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

Operator DNA sequence variation enhances high affinity binding by hinge helix mutants of lactose repressor protein

The mechanism by which genetic regulatory proteins discern specific target DNA sequences remains a major area of inquiry. To explore in more detail the interplay between DNA and protein sequence, we have examined binding of variant lac operator DNA sequences to a series of mutant lactose repressor proteins (LacI). These proteins were altered in the C-terminus of the hinge region that links the N-terminal DNA binding and core sugar binding domains. Variant operators differed from the wild-type operator, O(1), in spacing and/or symmetry of the half-sites that contact the LacI N-terminal DNA binding domain. Binding of wild-type and mutant proteins was affected differentially by variations in operator sequence and symmetry. While the mutant series exhibits a 10(4)-fold range in binding affinity for O(1) operator, only a approximately 20-fold difference in affinity is observed for a completely symmetric operator, O(sym), used widely in studies of the LacI protein. Further, DNA sequence influenced allosteric response for these proteins. Binding of this LacI mutant series to other variant operator DNA sequences indicated the importance of symmetry-related bases, spacing, and the central base pair sequence in high affinity complex formation. Conformational flexibility in the DNA and other aspects of the structure influenced by the sequence may establish the binding environment for protein and determine both affinity and potential for allostery.

Lactose repressor protein: functional properties and structure

The lactose repressor protein (LacI), the prototype for genetic regulatory proteins, controls expression of lactose metabolic genes by binding to its cognate operator sequences in E. coli DNA. Inducer binding elicits a conformational change that diminishes affinity for operator sequences with no effect on nonspecific binding. The release of operator is followed by synthesis of mRNA encoding the enzymes for lactose utilization. Genetic, chemical and physical studies provided detailed insight into the function of this protein prior to the recent completion of X-ray crystallographic structures. The structural information can now be correlated with the phenotypic data for numerous mutants. These structures also provide the opportunity for physical and chemical studies on mutants designed to examine various aspects of lac repressor structure and function. In addition to providing insight into protein structure-function correlations, LacI has been utilized in a wide variety of applications both in prokaryotic gene expression and in eukaryotic gene regulation and studies of mutagenesis.

Detection of protein-DNA complex formation by time-resolved fluorescence depolarization of bound ethidium bromide

We introduce the use of time-resolved fluorescence spectroscopy to probe the interaction between gene regulatory proteins and DNA. Changes in the decay kinetics of fluorescence polarization anisotropy of ethidium bromide bound to DNA segments report changes in hydrodynamic volume and shape which occurs upon complex formation between protein and DNA. We have used the decay of fluorescence polarization anisotropy as a spectroscopic handle on the interaction between several site-specific DNA-binding proteins involved in transcriptional regulation (the cro repressor of coliphage lambda, the lac repressor of Escherichia coli, and the RNA polymerase of coliphage T7) and their target DNA fragments ranging in length from 17 to 36 base pairs. The technique allows one to follow complex formation while varying solution conditions such as temperature, pH, ionic strength, and presence of effector molecules. Macromolecular concentrations ranging from 10(-7) to 10(-4) M can be used, allowing estimates of relative binding affinities. The magnitude of the observed rotational correlation times (phi obs) can be used to infer information about the size and shape of the complexes.

Solution conformations of DNAs containing binding sites of the catabolite gene activator protein and lac repressor protein: characterization by Raman spectroscopy

Raman spectra from three subfragments of the Escherichia coli lactose promoter region were obtained in 0.1 M NaCl. The three DNAs are 21, 40, and 62 bp in length. The 21 and 62 bp DNAs contain the binding site for the catabolite gene activator protein (CAP). The 40 bp DNA contains the binding site for the lac repressor. A quantitative analysis of Raman band characteristics indicates an overall B-type conformation for these gene regulatory sites. Bands which correspond to A-family (807 cm-1) and B-family (834 cm-1) deoxyribose phosphate vibrations have the same intensities as bands found in heterogeneous DNAs. The spectra of the 21 bp CAP site have, however, a small band at 867 cm-1 and several other small differences similar to some characteristics observed in C-DNA spectra. Several dG nucleosides in the CAP site appear to be altered from the conventional C2'-endo/anti conformation. At 45 degrees C, well below the melting region of these DNAs, small changes occur in the spectra of the 40 bp lac repressor site which are not observed in the other DNAs. A weak band occurs at 705 cm-1, and intensity changes are observed at 497, 682, and 792 cm-1. The changes suggest that the conformations of several dG nucleosides are altered and that a small region may exist with characteristics of an A-family backbone. This conformational change at 45 degrees C coincides with previous NMR observations indicating an enhanced imino proton exchange rate at a GTG sequence within the lac operator site.

Photochemical modifications of lac repressor--II. Tryptophan photochemistry as a probe in studying the allosteric behaviour of the protein

Irradiation of lac repressor under aerobic conditions in the near UV region (295-400 nm) decreases the Trp fluorescence of the protein. A total loss of fluorescence corresponds to the destruction of all tryptophanyl residues. Irradiation with light of wavelength between 250 and 400 nm quenches fluorescence completely when only half of the Trp residues ae destroyed. An internal photodynamic effect, in which N-formylkynurenine, a principal photoproduct of Trp, sensitizes further the destruction of the other Trp residues, accounts for our results. Experiments performed in the presence of sodium azide suggest that singlet oxygen is not involved in the destruction of Trp, but may be responsible for histidine degradation. Irradiating the repressor complexed with non-operator E. coli DNA has the same effect on Trp residues as irradiating repressor alone. On the contrary, when repressor is complexed to lac operator, both tryptophanyl residues seem to be destroyed simultaneously. This indicates that binding of specific operator DNA at the DNA site induces changes in the environment of the tryptophanyl residues (mainly tor Trp 220) which cannot further transfer in excitation energy to the photoproduct of the other Trp. A prolonged irradiation destroys the complex, leading to the same result observed for non-specific complex or for repressor alone. These results are discussed in terms of the proximity of Trp from the inducer binding site and the allosteric behaviour of the repressor.

Lac repressor-Lac operator complexes. Solution X-ray scattering and electrophoretic studies

Complexes between the Lac repressor and a small DNA operator fragment (29 base pairs) were investigated using polyacrylamide gel electrophoresis and solution X-ray scattering. Titration of the DNA fragment with the repressor, followed by gel electrophoresis showed that only two types of complexes are formed with repressor/operator ratios of 0.5 and 2. Radii of gyration and forward scattered intensities were obtained from Guinier plots for repressor/operator ratios ranging from 0.3 to 2. They demonstrated that the first complex contains one repressor and two operators, whereas the second one contains four repressors and two operators. Mixing operator and repressor in equimolar concentrations leads to a mixture of both complexes. A possible model for the four repressor/two operator complex is proposed.

Thermodynamic origins of specificity in the lac repressor-operator interaction. Adaptability in the recognition of mutant operator sites

A system has been developed for facile generation and characterization of mutant lac operator sites, free of competing pseudo operator sequences. The interaction of lac repressor with these sites has been investigated by the nitrocellulose filter binding assay. The equilibrium binding affinity for each of three single-site changes was reduced by more than three orders of magnitude relative to the wild-type operator under standard assay conditions. The free-energy changes associated with single base-pair substitutions are not additive. We propose that adaptations in the recognition surface of the repressor involving significant trade-offs between electrostatic versus non-electrostatic interactions and between enthalpic versus entropic contributions to the binding free energy occur, in order to achieve the most stable complex with a given DNA sequence.

Correlation of lac operator DNA imino proton exchange kinetics with its function

The kinetics for imino hydrogen exchange, at individual base pairs in the DNA sequence corresponding to the lactose operon operator of Escherichia coli, has been examined by NMR saturation recovery measurements as a function of temperature. Three 17-base-pair subsections of the lac operator DNA were chemically synthesized for these studies. The results support our previous observations in the 36-base-pair complete lac operator DNA fragment that has been used in our previous NMR studies. The results indicate faster opening kinetics at a GTG/CAC that is also the site of operator mutations leading to the highest level of constitutive beta-galactosidase synthesis. The GTG/CAC sequence occurs frequently and often symmetrically in prokaryotic and eukaryotic DNA sites where one anticipates specific protein interaction for gene regulation or recombination.

Sequence-specific resonance assignments in the 1H nuclear-magnetic-resonance spectrum of the lac repressor DNA-binding domain 1-51 from Escherichia coli by two-dimensional spectroscopy

The assignment of the 1H nuclear magnetic resonance (NMR) spectrum of the DNA-binding domain 1-51 of lac repressor from Escherichia coli is described and documented. The assignments are based entirely on the amino acid sequence and on two-dimensional NMR experiments at 360 MHz and 500 MHz. Individual assignments were obtained at 18 degrees C for the backbone protons of 44 out of the total of 51 amino acids residues, the exceptions being Met-1, Lys-2, Tyr-7, Arg-35, Glu-36, Lys-37 and Ile-48. Complete assignments of the non-labile hydrogen atoms of the side chain were obtained for 33 residues, and for Asn-46 and Asn-50 the delta amide protons were also identified. The chemical shifts for the assigned resonances at 18 degrees C are listed for an aqueous solution at pH 4.9 and at pH 6.8.

Secondary structure of the lac repressor DNA-binding domain by two-dimensional 1H nuclear magnetic resonance in solution

A recently proposed approach for spatial structure determination in noncrystalline proteins by nuclear magnetic resonance was applied to the lac repressor DNA-binding domain. On the basis of sequence-specific 1H NMR assignments, the location of alpha-helices in the amino acid sequence was determined from nuclear Overhauser enhancement data and from amide proton exchange studies. These investigations provide detailed experimental data on the structure of a noncrystalline DNA-binding protein. The results support the hypothesis advanced by others that sequence-specific interactions between lac repressor and DNA are mediated by a particular spatial arrangement of two alpha-helices common to various different DNA-binding proteins.

Perturbation of lac operator DNA modification by tryptic core protein from lac repressor

Operator DNA fragments were modified in the presence of lac repressor protein or its trypsin-resistant core. Operator DNA was alkylated or cleaved enzymatically with these related proteins present to compare the influences of their binding on the reactivities or enzymatic susceptibilities of individual bases in the sequence. These two protein species have pronounced and distinguishable effects on the reactivity of the bases of the operator fragment toward methylation by dimethyl sulfate. Perturbation of base alkylation by the trypsin-resistant core repressor is most pronounced in the inner, asymmetric region of the operator DNA, while repressor effects extend further on either end of the operator sequence. Digestion of the two protein-operator complexes by DNase I yields fragment patterns that differ primarily in extent of protection. These data extend the experimental base supporting the involvement of the core region of the lac repressor in addition to its NH2 termini in the operator-specific binding activity of this protein.

Possible molecular detent in the DNA structure at regulatory sequences

A common feature that appears in a number of DNA sites where proteins interact is the sequence GTG/CAC. In the lac operator this sequence leads to a region with a higher imino proton exchange rate well below the optical melting temperature. It is suggested that this reflects a structural feature recognized by proteins that bind specific sites on the DNA molecule.

DNA-binding proteins

The structures of three proteins that regulate gene expression have been determined recently and suggest how these proteins may bind to their specific recognition sites on the DNA. One protein (Cro) is a repressor of gene expression, the second (CAP) usually stimulates gene expression, and the third (lambda repressor) can act as either a repressor or an activator. The three proteins contain a substructure consisting of two consecutive alpha helices that is virtually identical in each case. Structural and amino acid sequence comparisons suggest that this bihelical fold occurs in a number of proteins that regulate gene expression, and is an intrinsic part of the DNA-protein recognition event. The modes of repression and activation by Cro and lambda repressor are understood reasonably well, but the mode of action of CAP is still unclear.