Physical map of the coliphage 186 chromosome. I. Gene content of the BamHI, PstI and other restriction fragments

The late-expressed region of the temperate coliphage 186 genome

The late-lytic region of the genome of bacteriophage 186 encodes the phage proteins that synthesize the complex viral particle and lyse the bacterial host. We report the completion of the DNA sequence of the late region and the assignment of 18 previously identified genes to open reading frames in the sequence. The 186 late region is similar to the late region of phage P2, sharing 26 genes of known function: the single gene for activation of late gene transcription, 6 genes for construction of DNA-containing heads, 16 for tail morphogenesis, and 3 for cell lysis. We identified two 186 late genes with unknown function; one is homologous to previously unrecognised genes in P2, HP1, and phiCTX, and the other may modulate DNA packaging. The 186 late region, like the rest of the genome, lacks the lysogenic conversion genes that are carried by P2, allowing the 186 late region to be transcribed from only three late promoters rather than four. The relative absence of lysogenic conversion genes in 186 suggests that the two phages have evolved to use the lytic and lysogenic reproductive modes to different extents.

Metal- and DNA-binding properties and mutational analysis of the transcription activating factor, B, of coliphage 186: a prokaryotic C4 zinc-finger protein

Coliphage 186 B is a 72-amino acid protein belonging to the Ogr family of analogous transcription factors present in P2-like phage, which contain a Cys-X2-Cys-X22-Cys-X4-Cys presumptive zinc-finger motif. The molecular characterization of these proteins has been hampered by their insolubility, a difficulty overcome in the present study by obtaining B as a soluble cadmium-containing derivative (CdB). Atomic absorption spectroscopy showed the presence of one atom of cadmium per molecule of purified CdB. The UV absorption spectrum revealed a shoulder at 250 nm, characteristic of CysS-Cd(II) ligand-to-metal charge-transfer transitions, and the difference absorption coefficient after acidification (delta epsilon 248, 24 mM-1 cm-1) indicated the presence of a Cd(Cys-S)4 center. Gel mobility shift analysis of CdB with a 186 late promoter demonstrated specific DNA-binding (KD, app 3-4 microM) and the protein was shown to activate transcription in vitro from a promoter-reporter plasmid construct. The B DNA-binding site was mapped by gel shift and DNAase I cleavage protection experiments to an area between-70 and -43 relative to the transcription start site, coincident with the consensus sequence, GTTGT-N8-TNANCCA, from -66 to -47 of the 186 and P2 late promoters. Inactive B point mutants were obtained in the putative DNA-binding loop of the N-terminal zinc-finger motif and in a central region thought to interact with the Escherichia coli RNA polymerase alpha-subunit. A truncated B mutant comprising the first 53 amino acids (B1-53) exhibited close to wild-type activity, showed a DNA-binding affinity similar to that of the full-length protein, and could be reconstituted with either Cd or Zn. Gel permeation analysis revealed that B1-53 was a majority dimeric species whereas wild-type B showed larger oligomers. 186 B therefore exhibits a potentially linear organization of functional regions comprising an N-terminal C4 zinc-finger DNA-binding region, a dispensable C-terminal region involved in protein self-association, and a central region that interacts with RNA polymerase.

Control of gene expression in the temperate coliphage 186. IX. B is the sole phage function needed to activate transcription of the phage late genes

Using plasmid clones we have determined that the late control function B is the only phage function that is needed to activate a late promoter of coliphage 186, and we predict that it functions as an auxiliary factor to RNA polymerase in the activation of late transcription. We have also shown that a high concentration of B will activate late transcription from a prophage, and we conclude that replicating DNA is not a template requirement for B to function. The original demonstration of a need for the replication gene A in late transcription can be explained by the fact that replication leads to an increase in B gene dosage, with the consequent increase in B concentration leading to the efficient activation of the late promoters.

Control of gene expression in the temperate coliphage 186. X. The cI repressor directly represses transcription of the late control gene B

We have found that the repressor of 186 lytic transcription, CI, represses transcription of the late control gene B, with no involvement of the B protein itself. In clone studies we showed that CI repressed transcription from the B promoter and that temperature inactivation of CIts led to B derepression. We conclude that CI repressor directly represses transcription of the B gene and, with prophage induction, it is probable that the inactivation of the CI repressor not only derepresses early lytic transcription, but also derepresses B gene transcription, leading to the activation of transcription from the late promoters.

Control of gene expression in the temperate coliphage 186. VIII. Control of lysis and lysogeny by a transcriptional switch involving face-to-face promoters

The lysogenic and early lytic operons of the temperate coliphage 186 are transcribed divergently. Primer extension mapping of the 5' ends of these in vivo transcripts showed that the rightward lytic promoter, pR, and the leftward lysogenic promoter, pL, are arranged face-to-face, with their transcripts overlapping by 60 bases. We examined the control of transcription from pR and pL using galK as a reporter gene. The product of the lysogenic cI gene strongly repressed pR transcription while allowing pL transcription. The product of the lytic apl gene (formerly CP75) strongly repressed pL transcription while allowing pR transcription. Thus, the cI-pR-pL-apl region functioned as a transcriptional switch, determining whether transcription was lytic or lysogenic. Also, the cI gene product was able to stimulate pL, possibly by alleviating an inhibition of pL transcription caused by convergent transcription from pR. Other consequences of the face-to-face promoter arrangement are discussed.

DNA replication studies with coliphage 186. III. A single phage gene is required for phage 186 replication

We have shown that the BglII to BamHI (79.6% to 95.8%) region of the coliphage 186 chromosome can direct 186-specific replication. DNA sequencing of the region revealed five presumptive genes, CP80, CP81, CP83, CP84 and CP87. Surprisingly, alleles of the previously defined replication gene, A, were localized in both CP84 and CP87. We have successfully constructed a 186 minichromosome using the single gene CP87, and determined that CP84 was not concerned with replication, neither of a minichromosome nor of the phage. Rather, the replication defect seen with amber mutants of CP84 reflects a polarity effect on the downstream expression of CP87. We have concluded that CP87 is the only phage gene necessary for 186 replication, and have called it gene A.

Control of gene expression in the P2-related temperate coliphage 186. VI. Sequence analysis of the early lytic region

We have completed the sequence of the 186 early lytic region and established that this region encodes the four genes CP75, CP76, CP77 and CP78, with CP79 the first gene of the next region. Functions have been assigned to the four early genes.

DNA replication studies with coliphage 186. II. Depression of host replication by a 186 gene

Using pre-labelling rather than pulse-labelling studies to determine rates of replication, we have shown that coliphage 186 infection is accompanied by a depression in host DNA replication. We have isolated mutants of the phage gene involved and mapped them in the early region of the phage genome. Sequencing the mutants ultimately led us to the identification of the gene that we have named the dhr gene.

Control of gene expression in the P2-related temperate coliphages. IV. Concerning the late control gene and control of its transcription

In this paper we have sequenced four amber mutants and thereby confirmed the gene D (CP65) and gene B (CP67) assignments made in the accompanying paper (Kalionis et al., 1986). We have also studied, by gel electrophoresis, the transcription patterns of gene B in vivo. In a lysogen, gene B is present on a short transcript under autogenous (negative) control. Upon prophage induction, this transcript is amplified, but later in the cycle gene B is present on a larger transcript that originates in the late region. We have detected two copies of an inverted repeat in the promoter region of the B gene that we predict is recognized by the B protein. One arm of this repeat is associated with three of four P2 late promoters, downstream from the start point of transcription. The repeat is not present in the promoter region of P2 ogr. We describe the considerable homology in amino acid sequence seen with the late control proteins 186 gpB, P4 gp delta and P2 gpOgr, and present a working model for control of late gene transcription.

Control of gene expression in the P2-related template coliphages. III. DNA sequence of the major control region of phage 186

The PstI fragment (65.5% to 77.4%) of coliphage 186, known genetically to encode the major control genes, has been sequenced, and an analysis performed to assess coding capacity, transcription-translation signals, and to identify any other significant features. Our analysis indicates that the region encodes: seven genes, including the int and cI genes, which overlap, the late control gene B, and two genes, named CP75 and CP76, encoding potential DNA-binding proteins; a promoter pB and terminator tB for the rightward transcription of the B gene, and we predict the existence of this transcript in a lysogen; a promoter pL and terminator tL for leftward transcription that encodes the int and cI genes, and represents the presumed lysogenic transcript; a promoter pR for rightward transcription to give the presumed (early) lytic transcript that is overlapping and convergent with the lysogenic transcript; and finally, a potential operator site for repressor binding in the region of the pR promoter. Preliminary evidence is presented to support this analysis.

Genetic map of coliphage 186 from a novel use of marker rescue frequencies

A genetic map of phage 186 has been constructed, using the frequency of marker rescue from 186 mutant prophages for genes to the left of att, and int promoted recombination for genes to its right. At the left end of the genome lie 7 genes involved in the formation of the phage head, followed to the right by the lysis gene P, a gene (O) of unknown function, and a group of 11 genes involved in the formation of the phage tail. Gene B, the late control gene, lies to the right of this group but to the left of the phage attachment site. To the right of the att site lie the non-essential genes (cI and cII) involved in lysogen formation and the gene (A) required for 186 DNA synthesis.

Coliphage 186 Replication is delayed when the host cell is UV irradiated before infection

In contrast to results with injections by lambda and P2, the latent period for infection by coliphage 186 is extended when the host cell is UV irradiated before infection. We find that 186 replication is significantly delayed in such a cell, even though the phage itself has not been irradiated. In contrast, replication of the closely related phage P2 under the same conditions is not affected.

In vivo transcription studies of coliphage 186

The temporal apperance of transcripts from the 186 chromosome has been determined by pulse-labeling at different times after prophage induction and hybridization of RNA extracts to cloned restriction fragments of 186. Studies with different mutants and induction in the presence of chloramphenicol suggested a controlled pattern of transcription and led us to propose the existence of a primary control gene analogous to the lambda gene N.