Dissociation of the lactose repressor-operator DNA complex: effects of size and sequence context of operator-containing DNA

The dissociation kinetics for repressor-32P-labeled operator DNA have been examined by adding unlabeled operator DNA to trap released repressor or by adding a small volume of concentrated salt solution to shift the Kd of repressor-operator interaction. The dissociation rate constant for pLA 322-8, an operator-containing derivative of pBR 322, was 2.4 X 10(-3) s-1 in 0.15 M KCl. The dissociation rate constant at 0.15 M KCl for both lambda plac and pIQ, each of which contain two pseudooperator sequences, was approximately 6 X 10(-4) s-1. Elimination of flanking nonspecific DNA sequences by use of a 40 base pair operator-containing DNA fragment yielded a dissociation rate constant of 9.3 X 10(-3) s-1. The size and salt dependences of the rate constants suggest that dissociation occurs as a multistep process. The data for all the DNAs examined are consistent with a sliding mechanism of facilitated diffusion to/from the operator site. The ability to form a ternary complex of two operators per repressor, determined by stoichiometry measurements, and the diminished dissociation rates in the presence of intramolecular nonspecific and pseudooperator DNA sites suggest the formation of an intramolecular ternary complex. The salt dependence of the dissociation rate constant for pLA 322-8 at high salt concentrations converges with that for a 40 base pair operator. The similarity in dissociation rate constants for pLA 322-8 and a 40 base pair operator fragment under these conditions indicates a common dissociation mechanism from a primary operator site on the repressor.     

Analysis of trp repressor-operator interaction by filter binding.

A filter binding assay was developed that allows measurement of specific binding of trp repressor to operator DNA. The most important feature of this procedure is the concentration and type of salt present in the binding buffer. Using this assay the dissociation constant of the repressor-operator complex was determined to be 2.6 X 10(-9) M, and 1.34 repressor dimers were found to be bound to each operator-containing DNA molecule. These values agree with those obtained by more complex methods. The dissociation constant of the repressor for the corepressor L-tryptophan in the presence of operator DNA was shown to be 2.5 X 10(-5) M. A synthetic 48 bp operator fragment was used to determine the repressor-operator dissociation constant in the presence of tryptophan or tryptophan analogs which have higher or lower affinities for aporepressor. The rate of dissociation of repressor from operator DNA also was determined. Our findings indicate that dissociation is influenced by the concentration of tryptophan or tryptophan analogs and suggest that release of the corepressor may be the first step in dissociation of the repressor-operator complex.     

Interaction of effecting ligands with lac repressor and repressor-operator complex.

The equilibrium association constants for the binding of a wide variety of effecting ligands of the lac repressor were measured by equilibrium dialysis. Also, detailed investigations of the apparent rate of dissociation of repressor-operator comples as a function of ligand concentration were carried out for several inducers and anti-inducers. The affinity of repressor-ligand comples for operator DNA was evaluated from the specific rate constants at saturating concentrations of effecting ligand. By fitting the experimental data depicting the functional dependence of the rate of dissociation upon ligand concentrations to calculated curves, assuming simple models of the induction mechanism, the equilibrium association constant for the binding of effecting ligand to repressor-operator comples was determined. Inducers reduce the affinity of lac repressor for operator DNA by a factor of approximately 1000 under standard conditions; the extent of destabilization depends on Mg2+ ion concentration. Anti-inducers increase the affinity of repressor for operator at most a factor of five. Only one neutral ligand, which binds to repressor without altering the stability of repressor-operator comples, was found. No homotropic or heterotropic interactions in the binding of effecting ligands either to repressor or to repressor-operator complex are evident.     

Interaction of chloroquine with linear and supercoiled DNAs. Effect on the torsional dynamics, rigidity, and twist energy parameter

The magnitude and uniformity of the torsion elastic constant (alpha) of linear pBR322 DNA and supercoiled pBR322 DNAs with high-twist (sigma = -0.083) and normal-twist (sigma = -0.48) are measured in 0.1 M NaCl as a function of added chloroquine/base-pair ratio (chl/bp) by studying the fluorescence polarization anisotrophy (FPA) of intercalated ethidium dye. The time-resolved FPA is measured by using a picosecond dye laser for excitation and time-correlated single-photon counting detection. A general theory is developed for the binding of ligands that unwind superhelical DNAs, and the simultaneous binding of two different intercalators is treated in detail. The equilibrium constant (K) for binding chloroquine to linear pBR322 DNA and the number (r) of bound chloroquines per base pair are determined from the relative amplitude ratio of the slow (normally intercalated) and fast (free) components in the decay of the (probe) ethidium fluorescence intensity as a function of chl/bp. For chloroquine binding to supercoiled pBR322 DNAs, the intrinsic binding constant is assumed to be the same as for the linear DNA, but the twist energy parameter ET (N times the free energy to change the linking number from 0 to 1 in units of kBT) is regarded as adjustable. Using the best-fit ET, the binding ratios r are calculated for each chl/bp ratio. Twist energy parameters are also determined for ethidium binding to these supercoiled DNAs by competitive dialysis. For chloroquine binding, we obtain ET = 360 and 460 respectively for the normal-twist and high-twist supercoiled DNAs. For ethidium binding the corresponding values are ET = 280 +/- 70 and 347 +/- 50. Like other dye-binding values, these are substantially lower than those obtained by ligation methods. In the absence of chloroquine, the torsion constants of all three DNAs are virtually identical, alpha = (5.0 +/- 0.4) x 10(-12) dyn.cm. For linear pBR322 DNA, the magnitude and uniformity of alpha remain unaltered by intercalated chloroquine up to r = 0.19. This finding argues that the FPA is not significantly relaxed by diffusion of any kinks or solitons. If alpha d denotes the torsion constant between a dye and a base pair and alpha 0 that between two base pairs, then our data imply that alpha d/alpha 0 lies in the range 0.65-1.64, with a most probable value of 1.0.(ABSTRACT TRUNCATED AT 400 WORDS)     

Poisson-Boltzmann analysis of the lambda repressor-operator interaction.

A theoretical study of the ion atmosphere contribution to the binding free energy of the lambda repressor-operator complex is presented. The finite-difference form of the Poisson-Boltzmann equation was solved to calculate the electrostatic interaction energy of the amino-terminal domain of the lambda repressor with a 9 or 45 base pair oligonucleotide. Calculations were performed at various distances between repressor and operator as well as at different salt concentrations to determine ion atmosphere contributions to the total electrostatic interaction. Details in the distribution of charges on DNA and protein atoms had a strong influence on the calculated total interaction energies. In contrast, the calculated salt contributions are relatively insensitive to changes in the details of the charge distribution. The results indicate that the ion atmosphere contribution favors association at all protein-DNA distances studied. The theoretical number of ions released upon repressor-operator binding appears to be in reasonable agreement with experimental data.     

Specific binding of lac repressor to linear versus circular polyoperator molecules

Gel shift assays were used to examine the binding of the lactose (lac) repressor to polyoperator DNA molecules. Specific binding was differentiated from nonspecific DNA association by (i) equilibrating repressor-operator complexes below the nonspecific association constant and (ii) demonstrating the effects of the inducer isopropyl beta-D-thiogalactoside (IPTG) on the formation of repressor-operator complexes. With the linear polyoperator molecules, all eight operator sites could be simultaneously bound by distinct repressors. However, with circular molecules, the eight operator sites were saturable by repressor only in the nicked circular state and not in the covalently closed circular form. Under the experimental conditions used, there was no evidence of bifunctional repressor binding or loop formation. The results suggest that the conformational perturbation of DNA that occurs upon specific repressor binding was retained in topologically closed molecules and could modify other operator sites so as to make them unavailable for specific binding.     

Site and sequence specificity of the daunomycin-DNA interaction

The site and sequence specificity of the daunomycin-DNA interaction was examined by equilibrium binding methods, by deoxyribonuclease I footprinting studies, and by examination of the effect of the antibiotic on the cleavage of linearized pBR322 DNA by restriction endonucleases PvuI and EcoRI. These three experimental approaches provide mutually consistent results showing that daunomycin indeed recognizes specific sites along the DNA lattice. The affinity of daunomycin toward natural DNA increases with increasing GC content. The quantitative results are most readily explained by binding models in which daunomycin interacts with sites containing two adjacent GC base pairs, possibly occurring as part of a triplet recognition sequence. Deoxyribonuclease I footprinting studies utilizing the 160 base pair (bp) tyrT DNA fragment and 61 and 53 bp restriction fragments isolated from pBR322 DNA further define the sequence specificity of daunomycin binding. Specific, reproducible protection patterns were obtained for each DNA fragment at 4 degrees C. Seven protected sequences, ranging in size from 4 to 14 bp, were identified within the tyrT fragment. Relative to the overall tyrT sequence, these protected sequences were GC rich and contained a more limited and distinct distribution of di- and trinucleotides. Within all of the protected sequences, a triplet containing adjacent GC base pairs flanked by an AT base pair could be found in one or more copies. Nowhere in the tyrT fragment did that triplet occur outside a protected sequence. The same triplet occurred within seven out of nine protected sequences observed in the fragments isolated from pBR322 DNA. In the two remaining cases, three contiguous GC base pairs were found. We conclude that the preferred daunomycin triplet binding site contains adjacent GC base pairs, of variable sequence, flanked by an AT base pair. This conclusion is consistent with the results of a recent theoretical study of daunomycin sequence specificity [Chen, K.-X., Gresh, N., & Pullman, B. (1985) J. Biomol. Struct. Dyn. 3, 445-466]. Adriamycin and the beta-anomer of adriamycin produce the same qualitative pattern of protection as daunomycin with the tyrT fragment. Daunomycin inhibits the rate of digestion of pBR322 DNA by PvuI (recognition sequence 5'-CGATCG-3') to a greater extent than it does EcoRI (recognition sequence 5'-GAATTC-3'), a finding consistent with the conclusions derived from our footprinting studies. Our results, as a whole, are the clearest indication to date that daunomycin recognizes a specific DNA sequence as a preferred binding site.     

Interaction of Hoechst 33258 with repeating synthetic DNA polymers and natural DNA

Fluorescence, circular dichroism and sedimentation through cesium chloride gradient techniques were performed to study the physical properties of the binding of the bisbenzimidazole dye Hoechst 33258 (H33258) to natural DNAs and synthetic polynucleotides of defined repeating units. These studies show that Hoechst 33258 exhibits at least two modes of interaction with duplex DNA: (1) a strong base pair specific mode which requires at least 4 consecutive AT base pairs and (2) a weaker mode of binding which is significantly reduced in the presence of high salt (0.4 M NaCl) and exhibits no apparent base specificity. The H33258 binding was found to be sensitive to the substitutions in the minor groove elements of a series of synthetic polynucleotides supporting the model of H33258 binding in the minor groove of the DNA with AT rich sequences. Similar mode of binding was predicted in natural DNAs by methylation of dye-DNA complexes. Footprint analysis of the complex of dye to a pBR322 fragment also supports that a minimum of 4 consecutive AT base pairs are required for H33258 binding to DNA.     

The ban operon of bacteriophage P1. Localization of the promoter controlled by P1 repressor

Repression of a strong promoter localized 5' to the P1 ban gene is a prerequisite for cloning the ban operon in the multicopy plasmid pBR325. Repression is brought about by the binding of P1 repressor to the operator of the ban operon (Heisig, A., Severin, I., Seefluth, A. K., and Schuster, H. (1987) Mol. Gen. Genet. 206, 368-376). Binding of RNA polymerase in vitro overlaps with the operator and is inhibited by P1 repressor as shown by electron microscopy. The mutant P1 bac, which renders ban expression constitutive, contains a single base pair exchange within the operator. As a consequence, more repressor is required (i) for the inhibition of binding of RNA polymerase, and (ii) for the electrophoretic retardation of a P1 bac DNA fragment when compared to the corresponding bac+ fragment. A P1 ban recombinant plasmid containing a 4-base pair deletion close to the operator still allows binding of repressor but not of RNA polymerase. By that means, a repressible promoter is located at the P1 map position 72 in a distance of about 2.5 kilobase pairs to the beginning of the ban gene.     

Equilibria and kinetics of lac repressor-operator interactions by polyacrylamide gel electrophoresis.

We describe the use of gel electrophoresis in studies of equilibrium binding, site distribution, and kinetics of protein-DNA interactions. The method, which we call protein distribution analysis, is simple, sensitive and yields thermodynamically rigorous results. It is particularly well suited to studies of simultaneous binding of several proteins to a single nucleic acid. In studies of the lac repressor-operator interaction, we found that binding to the so-called third operator site (03) is 15-18 fold weaker than operator binding, and that the binding reactions with the first and third operators are uncoupled, implying that there is no communication between the sites. Pseudo-first order dissociation kinetics of the repressor-203 bp operator complex were found to be temperature sensitive, with delta E of 80 kcal mol-1 above 29 degrees C and 26 kcal mol-1 below. The half life of the complex (5 min at 21 degrees C) is shorter than that reported for very high molecular weight operator-containing DNAs, but longer than values reported for much shorter fragments. The binding of lac repressor core to DNA could not be detected by this technique: the maximum binding constant consistent with this finding is 10(5) M-1.     

Structure of the Tet repressor and Tet repressor-operator complexes in solution from electrooptical measurements and hydrodynamic simulations

The Tet repressor protein and tet operator DNA fragments and their complexes have been analyzed by electrooptical procedures. The protein shows a positive linear dichroism at 280 nm, a negative linear dichroism at 248 nm, and a strong permanent dipole moment of 3.5 X 10(-27) C m, which is independent of the salt concentration within experimental accuracy. Its rotation time constant of 40 ns indicates an elongated structure, which is consistent with a prolate ellipsoid of 100 A for the long axis and 40 A for the short axis. The time constant can also be fitted by a cylinder of length 78 A and diameter 37 A, which is consistent with nuclease protection data reported on repressor-operator complexes, if the cylinder axis is aligned parallel to the DNA axis. Addition of tetracycline induces changes of the limit dichroism but very little change of the rotation time constant. The rotation time constants observed for the operator DNA fragments show some deviations from the values expected from their contour length; however, these deviations remain relatively small. Formation of repressor-operator complexes leads to some increase of the DNA rotation time constants. Simulations by bead models demonstrate that these time constants can be explained without any major change of the hydrodynamic dimension of the components. The data for the complexes are fitted by bead models with smooth bending of the DNA corresponding to a radius of curvature of 500 A, but at the given accuracy, we cannot rule out that the DNA in the complex remains straight or is bent to a smaller radius of approximately 400 A. Thus, binding of the Tet repressor, which is a helix-turn-helix protein as judged from its sequence, to its operator seems to induce minor bending but does not induce strong bending of the DNA double helix.     

Large-scale purification, oligomerization equilibria, and specific interaction of the LexA repressor of Escherichia coli

A rapid large-scale procedure for the purification of the LexA repressor of Escherichia coli is described. This procedure allows one to get more than 100 mg of purified protein from 100 g of bacterial paste with a purity of at least 97%. This method is comparable to earlier, far more complicated purification procedures giving clearly smaller yields. It is shown that the LexA protein may be identified spectroscopically by a large A235/A280 ratio and very pronounced ripples in the absorption spectrum arising from a high amount of phenylalanine residues with respect to that of the other aromatic amino acids. Polyacrylamide gel electrophoresis has been used to study the specific interaction of LexA with a recA operator fragment. The quaternary structure of LexA has been studied by equilibrium ultracentrifugation and sedimentation velocity measurements. The sedimentation coefficient increases with increasing LexA concentration, indicating that LexA is involved in self-association. This finding has been confirmed by equilibrium ultracentrifugation. The results are best described by a monomer-dimer and a subsequent dimer-tetramer equilibrium, with an association constant of 2.1 X 10(4) M-1 for the dimer and 7.7 X 10(4) M-1 for the tetramer formation. These relatively small association constants determined under near-physiological pH and salt conditions suggest that in vivo LexA should be essentially in the monomeric state. The degree to which LexA decreases the electrophoretic mobility of a 175 base pair fragment harboring the recA operator suggests that the recA operator interacts nevertheless with a LexA dimer. However, our results may be also explained by the binding of a LexA monomer with a simultaneous bending of the DNA fragment.     

Amino acids determining operator binding specificity in the helix-turn-helix motif of Tn10 Tet repressor.

Each of 22 amino acids in the proposed alpha-helix-turn-alpha-helix operator binding motif of the Tn10 encoded Tet repressor was replaced by alanine and one residue was replaced by valine to determine their role in tet operator recognition by a 'loss of contact' analysis with 16 operator variants. One class of amino acids consisting of T27 and R28 in the first alpha-helix and L41, Y42, W43 and H44 in the recognition alpha-helix are quantitatively most important for wild-type operator binding. These residues are probably involved in the structural architecture of the motif. A second class of residues is quantitatively less important for binding, but determines specificity by forming base pair specific contacts to three positions in tet operator. This property is most clearly demonstrated for Q38 and P39 and to a lesser extent for T40 at the N-terminus of the recognition alpha-helix. The contacted operator base pairs indicate that the N-terminus of the recognition alpha-helix is located towards the palindromic center in the repressor-operator complex. Although the orientation of the recognition alpha-helix in the Tet repressor-tet operator complex is inversed as compared with the lambda- and 434 repressor-operator complexes, the reduced operator binding of the TA27 mutation in the first alpha-helix suggests that the hydrogen bonding networks connecting the two alpha-helices may be similar in these proteins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Non-contacted bases affect the affinity of synthetic P22 operators for P22 repressor.

The affinity of synthetic P22 operators for P22 repressor varies with the base sequence at the operator's center. At 100 mM KCl, the affinity of these operators for P22 repressor varies over a 10-fold range. Dimethylsulfate protection experiments indicate that the central bases of the P22 operator are not contacted by the repressor. The KD for the complex of P22 repressor with an operator bearing central T-A bases (9T) increases less than 2-fold between 50 and 200 mM KCl, whereas the KD for the complex of repressor with an operator bearing central C-G bases (9C) increases 10-fold in the same salt range. The DNase I cleavage patterns of both bound and unbound P22 operators also vary with central base sequence. The DNase I pattern of the repressor-9C operator complex changes markedly with salt concentration, whereas that of the 9T operator-repressor complex does not. These changes in nuclease digestion pattern thereby mirror the salt-dependent changes in the P22 operator's affinity for repressor. P22 repressor protects the central base pair of the 9T operator from cleavage by the intercalative cleavage reagent Cu(I)-phenanthroline, while repressor does not protect the central bases of the 9C operator. Together these data indicate that central base pairs affect P22 operator strength by altering the structure of the unbound operator and the repressor-operator complex.     

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.     

Studies on gene control regions XII. The functional significance of a lac operator constitutive mutation.

The functional significance of a lac operator constitutive mutation has been determined. The transition adenine-thymine to guanine-cytosine was shown to be a constitutive mutation simply because thymine contains the functionally important 5-methyl group whereas cytosine does not. The remainder of the base pair is of no consequence. The experimental approach was to synthesize various modified operators containing cytosine, 5-methyl-cytosine, and 5-bromocytosine. The synthetic operator containing a guanine-cytosine base pair displays an eightfold reduction in stability with lac repressor whereas the operator containing 5-methylcytosine binds repressor at least as tightly as does the wild type sequence. Results published previously have shown that a similar decrease in stability of the repressor-operator complex can be obtained simply by substituting uracil for thymine or by inverting the base pair to thymine-adenine. All these results taken together implicate the thymine 5-methyl as the only important functional group recognized by the lac repressor at this base pair. Further confirmation of this conclusion was obtained by substitution of 5-bromocytosine and 5-bromouracil at this base pair. Both altered the stability of the repressor-operator complex by about the same percent suggesting that the bromine atom was the important determinant of complex stability for 5-bromopyrimidine analogs.     

Formation of mixed disulfide adducts at cysteine-281 of the lactose repressor protein affects operator and inducer binding parameters

The lactose repressor protein has been modified with three sulfhydryl-specific reagents which form mixed disulfide adducts. Methyl methanethiosulfonate (MMTS) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) completely reacted with all three cysteine residues, whereas only partial reaction was observed with didansylcystine. Cysteines-107 and -140 reacted stoichiometrically with MMTS and DTNB, while Cys-281 was modified only at higher molar ratios. Didansylcystine reacted primarily with cysteines-107 and -140. Affinity of MMTS-modified repressor for 40 base pair operator DNA was decreased 30-fold compared to unmodified repressor, and this decrease correlated with modification of cysteine-281. DTNB-modified repressor bound operator DNA with a 50-fold weaker affinity than unmodified repressor. Modification of the lac repressor with didanylcystine decreased operator binding only 4-fold, and nonspecific DNA binding increased 3-fold compared to unmodified repressor. No change in the inducer equilibrium binding constant was observed following modification with any of these reagents. In contrast, inducer association and dissociation rate constants were decreased approximately 50-fold for repressor completely modified with MMTS or DTNB, while didansylcystine had minimal effect on inducer binding kinetics. Correlation between modification of Cys-281 and the observed decrease in rate constants indicates that this region of the protein regulates the accessibility of the sugar binding site. The parallel between the increase in the Kd for repressor binding to operator, the altered rate constant for inducer binding, and modification of cysteine-281 suggests that this region of the protein is crucially involved in the function of the repressor protein.     

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.