abolishing the affinity of TetR for its operator DNA.     

Interaction of the Bacillus subtilis phage phi 105 repressor DNA: a genetic analysis.

The Bacillus subtilis phage phi 105 repressor specifically recognizes a 14-bp operator sequence which does not exhibit 2-fold rotational symmetry. To facilitate a genetic analysis of this sequence-dependent DNA binding a B. subtilis strain was constructed in which mutations affecting the phi 105 repressor-operator interaction cause a selectable phenotype, chloramphenicol resistance. After in vivo mutagenesis, we isolated and mapped 22 different mutations in the repressor coding sequence, 15 of which are missense substitutions. These are exclusively located in the N-terminal part (positions 1-43) of the 144 residue long polypeptide. Two nonsense mutants, at positions 70 and 89, respectively, still show partial repressor activity. These data suggest that the phi 105 repressor consists of at least two independently folding structural domains, of which the N-terminal is involved in operator binding. Twelve missense mutations are clustered in a region extending from Gln-18 to Arg-37, which we propose to be the DNA-binding alpha-helix--beta-turn--alpha-helix motif, common to all lambda Cro-like repressors. The second ('recognition') helix shows significant homology with the corresponding sequence in Tn3 resolvase, and there is also a striking similarity between the phi 105 operator and the consensus sequence for a Tn3 res half-site. Based on these observations, and on the previously isolated phi 105 0c mutants, we tentatively assign some specific contacts between base pairs from the first half of a phi 105 operator site and amino acids from the repressor's 'recognition helix'.     

Binding studies with mutants of Zif268. Contribution of individual side chains to binding affinity and specificity in the Zif268 zinc finger-DNA complex.

The Zif268 zinc finger-DNA complex has served as a model system for understanding how Cys2His2 type zinc fingers recognize DNA. Structural studies of the Zif268-DNA complex revealed that residues at four positions in the alpha helix of each zinc finger play key roles in recognition, but there has been no information about the precise contributions of individual residues. Here we report the results of binding studies involving five mutants of Zif268 that have changes in the base-contacting residues of finger one. These studies let us evaluate the contributions that Arg18 (position -1 of the alpha helix), Asp20 (position 2), Glu21 (position 3), and Arg24 (position 6) make to the overall energy of DNA binding. Our results confirm the important role played by these arginines. By comparing the affinities of the wild type and mutant peptides for various sites, we also prove that Asp20 and Glu21 play important roles in determining binding site specificity.     

The interaction of the recognition helix of lac repressor with lac operator.

We have constructed a system which allows systematic testing of repressor--operator interactions. The system consists of two plasmids. One of them carries a lac operon in which lac operator has been replaced by a unique restriction site into which synthetic operators can be cloned. The other plasmid carries the gene coding for the repressor, in our case a semisynthetic lacI gene of which parts can be exchanged in a cassette-like manner. A galE host allows us to select for mutants which express repressors with altered specificities. Here we report the change of specificity in the lac system by changing residues 1 and 2 of the recognition helix of lac repressor. The specificity changes are brought about cooperatively by the change of both residues. Exchanges of just one residue broaden the specificity. Our results hint that the recognition helix of lac repressor may possibly have the opposite orientation to those in Lambda cro protein or 434 CI repressor.     

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.