The tripartite immunity system of phages P1 and P7.

Prophages P1 and P7 exist as unit copy DNA plasmids in the bacterial cell. Maintenance of the prophage state requires the continuous expression of two repressors: (i) C1 is a protein which negatively regulates the expression of lytic genes including the C1 inactivator gene coi, and (ii) C4 is an antisense RNA which specifically inhibits the synthesis of an anti-repressor Ant. In addition, C1 repression is strengthened by lxc encoding an auxiliary repressor protein. The repressors C1, C4 and Lxc are components of a tripartite immunity system of the two phages. Here, the mode of action of these regulatory components including their antagonists Coi and Ant is described.

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.

Acute obturator internus muscle strain in a rugby player: a case report.

A 28-year-old male rugby player presented with severe onset of right hip pain when he fell awkward after a ruck during an international match. A rare case of an acute strain of the obturator internus muscle, a deep muscle of the hip joint, is reported, which resolved completely after a period of rest and intense active physical therapy.

Purification of the C1 repressor of bacteriophage P1 by fast protein liquid chromatography.

A fast protein liquid chromatographic method is described for the purification of the C1 repressor of bacteriophage P1 and its truncated form C1*. By using one crude extract, both repressor proteins were purified in parallel to homogeneity and were shown to interact specifically with P1 operator DNA in vitro. The method involves an affinity chromatographic step on heparin-Sepharose, followed by a combination of ion-exchange chromatography on Q Sepharose and S Sepharose. The availability of a homogeneous preparation of the phage repressor is a prerequisite for studies on its structure-function relationship.

Multiple repressor binding sites in the genome of bacteriophage P1.

After digestion of bacteriophage P1 DNA with EcoRI in the presence of P1 repressor, 6 repressor binding sites were identified in 5 of 26 EcoRI fragments. Binding sites were localized by the decreased mobility of DNA fragment-repressor complexes during electrophoresis and by DNase protection ("footprinting") analysis. The repressor binding sites, or operators, comprise a 17-base-pair-long consensus sequence lacking symmetrical elements. Three operators can be related to known genes, whereas the function of the others is still unknown. The mutant P1 bac, rendering ban expression constitutive, is identified as an operator-constitutive mutation of the ban operon.

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.

The c1 repressor inactivator protein coi of bacteriophage P1. Cloning and expression of coi and its interference with c1 repressor function.

The immC region of bacteriophage P1 contains the c1 repressor gene and its upstream region with four c1-controlled operators and four open reading frames. A c1 inactivator gene, coi, was defined by mutations in immC that suppress the virulence of the P1virC mutation. The exact location of the coi gene was not known (Scott, J.R. (1980) Curr. Top. Microbiol. Immunol. 90, 49-65). When a variety of P1 immC fragments were inserted into an expression vector, a gene product was inducible for the open reading frame 4 only. We identify this product as the c1 inactivator protein, coi by the following criteria: (a) expression of coi from a recombinant plasmid induces the P1 prophage and inhibits lysogenization of sensitive bacteria by P1; (b) all c1-controlled operator-promoter elements tested in vivo are derepressed by coi; (c) a partially purified coi protein (apparent molecular weight = 4800) interacts with c1 repressor and inhibits its binding to the operator in vitro. Based on these results we refine a model for the regulation of those genes and elements within immC which participate in the decision of P1 to enter the lytic or lysogenic pathway.

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.

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.

The c1 repressor of bacteriophage P1. Isolation and characterization of the repressor protein.

The c1 repressor gene of bacteriophage P1 is located on P1 DNA EcoRI fragment 7 (Sternberg, N. (1979) Virology 96, 129-142). Subfragments of P1 DNA EcoRI fragment 7 were cloned into expression vectors, and the c1 repressor protein from P1 wild-type phage and a revertant of a temperature-sensitive repressor mutant were overproduced in Escherichia coli and purified to near-homogeneity. The decreased electrophoretic mobility of P1 DNA BamHI fragment 9 in the presence of appropriate protein fractions was used as an assay for the repressor protein. Highly purified repressor migrates as a single polypeptide on denaturing sodium dodecyl sulfate-polyacrylamide gels, corresponding to a molecular weight of about 33,000. A molecular weight of about 63,000 for the native repressor molecule was calculated from determinations of the sedimentation coefficient, which was 2.6 s, and the Stokes radius, which was 55 A. Cross-linking the protein with glutaraldehyde yielded two bands. These data and a high frictional coefficient (2.1) suggest that the native repressor exists in solution as an asymmetric dimer molecule.

Three functions of bacteriophage P1 involved in cell lysis.

Amber and deletion mutants were used to assign functions in cell lysis to three late genes of bacteriophage P1. Two of these genes, lydA and lydB of the dar operon, are 330 and 444 bp in length, respectively, with the stop codon of lydA overlapping the start codon of lydB. The third, gene 17, is 558 bp in length and is located in an otherwise uncharacterized operon. A search with the predicted amino acid sequence of LydA for secondary motifs revealed a holin protein-like structure. Comparison of the deduced amino acid sequence of gene 17 with sequences of proteins in the SwissProt database revealed homologies with the proteins of the T4 lysozyme family. The sequence of lydB is novel and exhibited no known extended homology. To study the effect of gp17, LydA, and LydB in vivo, their genes were cloned in a single operon under the control of the inducible T7 promoter, resulting in plasmid pAW1440. A second plasmid, pAW1442, is identical to pAW1440 but has lydB deleted. Induction of the T7 promoter resulted in a rapid lysis of cells harboring pAW1442. In contrast, cells harboring pAW1440 revealed only a small decrease in optical density at 600 nm compared with cells harboring vector alone. The rapid lysis phenotype in the absence of active LydB suggests that this novel protein might be an antagonist of the holin LydA.

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.

Bacteriophage P1 gene 10 is expressed from a promoter-operator sequence controlled by C1 and Bof proteins.

Gene 10 of bacteriophage P1 encodes a regulatory function required for the activation of P1 late promoter sequences. In this report cis and trans regulatory functions involved in the transcriptional control of gene 10 are identified. Plasmid-borne fusions of gene 10 to the indicator gene lacZ were constructed to monitor expression from the gene 10 promoter. Production of gp10-LacZ fusion protein became measurable at about 15 min after prophage induction, whereas no expression was observed during lysogenic growth. The activity of an Escherichia coli-like promoter, Pr94, upstream of gene 10, was confirmed by mapping the initiation site of transcription in primer extension reactions. Two phage-encoded proteins cooperate in the trans regulation of transcription from Pr94: C1 repressor and Bof modulator. Both proteins are necessary for complete repression of gene 10 expression during lysogeny. Under conditions that did not ensure repression by C1 and Bof, the expression of gp10-LacZ fusion proteins from Pr94 interfered with transformation efficiency and cell viability. Results of in vitro DNA-binding studies confirmed that C1 binds specifically to an operator sequence, Op94, which overlaps the -35 region of Pr94. Although Bof alone does not bind to DNA, together with C1 it increases the efficiency of the repressor-operator interaction. These results are in line with the idea that gp10 plays the role of mediator between early and late gene transcription during lytic growth of bacteriophage P1.

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.

C1 repressor-mediated DNA looping is involved in C1 autoregulation of bacteriophage P1.

C1 repressor is required to repress the lytic functions of a P1 prophage in vivo. Transcription of the c1 gene is autoregulated via the C1-controlled operator Op99a,b which overlaps the promoter of the c1 gene. It is negatively affected by Lxc corepressor and the DNA region upstream of c1, which contains the additional operators Op99c, d, and e. We have explored these effects by constructing a set of lacZ reporter plasmids with Op99a,b and varying parts of the upstream DNA region. Transcription levels were measured in vivo with a two-plasmid system containing the lacZ reporter and a c1+ lxc+ or c1+ lxc- plasmid. Compared to the C1+Lxc-repressed lacZ reporter with all operators present, the basal level of beta-galactosidase activity increases successively when (i) upstream operators were deleted or inactivated, (ii) Lxc corepressor was removed, and (iii) C1 and Lxc were absent. By that means a 2 x 2 x 15-fold stepwise increase in enzyme activity was found. Using electron microscopy to visualize the interaction of C1 repressor with the operators in vitro, looped DNA molecules were observed. Although all operators can participate in C1-mediated DNA looping, loops between Op99a,b and Op99d occurred predominantly. Lxc is not required but increases drastically the frequency of loop formation. The results indicate that C1-mediated DNA looping may be a second element besides Lxc for fine-tuning the autoregulation of c1 transcription.