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

Structural basis of ECF-σ-factor-dependent transcription initiation

Extracytoplasmic (ECF) σ factors, the largest class of alternative σ factors, are related to primary σ factors, but have simpler structures, comprising only two of six conserved functional modules in primary σ factors: region 2 (σR2) and region 4 (σR4). Here, we report crystal structures of transcription initiation complexes containing Mycobacterium tuberculosis RNA polymerase (RNAP), M. tuberculosis ECF σ factor σ^L, and promoter DNA. The structures show that σR2 and σR4 of the ECF σ factor occupy the same sites on RNAP as in primary σ factors, show that the connector between σR2 and σR4 of the ECF σ factor–although shorter and unrelated in sequence–follows the same path through RNAP as in primary σ factors, and show that the ECF σ factor uses the same strategy to bind and unwind promoter DNA as primary σ factors. The results define protein-protein and protein-DNA interactions involved in ECF-σ-factor-dependent transcription initiation.

No structural data have been available for RNA polymerase holoenzymes or transcription initiation complexes that contain extracytoplasmic σ factors. Here the authors report the crystal structures of transcription initiation complexes comprising Mycobacterium tuberculosis RNA polymerase, extracytoplasmic σ factor σ^L and promoter DNA.

XylS-Pm promoter interactions through two helix-turn-helix motifs: identifying XylS residues important for DNA binding and activation

The XylS protein is the positive transcription regulator of the TOL plasmid meta-cleavage pathway operon Pm. XylS belongs to the AraC family of transcriptional regulators and exhibits an N-terminal domain involved in effector recognition, and a C-terminal domain, made up of seven alpha-helices conforming two helix-turn-helix DNA-binding domains. alpha-Helix 3 and alpha-helix 6 are the recognition helices. In consonance with XylS structural organization, Pm exhibits a bipartite DNA-binding motif consisting of two boxes, called A and B, whose sequences are TGCA and GGNTA, respectively. This bipartite motif is repeated at the Pm promoter so that one of the XylS monomers binds to each of the repeats. An extensive series of genetic epistasis assays combining mutant Pm promoters and XylS single substitution mutant proteins revealed that alpha-helix 3 contacts A box nucleotides, whereas alpha-helix 6 residues contact B box nucleotides. In alpha-helix 3, Asn246 and Arg242 are involved in specific contacts with the TG dinucleotide at box A, whereas Arg296 and Glu299 contact the second G and T nucleotides at box B. On the basis of our results and of the three-dimensional model of the XylS C-terminal domain, we propose that Ser243, Glu249 and Lys250 in alpha-helix 3, and Asn299 and Arg302 in alpha-helix 6 contact the phosphate backbones. Alanine substitutions at the predicted phosphate backbone-contacting residues yielded mutants with low levels of activity, suggesting that XylS-Pm binding specificity not only involves specific amino acid-base interactions, but also relies on secondary DNA structure, which, although at another level, also comes into play. We propose a model in which a XylS dimer binds to the direct repeats in Pm in a head-to-tail conformation that allows the direct interaction of the XylS proximal subunit with the RNA polymerase sigma factor.

Amino acid-DNA contacts by RhaS: an AraC family transcription activator

RhaS, an AraC family protein, activates rhaBAD transcription by binding to rhaI, a site consisting of two 17-bp inverted repeat half-sites. In this work, amino acids in RhaS that make base-specific contacts with rhaI were identified. Sequence similarity with AraC suggested that the first contacting motif of RhaS was a helix-turn-helix. Assays of rhaB-lacZ activation by alanine mutants within this potential motif indicated that residues 201, 202, 205, and 206 might contact rhaI. The second motif was identified based on the hypothesis that a region of especially high amino acid similarity between RhaS and RhaR (another AraC family member) might contact the nearly identical DNA sequences in one major groove of their half-sites. We first made targeted, random mutations and then made alanine substitutions within this region of RhaS. Our analysis identified residues 247, 248, 250, 252, 253, and 254 as potentially important for DNA binding. A genetic loss-of-contact approach was used to identify whether any of the RhaS amino acids in the first or second contacting motif make base-specific DNA contacts. In motif 1, we found that Arg202 and Arg206 both make specific contacts with bp -65 and -67 in rhaI1, and that Arg202 contacts -46 and Arg206 contacts -48 in rhaI2. In motif 2, we found that Asp250 and Asn252 both contact the bp -79 in rhaI1. Alignment with the recently crystallized MarA protein suggest that both RhaS motifs are likely helix-turn-helix DNA-binding motifs.

Structure and dynamics of the lac repressor-operator complex as determined by NMR

The structures of the lac repressor headpiece and of its complex with an 11 base-pair lac half-operator have been determined by NMR spectroscopy. By 15N relaxation studies the dynamic behavior of the free protein and of the protein in the complex could be established. In the three-helical lac headpiece local backbone mobility was detected in the N-terminal and C-terminal peptide regions and in the loop between helices II and III. Upon DNA binding this loop becomes more rigid and it changes its conformation considerably. The specificity of the protein-DNA interaction follows from a large number of hydrogen-bond and hydrophobic interactions between amino acid side chains and DNA backbone and bases. Restrained molecular dynamics calculations suggest that some of these interactions are dynamic in nature.

Modified nucleotides reveal the indirect role of the central base pairs in stabilizing the lac repressor-operator complex

Guanine residues in the lac operator were replaced by 2-aminopurine or purine analogues, pairing the modified nucleotides with C. The observed equilibrium dissociation constants for lac repressor binding to substituted operators were measured in 10 mM Tris, 150 mM KCl, 0.1 mM EDTA, 0.1 mM DTE, pH 7.6 at 25 degrees C. These measurements revealed five positions that destabilized the complex when substituted with either analogue. Two positions, which are related by a 2-fold symmetry, are in the major groove of the operator thought to directly interact with the protein. Three sites were in the central region of the operator. A purine analogue at a sixth site perturbed the local DNA structure and destabilized the complex. Alkylation interference experiments of the 2-aminopurine substituted operators demonstrated that, of the five affected, two substitutions displayed altered phosphate interference patterns at the phosphate adjacent to the substituted base. For these operators, complex formation was measured in different concentrations of KCl to assess the contribution of counterion release to the bimolecular process. The results indicated that both complexes were similar to wild-type, although minor changes were observed. The Kobs of the complex was then measured when 2-aminopurine or purine analogues were paired with uracil nucleotide, a base pair that serves to stabilize the DNA. The introduction of the new base pairs revealed two effects on the bimolecular interaction. For those operator sites that are thought to perturb the interaction directly, the affinity of the complex was weakened to levels observed for the singly-substituted operators. In contrast, the nucleotides of 2-aminopurine paired with uracil positioned in the central region of the operator served to enhance the stability of the complex. The purine-uracil base pair substitution on the other hand had a significant destabilizing effect on the interaction. We propose that the central base pairs modulate binding of the complex by altering the intrinsic properties of the DNA. Two specific attributes are required to achieve the lowest free energy of interaction. The DNA must have two interstrand hydrogen bonds to stabilize the duplex and it must have properties associated with directional bending or unwinding. This analysis does not rule out contributions by direct interactions between the protein and the central region of the operator but underscores how indirect effects play a major role in complex formation in this system.

Location, structure, and function of the target of a transcriptional activator protein

We have isolated and characterized single-amino-acid substitution mutants of RNA polymerase alpha subunit defective in CAP-dependent transcription at the lac promoter but not defective in CAP-independent transcription. Our results establish that (1) amino acids 258-265 of alpha constitute an "activation target" essential for CAP-dependent transcription at the lac promoter but not essential for CAP-independent transcription, (2) amino acid 261 is the most critical amino acid of the activation target, (3) amino acid 261 is distinct from the determinants for alpha-DNA interaction, and (4) the activation target may fold as a surface amphipathic alpha-helix. We propose a model for transcriptional activation at the lac promoter that integrates these and other recent results regarding transcriptional activation and RNA polymerase structure and function.

Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). II. Role at Class I and class II CAP-dependent promoters

CAP-dependent promoters can be divided into classes based on the position of the DNA site for CAP. In class I CAP-dependent promoters, the DNA site for CAP is located upstream of the DNA site for polymerase; the DNA site for CAP can be located at various distances from the transcription start point, provided that the DNS site for CAP and the DNA site for RNA polymerase are on the same face of the DNA helix. In class II CAP-dependent promoters, the DNA site for CAP overlaps the DNA site for RNA polymerase, replacing the -35 determinants for binding of RNA polymerase. In previous work, we have shown that a surface loop consisting of amino acid residues 152 to 166 of CAP is essential for transcription activation at the best-characterized class I CAP-dependent promoter, the lac promoter, and we proposed that this surface loop makes direct protein-protein contact with RNA polymerase in the ternary complex of lac promoter, CAP, and RNA polymerase. Here, we show that the surface loop consisting of amino acid residues 152 to 166 is essential for transcription activation at other class I CAP-dependent promoters and at a class II CAP-dependent promoter. We show further that the effects of alanine substitutions of residues 152 to 166 are qualitatively identical at the lac promoter and other class I CAP-dependent promoters, but are different at a class II CAP-dependent promoter. We propose that the surface loop consisting of residues 152 to 166 makes identical molecular interactions in transcription activation at all class I CAP-dependent promoters, irrespective of distance between the DNA site for CAP and the transcription start point, but makes a different set of molecular interactions in transcription activation at class II CAP-dependent promoters.

An invariant asparagine in the POU-specific homeodomain regulates the specificity of the Oct-2 POU motif

The homeodomain defines a family of transcription factors broadly involved in the regulation of gene expression. DNA recognition, as observed in three representative complexes (Engrailed, Antennapedia, and MAT alpha 2), is mediated in the major groove by a helix-turn-helix (HTH) element and in the minor groove by an N-terminal arm. The three complexes share similar overall features, but they also exhibit significant differences in DNA interactions. Because these differences may distinguish the biological activities of different classes of homeodomains, we have investigated the contribution of the Oct-2 POU-specific homeodomain (POUHD) to the specificity of the bipartite POU motif. Comparative studies of variant protein-DNA complexes demonstrate the following. (i) Mutations in an invariant residue in the POUHD HTH (N347; residue 10 of the putative recognition alpha-helix) reduce octamer binding with the relaxation of specificity at one position (5'-ATGCAAAT). The inferred HTH side chain-base interaction, although not observed in the solution structure of the Antennapedia complex, is in accord with homologous contacts in the Engrailed and MAT alpha 2 cocrystal structures. (ii) Comparison of the DNA-binding properties of POU and POUHD demonstrates that POUs and POUHD independently regulate specificity at opposite ends of the DNA site (5'-TATGCAAAT). Both domains contact the two central bases (5'-TATGCAAAT) where coordinate binding of POUS in the major groove overrides the intrinsic specificity of POUHD in the minor groove. (iii) The differential sensitivity of POU and POUHD to 2'-deoxyinosine substitutions (a minor-groove modification) suggests that POUS binding repositions the POUHD N-terminal "arm".(ABSTRACT TRUNCATED AT 250 WORDS)

An altered-specificity mutation in a human POU domain demonstrates functional analogy between the POU-specific subdomain and phage lambda repressor

The POU motif, conserved among a family of eukaryotic transcription factors, contains two DNA-binding domains: an N-terminal POU-specific domain (POUS) and a C-terminal homeodomain (POUHD). Surprisingly, POUS is similar in structure to the helix-turn-helix domains of bacteriophage repressor and Cro proteins. Such similarity predicts a common mechanism of DNA recognition. To test this prediction, we have studied the DNA-binding properties of the human Oct-2 POU domain by combined application of chemical synthesis and site-directed mutagenesis. The POUS footprint of DNA contacts, identified by use of modified bases, is analogous to those of bacteriophage repressor-operator complexes. Moreover, a loss-of-contact substitution in the putative POUS recognition alpha-helix leads to relaxed specificity at one position in the DNA target site. The implied side chain-base contact is identical to that of bacteriophage repressor and Cro proteins. These results establish a functional analogy between the POUS and prokaryotic helix-turn-helix elements and suggest that their DNA specificities may be governed by a shared set of rules.

T7 RNA polymerase mutants with altered promoter specificities

The amino acid at position 748 in T7 RNA polymerase (RNAP) functions to discriminate base pairs at positions -10 and -11 in the promoter. We have constructed a series of T7 RNAP mutants having all possible amino acid substitutions at this position. Surprisingly, most (13/19) substitutions result in active RNAPs, and many of these exhibit altered promoter specificities. Identification of mutant RNAPs with altered specificities expands the repertoire of highly specific phage RNAPs that are available for use in phage RNAP-based transcription systems and highlights the complexity of sequence-specific DNA recognition.

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.

In vivo interaction of Escherichia coli lac repressor N-terminal fragments with the lac operator

Escherichia coli lac repressor is a tetrameric protein composed of 360 amino acid subunits. Considerable attention has focused on its N-terminal region which is isolated by cleavage with proteases yielding N-terminal fragments of 51 to 59 amino acid residues. Because these short peptide fragments bind operator DNA, they have been extensively examined in nuclear magnetic resonance structural studies. Longer N-terminal peptide fragments that bind DNA cannot be obtained enzymatically. To extend structural studies and simultaneously verify proper folding in vivo, the DNA sequence encoding longer N-terminal fragments were cloned into a vector system with the coliphage T7 RNA polymerase/promoter. In addition to the wild-type lacI gene sequence, single amino acid substitutions were generated at positions 3 (Pro3----Tyr) and 61 (Ser61----Leu) as well as the double substitution in a 64 amino acid N-terminal fragment. These mutations were chosen because they increase the DNA binding affinity of the intact lac repressor by a factor of 10(2) to 10(4). The expression of these lac repressor fragments in the cell was verified by radioimmunoassays. Both wild-type and mutant lac repressor N termini bound operator DNA as judged by reduced beta-galactosidase synthesis and methylation protection in vivo. These observations also resolve a contradiction in the literature as to the location of the operator-specific, inducer-dependent DNA binding domain.

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.

Two amino acids in an RNA polymerase sigma factor involved in the recognition of adjacent base pairs in the -10 region of a cognate promoter

The recognition of promoter region -10 nucleotide sequences in prokaryotes is believed to be mediated by a segment of alpha-helix in a region of RNA polymerase sigma factors called 2.4. Earlier genetic studies implicated Thr-100 in region 2.4 of the Bacillus subtilis sigma factor sigma H in the recognition of the G.C base pair at position -13 in the -10 region (GAAT) of a cognate promoter. In confirmation of this assignment, we now show that a change-of-specificity mutant of sigma H in which Thr-100 was replaced with isoleucine suppresses a G.C----A.T nucleotide substitution at position -13 but not other "promoter down mutations" (causing impaired promoter activity) at positions -13, -12, and -11. We also show that a loss-of-contact mutant created by the replacement of Thr-100 with alanine (having a short side chain) enables sigma H to tolerate three different promoter down mutations at position -13 but not down mutations at other positions. Finally, we suggest the identification of an additional amino acid involved in base-pair recognition by the demonstration that the replacement of Arg-96 with alanine specifically suppresses an A.T----G.C promoter down mutation at position -12. The identification of amino acids that are four residues apart that are involved in the recognition of adjacent base pairs may fix the orientation of region 2.4 (its NH2 terminus being proximal to the promoter transcription start site) and is consistent with a model in which the recognition of promoter region -10 nucleotide sequences is mediated by an alpha-helix in which residues involved in base-pair contact are separated by one turn and clustered on one face of the helix.

Two-dimensional NMR study of a protein-DNA complex. lac repressor headpiece-operator interaction

The interaction of the N-terminal DNA-binding domain (56 amino acid residues) of the lac repressor with lac operator DNA was analyzed using two-dimensional NMR spectroscopy. Both half-operators (11 and 14 bp) and a complete fully symmetric 22 bp operator were studied. Two-dimensional nuclear Overhauser effect (2D NOE) spectra of headpiece-operator complexes were taken in both D2O and H2O solutions. Special attention was given to the problem of 1H resonance assignments. Based on an analysis of the proton-proton NOEs, a model for the headpiece-operator complex could be derived. In this model, most of the protein-DNA contracts occur between amino acid residues in the second helix (recognition helix) of the lac headpiece and DNA bases in the major groove. The orientation of this helix with respect to the dyad axis of the operator is opposite to that found in the X-ray structures of several other repressor-operator complexes.

Identification of a contact between arginine-180 of the catabolite gene activator protein (CAP) and base pair 5 of the DNA site in the CAP-DNA complex

We have used site-directed mutagenesis to replace amino acid 1 of the recognition alpha-helix of the catabolite gene activator protein (CAP), Arg-180, with glycine and with alanine. Substitution of Arg-180 of CAP eliminated specificity between G.C, A.T, C.G, and T.A at base pair 5 of the DNA half-site. The effect was position-specific: substitution of Arg-180 did not eliminate specificity between G.C, A.T, C.G, and T.A at base pair 7 of the DNA half-site. We conclude, in agreement with the model for the structure of the CAP-DNA complex [Weber, I. & Steitz, T. (1984) Proc. Natl. Acad. Sci. USA 81, 3973-3977; and Ebright, R., Cossart, P., Gicquel-Sanzey, B. & Beckwith, J. (1984) Proc. Natl. Acad. Sci. USA 81, 7274-7278], that Arg-180 of CAP makes a specificity-determining contact with base pair 5 of the DNA half-site in the CAP-DNA complex. The identification of the contact by Arg-180 in this report, in conjunction with the identification of the contact by Glu-181 in a previous report [Ebright, R., Cossart, P., Gicquel-Sanzey, B. & Beckwith, J. (1984) Nature (London) 311, 232-235], provides information sufficient to define the orientation of the helix-turn-helix motif of CAP with respect to DNA in the CAP-DNA complex.

Lysine 188 of the catabolite gene activator protein (CAP) plays no role in specificity at base pair 7 of the DNA half site

Two similar, but not identical, models have been proposed for the amino acid-base pair contacts in the CAP-DNA complex ('model I,' Weber, I. and Steitz, T., Proc. Natl. Acad. Sci. USA, 81, 3973-3977, 1984; 'model II,' Ebright, et al., Proc. Natl. Acad. Sci. USA, 81, 7274-7278, 1984). The most important difference between the two models involves Lys188 of CAP. Model I predicts that Lys188 of CAP makes a specificity determining contact with base pair 7 of the DNA half site. In contrast, model II predicts that Lys188 makes no contact with base pair 7 of the DNA half site. In the present work, we have used site-directed mutagenesis to replace Lys188 of CAP by Asn, an amino acid unable to make the putative contact. We have assessed the specificities of the following proteins, both in vitro and in vivo: wild-type CAP, [Asn188]CAP, [Val181]CAP, and [Val181;Asn188]CAP. The results indicate that Lys188 makes no contribution to specificity at base pair 7 of the DNA half site. We propose, contrary to model I, that Lys188 makes no contact with base pair 7 of the DNA half site.

Altered promoter recognition by mutant forms of the sigma 70 subunit of Escherichia coli RNA polymerase

We have systematically assayed the in vivo promoter recognition properties of 13 mutations in rpoD, the gene that encodes the sigma 70 subunit of Escherichia coli RNA polymerase holoenzyme, using transcriptional fusions to 37 mutant and wild-type promoters. We found three classes of rpoD mutations: (1) mutations that suggest contacts between amino acid side-chains of sigma 70 and specific bases in the promoter; (2) mutations that appear to affect either sequence independent contacts to promoter DNA or isomerization of the polymerase; and (3) mutations that have little or no effect on promoter recognition. Our results lead us to suggest that a sequence near the C terminus of sigma 70, which is similar to the helix-turn-helix DNA binding motif of phage and bacterial DNA binding proteins, is responsible for recognition of the -35 region, and that a sequence internal to sigma 70, in a region which is highly conserved among sigma factors, recognizes the -10 region of the promoter. rpoD mutations that lie in the recognition helix of the proposed helix-turn-helix motif affect interactions with specific bases in the -35 region, while mutations in the upstream helix, which is thought to contact the phosphate backbone, have sequence-independent effect on promoter recognition.

Mutation changing the specificity of an RNA polymerase sigma factor

We describe a mutation that changes the fine specificity of promoter selection by a secondary form of RNA polymerase holoenzyme in Bacillus subtilis. The product of regulatory gene spo0H is an RNA polymerase sigma factor called sigma H, which directs transcription of a sporulation gene known as spoVG. We show that the spo0H mutation spo0H81, which blocks transcription from the wild-type spoVG promoter, enhances transcription from a mutant form of the spoVG promoter (spoVG249) bearing a severe down-mutation (a G.C to A.T transition) at position -13 in the "-10 region." Suppression of the spoVG249 mutation is specific in the sense that the transcription from several other spoVG mutant promoters was not restored by the mutant sigma. Evidently, spo0H81 is a change-of-specificity mutation that alters sigma H-RNA polymerase in a way that decreases its capacity to use the wild-type spoVG promoter, while increasing its capacity to use the mutant promoter. Transcription experiments in vitro using RNA polymerase containing the wild-type or mutant sigma support this interpretation. The spo0H81 mutation causes a threonine (Thr100) to isoleucine substitution in a region of sigma H that is highly homologous among sigma factors of diverse origins. We discuss the possibility that Thr100 is an amino acid-base-pair contact site and that sigma factors contact the -10 region of their cognate promoters by means of amino acid residues in this highly conserved region.

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.

How lambda repressor and lambda Cro distinguish between OR1 and OR3

Although lambda repressor and lambda Cro bind to the same six operators on the phage chromosome, the fine specificities of the two proteins differ: repressor binds more tightly to OR1 than to OR3, and vice versa for Cro. In this paper, we change base pairs in the operators and amino acids in the proteins to analyze the basis for these preferences. We find that these preferences are determined by residues 5 and 6 of the recognition helices of the two proteins and by the amino-terminal arm, in the case of repressor. We also find that the most important base pairs in the operator which enable repressor and Cro to discriminate between OR1 and OR3 are position 3 (for Cro) and positions 5 and 8 (for repressor). These and previous results show how repressor and Cro recognize and distinguish between two related operator sequences.

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.