Four dimers of lambda repressor bound to two suitably spaced pairs of lambda operators form octamers and DNA loops over large distances.

Transcription factors that are bound specifically to DNA often interact with each other over thousands of base pairs [1] [2]. Large DNA loops resulting from such interactions have been observed in Escherichia coli with the transcription factors deoR [3] and NtrC [4], but such interactions are not, as yet, well understood. We propose that unique protein complexes, that are not present in solution, may form specifically on DNA. Their uniqueness would make it possible for them to interact tightly and specifically with each other. We used the repressor and operators of coliphage lambda to construct a model system in which to test our proposition. lambda repressor is a dimer at physiological concentrations, but forms tetramers and octamers at a hundredfold higher concentration. We predict that two lambda repressor dimers form a tetramer in vitro when bound to two lambda operators spaced 24 bp apart and that two such tetramers interact to form an octamer. We examined, in vitro, relaxed circular plasmid DNA in which such operator pairs were separated by 2,850 bp and 2,470 bp. Of these molecules, 29% formed loops as seen by electron microscopy (EM). The loop increased the tightness of binding of lambda repressor to lambda operator. Consequently, repression of the lambda PR promoter in vivo was increased fourfold by the presence of a second pair of lambda operators, separated by a distance of 3,600 bp.

A positive selection vector for cloning of long polymerase chain reaction fragments based on a lethal mutant of the crp gene of Escherichia coli.

We have constructed a cloning vector with a tight positive selection for recombinant clones in Escherichia coli. The positive selection pressure results from a lethal mutation within the E. coli gene coding for the catabolite gene activator protein CAP, which is disrupted whenever a fragment is successfully inserted. Here, we show that this "suicide" vector, pCAPs, is suitable for cloning of PCR products as long as 9.3 kb into several unique restriction sites which are scattered throughout the lethal gene.

A lethal mutant of the catabolite gene activator protein CAP of Escherichia coli.

The dimeric catabolite gene activator protein (CAP) of Escherichia coli uses its recognition helix to bind with each subunit the DNA sequence motif 5' G-7T-6G-5A-4 3'. It makes a direct amino acid-base contact with E181 and cytosine in position-5' on the reverse strand. While testing mutants of CAP in position 181 for specificity changes, we found that CAP E181Q is lethal in high amounts for the E. coli strains we used for cloning. We cloned this CAP mutant successfully in cya- strains, where CAP is inactive. Examination of the in vitro binding activities of CAP E181Q, and of in vivo activity when present in low, non-lethal amounts, revealed loss of specificity but not of binding capacity for its DNA targets. It binds well to CAP consensus with G or T in position-5, better to CAP consensus with A, C in position-5, quite well to lambda consensus operator with G in position-7 and rather weakly to lambda consensus.

Co-operative binding of two Trp repressor dimers to alpha- or beta-centred trp operators.

The alpha-centred trp operator binds one dimer of the Trp repressor, whereas the beta-centred trp operator binds two dimers of the Trp repressor (Carey et al., 1991; Haran et al., 1992). The Trp repressor with a Tyr-Gly-7 substitution binds almost as well as the wild-type Trp repressor to the alpha-centred trp operator, but it does not bind to the beta-centred trp operator. This confirms that Tyr-7 is involved in the interaction between Trp repressor dimers, as seen in the crystal structure (Lawson and Carey, 1993). Further experiments with alpha-centred trp operator variants showed that positions +/-1 of the alpha-centred trp operators play a crucial role in tetramerisation. The two innermost base pairs of the alpha-centred trp operator are not involved in contacts with the dimer of the Trp repressor binding to it. However, substitutions in these positions (T-A to G-T) effectively transform the alpha-centred trp operator into a beta-centred trp operator, and thus encourage the binding of two Trp repressor dimers to this operator. Finally, we demonstrate, with suitable heterodimers, that one subunit of each dimer suffices to bind to a beta-centred trp operator.

Mutant bZip-DNA complexes with four quasi-identical protein-DNA interfaces.

The complex between the yeast transcriptional activator GCN4 and the palindromic ATF/CREB site 5'- A4T3G2A1C0*G0'T1'C2'A3'T4'-3' shows dyad symmetry. The basic region of GCN4 contains a segment of 18 amino acids with a partially palindromic sequence: N-LKRARNTEA*ARRSRARKL-C. Symmetric residues are underlined. Apart from the ATF/CREB site, GCN4 also binds well to the symmetric variants with guanine in position 4 (5'-G4T3G2A1C0*G0'T1'C2'A3'C4'-3') or thymine in position 0 (5'-A4T3G2A1T0*A0'T1'C2'A3'T4'-3'). The half-sites of these sequences can be regarded as short pseudo-palindromes with central guanine 2/cytosine 2' base pairs. We investigated whether the geometry of the peptide of the basic region of GCN4 could be functionally related to the pseudo-palindromic character of some target half-sites. Since inspection of the X-ray structures of GCN4-DNA complexes reveals that several amino acid-DNA interactions are symmetric within the wild-type half-complexes, we introduced mutations into a GCN4 bZip peptide that improve the symmetry of the peptide. We found that most of the constructs retain specific DNA recognition. For one mutant, we conclude that it is not only capable of forming DNA complexes showing the well-known overall dyad symmetry, but that the protein-DNA interface of each half-complex can be divided further into two quasi-identical, quasi-symmetric substructures.

A comparison of the different DNA binding specificities of the bZip proteins C/EBP and GCN4.

The bZip proteins GCN4 and C/EBP differ in their DNA binding specificities: GCN4 binds well to the pseudopalindromic AP1 site 5'-A4T3G2A1C0T1C2'A3'T4'-3' and to the palindromic ATF/CREB sequence 5'-A4T3G2A1-C0*G0'T1'C2'A3'T4'-3'; C/EBP preferentially recognizes the palindromic sequence 5'-A4T3T2G1C0*G0'C1'A2'-A3'T4'-3'. According to the X-ray structures of GCN4-DNA complexes, five residues of the basic region of GCN4 are involved in specific base contacts: asparagine -18, alanine -15, alanine -14, serine -11 and arginine -10 (numbered relative to the start point of the leucine zipper, which we define as +1). In the basic region of C/EBP position -14 is occupied by valine instead of alanine, the other four residues being identical. Here we analyse the role of valine -14 in C/EBP-DNA complex formation. Starting from a C/EBP-GCN4 chimeric bZip peptide which displays C/EBP specificity, we systematically mutated position -14 of its basic region and characterized the DNA binding specificities of the 20 possible different peptides by gel mobility shift assays with various target sites. We present evidence that valine -14 of C/EBP interacts more strongly with thymine 2 than with cytosine 1' of the C/EBP binding site, unlike the corresponding alanine -14 of GCN4, which exclusively contacts thymine 1' of the GCN4 binding sites.

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition.

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of beta-galactosidase with symmetric variants of alpha- and beta-centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the alpha-centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the alpha-centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. A180, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for alpha-centered trp operator variants with exchanges in positions 3, 4 and 5.

Replacement of invariant bZip residues within the basic region of the yeast transcriptional activator GCN4 can change its DNA binding specificity.

Two residues are invariant in all bZip basic regions: asparagine -18 and arginine -10 (we define the first leucine of the leucine zipper of GCN4 as +1). X-ray structures of two specific GCN4-DNA complexes (Ellenberger et al., Cell, 71, 1223-1237, 1992; König & Richmond, J. Mol. Biol., 233, 139-154, 1993) demonstrate the involvement of both residues in specific base pair recognition. We replaced either asparagine -18 or arginine -10 with all other amino acids and tested the DNA binding properties of the resulting mutant peptides by gel mobility shift assays. Peptides with histidine -18 or tyrosine -10 bind with changed specificities to variants of the ATF/CREB site 5'A4T3G2A1C0*G0'T1'C2'A3'T4'3' with symmetric exchanges in positions 2/2' or 0/0', respectively. The double mutant with histidine -18 and tyrosine -10 combines the features of the parental single mutants and binds specifically to the respective double exchange target. Furthermore, the tyrosine -10 mutant clearly prefers the palindrome 5'ATGATATCAT3' over the corresponding pseudo-palindrome 5'ATGATTCA-T3', whereas the lysine -10 mutant binds better to the pseudo-palindromic AP1 site 5'ATGACTCAT3' than to the palindromic ATF/CREB site. Thus, although invariant within natural bZip proteins, asparagine -18 or arginine -10 can be functionally replaced by other amino acids, and their replacement can lead to new DNA binding specificities.

Quality and position of the three lac operators of E. coli define efficiency of repression.

Repression of the lac promoter may be achieved in two different ways: either by interference with the action of RNA polymerase or by interference with CAP activation. We investigated cooperative repression of the Escherichia coli lac operon by systematic conversion of its three natural operators (O1, O2 and O3) on the chromosome. We find that cooperative repression by tetrameric Lac repressor increases with both quality and proximity of the interacting operators. A short distance of 92 bp allows effective repression by two very weak operators (O3, O3). The cooperativity of lac operators is discussed in terms of a local increase of repressor concentration. This increase in concentration depends on flexible DNA which allows loop formation.

Creating new DNA binding specificities in the yeast transcriptional activator GCN4 by combining selected amino acid substitutions.

The specificity of the GCN4/DNA complex is mediated by a complicated network of interactions between the basic regions of both GCN4 monomers and their target halfsites. According to X-ray analyses (1, 2) one particular thymine of the target sequence is recognized by serine -11 and alanine -15 (we define the leucine in the first d-position of the heptad repeats as +1). We replaced serine -11 or alanine -15 with all other amino acids and analysed the DNA binding properties of the resulting stable GCN4 derivatives by electrophoretic mobility shift assays. Among these, mutants with tryptophan in position -11, or glutamic acid and glutamine in position -15, differ significantly from GCN4 in their DNA binding specificities. We then constructed selected double mutants, which differ from GCN4 in positions -11, -15 or -14 (3) of the basic region. The double mutants with tryptophan in position -11 and asparagine or serine in position -14 show drastically altered DNA binding specificities, presumably due to additive effects.

Genetic analysis of the leucine heptad repeats of Lac repressor: evidence for a 4-helical bundle.

Gel-filtration experiments indicate that a peptide (P2) composed of the basic region of GCN4 fused to the leucine heptad repeats of Lac repressor forms tetrameric aggregates. Gel-shift experiments were performed to determine the orientation of the helices in the tetrameric P2 aggregate. Sandwich-complex formation of peptide P2 with two DNA fragments containing two symmetrical CRE binding sites (5'-ATGACGTCAT-3') at a distance of 21 bp suggests antiparallel aggregation of the Lac leucine heptad repeats. Thus, we conclude that the leucine heptad repeats of Lac repressor have the ability to form homomeric 4-helical bundles with an antiparallel arrangement of the helices. This topology enables the two DNA fragments in the sandwich complexes to be held together by two tetramers of peptide P2. Replacement of the uncharged amino acids of the helical g and e positions of peptide P2 by the corresponding charged residues of GCN4 (peptide P4) results in a dimeric and parallel aggregation of the leucine heptad repeats, and consequently abolishes the potential to form sandwich structures. Similarly, a hybrid Lac repressor in which the GCN4 leucine zipper replaces the natural Lac leucine heptad repeats forms dimers only. It regains the ability to form tetramers when the charged amino acids in helical positions g and e are replaced by uncharged alanines.

The DNA binding specificity of the basic region of the yeast transcriptional activator GCN4 can be changed by substitution of a single amino acid.

The X-ray structure of a GCN4 DNA complex (1) shows, that specific DNA binding of the GCN4 basic region is mediated by a complicated network of base pair and DNA backbone contacts. According to the X-ray structure, alanine -14 of the basic region of GCN4 (we define the first leucine of the leucine zipper as +1) makes a hydrophobic contact to the methyl group of the thymine next to the center of the GCN4 binding site 5' ATGACTCAT 3'. We tested the DNA binding properties of the nineteen derivatives of GCN4, which carry all possible amino acids in position -14 of the basic region. Substitution of alanine -14 of GCN4 by either asparagine or cysteine changes the DNA binding specificity. Serine in this position broadens the specificity for position 1 of the target, whereas other amino acids either retain or decrease GCN4 specificity.

Mutants with substitutions for Glu171 in the catabolite activator protein (CAP) of Escherichia coli activate transcription from the lac promoter.

Single amino acid substitutions for residue Glu171 in helix E of the catabolite gene activator protein (CAP) of Escherichia coli have been reported to abolish activation of transcription without impairing binding to the CAP site of the lac promoter. The negative charge of Glu171 was proposed to transmit the activating signal from CAP to RNA polymerase. However, this idea has been challenged by later work. We set up a system to re-examine this issue. We analysed the ability of mutant CAP-E171L and CAP-E171K proteins to bind a near-consensus CAP site in vivo and found it to be diminished fourfold relative to wild type in each case. Activation of lac transcription by these mutant proteins remains the same as with wild-type CAP. Thus our results confirm that Glu171 in helix E of CAP is not involved directly in the activation of transcription. Yet CAP-E171K does not activate transcription as well as wild-type CAP under all circumstances. Possible reasons for this absence of activation are discussed.

Identification of three residues in the basic regions of the bZIP proteins GCN4, C/EBP and TAF-1 that are involved in specific DNA binding.

The bZIP regions of the eukaryotic transcription factors GCN4 and C/EBP have similar protein sequences but they recognize different DNA sequences. In order to understand their specificity, a vector was constructed which permits overexpression in Escherichia coli of those domains of GCN4 that are necessary and sufficient for specific DNA binding i.e. the basic region and the leucine zipper. Specific DNA binding was monitored with gel shift experiments. The residues of the basic region of GCN4 were systematically replaced by those of C/EBP to transform GCN4 into C/EBP with respect to DNA binding. Residues -17, -16 and -14 were found to be responsible for switching GCN4 to C/EBP binding specificity (we define as residue +1 the first leucine of the first leucine heptad repeat of GCN4). We broadened the specificity of GCN4 to TAF-1 by replacing residues -15 and -17 and we changed the specificity of C/EBP to TAF-1 by swapping residue -17 of a particular hybrid. Thus residues positioned from -14 to -17 of the basic region play a key role in recognizing specific DNA sequences.

Lac repressor with the helix-turn-helix motif of lambda cro binds to lac operator.

Lac repressor, lambda cro protein and their operator complexes are structurally, biochemically and genetically well analysed. Both proteins contain a helix-turn-helix (HTH) motif which they use to bind specifically to their operators. The DNA sequences 5'-GTGA-3' and 5'-TCAC-3' recognized in palindromic lac operator are the same as in lambda operator but their order is inverted form head to head to tail to tail. Different modes of aggregation of the monomers of the two proteins determine the different arrangements of the HTH motifs. Here we show that the HTH motif of lambda cro protein can replace the HTH motif of Lac repressor without changing its specificity. Such hybrid Lac repressor is unstable. It binds in vitro more weakly than Lac repressor but with the same specificity to ideal lac operator. It does not bind to consensus lambda operator.

Repression of the E. coli lactose operon by cooperation between two individually unproductive "half-operator" sites.

Two remote and weak lac regressor binding sites can be used jointly to repress the synthesis of beta-galactosidase in E. coli, while they cannot separately. When this result is discussed in reference to the various modes of cooperation between the sites, it supports with a new approach a model implying the simultaneous binding of lac repressor to both sites with the formation of a DNA loop. In connection with this point, we present a new strategy to detect cooperative interactions in vivo, based on the asymmetry of the DNA binding site, formally equivalent here to a half-site, heterodimerization of the protein, and influence of orientation of the sites on repression at short and long distance.

A model of the lac repressor-operator complex based on physical and genetic data.

Computer graphics were used to build a molecular model of the complex of Lac repressor and lac operator. The model is based (a) on the NMR data of the Kaptein group [Boelens, R., Lamerichs, R. M. J. N., Rullmann, J. A. C., van Boom, J. H. & Kaptein, R. (1988) Protein Sequence Data Anal. 1, 487-498] and (b) on our genetic and biochemical data including specificity changes [Lehming, N., Sartorius, J., Kisters-Woike, B., von Wilcken-Bergmann, B. & Müller-Hill, B. (1990) EMBO J. 9, 615-621]. Effects of amino acid exchanges in the recognition helix could be predicted by the model and were subsequently tested and confirmed by genetic experiments. Comparison of the modelled lac complex with the known crystallographic structures of several helix-turn-helix DNA complexes reveals striking similarities and suggests rules which govern the recognition between particular amino acid side chains and particular base pairs in these systems.

The roles of residues 5 and 9 of the recognition helix of Lac repressor in lac operator binding.

We constructed expression libraries for Lac repressor mutants with amino acid exchanges in positions 1, 2, 5 and 9 of the recognition helix. We then analysed the interactions of residues 5 and 9 with operator variants bearing single or multiple symmetric base-pair exchanges in positions 3, 4 and 5 of the ideal fully symmetric lac operator. We isolated 37 independent Lac repressor mutants with five different amino acids in position 5 of the recognition helix that exhibit a strong preference for particular residues in position 2 and, to a lesser extent, in position 1 of the recognition helix. Our results suggest that residue 5 of the recognition helix (serine 21) contributes to the specific recognition of base-pair 4 of the lac operator. They further suggest that residue 9 of the recognition helix (asparagine 25) interacts non-specifically with a phosphate of the DNA backbone, possibly between base-pairs 2 and 3.

Dimer-to-tetramer assembly of Lac repressor involves a leucine heptad repeat.

The C-terminus of Lac repressor is responsible for the formation of repressor tetramers from active dimers. If properly grafted, the C-terminus of Lac repressor (amino acids 331 to 360) converts Gal repressor dimers into tetramers. Amino acids 342 to 356 of Lac repressor contain a 4-3 hydrophobic repeat of four leucines and one valine. Systematic amino acid replacements of all residues in this region show that the protein-protein interaction between repressor dimers depends mainly on the hydrophobic residues of the 4-3 repeat, which is constitutive for coiled coils. Thus the tetramerization site of Lac repressor resembles the leucine zipper motif found in a family of eukaryotic transcription factors.

Linker mutagenesis in the lacZ gene of Escherichia coli yields variants of active beta-galactosidase.

Synthetic octameric oligonucleotides that code for a unique restriction site were cloned into a randomly linearized plasmid that carries the lacZ gene. The insertions were mapped by digestion with appropriate restriction endonucleases. 12 mutants were identified which carry an insertion within the lacZ gene and still express active beta-galactosidase. Small deletions or duplications of the wild-type sequence occurred at these positions which restore the correct reading frame. The insertions occurred in the first and the last third of the internal duplication of the lacZ gene and within the domain homologous to dihydrofolate reductase.