T4 Bacteriophage-coded RNA polymerase subunit blocks host transcription and unfolds the host chromosome

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

The bacteriophage T4 regulatory protein gpunf/alc binds to DNA in the absence of RNA polymerase

DNA-cellulose chromatography and two-dimensional gel electrophoresis have been used to demonstrate the DNA-binding capacity of bacteriophage T4 gpunf/alc. The unf/alc protein does not bind to DNA via an association with RNA polymerase; gpunf/alc was shown to bind to DNA after separation from RNA polymerase and other large proteins by Sephadex chromatography.

Molecular proof that bacteriophage T4 alc and unf genes are the same gene

The DNA of bacteriophage T4 normally has a substituted base, hydroxymethylcytosine, instead of the usual cytosine. The bacteriophage shuts off host transcription after infection presumably by specifically blocking transcription of cytosine DNA. If T4 incorporates cytosine into its own DNA, this shutoff mechanism is directed back at itself and blocks its own transcription. Mutations which overcome this transcriptional block are in the T4 alc gene, and alc mutations allow the propagation of T4 with cytosine in their DNA (L. Snyder, L. Gold, and E. Kutter, Proc. Natl. Acad. Sci. USA 73:3098-3102, 1976). By genetic criteria, alc is the same as another gene, unf, whose product is required for the unfolding of the bacterial nucleoid after infection (K. Sirotkin, J. Wei, and L. Snyder, Nature [London] 265:28-32, 1977; D. P. Snustad, M. A. Tigges, K. A. Parson, C. J. H. Bursch, F. M. Caron, J. F. Koerner, and D. J. Tutas, J. Virol. 17:622-641, 1976; M. Tigges, C. J. H. Bursch, and D. P. Snustad, J. Virol. 24:775-785, 1977). The product of the alc gene has been identified as a 19-kilodalton protein (R. E. Herman, N. Haas, and D. P. Snustad, Genetics 108:305-317, 1984; E. Kutter, R. Drivdahl, and K. Rand, Genetics 108:291-304, 1984), and an open reading frame has been proposed to be the alc gene based on its size and map position (E. Kutter, R. Drivdahl, and K. Rand, Genetics 108:291-304, 1984). We used marker rescue techniques and DNA sequencing to confirm that this open reading frame is the alc gene. We also present a molecular proof that alc and unf are the same gene. While these results do not rigorously exclude the possibility that Unf and Alc are different activities of the same protein, they strongly support the conclusion that the unfolding of the bacterial nucleoid the blockage of transcription are but different manifestations of the same activity.

Bacteriophage T4 unf (=alc) gene function is required for late replication in the presence of plasmid pR386

The bacteriophage T4 unf gene, known to be involved in the arrest of transcription from cytosine-containing DNA, is unessential except in Escherichia coli strains containing plasmid pR386. Comparative genetic and biochemical analyses of parameters of unf+ and unf- phage growth in host cells isogenic except for the presence or absence of plasmid pR386 have shown that unf gene function is required for late phage DNA synthesis in the presence of the plasmid. Shutoff of host DNA, RNA, and protein syntheses, degradation of host DNA, adsorption, injection, and early phage DNA, RNA, and protein syntheses all occurred with normal or near-normal kinetics in unf- infections, even in the presence of the plasmid. The switch from early to late protein synthesis occurred in plasmid pR386-containing cells infected with unf+ or unf- phage. However, this switchover was slow in both cases and may be slower in unf- infections than in unf+ infections. Net incorporation of [3H]thymidine terminated at about 30 min after infection of pR386-containing cells with unf- phage at 30 degrees C. Alkaline sucrose gradient studies of the intracellular pools of replicative DNA in unf-infected plasmid pR386-containing cells indicated that this DNA is not detectably nickel or cleaved at the time that DNA synthesis aborts. The addition of chloramphenicol subsequent to early enzyme synthesis prevented the arrest of DNA synthesis in plasmid-containing cells infected with unf-phage.

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.

In vitro transcription of phage T4 late genes on purified DNA by partially purified RNA polymerase from T4-infected Escherichia coli b cells

RNA polymerase was purified from 'late' phage T4-infected Escherichia coli B cells by DNA-cellulose affinity chromatography and high salt agarose filtration. The DNA-cellulose-purified RNA polymerase preparation contained T4-coded DNA endonuclease activity and several proteins, some with sizes comparable with the known T4 maturation factors, essential for late RNA synthesis. Some of these proteins, and the DNA endonuclease utilizing native, parental T4 DNA and supercoiled phi X 174 DNA as substrates, were partially separated from the RNA polymerase as a complex during agarose filtration. In vitro RNA was made by the DNA-cellulose-purified RNA polymerase using native, parental T4 DNA as template. About 26% of the in vitro RNA was transcribed from the DNA r-strand; 75% from the same r-strand region as in vivo late after infection. Both the abundancy and specificity of the in vitro r-strand transcription were markedly reduced after agarose filtration of the enzyme. Addition of the proteins separated from the RNA polymerase during agarose filtration caused a restoration of in vitro r-strand transcription abundance, but not its specificity. These results show that partially purified RNA polymerase from T4-infected E. coli B cells was able to transcribe late T4 genes in vitro with some abundancy and specificity on purified, parental T4 DNA, but further purification of the enzyme caused an irreversible reduction of this ability.

Plasmid pR386 renders Escherichia coli cells restrictive to the growth of bacteriophage T4 unf mutants

The introduction of the F1 incompatibility group plasmid pR386 Tc into several common laboratory strains of Escherichia coli rendered them restrictive to the growth of bacteriophage T4 unf mutants, which are defective in unfolding the host genome. The growth inhibition was temperature dependent. The single mutant unf39 x 5 exhibited an efficiency of plating of less than 10(-8) at 27 degrees C. However, at 37 degrees C, complete growth inhibition occurred only when host DNA degradation was also absent.

Bacteriophage T4 alc gene product: general inhibitor of transcription from cytosine-containing DNA

The alc gene of bacteriophage T4 was originally defined on the basis of mutations which allow late protein synthesis directed by T4 DNA containing cytosine rather than hydroxymethylcytosine. The question remained whether the normal alc gene product (gpalc) also blocks the transcription of early genes from cytosine-containing DNA. Complementation experiments were performed between hydroxymethylcytosine-containing phage which direct gpalc synthesis but carry mutations in a given gene(s) and cytosine-containing phage carrying that gene(s). The required protein would then have to be directed by the cytosine-containing DNA: it is looked for directly on polyacrylamide gels or through its physiological effects or both. For all early proteins examined in this way, no synthesis was observed when 95 to 100% of the hydroxymethylcytosine was substituted by cytosine in the infecting DNA, whereas there was significant synthesis with 75% substitution or less. The results indicate that gpalc is carried in with the infecting DNA or is made very early to block transcription of all cytosine-containing DNA.

Mapping of two transcription mutations (tlnI and tlnII) conferring thiolutin resistance, adjacent to dnaZ and rho in Escherichia coli

Two mutations in Escherichia coli conferring resistance to the transcription initiation inhibitor, thiolutin, have been mapped. One of these mutations (tln-I)( maps at 10.2 min on the genetic map and is cotransducible with dnaZ at a frequency of approximately 50%. The other mutation (tln-II) maps between metE and ilvD, probably close to rho, and is cotransducible with ilvD at a frequency of approximately 65%. The presence of both the mutations in the same cell confers resistance to thiolutin in minimal medium. Either one of them alone renders the cell 'conditionally auxotrophic' in the presence of the drug. The implications of these findings are discussed in relation to the mode of action of the thiolutin sensitive factors in transcription.

Correlation between genetic map and map of cleavage sites for sequence-specific endonucleases SalI, KpnI, BglI, and BamHI in bacteriophage T4 cytosine-containing DNA

Cleavage sites for SalI, KpnI, BglI, and BamHI in cytosine-containing DNA from T4 alc10(alc) nd28(denA) D2a2(denB) amE51x5(56) amN55x5(42) have been mapped relative to each other, and the positions of deletions sa delta 9 (D1-stp), r1589(rII), del(39-56)12, and tk2(rI-tk) relative to these cleavage sites have been determined. Based on these analyses, a physical map of the T4 genome containing 166 kilobase pairs has been constructed.

Shutoff of lambda gene expression by bacteriophage T4: role of the T4 alc gene

Bacteriophage T4 normally contains 5-hydroxymethylcytosine instead of cytosine in its DNA. Multiple mutants of T4 which synthesize DNA with cytosine do not transcribe their late genes due to the action of the T4 alc gene (Snyder et al., Proc. Natl. Acad. Sci. U.S.A. 73:3098--3102, 1976), which is also responsible for unfolding the host nucleoid after T4 infection (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977). It seems reasonable that T4 alc function plays a role in shutting off host transcription, and the observation that some of the RNA made after infection with a T4 alc mutant hybridizes to Escherichia coli DNA (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977) supports this hypothesis. Although it is likely that the roles of the alc function in the blocking of some types of transcription and in the unfolding of the host nucleoid are related, it is not known how these effects are achieved or, in fact, whether all types of transcription are affected equally by the alc function. In an attempt to answer these questions, we studied the effect of T4 alc function on bacteriophage lambda transcription and on the structure of intracellular lambda DNA. We found that the alc function is responsible for the shutoff of lambda late transcription but probably not for the shutoff of lambda early transcription. We also found that alc does not block lambda transcription by directly removing the supercoils from circular lambda DNA via either a nicking or topoisomerase activity. Furthermore, we conclude that T4 infection also prevents the translation of non-T4 mRNA because late lambda mRNA's were made after superinfection by a T4 alcs mutant and were of normal length but were not translated into lambda late proteins.

Characterization of Azotobacter vinelandii deoxyribonucleic acid and folded chromosomes

The properties of Azotobacter vinelandii deoxyribonucleic acid (DNA) and folded chromosomes were studied and compared to those of Escherichia coli as a standard. Based on melting temperature and buoyant density measurements, the guanosine + cytosine content of purified A. vinelandii DNA was 65%, whereas that of E. coli DNA was 50%. The results of renaturation studies showed that the unique DNA sequence lengths of the two organisms were similar with Cot1/2 values of 7.3 +/- 0.4 mol.s/liter and 7.5 +/- 0.3 mol.s/liter, respectively, for A. vinelandii and E. coli. Folded chromosomes of A. vinelandii sedimented in a centrifugal field at a rate identical to those derived from E. coli, 1,600 to 1,700S. Based on the DNA content per cell and the mass of a single genome, A. vinelandii contains at least 40 chromosomes per cell.

Transcription of bacteriophage T4 DNA in vitro: selective initiation with dinucleotides

The transcription products of phage T4 DNA in vitro are separated on polyacrylamide gels. The influence of salt, polymerase, triphosphate concentration and glucosylation on the RNA synthesis are shown. Individual transcripts are initiated selectively with dinucleotides and a single triphosphate. This technique allows the prediction of the initiation sequences of several T4 transcripts.

Modified bases in the DNAs of unicellular eukaryotes: an examination of distributions and possible roles, with emphasis on hydroxymethyluracil in dinoflagellates

The occurrence of small amounts of one or more of several modified bases in the DNA of an organism is widespread in nature. Prominent among these bases are 5-methylcytosine, N6-methyladenine and 5-hydroxymethyluracil. All can be found in varying amounts in DNA of viral, prokaryotic and eukaryotic origin. In some organisms, modified nucleotides comprise a large fraction of DNA nucleotides and in others there is complete replacement of one of the common four nucleotides by a modified one. This article discusses the distributions and possible roles of the several modified bases found in prokaryote and eukaryote DNAs. Emphasis is given (1) methylcytosine in a broad variety of eukaryotes, (2) methyladenine in certain protozoa and protophyta and (3) hydroxymethyluracil in dinoflagellates. Attention is focused on the phenomenology and the possible consequences of the presence of hydroxymethyluracil in DNA.

Revised location of the rIII gene on the genetic map of bacteriophage T4

Two- and three-factor crosses showed that the T4 rIII gene is located between genes 31 and 30 rather than between genes 31 and 63.

Genetic identification of cloned fragments of bacteriophage T4 DNA and complementation by some clones containing early T4 genes

Bacteriophage T4 DNA containing cytosine has been obtained from cells infected with phage mutant in genes 42, 56, denA and denB. This DNA can be cut by a number of restriction endonucleases. Fragments obtained by digestion of this DNA with EcoRI have been cloned using the vector plasmid pCR1. Clones containing T4 DNA were identified by hybridization with radioactive early and late T4 RNA. A simple marker rescue technique is described for the genetic identification of the cloned T4 fragments. Some of the T4-hybrid plasmids which contain entire T4 genes can complement temperature sensitive and amber mutants of T4.