Lac repressor–operator interaction: N-terminal peptide backbone 1H and 15N chemical shifts upon complex formation with DNA

When the lac repressor tetramer is bound to its DNA operator, methylation protection shows the nearly symmetric operator half-sites are contacted asymmetrically. This asymmetric binding results from the DNA sequence/structure. The reported structure of lac repressor N-terminal fragment and an 11 base-pair operator left half-site provides no information concerning the effect of asymmetric binding, from left operator half-site to right half-site, upon the polypeptide backbone. We isolated uniformly ¹⁵N labeled 56 amino acid wild-type (HP56WT) and 64 residue mutant [Pro3>Tyr3] (HP64tyr3) lac repressor N-terminal DNA binding fragments for ¹H/¹⁵N NMR studies with the left and right operators separately. Spectral coincidence of these longer fragments, indicating structural similarity with a protease derived 51 amino acid fragment for which the amide correlations are assigned, allows for assignment of the common amide resonances. For both HP56WT and HP64tyr3, spectral overlap of the amide correlation peaks reveals the polypeptide backbones of the uncomplexed polypeptides are structurally similar. Likewise the complexes of the peptides to the 11 base-pair lac left operator half-site are similar. On the other hand, complexes of HP56WT and the left compared to the right lac operator half-site show different residues of the polypeptide are affected by binding different half-sites of the operator. Thus, the DNA sequence/structure transmits asymmetry to the polypeptide backbone of the interacting protein.     

Escherichia coli lac repressor is elongated with its operator DNA binding domains located at both ends

From small-angle X-ray scattering experiments on solutions of Escherichia coli lac repressor and repressor tryptic core, we conclude that the domains of repressor that bind to operator DNA lie at the ends of an elongated molecule. The addition of the inducer, isopropyl-β-d-thiogalactoside, to either repressor or core does not produce a measurable structural change, since the radius of gyration of repressor is 40.3 ± 1.9 Å without and 42.2 ± 1.7 Å with isopropyl-β-d-thiogalactoside; the core radius of gyration is 35.4 ± 1.1 Å without ligand and 36.3 ± 1.1 Å with isopropyl-β-d-thiogalactoside. In the context of data from single crystals of repressor and core, the measured radii of gyration are shown to be consistent with a core (or repressor) molecule of dimensional anisotropy 1: (1.5 to 2.0): (3.0 to 4.0). The 5 Å difference in radius of gyration between native and core repressor is interpreted to mean that the amino terminal 59 residues (headpieces) lie at the ends of an elongated repressor molecule. This structure implies that the repressor may have DNA binding sites, consisting of two adjacent headpieces, on each end of the molecule and this binds to the DNA with its long axis perpendicular to the DNA.     

Lac repressor binding to poly (d(A-T)). Conformational changes

The binding of $\text{lac}$ repressor to poly [d(A-T)] at low ionic strength has been investigated by circular dichroism, fluorescence and light scattering. Poly [d(A-T)] undergoes an important conformational change upon binding to $\text{lac}$ repressor. The maximum number of binding sites corresponds to about one tetrameric repressor per 11 base pairs of poly[d(A-T)]. The inducer isopropyl β-D-thiogalactoside (IPTG) does not affect the binding of $\text{lac}$ repressor to poly[d(A-T)]. It binds equally well to free and poly[d(A-T)] -bound repressor.     

Enzymatic digestion of operator DNA in the presence of the lac repressor tryptic core

The trypsin-resistant core protein of the lac repressor was utilized in protecting operator DNA from two types of enzymatic digestion. Core repressor protects and enhances operator DNA digestion by DNase I in the same fashion as intact repressor, though to a lesser degree on the lower strand. DNase I patterns found for the ternary complexes (protein-sugar-operator) were consistent with the expected affinity alterations of the protein species in response to binding these ligands. The 3′ boundaries obtained by exonuclease III digestion for the intact repressor-operator complex varied slightly from those reported by Shalloway et al. (1980). Asymmetric binding to operator by the core repressor fragment was suggested by differences in the 3′ boundary for the core compared to intact repressor on the promoter-distal side of the complex. A composite picture of repressor structure and function emerges from the protection studies reported here and in the accompanying paper. In light of these and other results, models for repressor binding are examined.     

Purification of Lac repressor protein using polymer displacement and immobilization of the protein

Lac repressor protein was purified from E. coli BMH8117 harboring plasmid pWB1000 and E. coli K₁₂BMH 71-18 strains. Displacement of the protein with poly(ethyleneimine) (PEI) from phosphocellulose cation exchange column was shown to be an effective elution strategy. It resulted in better recoveries and sharper elution profiles than traditional salt elution without effecting the purity of the protein. The elution is assumed to proceed via displacement of bound protein by PEI when the polymer binds to the ion exchanger. The minor impurities in the protein solution were finally removed by chromatography on immobilized metal affinity column. The repressor protein undergoes distinct conformational changes upon addition of specific inducer isopropyl--D-thiogalactoside (IPTG), which is evidenced by changes in ultraviolet absorption spectrum. The protein was immobilized covalently to the Sepharose matrix. The intact biological activity of the protein after immobilization was shown by binding of genomic DNA and lac operator plasmid DNA from E. coli to the immobilized lac repressor.     

High Resolution Structural Studies of Cro Repressor Protein and Implications for DNA Recognition

Abstract

Cro repressor is a small dimeric protein that binds to specific sites on the DNA of bacteriophage λ. The structure of Cro has been determined and suggests that the protein binds to its sequence-specific sites with a pair of two-fold related α-helices of the protein located within successive major grooves of the DNA.

From the known three-dimensional structure of the repressor, model building and energy refinement have been used to develop a detailed model for the presumed complex between Cro and DNA. Recognition of specific DNA binding sites appears to occur via multiple hydrogen bonds between amino acid side chains of the protein and base pair atoms exposed within the major groove of DNA. The Cro:DNA model is consistent with the calculated electrostatic potential energy surface of the protein.

From a series of amino acid sequence and gene sequence comparisons, it appears that a number of other DNA-binding proteins have an α-helical DNA-binding region similar to that seen in Cro. The apparent sequence homology includes not only DNA-binding proteins from different bacteriophages, but also gene-regulatory proteins from bacteria and yeast. It has also been found that the conformations of part of the presumed DNA-binding regions of Cro repressor, λ repressor and CAP gene activator proteins are strikingly similar. Taken together, these results strongly suggest that a two-helical structural unit occurs in the DNA-binding region of many proteins that regulate gene expression. However, the results to date do not suggest that there is a simple one-to-one recognition code between amino acids and bases.

Crystals have been obtained of complexes of Cro with six-base-pair and nine-basepair DNA oligomers, and X-ray analysis of these co-crystals is in progress.     

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.     

Infrared study of the secondary structure of lac repressor and its tryptic core

The lac repressor and its tryptic core were studied by ir spectroscopy, and their β-structure content was determined by analysis of the spectra. Using protein-derived reference spectra, we find a β-content for lac repressor of 18% and of 23% for its tryptic core. The higher amount of β-conformation in the tryptic core is confirmed by another type of analysis (decomposition of the spectra in Gaussian curves). These results are discussed with respect to their implications for the structure of the N-terminal “headpiece” of lac repressor and for the mode of interaction of lac repressor with lac operator.     

A model for the non-specific binding of catabolite gene activator protein to DNA

The binding of E. coli catabolite gene activator protein (CAP) to non-specific sequences of DNA has been modelled as an electrostatic interaction between four basic side chains of the CAP dimer and the charged phosphates of DNA. Calculation of the electrostatic contribution to the binding free energy at various separations of the two molecules shows that complex formation is favored when CAP and DNA are separated by as much as 12 A. Thus, the long range electrostatic interactions may provide the initial energy for complex formation and also the correct relative orientation of CAP and DNA. The non-specific complex does not involve the penetration of amino acid side chains into the major grooves of DNA and permits 'sliding' of the protein along DNA, which would enhance the rate of association of CAP with the specific site as has been proposed previously for lac repressor. We propose that, as it 'slides', CAP is moving in and out of the major grooves in order to sample the DNA sequence. Recognition of the specific DNA site is achieved by a complementarity in structure and hydrogen bonding between amino acids and the edges of base pairs exposed in the major grooves of DNA.     

Repressor--operator interaction in the lac operon. II. Observations at the tyrosines and tryptophans

This paper shows that ¹⁹F-nuelear magnetic resonance spectroscopy on 3-fluoro-tyrosine and 5-fluorotryptophan-substituted wild-type lactose operon repressors from Escherichia coli can be used to examine the interactions with lac operator DNA.A survey of inducer and salt concentration effects on the repressor-operator complex is presented. The data lead us to a scheme for the interactions between the repressor, operator and inducer, in both binary and ternary complexes, that accommodate the results published by others.The complex between the tetrameric repressor and one 36 base-pair operator DNA fragment results in the simultaneous broadening of the resonances from all four N-terminal DNA binding domains. The actual contacts made by these binding domains are similar but probably not identical.The binding of the inducer molecule to the tetrameric repressor results in an allosteric change that can be monitored by the increased intensity of the resonances from individual tyrosine residues in the N-terminal binding domain. This increased N-terminal tyrosine resonance intensity in the complex is transmitted to repressor subunits that have not yet bound an inducer molecule.     

Mapping of the multiple regulatory sites for putP and putA expression in the putC region of Escherichia coli

Summary The effects of regulatory proteins on the expression of putP and putA were studied using put-lacZ fusion genes. The expression of the putP-lacZ gene was activated by the glnG gene product and the catabolite gene activator protein (CAP). The putA gene product inhibited activation of putP-lacZ gene expression by CAP or the glnG gene product and its inhibition was greater in the absence of proline. The expression of the putA-lacZ gene was activated by CAP and repressed by the glnG gene product. The putA gene product acted as a repressor in the absence of proline, but not in its presence. Studies using put-lacZ fusion genes with upstream deletions showed that the region required for the activation of putP by CAP was within 234 bp upstream of the translational initiation site and that that for the activation of putP was within 107 bp upstream of the translational initiation site of the putA gene. This supported the suggested locations of CAP binding sites. The region required for induction of putP and putA expression by proline was located at the Hpal site 182 bp upstream of the translational starting site of putA, suggesting that a sequence of dyad symmetry located 1 bp to the left of the HpaI site is a candidate for the binding site of the putA gene product.Abbreviations AC L-azetidine-2-carboxylic acid - Ap ampicillin - CAP catabolite gene activator protein - NR_I nitrogen regulator I - RF DNA DNA replicative form - Str streptomycin - Tc tetracycline - TTC 2,3,5-triphenyl tetrazolium chloride - UV ultraviolet     

Opposite allosteric mechanisms in TetR and CAP

Regulation of the DNA binding affinity of an oligomeric protein can be considered to consist of an intrinsic component, in which the affinity of an individual DNA‐binding domain is modulated in response to effector binding, and an extrinsic component, in which the relative position of the protein's two DNA‐binding domains are altered so that they can or cannot contact both half‐site operators simultaneously. We demonstrated directly that the TetR repressor utilizes an extrinsic mechanism and CAP, the catabolite activator protein, utilizes an intrinsic mechanism.     

Regulation in repressor inactivation by RecA protein

Treatments that damage DNA or inhibit DNA synthesis in E. coli induce the expression of a set of functions called SOS functions that are involved in DNA repair, mutagenesis, arrest of cell division and prophage induction. Induction of SOS functions is triggered by inactivation of the LexA repressor or a phage repressor. Inactivation of these repressors results from their cleavage by the E. coli RecA protein in the presence of single-stranded DNA and a nucleoside triphosphate.We found that these cleavage reactions are controlled by two mechanisms in vitro: one is through the structural change of the RecA protein in the ternary complex, RecA-ssDNA-ATP-γ-S. The active ternary complex is formed by binding of ATP-γ-S to a complex of RecA protein and ssDNA. On the other hand, when the RecA protein binds to ATP-γ-S prior to its binding to ssDNA, the resulting complex has no or only very weak cleavage activity toward the repressor. This structural change is negatively controlled by its C-terminal part. The loss of the 25 amino acid residues from the C-terminal leads the RecA protein to stable binding to dsDNA as well as ssDNA, and the protein takes the activated form for the repressor cleavage constitutively. The other mechanism is through the structural change of the repressor. The cleavage reaction of a ∅80cI repressor is greatly stimulated by the presence of d(G-G), and d(G-G) stimulates the cleavage by binding to the C-terminal half of the ∅80cI repressor. Moreover, the C-terminal fragment of the cleaved products of the 80cI repressor was able to cleave a ∅80cI-λ chimeric repressor. These results strongly suggested that th active site of the repressor cleavage was located in the C-terminal domain of the repressor and that the C-terminal fragment produced by the cleavage could cleave the repressor.     

DNA-binding site of lac repressor probed by dimethylsulfate methylation of lac operator.

In order to compare the structures of the DNA-binding sites on variants of the lac repressor, we have studied the influence of these variants on the dimethylsulfate methylation of the lac operator. Since a bound protein changes the availability of specific purines in the operator to this chemical attack, comparisons of the methylation patterns will show similarities or differences in the protein DNA contacts. We compared lac repressor, induced lac repressor (repressor bound to the gratuitous inducer isopropyl-β-d-thiogalactoside), mutant repressors having increased operator affinities (X86, I12 and the X86-I12 double mutant) and repressor peptides (long headpiece, residues 1 to 59 and short headpiece. residues 1 to 51). All of these repressors and repressor peptides exhibit the same general pattern of protection and enhancement in the operator; however, the short headpiece pattern differs most from that of the repressor while the induced repressor and the long headpiece show intermediate patterns that are strikingly similar to each other. The mutant repressors do not show an isopropyl-β-d-thiogalactoside effect but otherwise are almost indistinguishable from wild-type repressor. These results demonstrate that all molecules bind to the operator using basically the same protein-DNA contacts; they imply that (1) most and possibly all repressor contacts to operator lie within amino acids 1 to 51, (2) inducer weakens many contacts rather than totally disrupting one or even a few and (3) the tight-binding mutants do not make additional contacts to the DNA.These results are consistent with a model in which the amino-terminal portions of two repressor monomers make the DNA contacts. We show that one can understand the affinity of binding as related to the accuracy of the register of the two amino-terminal portions along the DNA. Furthermore, the action of inducer and the behaviour of the tight binding mutants can be accomodated within a two-state model in which the strongly or weakly binding states correspond to structures in which the amino-terminal regions are rigidly or loosely held with respect to each other.     

Complexes of Escherichia coli lac-repressor with non-operator DNA revealed by electron microscopy: two repressor molecules can share the same segment of DNA.

Complexes of Escherichia coli lac-repressor with non-operator DNA have been visualized in the electron microscope using high-resolution metal shadowing and negative staining. Under conditions of a high ratio of repressor to DNA, all the DNA molecules are covered by repressor molecules and the resulting complexes appear as flattened ribbons with a width of approximately 200 Å. The overall dimensions of these complexes and their substructure indicate that it is very likely that repressor molecules are tightly packed on both “sides” of the DNA helix. Thus two repressor molecules can share the same segment of non-operator DNA by binding to opposite sides of the DNA helix.     

Restriction and modification enzymes detect no allosteric changes in DNA with bound lac repressor or RNA polymerase

A 203 base-pair fragment containing the lac operator/promoter region of Escherichia coli was inserted into the EcoRI site of the plasmid vector pKC7. Rates of restriction endonuclease cleavage of the flanking EcoRI sites and of several other restriction sites on the DNA molecule were then compared in the presence and absence of bound RNA polymerase or lac repressor. The rates were identical whether or not protein had been bound, even for sites as close as 40 base-pairs from a protein binding site. No difference was detected using supercoiled, nicked circular, or linear DNA substrates. No apparent change in the rates of methylation of EcoRI sites by EcoRI methylase was produced by binding the regulatory proteins.