Three additional operators, Op21, Op68, and Op88, of bacteriophage P1. Evidence for control of the P1 dam methylase by Op68

The repressor of bacteriophage P1, encoded by the c1 gene, is responsible for maintaining the P1 prophage in the lysogenic state. Previously, 11 c1 repressor binding sites or operators scattered over the whole genome of P1 have been found. From sequence analysis an asymmetric, 17-base pair consensus sequence, ATTGCTCTAATAAATTT, was derived. Using a synthetic 15-base-long oligodeoxyribonucleotide as operator probe, we have identified three additional operators. We have mapped the operators at the positions 21,68, and 88 of the P1 genome and determined their sequence. These operators are controlled by c1 because corresponding P1 DNA fragments (i) require c1 repressor in vivo in order to be clonable in multicopy plasmids, (ii) exhibit a c1-repressible promoter activity, (iii) are retarded by c1 repressor protein during electrophoresis, and (iv) contain the 17-base pair consensus sequence with one mismatch base each. Furthermore, we suggest that expression of the DNA adenine methylase (dam) encoded by P1 is controlled via Op68.     

Saturation mutagenesis of the Tn10-encoded tet operator O1. Identification of base-pairs involved in Tet repressor recognition

Saturation mutagenesis of Tn10-encoded tet operator O1 was performed by chemical synthesis of 30 sequence variants yielding all possible point mutations of an operator half side. Their effect on Tet repressor binding was scored by an in-vivo repressor titration system. Tet repressor affinities of selected operator mutants were further characterized in vitro by dissociation rate measurements. The O1 sequence spans 19 base-pairs. Out of these, all 18 palindromic base-pairs are involved in Tet repressor recognition. The central base-pair does not contribute to sequence-specific binding of Tet repressor. At position 1 a pyrimidine residue is sufficient for maximal affinity to the repressor. At positions 2, 3 and 4, each mutation reduces repressor binding at least tenfold. Mutations at positions 5, 6, 7, 8 and 9 result in less drastic reductions of Tet repressor binding. Differential effects of mutations at a given position are used to deduce the chemical functions contacted by Tet repressor. The T.A to A.T transversion at position 9 increases Tet repressor affinity slightly, while all other mutations decrease repressor binding. The increased affinity of the wild-type tet operator O2 compared to wild-type O1 results from the addition of two favorable transversions at positions +/- 9 and an unfavorable T.A to C.G transition at position -7. Deletion or palindromic doubling of the central base-pair of the O1 palindrome reveals that the wild-type spacing of both operator half sides is crucial for efficient Tet repressor binding.     

Crystallographic analysis of Lac repressor bound to natural operator O1

Previous structures of Lac repressor bound to DNA used a fully symmetric "ideal" operator sequence that is missing the central G-C base-pair present in the three natural operator sequences. Here we have determined the X-ray crystal structure of a dimeric Lac repressor bound to a 22 base-pair DNA with the natural operator O1 sequence and the anti-inducer ONPF, at 4.0 A resolution. The natural operator is bent in the same way as the symmetric sequence, due to the binding of the hinge helices of the repressor to the minor groove at the central GCGG sequence of O1. Comparison of the structures of the repressor bound to the natural and symmetric operators shows very similar overall structures, with only slight rearrangements of the headpiece domains of the repressor. Analysis of crystals with iodinated DNA shows that the operator is uniquely positioned and allows for the sequence registration of the DNA relative to the repressor to be determined. The kink in the operator is centered between the left half-site and the central G-C base-pair of O1. Our results are most consistent with a previously proposed model in which, relative to the complex with the symmetric operator, the repressor accommodates binding to the natural operator sequence by shifting the position of the right headpiece by one base-pair step towards the center of O1.     

The Bof protein of bacteriophage P1 exerts its modulating function by formation of a ternary complex with operator DNA and C1 repressor.

Bacteriophage P1 encodes several regulatory elements for the lytic or lysogenic response, which are located in the immC, immI, and immT regions. Their products are the C1 repressor of lytic functions with the C1 inactivator protein Coi, the C4 repressor of antirepressor synthesis and the modulator protein Bof, respectively. We have studied in vitro the interaction of the components of the immC and immT regions with C1-controlled operators using highly purified Bof, C1, and Coi proteins. Bof protein (M(r) = 9,800) does not interact with C1 repressor alone, but as shown by DNA mobility shift experiments, in the presence of C1 repressor Bof binds to all operators tested by forming a C1.Bof-operator DNA ternary complex. The effect of this complex formation was studied in more detail with the operator of the c1 gene. Here, Bof only marginally alters the C1 repressor footprint at Op99a,b, but nevertheless considerably influences the repressibility of the operator.promoter element: (i) the autoregulated c1 mRNA synthesis is further down-regulated and (ii) the ability of Coi protein to dissociate the C1.operator DNA complex is strongly inhibited. We suggest that Bof protein functions by modulating C1 repression of many widely dispersed operators on the prophage genome.     

Operator sequences of bacteriophages P22 and 21

We have determined the sequences of the left and right operators of bacteriophages P22 and 21. The corresponding operators of the two phages have nearly identical sequences, thus explaining how the repressor of each phage recognizes the operators of the other. Experiments probing the binding of repressor and operator show that each operator contains three repressor binding sites. The repressor binding sites are 18 base-pair, partially symmetric sequences. The dispersed symmetric sequence A.T.AAG.…CTT.A.T is highly conserved among the 12 repressor binding sites of the two phages. Four virulent mutations have been sequenced; all of them alter bases in the conserved sequence.     

The ban operon of bacteriophage P1. Localization of the promoter controlled by P1 repressor

Repression of a strong promoter localized 5' to the P1 ban gene is a prerequisite for cloning the ban operon in the multicopy plasmid pBR325. Repression is brought about by the binding of P1 repressor to the operator of the ban operon (Heisig, A., Severin, I., Seefluth, A. K., and Schuster, H. (1987) Mol. Gen. Genet. 206, 368-376). Binding of RNA polymerase in vitro overlaps with the operator and is inhibited by P1 repressor as shown by electron microscopy. The mutant P1 bac, which renders ban expression constitutive, contains a single base pair exchange within the operator. As a consequence, more repressor is required (i) for the inhibition of binding of RNA polymerase, and (ii) for the electrophoretic retardation of a P1 bac DNA fragment when compared to the corresponding bac+ fragment. A P1 ban recombinant plasmid containing a 4-base pair deletion close to the operator still allows binding of repressor but not of RNA polymerase. By that means, a repressible promoter is located at the P1 map position 72 in a distance of about 2.5 kilobase pairs to the beginning of the ban gene.     

Quantitative analysis of Tn10 Tet repressor binding to a complete set of tet operator mutants.

A saturating oligonucleotide-directed mutagenesis of both tet operators in the tet regulatory sequence was performed yielding mutants with four identical base pair exchanges at equivalent positions in the four tet operator half sides. The mutants were cloned between bipolar lacZ and galK indicator genes on a multicopy plasmid allowing the quantitative analysis of their effects in vivo. In the absence of Tet repressor the mutations lead to considerably different expression levels of both genes. They are discussed with respect to the promoter consensus sequences. In particular, the -10 region of the in vivo active tetPR2 promoter is unambiguously defined by these results. In the presence of Tet repressor most of the mutants exhibit a lower affinity for that protein as determined quantitatively by their reduced expression levels. In general, tet operator recognition is most strongly affected by alterations of base pairs near the center of the palindromic sequence. The most important position is the third base pair, followed by base pairs two, four, five and six, the latter showing similar effects as base pair one. At each position, the four possible base pairs show different affinities for Tet repressor. They are discussed according to their exposure of H-bond donors and -acceptors in the major and minor grooves of the B-DNA. The results are in agreement with major groove contacts at positions two, three and five. At position four a low potential correlation of efficiencies with the H-bonding in the minor groove is found, while mutations at position six seem to influence repressor binding by other mechanisms.     

Contacts between Tet repressor and tet operator revealed by new recognition specificities of single amino acid replacement mutants.

We have analyzed the DNA binding properties of Tet-repressor mutants with single amino acid residue replacements at eight positions within the alpha-helix-turn-alpha-helix DNA-binding motif. A saturation mutagenesis of Gln38, Pro39, Thr40, Tyr42, Trp43 and His44 in the second alpha-helix was performed; in addition, several substitutions of Thr27 and Arg28 in the first alpha-helix were constructed. The abilities of these mutant repressors to bind a set of 16 operator variants were determined and revealed 23 new binding specificities. All repressor mutants with DNA-binding activity were inducible by tetracycline, while mutants lacking binding activity were trans-dominant over the wild-type. All mutant proteins were present at the same intracellular steady-state concentrations as the wild-type. These results suggest the structural integrity of the mutant repressors. On the basis of the new recognition specificities, five contacts between a repressor monomer and each operator half-site and the chemical nature of these repressor-operator interactions are proposed. We suggest that Arg28 contacts guanine of the G.C base-pair at operator position 2 with two H-bonds, Gln38 binds adenine of the A.T base-pair at position 3 with two H-bonds, and the methyl group of Thr40 participates in a van der Waals' contact with cytosine of the G.C base-pair at position 6 of tet operator. A previously unrecognized type of interaction is proposed for Pro39, which inserts its side-chain between the methyl groups of the thymines of T.A and A.T base-pairs at positions 4 and 5. Computer modeling of these proposed contacts reveals that they are possible using the canonical structures of the helix-turn-helix motif and B-DNA. These contacts suggest an inverse orientation of the Tet repressor helix-turn-helix with respect to the operator center as compared with non-inducible repressor-operator complexes, and are supported by similar contacts of other repressor-operator complexes.     

Interaction of the Bacillus subtilis phage phi 105 repressor DNA: a genetic analysis.

The Bacillus subtilis phage phi 105 repressor specifically recognizes a 14-bp operator sequence which does not exhibit 2-fold rotational symmetry. To facilitate a genetic analysis of this sequence-dependent DNA binding a B. subtilis strain was constructed in which mutations affecting the phi 105 repressor-operator interaction cause a selectable phenotype, chloramphenicol resistance. After in vivo mutagenesis, we isolated and mapped 22 different mutations in the repressor coding sequence, 15 of which are missense substitutions. These are exclusively located in the N-terminal part (positions 1-43) of the 144 residue long polypeptide. Two nonsense mutants, at positions 70 and 89, respectively, still show partial repressor activity. These data suggest that the phi 105 repressor consists of at least two independently folding structural domains, of which the N-terminal is involved in operator binding. Twelve missense mutations are clustered in a region extending from Gln-18 to Arg-37, which we propose to be the DNA-binding alpha-helix--beta-turn--alpha-helix motif, common to all lambda Cro-like repressors. The second ('recognition') helix shows significant homology with the corresponding sequence in Tn3 resolvase, and there is also a striking similarity between the phi 105 operator and the consensus sequence for a Tn3 res half-site. Based on these observations, and on the previously isolated phi 105 0c mutants, we tentatively assign some specific contacts between base pairs from the first half of a phi 105 operator site and amino acids from the repressor's 'recognition helix'.     

Characterization of the binding sites of c1 repressor of bacteriophage P1. Evidence for multiple asymmetric sites

The repressor of bacteriophage P1, encoded by the c1 gene, is responsible for maintaining a P1 prophage in the lysogenic state. In this paper we present: (1) the sequence of the rightmost 943 base-pairs of the P1 genetic map that includes the 5'-terminal 224 base-pairs of the c1 gene plus its upstream region; (2) the construction of a plasmid that directs the production of approximately 5% of the cell's protein as P1 repressor; (3) a deletion analysis that establishes the startpoint of P1 repressor translation; (4) filter binding experiments that demonstrate that P1 repressor binds to several regions upstream from the c1 gene; (5) DNase I footprint experiments that directly identify two of the P1 repressor binding sites. Sequences very similar to the identified binding sites occur in at least 11 sites in P1, in most cases near functions known, or likely, to be controlled by repressor. From these sites we have derived the consensus binding site sequence ATTGCTCTAATAAATTT. We suggest that, unlike other phage operators, the P1 repressor binding sites lack rotational symmetry.     

Phage λ Cro Protein and Ci Repressor Use Two Different Patterns of Specific Protein-DNA Interactions to Achieve Sequence Specificity in Vivo

By assaying the binding of wild-type Cro to a set of 40 mutant lambda operators in vivo, we have determined that the 14 outermost base pairs of the 17 base pair, consensus lambda operator are critical for Cro binding. Cro protein recognizes 4 base pairs in a lambda operator half-site in different ways than cI repressor. The sequence determinants of Cro binding at these critical positions in vivo are nearly perfectly consistent with the model proposed by W. F. ANDERSON, D. H. OHLENDORF, Y. TAKEDA and B. W. MATTHEWS and modified by Y. TAKEDA, A. SARAI and V. M. RIVERA for the specific interactions between Cro and its operator, and explain the relative order of affinities of the six natural lambda operators for Cro. Our data call into question the idea that lambda repressor and Cro protein recognize the consensus lambda operator by nearly identical patterns of specific interactions.     

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.     

Characterization of the interaction of the glp repressor of Escherichia coli K-12 with single and tandem glp operator variants.

The glp operons of Escherichia coli are negatively controlled by the glp repressor. Comparison of the repressor-binding affinities for consensus and altered consensus operators in vivo showed that all base substitutions at positions 3, 4, 5, and 8 from the center of the palindromic operator caused a striking decrease in repressor binding. Substitutions at other positions had a severe to no effect on repressor binding, depending on the base substitution. The results obtained indicate that the repressor binds with highest affinity to operators with the half-site WATKYTCGWW, where W is A or T, K is G or T, and Y is C or T. Strong cooperative binding of the repressor to tandem operators was demonstrated in vivo. Cooperativity was maximal when two 20-bp operators were directly repeated or when 2 bp separated the two operators. Cooperativity decreased with the deletion of 2 bp or the addition of 4 bp between the individual operators. Cooperativity was eliminated with a 6-bp insertion between the operators.     

Dual Regulatory Control of a Particle Maturation Function of Bacteriophage P1

A unique arrangement of promoter elements was found upstream of the bacteriophage P1 particle maturation gene (mat). A P1-specific late-promoter sequence with conserved elements located at positions -22 and -10 was expected from the function of the gene in phage morphogenesis. In addition to a late-promoter sequence, a -35 element and an operator sequence for the major repressor protein, C1, were found. The -35 and -10 elements constituted an active Escherichia coli sigma(70) consensus promoter, which was converted into a P1-regulated early promoter by the superimposition of a C1 operator. This combination of early- and late-promoter elements regulates and fine-tunes the expression of the particle maturation gene. During lysogenic growth the gene is turned off by P1 immunity functions. Upon induction of lytic growth, the expression of mat starts simultaneously with the expression of other C1-regulated P1 early functions. However, while most of the latter functions are downregulated during late stages of lytic growth the expression of mat continues throughout the entire lytic growth cycle of bacteriophage P1. Thus, the maturation function has a head start on the structural components of the phage particle.     

Lambda cro repressor complex with OR3 operator DNA. 19F nuclear magnetic resonance observations

The interaction of lambda cro repressor with DNA is probed using synthetic 17 base-pair OR3 operators in which 5-fluorodeoxyuridine has been systematically incorporated at each of the nine positions normally occupied by a thymidine residue. By monitoring changes in chemical shift of the fluorine resonances upon cro repressor binding in aqueous buffers of varying 2H2O content, we have examined the specific cro repressor-OR3 DNA complex in detail. The results are interpreted in the context of the popular model for cro repressor-OR3 complex derived from the three-dimensional structure of the cro repressor in the absence of DNA. The results presented here not originally predicted by the model are: (1) there is an asymmetry in the environment at the two ends of the operator, although the base-pairs involved and the cro repressor dimer are symmetric; (2) there appears to be distortion of the DNA helix at two distinct positions; (3) changes of the DNA environment in the middle of the helix suggest additional DNA distortion not near the contact areas proposed in the model.     

The c1 repressor of bacteriophage P1 operator-repressor interaction of wild-type and mutant repressor proteins.

The c1 repressor gene of bacteriophage P1 and the temperature-sensitive mutants P1c1.100 and P1c1.162 was cloned into an expression vector and the repressor proteins were overproduced. A rapid purification procedure was required for the isolation of the thermolabile repressor proteins. Identification of the highly purified protein of an apparent molecular weight of 33,000 as the product of the c1 gene was verified by (i) the coincidence of partial amino acid sequences determined experimentally to that deduced from the c1 DNA sequence, and (ii) the temperature-sensitive binding to the operator DNA of the thermolabile repressor proteins. Analysis of the products of c1-c1.100 recombinant DNAs relates the thermolability to an unknown alteration in the C-terminal half of the c1.100 repressor. Binding to the operator DNA of c1 repressor is sensitive to N-ethylmaleimide. Since the only three cysteine residues are located in the C-terminal half of the repressor it is suggested that this part of the molecule is important for the binding to the operator DNA. This assumption is supported by the findings that a 14-kDa C-terminal repressor fragment obtained by cyanogen bromide cleavage retains DNA binding properties.     

DNA supercoiling promotes formation of a bent repression loop in lac DNA

Titration experiments on supercoiled lac DNA show that one repressor tetramer can bind simultaneously to the primary lac operator and to the very weak lac pseudo-operator, located 93 base-pairs apart. The formation of this complex is accompanied by the appearance of an extreme hypersensitive site in a five base-pair sequence located approximately midway between the operators. This remote sequence is hypersensitive to attack by two different chemical probes, dimethyl sulfate and potassium permanganate, the latter of which is a new probe for distorted DNA. We interpret these results in terms of a complex in which lac repressor holds two remote operators together in a DNA loop. The formation of this bent DNA loop requires negative DNA supercoiling. In vivo, both lac operators bind repressor even though the presence of multiple operator copies has forced the two operators to compete for a limited amount of repressor. This suggests that the operator and pseudo-operator have similar affinities for repressor in vivo. Such similar affinities were observed in vitro only when DNA supercoiling forced formation of a repression loop.