lac Repressor: a proton magnetic resonance look at the deoxyribonucleic acid binding fragment

Cell-free expression and selective isotope labelling in protein NMR

Isotope labelling is a very powerful tool in NMR studies of proteins and has been employed in various ways for over 40 years. 15N and 13C incorporation, using recombinant expression systems, is now commonplace because heteronuclear experiments assist with the fundamental problems of peak resolution and assignment. The use of selective labelling for peak assignment has been restricted by the scrambling of isotope label through metabolic pathways within the expression host organism. The availability of efficient cell-free expression systems with low levels of metabolic conversion allow the increasing use of selective isotope labelling as a tool in protein NMR. We describe two examples, one where a selective labelling scheme can identify backbone amide peaks from unassigned 1H--15N HSQC and HNCO spectra of a 84 residue protein, and another where a specific backbone amide in a 198 residue construct of the ninth and tenth Type III repeats from human fibronectin can be labelled and rapidly identified using a simple HSQC experiment.

31P NMR spectra of oligodeoxyribonucleotide duplex lac operator-repressor headpiece complexes: importance of phosphate ester backbone flexibility in protein-DNA recognition

The 31P NMR spectra of various 14-base-pair lac operators bound to both wild-type and mutant lac repressor headpiece proteins were analyzed to provide information on the backbone conformation in the complexes. The 31P NMR spectrum of a wild-type symmetrical operator, d(TGTGAGCGCTCACA)2, bound to the N-terminal 56-residue headpiece fragment of a Y7I mutant repressor was nearly identical to the spectrum of the same operator bound to the wild-type repressor headpiece. In contrast, the 31P NMR spectrum of the mutant operator, d(TATAGAGCGCTCATA)2, wild-type headpiece complex was significantly perturbed relative to the wild-type repressor-operator complex. The 31P chemical shifts of the phosphates of a second mutant operator, d(TGTGTGCGCACACA)2, showed small but specific changes upon complexation with either the wild-type or mutant headpiece. The 31P chemical shifts of the phosphates of a third mutant operator, d(TCTGAGCGCTCAGA)2, showed no perturbations upon addition of the wild-type headpiece. The 31P NMR results provide further evidence for predominant recognition of the 5'-strand of the 5'-TGTGA/3'-ACACT binding site in a 2:1 protein to headpiece complex. It is proposed that specific, strong-binding operator-protein complexes retain the inherent phosphate ester conformational flexibility of the operator itself, whereas the phosphate esters are conformationally restricted in the weak-binding operator-protein complexes. This retention of backbone torsional freedom in strong complexes is entropically favorable and provides a new (and speculative) mechanism for protein discrimination of different operator binding sites. It demonstrates the potential importance of phosphate geometry and flexibility on protein recognition and binding.

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.

Assignment of the 1H-NMR spectrum of a lac repressor headpiece-operator complex in H2O and identification of NOEs. Consequences for protein-DNA interaction

A complex between the headpiece amino-terminal residues 1-56 of lac repressor (HP56) and an 11-bp lac operator fragment was studied by 1H NMR. The sequence specific assignment of the exchangeable and non-exchangeable protons has been accomplished. Several protons have favourable chemical shifts in the complex, therefore new intraprotein NOEs could be found that had not been unambigously identified in the free protein. By comparison, most of these intraprotein NOEs are also present in the spectra of the free headpiece but some are different. Furthermore, several new proteins DNA NOEs could be identified. The NOE between the side-chain amide protons of Gln18 and C5H of C7 confirms the specific contact between these residues which was proposed from genetic experiments [Ebright, R. M. (1985) J. Biomol. Struct. & Dyn. 3, 281-297]. The implications of the new data for the interaction between the lac repressor headpiece and its operator are discussed.

Folding transition in the DNA-binding domain of GCN4 on specific binding to DNA

Protein-DNA recognition is often mediated by a small domain containing a recognizable structural motif, such as the helix-turn-helix or the zinc-finger. These motifs are compact structures that dock against the DNA double helix. Another DNA recognition motif, found in a highly conserved family of eukaryotic transcription factors including C/EPB, Fos, Jun and CREB, consists of a coiled-coil dimerization element the leucine-zipper and an adjoining basic region which mediates DNA binding. Here we describe circular dichroism and 1H-NMR spectroscopic studies of another family member, the yeast transcriptional activator GCN4. The 58-residue DNA-binding domain of GCN4, GCN4-p, exhibits a concentration-dependent alpha-helical transition, in accord with previous studies of the dimerization properties of an isolated leucine-zipper peptide. The GCN4-p dimer is approximately 70% helical at 25 degrees C, implying that the basic region adjacent to the leucine zipper is largely unstructured in the absence of DNA. Strikingly, addition of DNA containing a GCN4 binding site (AP-1 site) increases the alpha-helix content of GNC4-p to at least 95%. Thus, the basic region acquires substantial alpha-helical structure when it binds to DNA. A similar folding transition is observed on GCN4-p binding to the related ATF/CREB site, which contains an additional central base pair. The accommodation of DNA target sites of different lengths clearly requires some flexibility in the GCN4 binding domain, despite its high alpha-helix content. Our results indicate that the GCN4 basic region is significantly unfolded at 25 degrees C and that its folded, alpha-helical conformation is stabilized by binding to DNA.

Photo-CIDNP study of the interaction between lac repressor headpiece and lac operator DNA

Lac repressor headpiece (HP) and intact lac repressor have been studied using the photo-CIDNP method. At neutral pH histidine 29, tyrosines 7, 12 and 17 and methionine 1 are polarised. His-29 polarizations are weaker and broader in HP59 than in HP51 indicating that the C-terminal octapeptide in HP59 adopts a conformation that allows an interaction with His-29. The photo-CIDNP spectra of intact lac repressor and HP51 are very similar, showing that the same residues are accessible to the photo-excited flavin. An equimolar mixture of HP51 and a 14 base pair lac operator fragment strongly suppresses the photo-CIDNP effect of tyrosines 7 and 17 and abolishes the His-29 polarizations. The results are compared with earlier photo-CIDNP measurements on a complex of headpiece with poly[d(AT)] and with a model derived from a 2D NMR study on a lac headpiece-operator complex.

Missense mutation in the lacI gene of Escherichia coli. Inferences on the structure of the repressor protein

The lac repressor has been studied extensively but a precise three-dimensional structure remains unknown. Studies using mutational data can complement other information and provide insight into protein structure. We have been using the lacI gene-repressor protein system to study the mutational specificity of spontaneous and induced mutation. The sequencing of over 6000 lacI- mutations has revealed 193 missense mutations generating 189 amino acid replacements at 102 different sites within the lac repressor. Replacement sites are not distributed evenly throughout the protein, but are clustered in defined regions. Almost 40% of all sites and over one-half of all substitutions found occur within the amino-terminal 59 amino acid residues, which constitute the DNA-binding domain. The core domain (residues 60 to 360) is less sensitive to amino acid replacement. Here, substitution is found in regions involved in subunit aggregation and at sites surrounding residues that are implicated in sugar-binding. The distribution and nature of missense mutational sites directs attention to particular amino acid residues and residue stretches.

Complex of lac repressor headpiece with a 14 base-pair lac operator fragment studied by two-dimensional nuclear magnetic resonance

Two-dimensional nuclear Overhauser enhancement spectra are presented of the complex of lac repressor headpiece with a 14 base-pair lac operator fragment. Analysis of nuclear Overhauser enhancements observed between protein and DNA shows that the second helix of the headpiece ("the recognition helix") binds in the major groove of DNA as has been suggested, but that the orientation of this helix is approximately 180 degrees different from the proposed models.

Evidence for a contact between glutamine-18 of lac repressor and base pair 7 of lac operator

Glutamine-18 of the lac repressor (lacR) has been substituted by glycine, by serine, and by leucine. The specificities of wild-type lacR and of the three substituted lacR variants have been analyzed with respect to base pairs 5, 6, 7, 8, 9, and 10 of the lac operator (lacO). The data indicate that [Gly18]lacR, [Ser18]lacR, and [Leu18]lacR lose the ability to distinguish between the O+ base pair G . C and the Oc base pairs T . A and A . T at position 7 of lacO (KdOc/KdO+ approximately equal to 1). In contrast, the three substituted variants retain the ability to discriminate O+ from Oc at each other position, by factors of 9 to 37. Therefore, I propose that glutamine-18 contacts base pair 7 of lacO. These data suggest that the interaction between the helix-turn-helix motif and DNA may be very similar or identical in lacR and the catabolite gene activator protein.

Use of "loss-of-contact" substitutions to identify residues involved in an amino acid-base pair contact: effect of substitution of Gln18 of lac repressor by Gly, Ser, and Leu

A procedure to identify which base pair of lac operator (lacO) a suspected contacting amino acid of Lac repressor (LacR) interacts with is presented. The procedure is to eliminate the ability of the amino acid under study to contact DNA, and then to determine at which base pair--if any--specificity is eliminated. To implement this procedure, four sets of Escherichia coli K-12 strains have been constructed. These strains permit: (i) the substitution of a selected amino acid of LacR by, respectively, Gly, Ser, Leu, or Gln, and (ii) the analysis of the specificity of the resulting substituted LacR with respect to base pairs 5, 6, 7, 8, 9, and 10 of lacO. This procedure has been applied to Gln18 of LacR. The preliminary data indicate that LacR (Gln18----Gly) is unable to distinguish between the O+ base pair G:C and the Oc base pair T:A at position 7 of lacO (KDOc/KDO+ = 0.93). In contrast, LacR(Gln18----Gly) discriminates O+ from Oc by a factor of 13 to 23 at each other position. The same qualitative pattern of results was obtained with LacR(Gln18----Ser) and LacR (Gln18----Leu). Therefore, I propose that Gln18 contacts base pair 7 of lacO. This proposal is consistent with the contact predicted in Ebright, R. in Protein Structure, Folding, and Design. D. Oxender ed., Alan R. Liss, New York (1985), in press.

lac operator DNA modification in the presence of proteolytic fragments of the repressor protein

Singly end-labeled DNA fragments containing the lactose operator were methylated in the presence of the lactose repressor and homogeneous preparations of its proteolytic fragments. Binding of core protein produced by mild trypsin digestion yielded a methylation perturbation pattern that differed significantly from that elicited by binding to intact repressor, although similarities in the patterns for these related proteins were noted in the central, asymmetric region of the operator. An NH2-terminal peptide (residues 1 to 56) from lac repressor bound operator fragments in a nitrocellulose filter assay, but failed to perturb DNA methylation significantly relative to the pattern in the absence of peptide. Binding of hybrid tetramers of core and intact repressor monomers produced related but unique methylation patterns for the purines on the operator fragment. The general pattern of perturbation observed suggests preferred binding of a single NH2 terminus to the promoter-distal region of the operator and asymmetric interaction of the core region with the operator sequence. Differences in purine methylation patterns produced by the presence of effector complexes of repressor and core protein suggest the possible nature of changes in protein topology that result in the affinity changes accompanying induction.

Spatial arrangement of the three alpha helices in the solution conformation of E. coli lac repressor DNA-binding domain

The relative orientations of the 3 helices in the DNA-binding domain ('headpiece') of lac repressor have been determined using distance constraints obtained from 2-dimensional 1H nuclear Overhauser enhancement spectra. The relative orientations of its helices is similar to that of the central 3 helices in the DNA-binding domain of the lambda repressor of the bacteriophage lambda.

Molecular modelling of protein-nucleic acid interactions

Computer modeling techniques to study the interaction of proteins with nucleic acids are presented. The methods utilize information from genetic and chemical modification experiments and macromolecular structural constraints. These techniques, in addition to computer model building procedures and theoretical energy calculations, are illustrated for the study of the lac and cro repressor-operator systems. Our predicted interactions between lac and its operator agree with those recently reported for lac based upon sequence alignment with the cro repressor. Several molecular models of the putative helical segment of cro interacting with its OR3 operator are presented. These models are reflective of intermediate conformations experienced by the repressor in recognition of the operator sequence. The results of our studies are further discussed in terms of the design of short peptides interacting with nucleic acid sequences and the evolutionary requirements in establishing these repressor interactions.

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.

Solution NMR studies of intact lambda repressor

Using a combination of two and one-dimensional NMR spectroscopy, it is shown that in the intact bacteriophage lambda repressor, the N-terminal domain assumes the same global structure as when it remains isolated. It is further shown that the N-terminal domain is only loosely attached to the C-terminal domain in the intact repressor.

NMR study of the interaction between the lac repressor and the lac operator

Binding of the lac repressor headpiece, the N-terminal region of the lac repressor, to the lac operator of Escherichia coli was studied by 1H-NMR spectroscopy. Two DNA fragments, of 51 base pairs and 62 base pairs, containing the lac operator region, were investigated. The signals of their hydrogen-bonded imino protons were well resolved in the 500-MHz NMR spectra. The spectra of the free lac operator DNA are similar to those obtained from ring-current-shift calculations for a B-DNA structure. Complex formation with the headpiece led to small but nevertheless characteristic changes in the spectra. The fact that very few imino resonances shifted upon addition of headpiece, as well as the variety in direction and size of these chemical shifts, indicate the formation of a specific complex between the lac repressor and the lac operator. The observed changes in the resonance positions exclude the intercalation of tyrosine residues of the headpiece between adjacent base pairs of the lac operator as well as the formation of a cruciform structure. They rather reflect a small conformational transition in the DNA itself, caused for example by an alteration in the tilt of a few base pairs or a shift of the keto-enol tautomeric equilibrium of the bases towards the enolic form.

lac Repressor headpiece binds specifically to half of the lac operator: a proton nuclear magnetic resonance study

The complex formation of the N-terminal domain (headpiece) of the Escherichia coli lac repressor and a synthetic 14-base-pair lac operator fragment has been investigated by 1H NMR. Titration shifts in the imino-proton region of the DNA spectrum and in the aromatic region of the headpiece spectrum are examined in detail and interpreted where possible. The assignment of the resonances in the complex follows in part from the titration data and is completed by nuclear Overhauser measurements. The shift of the His-29 C-2 resonance has been used to assess the binding strength of the complex. Evidence is presented for the presence of a high-affinity site on the lac operator fragment (KD less than or equal to 2 X 10(-5) M), which shows features in common with one of the specific binding sites on the complete lac operator, and for the presence of a second, nonspecific binding site with lower affinity. The influence of this second site on the interpretation of the binding data is discussed.

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.

Homology among DNA-binding proteins suggests use of a conserved super-secondary structure

The amino acid sequences of the repressor and cro proteins of phages lambda, 434 and P22 are homologous, especially in a region in which repressor and lambda cro have a similar alpha-helix-turn-alpha-helix secondary structure. Model-building studies indicate that this structure is important in DNA binding, and we suggest it may be a common feature of many DNa-binding proteins.

Structure of the DNA-binding region of lac repressor inferred from its homology with cro repressor

It is shown that the amino acid sequence and the DNA gene sequence of the 25 amino-terminal residues of the lac repressor protein of Escherichia coli are homologous with the sequences of five DNA-binding proteins: the cro repressor proteins from phage lambda and phage 434, the cI and cII proteins from phage lambda, and the repressor protein from Salmonella phage P22. The region of homology between lac repressor and the other proteins coincides with the principal DNA-binding region of cro repressor. In particular, residues Tyr-17 through Gln-26 of lac repressor correspond to the alpha-helix Gln-27 through Ala-36 of cro repressor, which we have postulated to bind within the major groove of the DNA and to be primarily responsible for the recognition of the DNA operator region by the protein [Anderson, W. F., Ohlendorf, D. H., Takeda, Y. & Matthews, B. W. (1981) Nature (London) 290, 754--758]. By analogy with cro repressor, we propose that residues 17--26 of lac repressor are alpha-helical and that this helix and a twofold-related alpha-helix in an adjacent subunit bind within successive major grooves of the lac operator, which is in a right-handed Watson--Crick B-DNA conformation. Also, by analogy with cro repressor, we suggest that residues Thr-5 through Ala-13 of lac repressor form a second alpha-helix and contribute, in part, to DNA binding. The proposed structure for the DNA-binding region of lac repressor is consistent with chemical protection data and with genetic experiments identifying the probable locations of a number of the residues of the repressor protein that either do or do not participate in DNA binding.

lac repressor-lac operator interaction: NMR observations

We show here the changes in the NMR spectra of the Escherichia coli lac repressor when bound to isolated lac operator DNA. The observations focus on the aromatic residues--four tyrosines and a single histidine--in the amino-terminal DNA binding domain of the lac repressor. There is a good correlation between chemical shift changes seen by 19F NMR when compared with 1 H NMR of otherwise identical repressor--DNA complexes. The results suggest that the tyrosines do not intercalate in the DNA. The NMR spectral changes with similarly sized DNA fragments, not containing the lac operator DNA sequence, are different. Thus, the amino-terminal domain of the lac repressor is independently capable of discriminating between lac operator and nonspecific DNA sequences. There can be two amino-terminal fragments per operator in the specific complex.