Regulation of expression of cloned bacteriophage T4 late gene 23

Transactivation of a plasmid-borne bacteriophage T4 late gene

We examined how a plasmid-borne T4 late gene is activated by infecting T4 phage (transactivation). A gene fusion system was developed where expression of a late gene promoter fused to the lacZ gene may easily be followed by measuring beta-galactosidase activity. Considerable transactivation can occur, provided that the infecting phage contains a mutation which abolishes the denB-encoded endonuclease, and that the gene 46-encoded exonuclease is functional. The level of transactivation was correlated with the formation of high molecular weight DNA composed of tandem repeats of plasmid DNA. The formation of these molecules and subsequent transactivation depended on DNA replication and homology between phage and plasmid DNAs. Also the capacity of bacteriophage T4, grown on cells containing a plasmid-borne T4 gene, to transduce the plasmid provided indirect evidence of the formation of these tandem-repeat molecules. A good correlation was established between the ability to transduce and the presence of sequence homology between the phage and the plasmid. However, the requirement for phage/plasmid homology is no longer prerequisite if transcription from the plasmid is permitted by introducing an alc mutation into the infecting phage, presumably because this allows DNA replication to start through RNA priming.

Deletion of the essential gene 24 from the bacteriophage T4 genome

We deleted the essential gene 24 from the genome of bacteriophage T4. The delta 24 phage is a conditional lethal mutant that can grow only when the host strain supplies the product of gene 24 in trans, or when the phage acquires a functional gene 24 by some type of recombination event. Thus, gene 24 can be used as a selectable marker, for example permitting transposition into the T4 genome and analyses of plasmid-phage recombination [Woodworth and Kreuzer, Mol. Microbiol. 6 (1992) 1289-1296; H.W.E. and K.N.K., manuscript submitted]. We also found that the promoter region of gene 24 allows a low level of autonomous plasmid replication in T4-infected cells, raising the possibility of a previously unrecognized mode of T4 replication initiation.

Bacteriophage T4 late transcription from plasmid templates is enhanced by negative supercoiling

Concurrent viral replication is normally required to activate bacteriophage T4 late promoters; replication is thought to provide a template structure which is competent for late transcription. Transcription from plasmid-borne T4 late promoters, however, is independent of replication in vivo and in vitro. In this work, we have shown that, when the late gene 23 promoter is located on a plasmid, its utilization in vivo depends upon the ability of host DNA gyrase to maintain some degree of negative superhelicity. This suggests that an alternative pathway exists for activation of late promoters: DNA which is under sufficient negative torsional stress is already competent for late transcription. We also describe a method for isolating ternary complexes of plasmid DNA, RNA polymerase, and nascent RNA which have initiated transcription in vivo. The topoisomer distribution of such ternary complexes prepared from T4-infected cells showed that, late in infection, transcriptional activity resides primarily in the subset of the plasmid population with the most negatively supercoiled topoisomers. However, the overall transcriptional pattern in these ternary complexes indicated that both vector and T4 sequences are actively transcribed. Much of this transcriptional activity could be independent of gp55, the T4-specific RNA polymerase-binding protein that confers late promoter recognition.

Topoisomerization of plasmid DNA in Escherichia coli infected with bacteriophage T4

The degradation of host DNA, and the block to transcription of cytosine-containing DNA, which are a part of the normal course of infection by bacteriophage T4, can be eliminated in an appropriate T4 genetic background (designated as our reference type, or r.t.), so that T4 late promoters carried on plasmid DNA can function. The changes of topoisomer distribution that ensue when phage T4 r.t. infect Escherichia coli carrying a plasmid containing a T4 late promoter were analyzed. The linking number of the covalently closed circular plasmid DNA increased (implying relaxation) at the same time as the distribution of topoisomers became much broader. The relaxation of plasmid DNA was primarily, but not exclusively, due to T4 DNA topoisomerase II. The bacterial DNA topoisomerase II (gyrase) continued to function after phage infection to maintain some degree of superhelicity in plasmid DNA. When the DNA gyrase was inhibited by coumermycin or oxolinic acid, the topoisomer distribution became distinctly bimodal, part of the DNA remaining highly negatively supercoiled. It is argued that the observed post-infection topological changes involve relaxation of torsional stress and changes of binding by proteins that topologically constrain the plasmid DNA.

The complex pattern of transcription in the segment of the bacteriophage T4 genome containing three of the head protein genes

A detailed analysis of the temporal pattern of transcription in the gene 22-24 region of bacteriophage T4 has been made. Each of these three late genes has its own promoter, activated during the late phase of viral development. There is also late transcription of the opposite DNA strand across two of these late promoters. The 5' ends of these two sets of convergent transcripts have been mapped to sites designated Q22 and Q23. Middle (T4 gene mot product-dependent) transcription was found opposing the third late promoter, P24. An early promoter was mapped to the region between genes 23 and 24.

Regulation of transcription in the segment of the bacteriophage T4 genome containing three of the head protein genes: plasmid-specific and phage chromosome-specific effects

The activity of the phage T4 late promoters, P22, P23, and P24, is regulated by the gene 33, 45, and 55 products and, through the gene 43 product, by DNA replication. The accumulation of RNA of opposing polarity, with 5' ends mapping to Q22 and Q23, as described by T. Elliott, G. A. Kassavetis, and E. P. Geiduschek (Virology, 1984, 260-282), is subject to the same regulation. When located on a plasmid, the P23 promoter escapes the gene 43 product dependence.

Bacteriophage T4 gol site: sequence analysis and effects of the site on plasmid transformation

The Escherichia coli lit gene product is required for the multiplication of bacteriophage T4 at temperatures below 34 degrees C. After infection of a lit mutant host, early gene product synthesis is normal, as is T4 DNA replication; however, the late gene products never appear, and early gene product synthesis eventually ceases. Consequently, at late times, there is no protein synthesis of any kind (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979; W. Champness and L. Snyder, J. Mol. Biol. 155:395-407, 1982), and no phage are produced. We have isolated T4 mutants which can multiply in lit mutant hosts. The responsible T4 mutations (called gol mutations) completely overcome the block to T4 gene expression (Cooley et al., J. Bacteriol. 140:83-91). We have proposed that gol mutations alter a cis-acting regulatory site on T4 DNA rather than a diffusible gene product and that the wild-type form of the gol site (gol+) somehow interferes with gene expression late in infection (Champness and Snyder, J. Mol. Biol. 155:395-409). In this communication, we report the sequence of the gol region of the T4 genome from five different gol mutants. The gol mutations are all single-base-pair transitions within 40 base pairs of DNA. Therefore, the gol site is at least 40 base pairs long. The sequence data confirm that the gol phenotype is not due to an altered protein. We also report that the gol+ site in plasmids prevents transformation of Lit- but not Lit+ E. coli. Thus, the gol site is at least partially active in the absence of the T4 genome.

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.

Site-specific cleavage of bacteriophage T4 DNA associated with the absence of gene 46 product function

A plasmid containing a copy of the late gene 23 was cleaved at two specific locations after bacteriophage T4 infection. Cleavage at the major site, which is at the 3' end of gene 23, was detected only in the absence of gene 46 product function and was independent of the state of modification of cytosine residues. Cutting of plasmid (cytosine-containing) DNA at this site was independent of phage DNA replication and late transcription functions. A second cleavage site, in vector DNA, was also mapped. The minor extent of cutting at this site was independent of gene 46 function. Gene 46 codes for, or controls, an exonuclease involved in T4 DNA recombination and in degradation of cytosine-containing DNA.

Monocistronic and polycistronic bacteriophage T4 gene 23 messages

We studied transcription of T4 late genes by in vitro translation of size-fractionated late RNA and by hybridization of T4 late RNA to plasmids containing identified T4 late genes. We identified mRNA species that coded for the late proteins gp10, gp18, gp21, gp22, gp23, and gp24. Functional mRNA's that coded for the early proteins gp32 and IPIII were also detected after fractionation of late RNA. As in preparations of early RNA, gene 32 message activity was present in two species of RNA, which had molecular weights of approximately 0.5 x 10(6) and 0.8 x 10(6), and IPIII message activity was present in multiple species of RNA. Gene 24 and gene 10 message activities migrated as single species that had approximate molecular weights of 0.5 x 10(6) and 1.2 x 10(6), respectively. mRNA activity for gp18 migrated heterogeneously. We detected multiple transcripts from gene 23 by in vitro translation and by hybridization of late RNA to plasmids containing genes 21 through 23. Both types of analysis indicated that the major gene 23 transcript had a molecular weight of 0.75 x 10(6). In addition, two gene 23 transcripts having molecular weights of about 1.0 x 10(6) and 1.3 x 10(6) were present; these RNA species also coded for gp21 and gp22. Physical linkage of transcripts from genes 21, 22, and 23 was demonstrated by hybridization.

Genetic complementation by cloned bacteriophage T4 late genes

Bacteriophage T4 containing nonsense mutations in late genes was found to be genetically complemented by four conjugate T4 genes (7, 11, 23, or 24) located on plasmid or phage vectors. Complementation was at a very low level unless the infecting phage carried a denB mutation (which abolishes T4 DNA endonuclease IV activity). In most experiments, the infecting phage also had a denA mutation, which abolishes T4 DNA endonuclease II activity. Mutations in the alc/unf gene (which allow dCMP-containing T4 late genes to be expressed) further increased complementation efficiency. Most of the alc/unf mutant phage strains used for these experiments were constructed to incorporate a gene 56 mutation, which blocks dCTP breakdown and allows replication to generate dCMP-containing T4 DNA. Effects of the alc/unf:56 mutant combination on complementation efficiency varied among the different T4 late genes. Despite regions of homology, ranging from 2 to 14 kilobase pairs, between cloned T4 genes and infecting genomes, the rate of formation of recombinants after T4 den:alc phage infection was generally low (higher for two mutants in gene 23, lower for mutants in gene 7 and 11). More significantly, when gene 23 complementation had to be preceded by recombination, the complementation efficiency was drastically reduced. We conclude that high complementation efficiency of cloned T4 late genes need not depend on prior complete breakage-reunion events which transpose those genes from the resident plasmid to a late promoter on the infecting T4 genome. The presence of the intact gene 23 on plasmids reduced the yield of T4 phage. The magnitude of this negative complementation effect varied in different plasmids; in the extreme case (plasmid pLA3), an almost 10-fold reduction of yield was observed. The cells can thus be said to have been made partly nonpermissive for this lytic virus by incorporating a part of the viral genome.