LexA repressor induces operator-dependent DNA bending.

LexA, the repressor of the SOS system in Escherichia coli induces a substantial DNA bending upon interaction with the operator of the caa gene, which codes for the bacterial toxin colicin A. Analysis by gel electrophoresis of a family of DNA fragments of identical length, but bearing the caa operator at different positions, shows that DNA bending occurs close to or within the operator sequence upon LexA binding. In contrast, the interaction of LexA with the recA operator induces no detectable bending on 5% polyacrylamide gels. This difference between the two operators is likely to be due to an intrinsic bendability of the caa operator related to thymine tracts located on both sides of the operator. Such tracts do not exist in the recA operator. The free DNA fragments harbouring the caa operator show a slight tendency to bend even in the absence of the LexA repressor. The centre of this intrinsic bend is located close to or within the caa operator.

Specificity of N-acetoxy-N-2-acetylaminofluorene-induced frameshift mutation spectrum in mismatch repair deficient Escherichia coli strains mutH, L, S and U.

The mismatch repair system of Escherichia coli is known to contribute to the fidelity of the replicational process. This system involves the functions of mutH, mutL, mutS and mutU (uvrD) loci which recognize mispaired bases as a consequence of errors due to the polymerase itself. Chemical modifications of DNA have also been suspected to create mispaired bases which, if the mispaired bases are removed, will lead to mutations by frameshift. Using the pBR322 plasmid DNA modified by the ultimate carcinogen N-acetoxy-N-2-acetylaminofluorene (N-Aco-AAF) we have investigated this possibility in a forward mutational assay (tetracycline sensitivity). This fluorene derivative has been shown to induce predominantly frameshift mutations. Our results show that: The sensitivity of the deficient strains mutH, mutL and mutS to the AAF adducts is similar to that of the corresponding wild-type strain. However, the mutU strain appears much more sensitive to those adducts although less than a uvrA, B or C-deficient strain. This suggests that the mutU gene product is involved in the repair of AAF adducts. For the four mut deficient strains, and as it was shown with the wild-type strain, AAF adducts induced mutations to tetracycline sensitivity are only observed when the SOS system of the host bacteria is induced by irradiation of the cells prior to transformation with the modified plasmid. The mutation frequencies depend upon the ultraviolet light doses and similar maxima were found for the four mut strains and the corresponding wild-type strain. In agreement with the results obtained with wild-type or uvrA strains we observe that AAF adducts induce mostly frameshift mutations in the mut strains. Two types of hot spots of mutagenesis were described in wild-type and uvrA strains occurring either at repetitive sequences or at sequences of the type 5' G-G-C-G-C-C 3' (NarI restriction enzyme recognition sequence). While the second type of mutational hot spot does exist in the mismatch repair-deficient strains, we observe that the repetitive sequences are no longer hot spots of mutations in these strains, suggesting that the mismatch repair protein complex is involved in the establishment of AAF-induced frameshift mutations at repetitive sequences.

Isolation and characterization of LexA mutant repressors with enhanced DNA binding affinity.

The LexA repressor from Escherichia coli is a sequence-specific DNA binding protein that shows no pronounced sequence homology with any of the known structural motifs involved in DNA binding. Since little is known about how this protein interacts with DNA, we have selected and characterized a great number of intragenic, second-site mutations which restored at least partially the activity of LexA mutant repressors deficient in DNA binding. In 47 cases, the suppressor effect of these mutations was due to an Ind- phenotype leading presumably to a stabilization of the mutant protein. With one exception, these second-site mutations are all found in a small cluster (amino acid residues 80 to 85) including the LexA cleavage site between amino acid residues 84 and 85 and include both already known Ind- mutations as well as new variants like GN80, GS80, VL82 and AV84. The remaining 26 independently isolated second-site suppressor mutations all mapped within the amino-terminal DNA binding domain of LexA, at positions 22 (situated in the turn between helix 1 and helix 2) and positions 57, 59, 62, 71 and 73. These latter amino acid residues are all found beyond helix 3, in a region where we have previously identified a cluster of LexA (Def) mutant repressors. In several cases the parental LexA (Def) mutation has been removed by subcloning or site-directed mutagenesis. With one exception, these LexA variants show tighter in vivo repression than the LexA wild-type repressor. The most strongly improved variant (LexA EK71, i.e. Glu71----Lys) that shows an about threefold increased repression rate in vivo, was purified and its binding to a short consensus operator DNA fragment studied using a modified nitrocellulose filter binding assay. As expected from the in vivo data, LexA EK71 interacts more tightly with both operator and (more dramatically) with non-operator DNA. A determination of the equilibrium association constants of LexA EK71 and LexA wild-type as a function of monovalent salt concentration suggests that LexA EK71 might form an additional ionic interaction with operator DNA as compared to the LexA wild-type repressor. A comparison of the binding of LexA to a non-operator DNA fragment further shows that LexA interacts with the consensus operator very selectively with a specificity factor of Ks/Kns of 1.4 x 10(6) under near-physiological salt conditions.

Spacing requirements between LexA operator half-sites can be relaxed by fusing the LexA DNA binding domain with some alternative dimerization domains.

The dimerization domain of the LexA repressor has been replaced by two heterologous dimerization motifs: the "leucine zipper" from the jun oncogene product and the carboxy-terminal oligomerization domain of Escherichia coli lac repressor. The corresponding hybrid proteins LexA1-87-Jun zipper and LexA1-87-lac repressor have been purified and their DNA binding properties have been studied using gel mobility shift assays. Both fusion proteins form stable specific complexes with a short DNA duplex harboring the CTGT(at)4ACAG consensus sequence of the LexA repressor. This conserved DNA binding capacity distinguishes these two fusion proteins from many others containing a LexA DNA binding domain fused to different heterologous transactivation and/or dimerization domains. However the fusion proteins LexA1-87-Jun zipper and LexA1-87-lac repressor behave differently from native LexA repressor in that these fusion proteins tolerate the insertion of additional base-pairs between the two invertedly repeated CTGT motifs. LexA1-87-Jun zipper requires two CTGT motifs and tolerates the insertion of at least two additional base-pairs between these motifs, whereas LexA1-87-lac repressor requires in fact only a single CTGT motif for the formation of a specific complex detectable in gel mobility shift assays. The inability of the normal LexA repressor to form well-defined complexes with operators containing additional base-pairs in the center suggests that the LexA "hinge region" between the amino-terminal DNA binding and the carboxy-terminal dimerization domain might not be entirely flexible. In an attempt to remove a hypothetical interaction between the LexA cleavage site (which is situated within the hinge region) and the catalytic cleavage center (situated within the carboxy-terminal domain) a LexA mutant repressor containing five simultaneous mutations in the hinge region has been constructed and purified. Surprisingly this mutant repressor failed to form stable complexes detectable by the gel mobility shift assay even with the normal consensus sequence, suggesting that the LexA hinge region is more than a simple connector between the two structural domains and that its chemical nature is important not only for LexA cleavage, but also for the formation of stable LexA-DNA complexes.

A LexA mutant repressor with a relaxed inter-domain linker.

The LexA protein is part of a large family of prokaryotic transcriptional repressors that contain an amino-terminal DNA binding domain and a carboxy-terminal dimerization domain. These domains are separated by a linker or hinge region, which is generally considered to be rather flexible and unconstrained. So far, no structure of any of the full-length repressors is available. Here we show that a mutant LexA repressor harboring several point mutations in the hinge region gets sensitive to trypsin and Glu-C cleavage over a segment of at least 20 amino acids, whereas the LexA wild-type hinge region is resistant to these proteases. These data are not compatible with the hypothesis of an fully flexible and/or unstructured inter-domain linker and suggest that the LexA hinge region is, in fact, constrained by contacts with the carboxy-terminal domain and/or a fairly stable local structure of the linker region.

A mutant LexA repressor harboring a cleavage motif cysteine-glycine remains inducible.

Using site-directed mutagenesis of the lexA gene we have changed the amino acid Ala-84 of the LexA repressor for a cysteine. The reason for this change was the striking homology between LexA and UmuD and the comparable size of the two amino acid side chains. Using an in vivo repression/induction assay it is shown that the LexA-Cys-84 mutant remains inducible by mitomycin C and UV irradiation essentially in the same way as the wild-type repressor.

In vitro study of the interaction of the LexA repressor and the UvrC protein with a uvrC regulatory region.

The in vitro interaction of the LexA repressor with a regulatory region of the uvrC gene has been studied by polyacrylamide gel electrophoresis. Although the uvrC promoter region shows some homology with the canonic LexA binding site, no specific binding of the repressor to this DNA sequence could be observed, but only a cooperative nonspecific binding. By the same technique we show that the UvrC protein does not bind specifically to this regulatory DNA sequence either, although the protein is able to bind nonspecifically and cooperatively to the double-stranded DNA fragment.

The carboxy-terminal domain of the LexA repressor oligomerises essentially as the entire protein.

The ability of the isolated carboxy-terminal domain of the LexA repressor of Escherichia coli to form dimers and tetramers has been investigated by equilibrium ultracentrifugation. This domain, that comprises the amino acids 85-202, is readily purified after self-cleavage of the LexA repressor at alkaline pH. It turns out that the carboxy-terminal domain forms dimers and tetramers essentially as the entire LexA repressor. The corresponding association constants were determined after non-linear least squares fitting of the experimental concentration distribution. A dimer association constant of K2 = 3 X 10(4) M-1 and a tetramer association constant of K4 = 2 X 10(4) M-1 have been determined. Similar measurements on the entire LexA repressor [(1985) Biochemistry 24, 2812-2818] gave values of K2 = 2.1 X 10(4) M-1 and K4 = 7.7 X 10(4) M-1. Within experimental error the dimer formation constant of the carboxy-terminal domain may be considered to be the same as that of the entire repressor whereas the isolated domain forms tetramers slightly less efficiently. It should be stressed that the potential error in K4 is higher than that in K2. The overall conclusion is that the two structural domains of LexA have also well-defined functional roles: the amino-terminal domain interacts with DNA and the carboxy-terminal domain is involved in dimerisation reinforcing in this way the binding of the LexA repressor to operator DNA.

DNA binding properties of the LexA repressor.

The LexA repressor from Escherichia coli negatively regulates the transcription of about 20 different genes upon binding with variable affinity to single-, double- or even triple-operators as in the case of the recN gene. Binding of LexA to multiple operators is cooperative if the spacing between these operators is favorable. LexA recognizes DNA via its amino-terminal domain. The three-dimensional structure of this domain has been determined by NMR measurements. It contains three alpha-helices spanning residues 8-20, 28-35 and 41-54. In view of this structure, but also according to homology considerations and the unusual contact pattern with the DNA backbone, the LexA repressor is not a normal helix-turn-helix DNA binding protein like for example phage lambda repressor. LexA is at best a distant relative of this class of transcription factors and should probably be considered as a protein that contains a new DNA binding motif. A cluster of LexA mutant repressors deficient in DNA binding falling into the third helix (residues 41-54 bp) suggests that this helix is involved in DNA recognition.

1H-NMR investigation of the interaction of the amino terminal domain of the LexA repressor with a synthetic half-operator.

A synthetic half-operator DNA-duplex, d(GCTACTGTATGT), containing a portion of the proposed recognition sequence (CTGT) of several "SOS" genes, has been synthesized. The dodecamer has been characterized through 1H-NMR spectroscopy. Complete assignment of exchangeable hydrogen bonded imino protons has been achieved by applying 1D NOE techniques and an analysis of the temperature dependence of the chemical shifts. In order to determine the specific role of the CTGT consensus sequence in the overall recognition process, the oligonucleotide duplex has been titrated with the amino terminal DNA binding domain of the LexA repressor. The observation of substantial changes of 1H-NMR chemical shifts in the imino proton region upon interaction with the protein strongly suggests that the protein binds specifically to the operator DNA. The largest deviations of 1H-NMR chemical shifts upon protein binding have been observed for protons assigned to the CTGT segment, thus strongly suggesting a direct involvement of this sequence in the binding process. At high potassium chloride concentrations the 1H-NMR chemical shift deviations are reverted which is consistent with the known drop in the affinity constant of LexA for operator DNA at high salt concentrations.

Base pair substitution and frameshift mutagenesis induced by apurinic sites and two fluorene derivatives in a recA441 lexA (Def) strain.

One of the consequences of the induction of the Escherichia coli SOS system is the increased ability of the cells to perform mutagenesis. Induction of the SOS system is the result of derepression of a set of genes through a regulatory mechanism controlled by LexA and RecA. In response to an inducing signal, RecA is activated in a form that facilitates the proteolytic cleavage of LexA repressor. Previous works have shown that activated RecA plays a second role, i.e. it is required for the establishment of base pair substitution mutations promoted by UV irradiation. Using a forward mutational assay and recA441 lexA (Def) host bacteria, we show that the result can be extended not only to other mutagens promoting base pair substitution mutations (Apurinic sites, Ap sites and N-hydroxy-N-2-aminofluorene, N-OH-AF) but also mutagens promoting frameshift mutations (N-Acetoxy-N-2-acetylaminofluorene, N-AcO-AAF). In the recA441 lexA (Def) strain all the genes which are part of the lexA regulon, including recA itself, are expressed constitutively. The recA441 mutation allows RecA to acquire its activated form when the bacteria are grown at 42 degrees C. We show that in such strains Ap sites or N-OH-AF induce a high level of mutations only when the bacteria are grown at 42 degrees C. On the other hand, we show that N-AcO-AAF can promote mutations even at 30 degrees C; the number of mutations being increased when the bacteria were grown at 42 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

The LexA repressor and its isolated amino-terminal domain interact cooperatively with poly[d(A-T)], a contiguous pseudo-operator, but not with random DNA: a circular dichroism study.

The interaction of the entire LexA repressor and its amino-terminal DNA binding domain with poly[d(A-T)] and random DNA has been studied by circular dichroism. Binding of both protein species induces an about 2-fold increase of the positive circular dichroism band at about 270 nm of both polynucleotides, allowing a precise determination of the principal parameters as a function of mono- and divalent salt concentration and pH. Both proteins interact much more strongly (about 2000-fold) with poly[d(A-T)] than with random DNA as expected from the homology with the specific consensus binding site of LexA (CTGTATATATATACAG). For both LexA and its DNA binding domain we find that the interaction with poly[d(A-T)] is cooperative with a cooperativity factor omega of about 50-70 for both proteins over a wide range of solvent conditions, suggesting that the carboxy-terminal domain of LexA is not involved in this type of cooperativity. On the contrary, no cooperativity could be detected for the interaction of the LexA DNA binding domain with a random DNA fragment. The overall binding constant K omega (or simply K in the case of random DNA) depends strongly on the salt concentration as observed for most protein-DNA interactions, but the behavior of LexA is unusual in that the steepness of this salt dependence (delta log K omega/delta log [NaCl]) is much more pronounced at slightly acidic pH values as compared to that at neutral or slightly alkaline pH. The behavior is not easily understood in terms of the current theories on the electrostatic contribution to protein-DNA interactions on the basis of polyelectrolyte theory. A comparison of the overall binding constant K omega of the entire LexA repressor and its DNA binding domain reveals that LexA binds only 20-50-fold stronger under a wide variety of salt and pH conditions. This result tends to demonstrate further that the additional energy due to the dimerization of LexA via the carboxy-terminal domain should be rather weak as expected from the small dimerization constant of LexA (2 X 10(-4) M-1).

Contacts between the LexA repressor--or its DNA-binding domain--and the backbone of the recA operator DNA.

Using hydroxyl radical footprinting and ethylation interference experiments, we have determined the backbone contacts made by the entire LexA repressor and its amino-terminal fragment with the recA operator DNA. These techniques reveal essentially the same contacts between both proteins and one side of the DNA helix if one assumes that the DNA stays in the normal B-conformation. This result is somewhat unexpected because protection of guanine bases against methylation suggested a somewhat twisted recognition surface. The backbone contacts revealed by both methods are symmetrically disposed with respect to the center of the operator, providing further evidence that the operator binds two LexA monomers. Each half-operator contains seven interfering phosphates. These phosphates are found on both sides of the 5'-CTGT sequence that is believed to be the principal recognition target. On the side close to the center of the operator are found two phosphates, whereas the other five are clustered on the side apart from the dyad axis. We are not aware of such an extended cluster of interfering phosphates for any other DNA-binding protein. A quantification of the hydroxyl radical footprints allowed us to compare further the affinity of the LexA repressor for the recA operator with that of its isolated DNA binding domain. We find an only 13-fold higher binding constant for LexA than for its amino-terminal domain, which is in good agreement with our earlier results for the uvrA operator using a completely different binding assay.

Large-scale purification, oligomerization equilibria, and specific interaction of the LexA repressor of Escherichia coli.

A rapid large-scale procedure for the purification of the LexA repressor of Escherichia coli is described. This procedure allows one to get more than 100 mg of purified protein from 100 g of bacterial paste with a purity of at least 97%. This method is comparable to earlier, far more complicated purification procedures giving clearly smaller yields. It is shown that the LexA protein may be identified spectroscopically by a large A235/A280 ratio and very pronounced ripples in the absorption spectrum arising from a high amount of phenylalanine residues with respect to that of the other aromatic amino acids. Polyacrylamide gel electrophoresis has been used to study the specific interaction of LexA with a recA operator fragment. The quaternary structure of LexA has been studied by equilibrium ultracentrifugation and sedimentation velocity measurements. The sedimentation coefficient increases with increasing LexA concentration, indicating that LexA is involved in self-association. This finding has been confirmed by equilibrium ultracentrifugation. The results are best described by a monomer-dimer and a subsequent dimer-tetramer equilibrium, with an association constant of 2.1 X 10(4) M-1 for the dimer and 7.7 X 10(4) M-1 for the tetramer formation. These relatively small association constants determined under near-physiological pH and salt conditions suggest that in vivo LexA should be essentially in the monomeric state. The degree to which LexA decreases the electrophoretic mobility of a 175 base pair fragment harboring the recA operator suggests that the recA operator interacts nevertheless with a LexA dimer. However, our results may be also explained by the binding of a LexA monomer with a simultaneous bending of the DNA fragment.

In vitro binding of LexA repressor to DNA: evidence for the involvement of the amino-terminal domain.

Both the amino-terminal and the carboxy-terminal domain of the LexA repressor have been purified using the LexA protein autodigestion reaction at alkaline pH, which leads to the same specific products as the physiological RecA-catalyzed proteolysis of repressor. We show by circular dichroism (c.d) that, upon non-specific binding to DNA, the purified amino-terminal domain induces a very similar if not identical conformational change of the DNA as does the entire repressor. The positive c.d. signal increases approximately 3-fold if the DNA lattice is fully saturated with protein. Further, the amino-terminal domain of the LexA protein binds specifically to the operator of the recA gene, producing qualitatively the same effects on the methylation pattern of the guanine bases by dimethylsulfate as the entire repressor, consisting of a methylation inhibition effect at four distal operator guanines and a slight enhancement at the central bases. The spacing between these contacts suggests that LexA does not bind to the operator along the same face of the DNA helix. As shown by c.d. studies the amino-terminal domain harbours a substantial amount of residues in alpha-helical conformation, a prerequisite for DNA recognition via a helix--turn--helix structural motif as proposed for many other regulatory proteins.

Interaction of a regulatory protein with a DNA target containing two overlapping binding sites.

The LexA repressor from Escherichia coli regulates the transcription of about 20 different genes upon binding to single or multiple operators. In this work we study the interaction of LexA with the control region of the caa gene (coding for the bacterial toxin colicin A) that contains two operators (O1 and O2) which overlap by at least 2 base pairs relevant for sequence specific DNA recognition. This arrangement raises the question of how the LexA molecules which bind to the central overlapping part of the two operators avoid steric clashes and further, of whether the interaction of LexA with the two operators is cooperative or not. To address these questions we have constructed two mutant operators (O1+O2- and O1-O2+) for which the two most strongly conserved base pairs in each of the external operator half-sites have been mutated. Using methylation interference with the complex formation of LexA with the wild-type and these two mutant operators we could show: 1) that the two mutant operators behave symmetrically in that the methylation of one crucial guanine base in both operator half-sites interferes strongly with complex formation, 2) but that in the wild-type operator (containing four functional operator half-sites) only the two external half-operators give rise to interference if this crucial guanine base is methylated, whereas methylation of the two equivalent guanine bases within the two central (overlapping) operator half-sites does not lead to interference with the formation of a complex where both operators are occupied simultaneously. These data suggest that the centrally bound LexA molecules adopt a somewhat different binding mode than those bound to the external half-operators in order to avoid steric clashes and/or to optimize protein-protein contacts which are likely to be at the origin of the binding cooperativity that we could demonstrate by quantitative DNase I footprinting and gel retardation experiments. While the methylation interference experiments revealed a non-equivalence for the binding of externally and centrally bound LexA molecules, both methylation protection and hydroxyl radical footprinting were unable to reveal this difference, suggesting that the difference between the two binding modes should be fairly subtle.

Phosphorylation of Escherichia coli proteins during the SOS response.

1. The phosphorylation of Escherichia coli proteins was analyzed comparatively before and after induction of the SOS response in a temperature-sensitive mutant strain. 2. The presence of phosphorylated proteins was evidenced by gel electrophoresis and autoradiography after labelling with radioactive orthophosphate in vivo or radioactive adenosine triphosphate in vitro. 3. Significant changes in the intensity of protein labelling were observed upon induction of the SOS functions: six proteins were found to be more phosphorylated while two others were less phosphorylated. Moreover, five additional proteins appeared to become phosphorylated exclusively during the SOS response. The molecular mass and isoelectric point of these various proteins were determined. 4. For most proteins, the changes in the pattern of protein phosphorylation were concomitant with variations in the amount of protein synthesized. 5. The changes in the pattern of phosphoproteins observed during the SOS response were not due to the temperature shift required experimentally for expressing the SOS phenotype. 6. Phosphorylation was found to be catalyzed by protein kinases that modify amino acid residues at hydroxyl groups in protein substrates. 7. Both in vivo and in vitro studies brought evidence that neither RecA nor LexA, the two key regulatory proteins of the SOS functions, were capable of undergoing phosphorylation.

DNA sequence determinants of LexA-induced DNA bending.

The LexA repressor from Escherichia coli induces DNA bending upon interaction with the two overlapping operators which regulate the transcription of the colicin A encoding gene caa. Both caa operators harbor T-tracts adjacent to their recognition motifs. These tracts have been suggested to be especially favorable for the promotion of LexA-induced DNA bending. Here we show that this is indeed the case, since disruption of the TTTT-tract adjacent to operator O1 by the replacement of the two central thymine bases by AA, GA or CG markedly reduces LexA-induced DNA bending. Simple A.T-richness in this position is thus not sufficient to promote full LexA-induced bending, albeit a TAAT sequence is always more efficient to promote bending than those sequences containing one or two C/G base pairs.

Specific protein-DNA complexes: immunodetection of the protein component after gel electrophoresis and Western blotting.

A method is described to determine the presence and the relative amount of proteins within specific protein-DNA complexes. The system studied is the LexA repressor from Escherichia coli and its interaction with the operator of the caa gene encoding the bacterial toxin colicin A. After separation of the free and the complexed 32P-labeled DNA on a native polyacrylamide gel, the bound proteins are transferred on a polyvinylidine difluoride (PVDF) membrane after sodium dodecyl sulfate denaturation. Development of the protein on the membrane was achieved on reaction with an anti-LexA antibody and the use of a second anti-antibody crosslinked with alkaline phosphatase. The phosphatase activity is monitored using 5-bromo-4-chloro-3-indolyl phosphate as a substrate and 4-nitroblue tetrazolium salt. A quantitation by densitometry of both the stained protein bands on the PVDF membrane and the DNA on autoradiograms allowed us to assign the relative stoichiometry of the two different complexes formed between LexA and the caa operator. The method should allow unraveling of complicated band shift patterns arising from the presence of several binding sites for a same protein, as in our case, or from the presence of different proteins binding to a same DNA fragment.

Genetic analysis of the LexA repressor: isolation and characterization of LexA(Def) mutant proteins.

We report the isolation of LexA mutant proteins with impaired repressor function. These mutant proteins were obtained by transforming a LexA-deficient recA-lacZ indicator strain with a randomly mutagenized plasmid harbouring the lexA gene and subsequent selection on MacConkey-lactose indicator plates. A total of 24 different lexA(Def) missense mutations were identified. All except three mutant proteins are produced in near-normal amounts suggesting that they are fairly resistant to intracellular proteases. All lexA(Def) missense mutations are situated within the first 67 amino acids of the amino-terminal DNA binding domain. The properties of an intragenic deletion mutant suggest that the part of the amino-terminal domain important for DNA recognition or domain folding should extent at least to amino acids 69 or 70. A recent 2D-NMR study (Lamerichs et al. 1989) has identified three alpha helices in the DNA binding domain of LexA. The relative orientation of two of them (helices 2 and 3) is reminiscent of, but not identical to, the canonical helix-turn-helix motif suggesting nevertheless that helix 3 might be involved in DNA recognition. The distribution of the lexA(Def) missense mutations along the first 67 amino-terminal amino acids indeed shows some clustering within helix 3, since 8 out of the 24 different missense mutations are found in this helix. However one mutation in front of helix 1 and five mutations between amino acids 61 and 67 suggest that elements other than helices 2 and 3 may be important for DNA binding.