A model for the binding of lac repressor to the lac operator

A model is suggested for the lac repressor binding to the lac operator in which the repressor polypeptide chain sequences from Gly 14 to Ala 32 and from Ala 53 to Leu 71 are involved in specific interaction with operator DNA. A correspondence between the protein and DNA sequences is found which explains specificity of the repressor binding to the lac operator. The model can be extended to describe specific binding of other regulatory proteins to DNA.     

Nonspecific binding of lac repressor to DNA. I. An absorption and circular dichroism study

Nonspecific binding of lac repressor on DNA has been studied by absorption and circular dichroism (CD) spectroscopies. In a first step, the complex formation is accompanied by an absorption difference spectrum and a change of the CD signal of the DNA. The absorption difference spectrum is mainly due to a spectral change of the DNA. The variation of the CD signal has been analyzed according to a model calculation, which takes into account the fact that the excluded site is shorter than the perturbed site. We found that in this first step one repressor can bind every 14 +/- 2 base-pairs, whereas one repressor perturbs 22 +/- 2 base-pairs. In a second step, more repressor can bind on DNA, but without further change in the absorption and CD spectrum, indicating that another binding process occurs. The model calculation developed here is general for all binding processes inducing a perturbation over a length of DNA longer than that of the excluded site.     

lac Operator nucleosomes. 2. lac Nucleosomes can change conformation to strengthen binding by lac repressor

We have shown previously that lac repressor binds specifically and quantitatively to lac operator restriction fragments which have been complexed with histones to form artificial nucleosomes (203 base pair restriction fragment) or core particles (144 base pair restriction fragment. We describe here a quantitative method for determining the equilibrium binding affinities of repressor for these lac reconstitutes. Quantitative analysis shows that the operator-histone reconstitutes may be grouped into two affinity classes: those with an affinity for repressor close to that of naked DNA and those with an affinity 2 or more orders of magnitude less than that of naked DNA. All particles in the lac nucleosome preparations bind repressor with high affinity, but the lac core particle preparations contain particles of both high and low affinities for repressor. Formaldehyde cross-linking causes all high-affinity species to suffer a 100-fold decrease in binding affinity. In contrast, there is no effect of cross-linking on species of low affinity. Therefore, the ability of a particle to be bound tightly by repressor depends on a property of the particle which is eliminated by cross-linking. Control experiments have shown that chemical damage to the operator does not accompany cross-linking. Therefore, the property sensitive to cross-linking must be the ability of the particle to change conformation. We infer that the particles of low native affinity, like cross-linked particles, are of low affinity because of an inability to facilitate repressor binding by means of this conformational change. Dimethyl suberimidate cross-linking experiments show that histone-histone cross-linking is sufficient to preclude high-affinity binding. Thus, the necessary conformational change involves a nucleosome histone core event. We find that the ability of a particle to undergo a repressor-induced facilitating conformational change appears to depend on the position of the operator along the DNA binding path of the nucleosome core. We present a general model which proposes that nucleosomes are divided into domains which function differentially to initiate conformational changes in response to physiological stimuli.     

Role of hydration in the binding of lac repressor to DNA

The osmotic stress technique was used to measure changes in macromolecular hydration that accompany binding of wild-type Escherichia coli lactose (lac) repressor to its regulatory site (operator O1) in the lac promoter and its transfer from site O1 to nonspecific DNA. Binding at O1 is accompanied by the net release of 260 +/- 32 water molecules. If all are released from macromolecular surfaces, this result is consistent with a net reduction of solvent-accessible surface area of 2370 +/- 550 A. This area is only slightly smaller than the macromolecular interface calculated for a crystalline repressor dimer-O1 complex but is significantly smaller than that for the corresponding complex with the symmetrical optimized O(sym) operator. The transfer of repressor from site O1 to nonspecific DNA is accompanied by the net uptake of 93 +/- 10 water molecules. Together these results imply that formation of a nonspecific complex is accompanied by the net release of 165 +/- 43 water molecules. The enhanced stabilities of repressor-DNA complexes with increasing osmolality may contribute to the ability of Escherichia coli cells to tolerate dehydration and/or high external salt concentrations.     

A comparison of lac repressor binding to operator and to nonoperator DNA

We have compared the operator and nonoperator DNA binding activities of the lac repressor with respect to inactivation or inhibition by trypsin, heat, actinomycin, and isopropylthiogal-actoside. The two DNA binding activities were found to differ only in their sensitivity to the inducing ligand isopropylthiogal-actoside. Repressor binding to poly(dT-dT-dG)·poly(dC-dA-dA) was shown not to be affected by isopropylthiogalactoside.     

Conformational prediction and circular dichroism studies on the lac repressor

Using the protein predictive model of Chou & Fasman (1974b), the secondary structure of the lac repressor has been elucidated from its amino acid sequence of 347 residues. The conformation is predicted to contain 37% α-helix and 35% β-sheet for the repressor, and 29% helix and 41% β-sheet for the trypsin-resistant core (residues 60 to 327). Circular dichroism studies indicate that native lac repressor contains 40% helix and 42% β-sheet, while the core has 16% helix and 54% β-sheet, in general agreement with the predicted conformation. The sharp reduction in helicity for the trypsinized lac repressor could be due to the loss of two long helical regions, 26–45 and 328–344, predicted at both terminals. There are extensive β-sheets predicted in the 215–324 region, which may be responsible for tetrameric stabilization found in both the lac repressor and the core. Residues 17 to 33 were previously predicted by Adler et al. (1972) to be helical and were proposed to bind in the major groove of DNA. However, the present analysis shows that there are two anti-parallel β-sheet regions: 4–7 and 17–24 at the N-terminal as well as 315–318 and 321–324 at the C-terminal of the lac repressor. These β-sheet pairs may assume the twisted “polypeptide double helix” conformation (Carter & Kraut, 1974) and bind to complementary regions in the major groove of DNA. The OH groups of Tyr at the N-terminal and those of Thr and Ser side chains, in both β-sheets at the N and C-terminal ends, could form hydrogen bonds to specific sites on the lac operator. There are 23 reverse β-turns predicted that may control the tertiary folding of the lac repressor, which is essential for operator binding. The behavior of several lac repressor mutants can be satisfactorily explained in terms of polar to non-polar group replacements as well as conformational changes in light of the present predicted model.     

lac Repressor-operator interaction. IX. The binding of lac repressor to operators containing Oc mutations

Representative members of the six classes of operator constitutive (O^c) point mutations, which have been mapped and well characterized in vivo, were crossed into λφ80 lac phages. The phage DNAs containing the O^c mutations were used to measure the affinity of the lac repressor (R) for each O^c operator by determining the half-lives of the different RO^c complexes in vitro. The results provide evidence that: (a) the higher the constitutive level of β-galactosidase in vivo, as the result of an O^c mutation, the lower the affinity of the lac repressor for that O^c operator, with a maximum difference of two orders of magnitude in affinity of the repressor for the highest O^c tested as compared to the wild type O⁺ operator; (b) the six classes of O^c operators appear to be twofold degenerate, in that two members of each class, which were previously distinguished by mapping, have the same affinity for the lac repressor; (c) an inducer and an anti-inducer have the same effect on the RO^c complexes as on the RO⁺ complexes; (d) the relationship between induction ratios in vivo and the binding constant of the repressor for each O^c mutation in vitro does not follow the mass action equation but rather a more complex dependency, which is discussed.These results suggest a functional symmetry in the lac operator.     

lac repressor forms loops with linear DNA carrying two suitably spaced lac operators.

Tetrameric lac repressor may bind to two lac operators on one DNA fragment and induce the intervening DNA to form a loop. Electron microscopy, non-denaturing polyacrylamide gel electrophoresis, and DNase I protection experiments were used to demonstrate such DNA loops, where the distance between the centres of symmetry of the two lac operators varies between 63 and 535 bp. Formation of a DNA loop is favoured by correct phasing of the two lac operators and a low concentration of both components of the reaction. When a large excess of lac repressor over DNA is used, a 'tandem' structure is observed, in which both lac operators are occupied independently by two repressor tetramers. When the concentrations of both lac repressor and lac operator are high, a 'sandwich' structure is observed, in which two DNA molecules are connected by two lac repressor tetramers in trans.     

Interaction between the lac operator and the lac repressor headpiece: fluorescence and circular dichroism studies

The interaction between the lac repressor headpiece and a small operator DNA fragment has been examined by fluorescence and circular dichroism (c.d.) measurements. Binding of the headpiece to the DNA fragment induces a strong quenching of the fluorescence of its tyrosine residues. Quantitative analysis of the fluorescence data demonstrates that, in a first step, two headpieces bind very strongly to the DNA fragment then weaker binding occurs. C.d. demonstrates that the binding induces conformational changes of the DNA. The c.d. change produced upon binding of the first two headpieces differs from that induced upon binding of two further headpieces . Binding of the second pair of headpieces is similar to non-specific binding to non-operator DNA. The conformation of the operator DNA in the presence of two headpieces differs drastically from that in presence of lac repressor. Addition of the core to the lac operator does not induce any conformational change of the nucleic acids. These results are discussed with respect to the relative roles of core and headpieces in the lac repressor-lac operator interaction.     

Stoichiometry of lac repressor binding to nonspecific DNA: three different complexes form

The stoichiometry of lac repressor binding to nonspecific DNA was investigated by three different techniques. Four molecules of the fluorescent probe 5,5'-bis(8-anilino-1-naphthalenesulfonate) [bis(ANS)] bind to each repressor subunit with an average dissociation constant of 20 microM. Nonspecific DNA displaces most of this bound bis(ANS), reducing the fluorescence. Titrations of repressor with nonspecific DNA monitored with high [bis(ANS)] (5-15 microM) had end points at 8 base pairs per repressor. Lower [bis(ANS)] (0.1-1 microM) resulted in end points at either 15 or 26 base pairs per repressor, depending on the ionic strength. These end points correspond to complexes containing approximately one, two, or four repressors per 28 base pairs. Boundary sedimentation velocity experiments with saturating amounts of repressor revealed that five repressors can bind to 28 base pairs. By monitoring the circular dichroism as DNA was added to repressor, the sequential appearance of complexes containing approximately four, two, and one repressors per 28 base pairs was observed. The inability of repressor cores or iodinated repressor to bind to complexes containing one or two repressors per 28 base pairs implies that all of the repressors directly contact the DNA in the complex containing four repressors per 28 base pairs. It is proposed that while two subunits of each repressor contact the DNA in complexes containing one or two repressors per 28 base pairs, only one subunit of each repressor contacts the DNA in the complex with four repressors per 28 base pairs. These results suggest a novel mechanism for the one-dimensional diffusion of repressor along DNA.     

Circular dichroism studies of the binding of o-nitrophenyl-beta-D-fucoside and o-nitrophenyl-beta-D-galactoside to lac repressor.

The binding of o-nitrophenyl-beta-D-fucoside and o-nitrophenyl-beta-D-galactoside to Escherichia coli lac repressor was investigated by circular dichroism in the wavelength range 300--400 nm corresponding to the o-nitrophenyl chromophores. The CD signal of both ligands drastically changed when they bound to lac repressor due to the asymmetric interaction of the o-nitrophenyl ring with chemical groups of protein. The CD spectra of bound ligands indicate close similarity between the environment of o-nitrophenyl-beta-D-fucoside and o-nitrophenyl-beta-D-galactoside on lac repressor. The CD signal is used to calculate the binding parameters (K and n) to lac repressor. It is demonstrated that the limited proteolytic digestion of lac repressor which gives a 'core protein' does not affect the environment of both ligands on the protein.     

Two helix DNA binding motif of CAP found in lac repressor and gal repressor.

Comparison of both the DNA and protein sequences of catabolite gene activator protein (CAP) with the sequences of lac and gal repressors shows significant homologies between a sequence that forms a two alpha-helix motif in CAP and sequences near the amino terminus of both repressors. This two-helix motif is thought to be involved in specific DNA sequence recognition by CAP. The region in lac repressor to which CAP is homologous contains many i-d mutations that are defective in DNA binding. Less significant sequence homologies between CAP and phage repressors and activators are also shown. The amino acid residues that are critical to the formation of the two-helix motif are conserved, while those residues expected to interact with DNA are variable. These observations suggest the lac and gal repressors also have a two alpha-helix structural motif which is involved in DNA binding and that this two helix motif may be generally found in many bacterial and phage repressors. We conclude that one major mechanism by which proteins can recognize specific base sequences in double stranded DNA is via the amino acid side chains of alpha-helices fitting into the major groove of B-DNA.     

Nonspecific binding of lac repressor to DNA. II. A small-angle neutron-scattering study

Complexes between lac repressor and DNA fragments from mononucleosomes have been studied by small-angle neutron scattering. Both the radius of gyration and the molecular weight of the complexes were measured, and the experimental results were interpreted according to a model with two types of complex (M. Charlier and J.-C. Maurizot, Biophys. Chem. 18 (1983) 303), and a statistical distribution of repressor on the DNA fragments. Good agreement between the model calculations and the experimental results was obtained. We concluded that there was an absence of strong cooperativity and of network formation between the complexes. The second type of binding, which does not induce any spectroscopic change, is marked by an increase in molecular weight of the complexes. Kinetic measurements were also made, which allowed the determination of the lifetime of the nonspecific DNA-repressor complexes.     

Energetic differences between the specific binding of a 40 bp DNA duplex and the lac promoter to lac repressor protein

The energetics of LRP binding to a 104 bp lac promoter determined from ITC measurements were compared to the energetics of binding to a shorter 40 bp DNA duplex with the 21 bp promoter binding site sequence. The promoter binding affinity of 2.47 +/- 0.0 1x 10(7) M(-1) was higher than the DNA binding affinity of 1.81 +/- 0.67 x 10(7) M(-1) while the binding enthalpy of -804 +/- 41 kJ mol(-1) was lower than that of the DNA binding enthalpy of -145 +/- 16 kJ mol(-1) at 298.15 K. Both the promoter and DNA binding reactions were exothermic in phosphate buffer but endothermic in Tris buffer that showed the transfer of four protons to LRP in the former reaction but only two in the latter. A more complicated dependence of these parameters on temperature was observed for promoter binding. These energetic differences are attributable to additional LRP-promoter interactions from wrapping of the promoter around the LRP.     

Genetic studies of the lac repressor. XII. Amino acid replacements in the DNA binding domain of the Escherichia coli lac repressor

Out of the first 62 residues of the lac repressor, 38 positions have been substituted by at least one amino acid exchange. The total number of replacements in this region is 131. Data from several studies are considered.     

Binding of lac repressor to the secondary lac operator in Escherichia coli.

Summary In the lac operon, the existence of a secondary repressor binding site, inside Z gene, had been inferred from in vitro binding studies (Reznikoff et al., 1974; Gilbert et al., 1975).A serie of deletions have been constructed from a lac transducing bacteriophage. Some of those deleted bacteriophages have still the property of derepressing a chromosomal lac operon, even though they do not contain any more the lac operator. This phenomenon is an indication that the secondary repressor binding site is also active in vivo.