Regulation of gene-specific RNA synthesis in bacteriophage T4

Post-transcriptional control by bacteriophage T4: mRNA decay and inhibition of translation initiation

Over 50 years of biological research with bacteriophage T4 includes notable discoveries in post-transcriptional control, including the genetic code, mRNA, and tRNA; the very foundations of molecular biology. In this review we compile the past 10 - 15 year literature on RNA-protein interactions with T4 and some of its related phages, with particular focus on advances in mRNA decay and processing, and on translational repression. Binding of T4 proteins RegB, RegA, gp32 and gp43 to their cognate target RNAs has been characterized. For several of these, further study is needed for an atomic-level perspective, where resolved structures of RNA-protein complexes are awaiting investigation. Other features of post-transcriptional control are also summarized. These include: RNA structure at translation initiation regions that either inhibit or promote translation initiation; programmed translational bypassing, where T4 orchestrates ribosome bypass of a 50 nucleotide mRNA sequence; phage exclusion systems that involve T4-mediated activation of a latent endoribonuclease (PrrC) and cofactor-assisted activation of EF-Tu proteolysis (Gol-Lit); and potentially important findings on ADP-ribosylation (by Alt and Mod enzymes) of ribosome-associated proteins that might broadly impact protein synthesis in the infected cell. Many of these problems can continue to be addressed with T4, whereas the growing database of T4-related phage genome sequences provides new resources and potentially new phage-host systems to extend the work into a broader biological, evolutionary context.

Translational regulation of expression of the bacteriophage T4 lysozyme gene

The bacteriophage T4 lysozyme gene is transcribed at early and late times after infection of E. coli, but the early mRNA is not translated. DNA sequence analysis and mapping of the 5' ends of the lysozyme transcripts produced at different times after T4 infection show that the early mRNA is initiated some distance upstream from the gene. The early mRNA is not translated because of a stable secondary structure which blocks the translational initiation site. The stable RNA structure has been demonstrated by nuclease protection in vivo. After DNA replication begins, two late promoters are activated; the late transcripts are initiated at sites such that the secondary structure can not form, and translation of the late messages occurs.

New control elements of bacteriophage T4 pre-replicative transcription

Bacteriophage T4 pre-replicative genes are transcribed, by Escherichia coli RNA polymerase, in two alternative modes: an early mode and a middle mode. Middle mode transcription is under the control of at least one viral protein, pmotA. We have identified two additional viral genes, motB and motC, that map in the dispensable region of the T4 genome, between genes 39 and 56. pmotB and pmotC are diffusible factors which provide an alternative to the motA dependent mode of middle transcription of many T4 genes. Deletions of motB and motC are in fact lethal only in combination with a motA mutant. motB controls one of the alternative modes of transcription of the rIIA gene. When motA or motB are missing, transcription of rIIA is quantitatively unaffected; when both are missing the transcription rate drops by about 75%. Control of transcription of the tRNA gene cluster is more complex. Transcription of subcluster 2 is maximally reduced (70%) only by deletions that, besides motB, cut out an adjacent region. We guess that this adjacent region codes for an additional control element, which we call motC. The motB gene is situated in a 750-base region between the left end-points of del(39-56)-1 and -4.

T4-induced antipolarity: temporal heterogeneity in response of early transcription units

When T4 infects Escherichia coli in the absence of protein synthesis, rho-mediated termination takes place on early polycistronic transcription units. During the early period of development, the appearance of delayed early transcripts becomes insensitive to the inhibition of protein synthesis. In the absence of the T4 gene product mot, an inducer for the middle mode of transcription, only the early polycistronic messengers are synthesized. In mot- -infected cells, the synthesis of the distal transcripts still becomes completely insensitive to the polar effect of chloramphenicol. This happens because potential rho-sensitive termination sites are not used in these cells. In this respect, overcoming polarity induced by chloramphenicol can be called a process of antitermination. The mot-independent antitermination can be studied by addition of chloramphenicol during infections with mot- bacteriophage. The effect is stable; it allows a constant percentage of rho-sensitive termination sites in the cell to be traversed by RNA polymerase for at least 10 min at 42 degrees C. By examining six different transcription units on the T4 genome, we find that each transcription unit has a cis-acting component (or components) which determines when its rho-sensitive termination site stops functioning. In extreme cases, rho acts with 100% efficiency in some transcription units, whereas it is almost inactive in others.

Mapping of in vitro transcription units and identification of primary transcripts of the D region of bacteriophage T4

The D region of bacteriophage T4 is comprised of six closely linked genes which are situated between 161 kb and 165 kb on the T4 chromosome. We studied the transcription of these genes in vitro by using DNA templates derived from a series of deletion mutants in this region. The mixture of primary products made by Escherichia coli RNA polymerase were fractionated by gel electrophoresis into discrete RNA species. The results obtained together with the known map positions of the deletions allowed to identify four wild-type and several deletion-specific transcripts of the D region. The end points of these transcripts were approximately mapped. The results demonstrate that the D region has two promoters and two terminators, an organisation which is similar to the previously established organisation of the T4 tRNA gene cluster.

Exclusion of bacteriophage T1 by bacteriophage lambda. II. Synthesis of T1-specific macromolecules under N-mediated excluding conditions

The results of experiments investigating T1 macromolecular synthesis under N-mediated excluding conditions failed to demonstrate a substantial alteration in the T1 mRNA production in excluding cultures at any stage in the T1 infectious cycle. The number of T1 DNA sequences in the excluding culture was found to be one-third to one-half that found in T1-infected cultures. The most severe reduction in T1-specific macromolecules was seen in protein synthesis. Total incorporation of labeled amino acids was reduced sixfold, and gel experiments confirmed that the T1-specific proteins capable of detection are reduced in excluding cells.

Point mutants in the D2a region of bacteriophage T4 fail to induce T4 endonuclease IV

We have studied the properties of presumptive point mutants in the D2a region of bacteriophage T4. Dominance tests showed that the D2a mutation was recessive to the wild-type allele. The mutations were shown to map in the D2a region by complementation against rII deletions. The D2a mutations were also located between gene 52 and rIIB by two- and three-factor crosses. The mutants are located at at least two distinct loci in the D2a region. The point mutants grow normally on all hosts tested and none of the mutants makes T4 endonuclease IV. We propose the name "denB" for the D2a locus.

Transcription units in bacteriophage T4

We have investigated the possibility of assigning genes of T4 bacteriophage to their units of transcription (scriptons) by studying gene expression from UV-irradiated DNA templates. Since RNA chains are prematurely terminated on UV-irradiated DNA templates and since the promotor distal part of the RNA chain is deleted, the expression of any gene is inversely proportional to the distance between the promotor and the promotor distal end of the gene. We find that the early genes, 43, 45 and rIIB, are promotor proximal. Since at least genes 43 and rIIB are classified as delayed early genes, these results suggest that their synthesis may require the recognition of new promotors. Additional early genes (44, 62, 42, 46, 47, 55, and rIIA) and some late genes (34, 37, and 38) have also been assigned positions relative to their promotors.

Association of the rIIA protein with the bacterial membrane

Cell membrane proteins synthesized after infection of Escherichia coli B with wild-type phage T4 and rIIA mutants were analyzed by dodecyl sulfate-polyacrylamide gel electrophoresis. A protein with an approximate molecular weight of 74,000 is present in membranes isolated from T4r(+)-infected cells, but is not found in membranes prepared from cells infected with an rIIA mutant in which the major part of the rIIA cistron is deleted. In addition, infection of E. coli B with different rIIA amber mutants and deletions gives peptides, which are associated with the bacterial membrane, of molecular weights consistent with the location of the respective mutations in the cistron. The rIIA protein is synthesized with delayed early kinetics. The synthesis of the rIIB protein, which is also located in the membrane, is not affected by mutations in the A cistron; conversely, synthesis of the rIIA protein is not affected by mutations in the B cistron. A mutant (rII 1589) contains a deletion that originates in the A cistron and extends into the adjacent B cistron. This mutant directs the synthesis of a compound membrane protein consisting of the undeleted portions of the A and B cistrons. The synthesis of the compound protein appears to be under the control of the A promoter.

Stability of cytosine-containing deoxyribonucleic acid after infection by certain T4 rII-D deletion mutants

When T-even phage infect Escherichia coli, synthesis of host deoxyribonucleic acid (DNA) rapidly ceases. If the phage carry a mutation in a gene essential for phage DNA synthesis, then the infected bacteria should make no DNA, either host DNA or phage DNA. However, we have found that infection with certain T4 gene 56 (deoxycytidine triphosphatase)-rII double mutants leads to substantial DNA synthesis. Only rII deletion mutations which extend into the middle third of the adjacent, nonessential D region lead to the anomalous DNA synthesis, when combined with a gene 56 mutation; the requirement probably is that the deletion extend into the D2a transcriptional unit identified by Sederoff et al. Genetic evidence indicates that the observed anomalous DNA synthesis is synthesis of phage DNA. We suggest that the D2a region controls, directly or indirectly, a nuclease involved in the breakdown of cytosine-containing DNA. In the absence of the D2a product, the cytosine-containing phage DNA made by the gene 56 mutant is stabilized.

Continuous requirement for host P10 protein during bacteriophage T4 infection

The Escherichia coli 30S ribosomal protein P10, the product of the str gene, known to be involved only in the initiation of protein syntehsis, is required for all bacteriophage T4 protein synthesis.

SV40-specific RNA in the nucleus and polyribosomes of transformed cells

Cells transformed by the oncogenic virus SV40 are known to contain viral DNA integrated into cellular DNA and to produce virus-specific RNA. It has been shown that nuclear molecules containing virus-specific sequences are considerably longer than presumed virus-specific mRNA molecules from cytoplasmic polyribosomes. This finding suggests the possibility that cytoplasmic mRNA is derived by the specific cleavage of larger nuclear RNA.

Biological effects of substituting cytosine for 5-hydroxymethylcytosine in the deoxyribonucleic acid of bacteriophage T4

Previous work from this laboratory has shown that the cytosine-containing T4 deoxyribonucleic acid (DNA) made by deoxycytidine triphosphatase (dCTPase) amber mutants is extensively degraded, and that nucleases controlled by genes 46 and 47 participate in this process. In this paper, we examine other consequences of a defective dCTPase. Included are studies of DNA synthesis and phage production, and of the control of both early and late protein synthesis after infection of Escherichia coli B with various T4 mutants defective in genes 56 (dCTPase), 42 (dCMP hydroxymethylase), 1 (deoxynucleotide kinase), 43 (DNA polymerase), 30 (polynucleotide ligase), 46 and 47 (DNA breakdown) or e(lysozyme). By varying the temperature of infection with a temperature-sensitive dCTPase mutant, we have been able to control intracellular dCTPase activity, and thus vary the cytosine content of the phage DNA. We have produced and characterized viable T4 phage in which cytosine replaces 20% of the 5-hydroxymethylcytosine (HMC) in the DNA. We present evidence which suggests that intact, cytosine-containing T4 DNA is much less efficient than is normal T4 DNA in directing the synthesis of tail-fiber antigen. Lysozyme production is much less affected by progressively decreasing dCTPase activity; however, complete substitution of cytosine is correlated with a depression of lysozyme synthesis greater than expected from the defective synthesis of DNA. Low but significant lysozyme synthesis is observed late after infection of E. coli B with T4 amber mutants defective in a number of genes controlling DNA synthesis. The "20% cytosine" T4 phage, once produced, can initiate an apparently normal infection at permissive temperatures; the synthesis of early enzymes, DNA, and phage does not appear to be impaired. Two roles for HMC in T4 DNA have been indicated previously: (i) involvement in host-controlled restriction of the phage, in which glucosylation of the hydroxymethyl group plays a crucial role (16, 29, 53, 58), and (ii) protection of vegetative DNA against phage-controlled nucleases, a protection not dependent on glucosylation (41, 66, 67). A third role is suggested by our present results: transcription of at least some late genes can occur only from HMC-containing DNA and not from cytosine-containing DNA.

Bacteriophage T4 DNA-dependent in vitro synthesis of lysozyme

A cell-free system derived from uninfected Escherichia coli previously was shown to synthesize beta-glucosyl transferase in response to T4 DNA. This same in vitro system, when incubated at slightly higher magnesium concentrations, also synthesized enzymatically active lysozyme. The lysozyme activity that appeared was judged to be T4-specific since antibodies prepared against authentic T4-lysozyme inactivated the in vitro synthesized enzyme. DNA from a T4 mutant carrying a deletion in the lysozyme gene stimulated amino acid incorporation to the same extent as wild-type T4 DNA but was inactive in directing the synthesis of lysozyme. Various inhibitors of RNA and protein synthesis inhibited the in vitro synthesis of lysozyme.