ban operon of bacteriophage P1. Mutational analysis of the c1 repressor-controlled operator

The repressor of bacteriophage P1, encoded by the c1 gene, represses the phage lytic functions and is responsible for maintaining the P1 prophage in the lysogenic state. The c1 repressor interacts with at least 11 binding sites or operators widely scattered over the P1 genome. From these operators, a 17 base-pair asymmetric consensus sequence, ATTGCTCTAATAAATTT, was derived. Here, we show that the operator, Op72 of the P1ban operon consists of two overlapping 17 base-pair sequences a and b forming an incomplete palindrome. Op72a matches the consensus sequence, whereas Op72b contains two mismatches. The evidence is based on the sequence analysis of 27 operator mutants constitutive for ban expression. They were identified as single-base substitutions at positions 2 to 10 of Op72a (26 mutants) and at position 8 of Op72b (one mutant). We conclude from gel retardation and footprinting studies that two repressor molecules bind to the operator and that positions 4, 5 and 7 to 10 of the operator play an essential role in repressor recognition.     

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.     

A bacteriophage P1-encoded modulator protein affects the P1 c1 repression system

Bacteriophage P1 encodes a tripartite immunity system composed of the immC, immI, and immT region. Their basic genetic elements are the c1 repressor of lytic functions, the c4 repressor which negatively regulates antirepressor synthesis, and the bof gene, respectively. The function of the latter will be described here. We have cloned and sequenced the bof gene from P1 wild type and a P1 bof amber mutant. Based on the position of a TAG codon of the bof amber mutant the bof wild type gene was localized. It starts with a TTG codon, comprises 82 codons, and is preceded by a promoter structure. The bof protein (Mr = 7500) was overproduced in Escherichia coli from a bof recombinant plasmid and was purified to near homogeneity. The N-terminal amino acids predicted from the DNA sequence of the bof gene were confirmed by sequence analysis of the bof protein. Using a DNA mobility shift assay, we show that bof protein enhances the binding of c1 repressor to the operator of the c1 gene. In accordance with this result, in transformants of Escherichia coli, containing both a bof- and a c1-encoding plasmid, c1 expression is down-regulated. We conclude that bof acts as a modulator protein in the repression of a multitude of c1-controlled operators in the P1 genome.     

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.     

Interaction of the Mnt repressor with 37-base pair synthetic operator DNA fragments. Importance of symmetric GC pairs

Mnt repressor is indirectly responsible for the maintenance of lysogeny of the phage P22. This repressor interacts with a 21-base pair operator DNA constituting within it a 17-base pair perfect 2-fold symmetric sequence whose bases make a direct contact with the protein. We have synthesized six 37-base pair DNAs consisting of 21 base pair natural operator and its modifications in which certain symmetrically situated GC base pairs were replaced systematically with ATs to understand their importance. The binding interaction studies of Mnt repressor to such natural and modified operator DNAs reported here indicate that the GCs close to the center of symmetry make major contacts with the protein whereas, GCs nearer to the periphery form weak contacts. Methylation protection experiments indicated that when the GCs near the center of symmetry were replaced with AT, the central GC became more accessible for dimethyl sulfate methylation with possible conformational change in DNA. The circular dichroism studies indicated that upon repressor binding conformational changes in DNA takes place with a possible increase in helicity of the repressor protein.     

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.     

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.     

A barbiturate-regulated protein binding to a common sequence in the cytochrome P450 genes of rodents and bacteria

Analyses of the 5' regulatory sequences of genes encoding barbiturate-inducible cytochromes P450BM-1 and P450BM-3 from Bacillus megaterium and of the 5' sequences of genes for barbiturate-inducible P450b and P450e of the rat revealed a string of 17 base pairs in each of the genes that shared a high degree of sequence identity. Labeled oligonucleotide probes of each of these four sequences were tested in gel retardation assays with protein obtained from B. megaterium grown either in the presence or absence of barbiturates or with protein from nuclear extracts from livers of rats left untreated or injected with phenobarbital. Each of the four 17-mers bound strongly to a single protein from bacteria grown in the absence of barbiturates, but this binding was dramatically reduced with protein from pentobarbital- or phenobarbital-grown cells. Conversely, the probes complexed weakly to one protein band from nuclear extracts from untreated rats but much more strongly with protein from phenobarbital-treated rats. Similar effects could be obtained by prolonged incubation with phenobarbital of either soluble protein from the bacteria grown in the absence of barbiturates or nuclear extract protein from untreated rats. Deletion analysis of the 5'-flanking region of the P450BM-1 gene of B. megaterium revealed a putative repressor binding site located within a 24-base pair DNA segment that included the 17-base pair sequence involved in barbiturate-regulated protein binding.     

Non-contacted bases affect the affinity of synthetic P22 operators for P22 repressor.

The affinity of synthetic P22 operators for P22 repressor varies with the base sequence at the operator's center. At 100 mM KCl, the affinity of these operators for P22 repressor varies over a 10-fold range. Dimethylsulfate protection experiments indicate that the central bases of the P22 operator are not contacted by the repressor. The KD for the complex of P22 repressor with an operator bearing central T-A bases (9T) increases less than 2-fold between 50 and 200 mM KCl, whereas the KD for the complex of repressor with an operator bearing central C-G bases (9C) increases 10-fold in the same salt range. The DNase I cleavage patterns of both bound and unbound P22 operators also vary with central base sequence. The DNase I pattern of the repressor-9C operator complex changes markedly with salt concentration, whereas that of the 9T operator-repressor complex does not. These changes in nuclease digestion pattern thereby mirror the salt-dependent changes in the P22 operator's affinity for repressor. P22 repressor protects the central base pair of the 9T operator from cleavage by the intercalative cleavage reagent Cu(I)-phenanthroline, while repressor does not protect the central bases of the 9C operator. Together these data indicate that central base pairs affect P22 operator strength by altering the structure of the unbound operator and the repressor-operator complex.     

Sequence-dependent variability of DNA structure. Influence of flanking sequences and fragment length on digestion by conformationally sensitive nucleases

DNase I and 1,10-phenanthroline-copper are two nucleolytic activities which are sequence-dependent in their scission reaction yet are not nucleotide-specific at their site of cutting. When these two nucleases are used to digest identical sequences in 18-base pair oligonucleotides and in restriction fragments 10-fold longer, the digestion patterns are similar at sequence positions in the interior of the fragment. Changes in reactivity to 1,10-phenanthroline-copper associated with mutational changes in the lac promoter in biochemically functional restriction fragments are duplicated in 18-base pair oligonucleotides. The structural variability of a given DNA sequence detected by these conformationally sensitive nucleolytic activities is therefore encoded in local sequence and not sensitive to fragment length. Digestion patterns of a repeated 7-base pair sequence within a longer sequence have the same characteristic except for the two nucleotides at the 5' periphery of the direct repeat. This conclusion is based on the digestion pattern of a restriction fragment which contains the polyadenylation site of the mouse immunoglobulin mu heavy chain gene. Two pairs of different 7-base pair sequences repeated in this fragment retain their distinctive digestion patterns. DNA sequences which comprise the binding sites of regulatory proteins, retain a characteristic structure only influenced at their peripheries by two to three bases of the flanking sequence.     

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.     

Genetic analysis of the lytic replicon of bacteriophage P1. I. Isolation and partial characterization

Despite the extensive genetic analysis of bacteriophage P1, the region of the viral genome that is responsible for its lytic (vegetative) replication has not been identified. In this paper we describe the identification of various fragments of P1 DNA that can replicate an otherwise replication-defective lambda vector when they are cloned into that vector. The fragments share a 2800 base-pair segment of the P1 genome that is located adjacent to the immI region of the phage. Replication mediated by the cloned P1 fragments is abolished by the product of the P1 c1 gene, the repressor of phage lytic functions. Since these properties resemble those of the P1 lytic replicon, we suggest that the 2800 base-pair segment identified here contains that replicon.     

C1 repressor of phage P1 is inactivated by noncovalent binding of P1 Coi protein.

The temperate phage P1 encodes two genes whose products antagonize the action of the phage's C1 repressor of lytic functions, namely a distantly linked antirepressor gene, ant, and a closely linked c1 inactivator gene, coi. Starting with an inducible coi-recombinant plasmid, Coi protein was overproduced and purified to near homogeneity. By using a DNA mobility shift assay we demonstrate that Coi protein inhibits the operator binding of the C1 repressors of the closely related P1 and P7 phages. Coi protein (Mr = 7,600) exerts its C1-inactivating function by forming a complex with the C1 repressor (Mr = 32,500) at a molar ratio of about 1:1, as shown by density gradient centrifugation and gel filtration. C1 repressor and Coi protein are recovered in active form from the complex, suggesting that noncovalent interactions are the sole requirements for complex formation. The interplay of repressor and antagonists operating in the life cycle of P1 is discussed.