Interaction of the P1c1 repressor with P1 DNA: localization of repressor binding sites near the c1 gene

Genome of bacteriophage P1

P1 is a bacteriophage of Escherichia coli and other enteric bacteria. It lysogenizes its hosts as a circular, low-copy-number plasmid. We have determined the complete nucleotide sequences of two strains of a P1 thermoinducible mutant, P1 c1-100. The P1 genome (93,601 bp) contains at least 117 genes, of which almost two-thirds had not been sequenced previously and 49 have no homologs in other organisms. Protein-coding genes occupy 92% of the genome and are organized in 45 operons, of which four are decisive for the choice between lysis and lysogeny. Four others ensure plasmid maintenance. The majority of the remaining 37 operons are involved in lytic development. Seventeen operons are transcribed from sigma(70) promoters directly controlled by the master phage repressor C1. Late operons are transcribed from promoters recognized by the E. coli RNA polymerase holoenzyme in the presence of the Lpa protein, the product of a C1-controlled P1 gene. Three species of P1-encoded tRNAs provide differential controls of translation, and a P1-encoded DNA methyltransferase with putative bifunctionality influences transcription, replication, and DNA packaging. The genome is particularly rich in Chi recombinogenic sites. The base content and distribution in P1 DNA indicate that replication of P1 from its plasmid origin had more impact on the base compositional asymmetries of the P1 genome than replication from the lytic origin of replication.

Second-site suppressors of the bacteriophage P1 virs mutant reveal the interdependence of the c4, icd, and ant genes in the P1 immI operon

The immI operon of phage P1 contains the genes c4, icd, and ant, which are transcribed in that order from the same constitutive promoter, P51b. The gene c4 encodes an antisense RNA which inhibits the synthesis of an antirepressor by acting on a target ant mRNA. Interaction depends on the complementarity of two pairs of short sequences encompassing virs+ and the ribosome-binding site involved in ant expression. Accordingly, in a P1 virs mutant phage, antirepressor is synthesized constitutively. We have isolated lysogen-proficient, second-site suppressors of P1 virs in order to evaluate the interdependence of the immI-specific genes. From a total of 17 suppressors analyzed, 15 were found to be located in the icd gene. They were identified as frameshift mutations, containing base insertions or deletions in tandem repeats of a single base pair. One suppressor was identified as a P51b promoter-down mutation; the second site of another suppressor was found to be located in the c4 gene. Furthermore, it was shown that virs cannot be suppressed by ant (icd+) suppressors. The results confirm the model that the immI operon is transcribed as a unit, that the icd and ant genes are translationally coupled, and that the constitutive synthesis of Icd protein alone is lethal to the bacterial cell. The existence of a c4 suppressor of virs, whose effect is not yet known, points to a still more complex regulation of antirepressor synthesis than was anticipated from the model.

Cloning, expression, and characterization of the icd gene in the immI operon of bacteriophage P1

The immI operon of P1 contains the genes c4, icd (formerly called orfx), and ant which are constitutively transcribed in that order from a single promoter, P51b. C4 is an antisense RNA which is processed from the precursor transcript. C4 RNA acts as a translational repressor of icd, thereby also inhibiting antirepressor (ant) synthesis. We have cloned the icd and the overlapping icd and ant genes. We show, by means of plasmid deletion analysis, that icd is translationally coupled to ant. An internal in-frame deletion of icd making up 65% of the codons still allows antirepressor synthesis at a reduced rate, indicating that a functionally active icd gene product is dispensable for ant expression. We identify the product of the icd gene as a 7.3-kDa protein which interferes with cell division. The results suggest that constitutive expression of icd, in the absence of a functionally active antirepressor, prevents P1 lysogen formation because of its detrimental effect on the host cell.

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.

Bacteriophage P1 Bof protein is an indirect positive effector of transcription of the phage bac-1 ban gene in some circumstances and a direct negative effector in other circumstances

Previous genetic studies have suggested that the Bof protein of bacteriophage P1 can act as both a negative and a positive regulator of phage gene expression: in bof-1 prophages, the ref gene and a putative phage ssb gene are derepressed, but expression of an operator-semiconstitutive variant of the phage ban gene (bac-1) is markedly reduced. An explanation of this apparent duality is suggested by recent reports that Bof is a corepressor of genes that are regulated by the phage C1 repressor, including the autoregulated c1 gene itself. Here we show, by means of operon fusions to lacZ, that the balance points between Bof-mediated decreases in c1 expression and Bof-mediated increases in C1 efficacy are different among various C1-regulated genes. Thus, expression of Bof by P1 prophages affects some genes (e.g., bac-1 ban) positively, and others (e.g., ref) negatively. Even at bac-1 ban, where the positive indirect effect of Bof is physiologically dominant, Bof can be seen to act as a corepressor if C1 is supplied from a nonautoregulated (ptac-c1) source, eliminating the effect of Bof on C1 synthesis.

The ImmC region of phage P1 codes for a gene whose product promotes lytic growth

The ImmC region of the temperate bacteriophage P1 contains c1, a gene that codes for a repressor of lytic growth. Located in the region upstream of c1 are four open reading frames capable of coding for low-molecular-weight proteins. The efficiency of lysogeny by P1+Cm was found to be reduced by almost 10(5)-fold when the host cells carry this region of ImmC on a multicopy plasmid. The sequences responsible for interfering with lysogen formation were localized to one of the small open reading frames (orf4) within ImmC. Insertions and deletions within orf4 suppress the virulent phenotype of P1virC mutants when introduced into the phage by recombination. These virC-suppressed mutant phage were found to be incapable of lytic growth unless the product of orf4 is provided in trans. The presence of orf4 was observed to interfere with repression by the c1 protein of ImmC-encoded promoters fused to lacZ. For this reason, we suggest that orf4 corresponds to coi, a gene previously proposed to code for an inactivator of c1-mediated repression.

The bof gene of bacteriophage P1: DNA sequence and evidence for roles in regulation of phage c1 and ref genes

The C1 repressor of bacteriophage P1 acts via 14 or more distinct operators. This repressor represses its own synthesis as well as the synthesis of other gene products. Previously, mutation of an auxiliary regulatory gene, bof, has been shown to increase expression of some C1-regulated P1 genes (e.g., ref) but to decrease expression of others (e.g., ban). In this study the bof gene was isolated on the basis of its ability to depress stimulation of Escherichia coli chromosomal recombination by the P1 ref gene, if and only if a source of C1 was present. C1 alone, but not Bof alone, was partially effective. The bofDNA sequence encodes an 82-codon reading frame that begins with a TTG codon and includes the sites of the bof-1(Am) mutation and a bof::Tn5 null mutation. Expression of ref::lacZ and cl::lacZ fusion genes was partially repressed in trans by a P1 bof-1 prophage or by plasmid-encoded C1 alone, which was in agreement with effects on Ref-stimulated recombination and with previous indirect evidence for c1 autoregulation. Repression of both fusion genes by plasmid-encoded C1 plus Bof or by a P1 bof+ prophage was more complete. When the C1 source also included a 0.7-kilobase region upstream from C1 which encodes the coi gene, repression of both c1::lacZ and ref::lacZ by C1 alone or by C1 plus Bof was much less effective, as if Coi interfered with C1 repressor function.

Organization of the immunity region immI of bacteriophage P1 and synthesis of the P1 antirepressor

The immI region of bacteriophage P1 includes the ant/reb gene, which encodes the antirepressor protein, and the c4 gene, which encodes a repressor molecule that negatively regulates antirepressor synthesis. The antirepressor interferes with the activity of the P1 repressor of lytic function, the product of the c1 gene. We have determined the DNA sequences of the immI region of P1 wild-type and the mutants virs, ant16, ant17, and reb22. Using suitable P1 immI DNA subfragments cloned into a vector of the T7 bacteriophage RNA polymerase expression system the antirepressor protein(s) was overproduced. On the basis of positions of immI mutations and the sizes of ant gene products, the following organizational feature of the P1 immI region is suggested: (1) the genes c4 and ant are cotranscribed in that order from the same promoter in the clockwise direction of the P1 genetic map; (2) an open reading frame for an unknown gene is located in between c4 and ant; (3) the site at which the c4 repressor acts is located within the c4 structural gene; (4) two antirepressor proteins of molecular weights 42,000 and 32,000 are encoded by a single open reading frame, with the smaller protein initiating at an in-frame start codon; (5) transcription of immI is regulated via a c1-controlled operator, Op51, indicating a communication between the immunity systems immC and immI.

The c1 genes of P1 and P7

The c1 genes of the heteroimmune phages P1 and P7 were sequenced and their products were compared. P7c1 expression was correlated with the translation in vitro of a protein whose predicted molecular weight (33,000 daltons) is indistinguishable from that of the P1c1 repressor. The c1 regions from both P1 and P7 were found to contain open reading frames capable of coding for a 283-amino acid protein whose predicted secondary structure lacks the helix-turn-helix motif commonly associated with repressor proteins. Two P1c1 amber mutations were localized to the 283-amino acid open reading frame. The P1c1 and P7c1 sequences were found to differ at only 18 positions, all but two of which alter the third position of the affected codon and do not alter the amino acid sequence of the protein. Plasmids expressing the c1 gene from either phage cause the repression of transcription from a cloned promoter situated upstream of P1c1.

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.

Bacteriophage P1 tail-fibre and dar operons are expressed from homologous phage-specific late promoter sequences

Two plasmid systems, containing the easily assayable galK and lacZ functions, were employed to study the regulation of the bacteriophage P1 tail-fibre and dar operons. Various P1 DNA fragments carrying either the 5' end of lydA (the 1st gene in the dar operon) or the tail-fibre gene 19 precede the promoterless coding region of galK or were fused, in-frame, to the lacZ gene. In the presence of an induced P1 prophage, GalK and LacZ activities were both detected after a 20 to 30 minute lag period, indicating that the dar and tail-fibre operons are expressed from positively regulated, late promoters. The corresponding DNA operons are expressed from positively regulated, late promoters. The corresponding DNA region of the closely related p15B plasmid exhibits comparable promoter properties. Deletion analysis mapped the promoter of a gene 19-lacZ fusion to a DNA region upstream from gene R, an open reading frame that precedes the coding frame of gene 19. The tail-fibre gene thus forms the second gene in a three gene operon (genes R, 19 (S) and U). Sequence comparison between this promoter region, upstream sequences of the lydA gene and the corresponding portions of the p15B genome allowed the identification of a highly conserved 38 base-pair sequence, which most likely represents a P1-specific late promoter. This was confirmed by 5' mapping of P1 mRNA. Transcription of both the tail-fibre and dar operons is initiated at sites five and six base-pairs, respectively, downstream from the first conserved nucleotide of this sequence. The conserved motif consists of a standard Escherichia coli -10 region followed by a nine base-pair palindromic sequence located centrally about position -22.

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.

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.