Early enzyme synthesis and its control in E. coli infected with some amber mutants of bacteriophage T4

Amber mutants of bacteriophage T4D: their isolation and genetic characterization

We have isolated a large number of mutants of bacteriophage T4D that are unable to form plaques on strain B of Escherichia coli, but are able to grow (nearly) normally on some other strains of E. coli, in particular strain CR63. These mutants, designated amber (am), have been characterized by complementation tests, by genetic crosses, and by their response to chemical mutagens. It is concluded that a particular subclass of base substitution mutations may give rise to amber mutants and that such mutants occur in many genes, which are widely distributed over the T4 genome.

Transcription of the T4 late genes

This article reviews the current state of understanding of the regulated transcription of the bacteriophage T4 late genes, with a focus on the underlying biochemical mechanisms, which turn out to be unique to the T4-related family of phages or significantly different from other bacterial systems. The activator of T4 late transcription is the gene 45 protein (gp45), the sliding clamp of the T4 replisome. Gp45 becomes topologically linked to DNA through the action of its clamp-loader, but it is not site-specifically DNA-bound, as other transcriptional activators are. Gp45 facilitates RNA polymerase recruitment to late promoters by interacting with two phage-encoded polymerase subunits: gp33, the co-activator of T4 late transcription; and gp55, the T4 late promoter recognition protein. The emphasis of this account is on the sites and mechanisms of actions of these three proteins, and on their roles in the formation of transcription-ready open T4 late promoter complexes.

The role of interactions between phage and bacterial proteins within the infected cell: a diverse and puzzling interactome

Interactions between bacteriophage proteins and bacterial proteins are important for efficient infection of the host cell. The phage proteins involved in these bacteriophage-host interactions are often produced immediately after infection. A survey of the available set of published bacteriophage-host interactions reveals the targeted host proteins are inhibited, activated or functionally redirected by the phage protein. These interactions protect the bacteriophage from bacterial defence mechanisms or adapt the host-cell metabolism to establish an efficient infection cycle. Regrettably, a large majority of bacteriophage early proteins lack any identified function. Recent research into the antibacterial potential of bacteriophage-host interactions indicates that phage early proteins seem to target a wide variety of processes in the host cell - many of them non-essential. Since a clear understanding of such interactions may become important for regulations involving phage therapy and in biotechnological applications, increased scientific emphasis on the biological elucidation of such proteins is warranted.

Without a license, or accidents waiting to happen

This is a memoir of circumstances that have shaped my life as a scientist, some of the questions that have excited my interest, and some of the people with whom I have shared that pursuit. I was introduced to transcription soon after the discovery of RNA polymerase and have been fascinated by questions relating to gene regulation since that time. My account touches on early experiments dealing with the ability of RNA polymerase to selectively transcribe its DNA template. Temporal programs of transcription that control the multiplication cycles of viruses (phages) and the precise mechanisms generating this regulation have been a continuing source of fascination and new challenges. A longtime interest in eukaryotic RNA polymerase III has centered on yeast and on the enumeration and properties of its transcription initiation factors, the architecture of its promoter complexes, and the mechanism of transcriptional initiation. These areas of research are widely regarded as separate, but to my thinking they have posed similar questions, and I have been unwilling or unable to abandon either one for the other. An additional interest in archaeal transcription can be seen as stemming naturally from this point of view.

Double-strand break repair in bacteriophage T4: Coordination of DNA ends and effects of mutations in recombinational genes

Coordination of DNA ends during double-strand break (DSB) repair was studied in crosses of bacteriophage T4 in which DSBs were induced site-specifically by SegC endonuclease in the DNA of only one of the parents. Coupling of the genetic exchanges to the left and to the right of the DSB was measured in the wild-type genetic background as well as in T4 strains bearing mutations in several recombination genes: 47, uvsX, uvsW, 59, 39 and 61. The observed quantitative correlation between the degree of coupling and position of the recombining markers in relation to the DSB point implies that the two variants of the splice/patch-coupling (SPC) pathway, the "sequential SPC" and the "SPC with fork collision", operate during DSB repair. In the 47 mutant with or without a das suppressor, coupling of the exchanges was greatly reduced, indicating a crucial role of the 47/46 complex in coupling of the genetic exchanges on the two sides of the DSB. From the observed dependence of the apparent coupling on the intracellular ratio of breakable and unbreakable chromosomes in different genetic backgrounds it is inferred that linking of the DNA ends by 47/46 protein is the mechanism that accounts for their concerted action during DSB repair. A mechanism of replicative resolution of D-loop intermediate (RR pathway) is suggested to explain the phenomenology of DSB repair in DNA arrest and uvsW mutants. A "left"-"right" bias in the recombinogenic action of two DNA ends of the broken chromosome was observed which was particularly prominent in the 59 (41-helicase loader) and 39 (topoisomerase) mutants. Phage topoisomerase II (gp39-52-60) is indispensable for growth in the DNA arrest mutants: the doubles 47(-)39(-), uvsX 39(-) and 59(-)39(-) are lethal.

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.

Two recombination-dependent DNA replication pathways of bacteriophage T4, and their roles in mutagenesis and horizontal gene transfer

Two major pathways of recombination-dependent DNA replication, "join-copy" and "join-cut-copy," can be distinguished in phage T4: join-copy requires only early and middle genes, but two late proteins, endonuclease VII and terminase, are uniquely important in the join-cut-copy pathway. In wild-type T4, timing of these pathways is integrated with the developmental program and related to transcription and packaging of DNA. In primase mutants, which are defective in origin-dependent lagging-strand DNA synthesis, the late pathway can bypass the lack of primers for lagging-strand DNA synthesis. The exquisitely regulated synthesis of endo VII, and of two proteins from its gene, explains the delay of recombination-dependent DNA replication in primase (as well as topoisomerase) mutants, and the temperature-dependence of the delay. Other proteins (e.g., the single-stranded DNA binding protein and the products of genes 46 and 47) are important in all recombination pathways, but they interact differently with other proteins in different pathways. These homologous recombination pathways contribute to evolution because they facilitate acquisition of any foreign DNA with limited sequence homology during horizontal gene transfer, without requiring transposition or site-specific recombination functions. Partial heteroduplex repair can generate what appears to be multiple mutations from a single recombinational intermediate. The resulting sequence divergence generates barriers to formation of viable recombinants. The multiple sequence changes can also lead to erroneous estimates in phylogenetic analyses.

Isolation and partial characterization of a bacteriophage T5 mutant unable to induce thymidylate synthetase and its use in studying the effect of uracil incorporation into DNA on early gene expression

A mutant of phage T5 which is unable to induce thymidylate synthetase was isolated. T5 thy mutants synthesized less DNA than did wild-type T5, and the burst size of progeny phage was correspondingly reduced two- to threefold in thy+ Escherichia coli. No DNA or progeny phage were made in E. coli thy hosts grown in the absence of exogenous thymine. When the T5 thy mutation was recombined with a T5 dut mutation (unable to induce dUTPase), replication resulted in progeny which contained significant amounts of uracil in their DNA, and these phage failed to produce plaques unless the plating host was deficient in uracil-DNA glycosylase. T5 phage containing various amounts of uracil in their DNA were prepared and used to determine the effect of uracil on the induction of the early enzyme dTMP kinase. The presence of uracil in the parental DNA increased the rate of induction of this enzyme by about 2.5-fold. The T5 thy gene was mapped and is located near the T5 frd gene on the B region of the T5 genome.

In vivo cleavage of cytosine-containing bacteriophage T4 DNA to genetically distinct, discretely sized fragments

Mutants of bacteriophage T4D that are defective in genes 42 (dCMP hydroxymethylase), 46 (DNA exonuclease), and 56 (dCTPase) produce limited amounts of phage DNA in Escherichia coli B. In this DNA, glucoylated 5-hydroxymethylcytosine is completely replaced by cytosine. We found that this DNA rapidly becomes fragmented in vivo to at least 16 discrete bands as visualized on agarose gels subjected to electrophoresis. The sizes of the fragments ranged from more than 20 to less than 2 kilobase pairs. When DNAs from two of these bands were radioactively labeled in vitro by nick translation and hybridized to XbaI restriction fragments of cytosine-containing T4 DNA, evidence was obtained that the two bands are genetically distinct, i.e., they contain DNA from different parts of the T4 genome. Mutational inactivation of T4 endonuclease II (gene denA) prevented the fragmentation. Three different mutations in T4 endonuclease IV (gene denB) caused the same minor changes in the pattern of fragments. We conclude that T4 endonuclease II is required, and endonuclease IV is involved to a minor extent, in the in vivo production of these cytosine-containing T4 DNA fragments. We view these DNA fragments as "restriction fragments" since they represent degradation products of DNA "foreign" to T4, they are of discrete size, and they are genetically distinct. Thus, this report may represent the first, direct in vivo demonstration of discretely sized genetically distinct DNA restriction fragments.

Membrane-associated DNase activity controlled by genes 46 and 47 of bacteriophage T4D and elevated DNase activity associated with the T4 das mutation

Lethal, amber mutations in T4 genes 46 and 47 cause incomplete degradation of host DNA, premature arrest of phage DNA synthesis, accumulation of abnormal DNA replication intermediates, and defective recombination. These phenotypes can be explained by the hypothesis that genes 46 and 47 control a DNA exonuclease, but in vitro demonstration of such a nuclease has not yet been reported. Membrane and supernatant fractions from 46- and 47- mutant-infected and 46+ 47+ control-infected cells were assayed for the presence of the protein products of these genes (i.e., gp46 and gp47) and for the ability to degrade various DNA substrates to acid-soluble products in vitro. The two proteins were found only on membranes. The membrane fraction from 46- 47- mutant-infected cells digested native or heavily nicked Escherichia coli DNA to acid-soluble products three to four times slower that the membrane fraction from control-infected cells. No such effect was found in the cytoplasmic fractions. The effect on nuclease activity in membranes was the same whether 46- and 47- mutations were present singly or together. NaClO4, a chaotropic agent, released both gp46 and gp47 from 46+ 47+ membranes, as well as the DNase activity controlled by genes 46 and 47. DNA cellulose chromatography of proteins released from membranes by NaClO4 showed that gp46 and gp47 bound to the native DNAs of both E. coli and T4. Thus, the overall enrichment of gp46 and gp47 relative to total T4 protein was 600-fold (10-fold in membranes, 2-fold more upon release from membranes by NaClO4, and 30-fold more upon elution from DNA cellulose). T4 das mutations, which partially suppress the defective phenotype of 46- and 47- mutants, caused a considerable increase in vitro DNase activity in both membrane and cytoplasmic fractions, We obtained evidence that the das+ gene does not function to inhibit E. coli exonuclease I or V, endonuclease I, or the UV endonuclease of gene uvrA or to decrease the activity of T4 exonuclease A or the T4 gene 43 exonuclease.

Evidence that the UV endonuclease activity induced by bacteriophage T4 contains both pyrimidine dimer-DNA glycosylase and apyrimidinic/apurinic endonuclease activities in the enzyme molecule

We performed experiments to determine whether the phage T4-induced UV endonuclease activity is a single protein containing both pyrimidine dimer-DNA glycosylase and apyrimidinic endonuclease activities. The UV endonuclease activity is induced by the denV gene and codes for the glycosylase activity. We obtained several kinds of evidence that the protein containing the glycosylase activity also contains the apyrimidinic endonuclease activity. After chromatography on DEAE-cellulose, the two activities copurified during phosphocellulose chromatography and Sephadex G-100 chromatography, with a constant ratio of activities across the activity peaks. On Sephadex G-100 columns the molecular weights of the two activities agreed within 2,500 or less. When an extract of cells infected with the T4 V1 mutant was purified in exactly the same way as an extract of cells infected with T4 V1+, neither glycosylase nor apyrimidinic endonuclease activity was detected in the normal elution position of the T4 UV endonuclease activity. The glycosylase and apyrimidinic endonuclease activities were induced with similar kinetics, which were characteristic of immediate early rather than delayed early enzymes. This correlated well with the presumed major role of these activities in repairing thymine dimers in parental DNA before DNA replication begins. Finally, glycosylase and apyrimidinic endonuclease activities were lost in parallel during incubation of the enzyme at 46 degree C. Our results indicated that both of these enzyme activities are contained in the same enzyme molecule and, probably, in the same polypeptide.

Translational regulation: identification of the site on bacteriophage T4 rIIB mRNA recognized by the regA gene function

The bacteriophage T4 gene regA encodes a protein that diminishes the expression of many unlinked early T4 genes. Previous work demonstrated that regA-mediated repression occurs after transcription. We report here on the identification of the target site on one regA-sensitive mRNA, the message encoding the phage T4 rIIB protein. The target for regA-mediated action overlaps the translational initiation domain of the rIIB messenger. The regA protein may be a repressor that operates translationally on a significant and interesting set of early phage T4 mRNAs.

Control of early gene expression of bacteriophage T4: involvement of the host rho factor and the mot gene of the bacteriophage

Many early mRNA species of bacteriophage T4 are not synthesized after infection of Escherichia coli in the presence of chloramphenicol. This has been interpreted as a need for T4 protein(s) to be synthesized to allow expression of some early genes, e.g., those for deoxycytidinetriphosphatase, deoxynucleosidemonophosphate kinase and UDP-glucose-DNA beta-glucosyltransferase. In the experiments described here, early mRNA of bacteriophage T4 was allowed to accumulate during chloramphenicol treatment. After the addition of rifampin to inhibit further RNA synthesis, and subsequent removal of chloramphenicol, the accumulated mRNA was permitted to express itself into measured enzyme activities. It was shown that the early mRNA species coding for deoxycytidinetriphosphatase and UDP-glucose-DNA beta-glucosyltransferase could be formed in the presence of chloramphenicol if the E. coli host cell carried a mutation in the structural gene for the RNA chain termination factor rho. This was interpreted to mean that T4 protein(s) with anti-rho activity is normally required for the expression of these two early genes. An altered rho-factor could not, however, relieve the need of phage protein synthesis for the formation of another early mRNA, that coding for deoxynucleosidemonophosphate kinase. In this case the mot gene of T4 seemed to be involved, since the primary infection of E. coli cells with the mot gene mutant tsG1 did not allow subsequent deoxynucleoside monophosphate kinase mRNA synthesis after wild-type phage infection in the presence of chloramphenicol. In control experiments, deoxynucleoside monophosphate kinase mRNA synthesis induced by wild-type phage superinfecting in the presence of chloramphenicol was facilitated by the primary infection with T4 phage containing an unmutated mot gene.

regA protein of bacteriophage T4D: identification, schedule of synthesis, and autogenous regulation

Proteins labeled with 14C-amino acids after infection of Escherichia coli B by T4 phage were examined by electrophoresis in the presence of sodium dodecyl sulfate. Four regA mutants (regA1, regA8, regA11, and regA15) failed to make a protein having a molecular weight of about 12,000, whereas mutant regA9 did make such a protein; regA15 produced a new, apparently smaller protein that was presumably a nonsense fragment, whereas regA11 produced a new, apparently larger protein. We conclude that the 12,000-dalton protein was the product of the regA gene. The molecular weight assignment rested primarily on our finding that the regA protein had the same mobility as the T4 gene 33 protein, which we identified by electrophoresis of whole-cell extracts of E. coli B infected with a gene 33 mutant, amE1120. Synthesis of wild-type regA protein occurred from about 3 to 11 min after infection at 37 degrees C in the DNA+ state and extended to about 20 min in the DNA- state. However, synthesis of the altered regA proteins of regA9, regA11, and regA15 occurred at a higher rate and for a much longer period in both the DNA+ and DNA- states; thus, the regA gene is autogenously regulated. At 30 degrees C, both regA9 and regA11 exhibited partial regA function by eventually shutting off the synthesis of many T4 early proteins; the specificity of this shutoff differed between these two mutants. We also obtained evidence that the regA protein is not Stevens's "polypeptide 3." As a technical point, we found that, when quantitating acid-precipitable radioactivity in protein samples containing sodium dodecyl sulfate, it was necessary to use 15 to 20% trichloroacetic acid; use of 5% acid, e.g., resulted in loss of over half of the labeled protein.

Shutoff of host macromolecular synthesis after T-even bacteriophage infection

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Deoxythymidine nucleotide metabolism in Bacillus subtilis W23 infected with bacteriophage SP1Oc: preliminary evidence that dTMP in SP10c DNA is synthesized by a novel, bacteriophage-specific mechanism

Despite the fact that mature SP10c DNA contains dTMP, the acid-soluble fraction of infected cells contained no dTTP during the interval of phage replication. However, infected cells contained normal cellular levels of dATP, dGTP, and dCTP. Upon infection of deoxythymidine-starved Bacillus subtilis M160 (a deoxythymidine-requiring mutant of B. subtilis W23), mature phage DNA with a normal dTMP content was made. SP10c codes for an enzyme that seems to catalyze the tetrahydrofolate-dependent transfer of 1-carbon fragments to the 5 position of dUMP. The transfer of 1-carbon fragments is not accompanied by oxidation of tetrahydrofolage to dihydrofolate, implying that the enzyme in question is not a dTMP synthetase. It is proposed that dTMP in mature SP10c DNA is derived by the postreplicational modification of some other nucleotide and not by the direct incorporation of dTTP into DNA.

Gene expression and stability of mRNA affected by DNA-arrested synthesis in gene 59, 46, and 47 mutants of bacteriophage T4

The effect of bacteriophage T4 gene 59 mutations (DNA-arrested synthesis) on kinetics of DNA synthesis, gene expression, and stability of mRNA has been studied. When Escherichia coli B was infected by a T4 gene 59 mutant, DNA synthesis proceeded to increase linearly after initiation, but started to decrease at 8 min and was completely arrested at 12 min at 37 degrees C. At various incubation temperatures (20 to 42 degrees C), the initial rates and times of arrest of DNA synthesis were different, but the total amount of DNA synthesized was constant. This result supports the hypothesis that function of gene 59 is required for the conversion of 63S DNA molecules to other replicative intermediates (39). The abnormality in protein synthesis caused by gene 59 mutation is manifested by (i) a delayed shutoff in the expression of early proteins (gene 43, 46, 39, 52, 63, 42-45, and some unidentified proteins), (ii) a reduced rate of late gene expression (gene 34, 37, 18, 20, 23, wac, 24, 22, 38, and 19), and (iii) an absence of cleavage of certain late proteins (23, 24, IPIII and 22 to 23(*), 24(*), IPIII(*), and small fragments). It appears that there was no effect on the expression of gene 33, 55, and 32 by a mutation in gene 59. Results obtained from an addition of rifampin at the prereplicative cycle after infection indicated that mRNA from genes 43, rIIA, 46, 39, 52, and 63 are more stable in T4amC5 (gene 59) than in wild-type-infected cells. mRNA remained functional longer in mutant-infected cells, and this may explain the prolonged synthesis of certain early proteins. The gene expression of other DNA arrested mutants-those in genes 46 and 47-showed a pattern of abnormal protein synthesis similar to that found in gene 59 mutant-infected cells, except more late proteins are synthesized. The gene expression in terms of phage DNA structure is discussed.

Late effect of bacteriophage T4D on the permeability barrier of Escherichia coli

Cold centrifugation of lysis-inhibited Escherichia coli B infected with wild-type T4D results in extensive lysis beginning around 20 min after infection at 37 degrees C. Infection with an e mutant, which fails to make lysozyme, prevents lysis, but does not prevent a marked loss of K+ and Mg3+. The t gene product, thought to disrupt the cytoplasmic membrane in natural lysis, is not required for this handling-induced cation loss or lysis. Three lines of evidence argue that late protein synthesis is required to develop this potential for cation loss; the potential does not develop in infections by: (i) mutants defective in DNA synthesis, (ii) mutants defective in gene 55, and (iii) wild-type T4 when chloramphenicol is added at 6 min after infection. All late mutants examined, which are blocked in the major pathways of morphogenesis, do not prevent development of the potential. The evidence argues for a new, late effect of T4 infection on the cytoplasmic membrane.

Slow switchover from host RNA synthesis to bacteriophage RNA synthesis after infection of Escherichia coli with a T4 mutant defective in the bacteriophage T4-induced unfolding of the host nucleoid

Most, if not all, host RNA synthesis was shut off after infection of Escherichia coli strain B/5 with a bacteriophage T4 multiple mutant defective in the abilities to induce (i) unfolding of the host nucleoid (unf-), (ii) nuclear disruption (ndd-), and (iii) host DNA degradation (denA-, denB-). The shutoff of host RNA synthesis and turn-on of phage RNA synthesis were slower after infection of E. coli with unf- phage than after infection with unf+ phage. This delay in the switchover from host RNA synthesis to phage RNA synthesis in unf- infections did not result in a measurable delay in the onset of nuclear disruption, deoxyribonucleoside monophosphate kinase synthesis, or DNA synthesis. unf39 did not complement alc (allows late transcription on cytosine-containing DNA) mutants, supporting the proposal of Sirotkin et al. [Nature (London) 265:28-32, 1977] that alc and unf are possibly the same gene.

Phage T4-modified RNA polymerase transcribes T4 late genes in vitro

Initiation of T4 late RNA synthesis has been achieved in an in vitro system prepared from Escherichia coli cells infected with wild-type or maturation-defective mutant T4 phage. The system uses a cellophane membrane as a mechanical support for concentrated cell lysates and for added streptolydigin-resistant RNA polymerases. Transcriptional activity and selectivity of added RNA polymerases are tested while endogenous RNA polymerase activity is inhibited by streptolydigin. T4-modified RNA polymerase is required for substantial stimulation of T4 late RNA synthesis.

In vivo functional interaction between DNA polymerase and dCMP-hydroxymethylase of bacteriophage T4

Some mutations in the structural gene for T4 DNA polymerase (gene 43) behave as suppressors of a deficiency in T4 dCMP-hydroxymethylase (gene 42). The suppression appears to involve a functional interaction between the two enzymes at the level of DNA replication. The hydroxymethylase deficiency caused DNA structural abnormalities in replication, and DNA polymerase lesions appeared to partially reverse these abnormalities. The results do not necessarily imply protein-protein interactions between the two enzymes, although both enzymes appear to play roles in controlling the fidelity of phage DNA replication.

Distinctive protein requirements of replication-dependent and -uncoupled bacteriophage T4 late gene expression

This paper further explores the relationship of viral DNA replication to bacteriophage T4 late gene expression. It is shown that replication coupled and -independent late transcription make different qualitative or quantitative demands on phage protein synthesis. In further analysis of these different protein synthesis requirements, experiments were performed with a temperature-sensitive mutant in T4 gene 55 (ts553). It is known that the gene 55 product regulates T4 late gene expression and binds to RNA polymerase. In the experiments presented here, it is shown that the temperature sensitivity of the ts553 gene 55 protein depends on whether it is involved in replication-coupled or -independent T4 late transcription. This is evidence that the proteins constituting the transcription apparatus interact differently with late transcription units in T4 DNA, depending on whether late transcription is replication coupled or independent.

Evidence for a diffusible T4 bacteriophage protein governing the initiation of delayed early RNA synthesis

Two forms of prereplicative phage RNA can be discerned in Escherichia coli early after infection with bacteriophage T4, immediate early and delayed early RNA. The transition from immediate early to delayed early RNA synthesis is inhibited by chloramphenicol. The present work presents evidence for the existence of a phage-specific protein, which effects this transition. Delayed early RNA formation was measured by a cistron-specific enzyme-forming-capacity method, in which RNA synthesized in the presence of chloramphenicol was allowed to express itself into enzyme activity after (i) the addition of rifampin to inhibit further transcription and (ii) subsequent removal of chloramphenicol. As representatives of delayed early transcription, the two phage-specific enzymes dCTPase and deoxynucleotide kinase were chosen. Primary infection with a phage mutant defective in one of these two enzymes was found to induce a diffusible factor, which in the presence of chloramphenicol could effect the formation of delayed early RNA corresponding to the missing enzyme, upon superinfection with wild-type phage. The activity of this factor, acting in trans, was abolished by the amino acid analogue ethionine. Mutation in the suA gene of the host did not relieve phage of the apparent need for protein synthesis in the transition from immediate early to delayed early phage RNA synthesis.

Exonuclease associated with bacteriophage T5-Induced DNA polymerase

T-5-induced DNA polymerase has been shown to possess a 3' leads to 5'-exonucleolytic activity. The exonuclease acts on both native and denatured DNA, but the apparent rate of degradation of denatured DNA is about five times faster than that for native DNA. The enzyme appears to act only on 3'-OH ends and produces mainly 5'-dNMP's. Like polymerase activity, exonuclease activity shows a pH optimum around 8.6. Mg2+, dithiothreitol, and N-ethylmaleimide had identical effects on both the activities. Nicked DNA was almost totally protected from exonuclease action under synthetic conditions, i.e., in the presence of 4dNTP's. Denatured DNA was partly degraded in the early phase of incubation with 4dNTP's, presumably due to unhybridized tails at the 3'-OH primer ends. However, the exonuclease activity was operative in both cases under synthetic conditions, as evidenced by template-dependent conversion of [3H]dTTP to [3H]dTMP.

Synthesis of the adenovirus-coded DNA binding protein in infected cells

Synthesis of the 75K (75K indicates a moleculatr weight of 70,000 to 75,000) DNA binding protein, an early virus-coded protein in adenovirus 2-infected KB cells, and its regulation were studied by using a radioimmune precipitation inhibition assay. The protein was first detected at 4 h postinfection and accumulated at an expoential rate. An arrest of further synthesis (accumulation) was observed at 10 to 11 h postinfection, coinciding with the onset of synthesis of late virion proteins. In contrast, when the infected cells were treated with 25 mug of arabinosyl cytosine per ml to block viral DNA replication, the synthesis of 75K protein did not cease but continue for up to 36 h postinfection. The synthesis of 75K protein in cells after release from a cycloheximide block (2 to 9 h postinfection) was analyzed. Increased amounts of early adenovirus-specific mRNA accumulate in infected cells during a cycloheximide block (Parsons and Green, 1971). However, cycloheximide treatment did not produce increased levels of 75K protein, and an abrupt arrest of 75K protein formation was again observed at the time of synthesis of late virion proteins. Partition of the 75K protein between the nuclear and cytoplasmic fractions during the course of infection was studied. The 75K protein appeared first in the cytoplasm and then in the nucleus after a slight lag. Accumulation of the 75K protein continued both in the cytoplasm and nucleus, with higher levels being found in the cytoplasm.

Regulation of early mRNA synthesis after bacteriophage T4 infection of Escherichia coli

Regulation of T4-specific mRNA synthesis was studied during leucine starvation of a leucine-requiring stringent Escherichia coli B strain. This was done by imposing starvation prior to T4 infection and then letting RNA synthesis proceed for different time periods. Rifampin or streptolydigin was added to stop further RNA synthesis, and protein synthesis was restored by addition of leucine. Samples were withdrawn at different times, and the enzyme-forming capacities found that, during conditions which elicit the stringent response in uninfected bacteria, immediate early mRNA is not stringently regulated. This conclusion contradicts the earlier conclusion of others, obtained by measuring incorporation of radioactive uracil; this is explained by the observation of Edlin and Neuhard (1967), confirmed and extended by us to the T4-infected cell, that the incorporation of uracil into RNA of a stringent strain is virtually blocked by amino acid starvation, whereas that of adenine continues at 30 to 50% of the rate seen in the presence of the required amino acid.

Synthesis of functional bacteriophage T4-delayed early mRNA in the absence of protein synthesis

When Escherichia coli B207 is grown either aerobically or under limited aerobic conditions, pretreated with chloramphenicol to block protein synthesis, and then infected with bacteriophage T4, the phage RNA which accumulates, termed "immediately early" (IE), contains the transcripts of a limited number of prereplicative genes. Among the transcripts which accumulate is the mRNA which serves as a template for deoxycytidylate hydroxymethylase (HMase) synthesis. Among the prereplicative gene transcripts which do not accumulate under these conditions are deoxycytidine triphosphatase (dCTPase), alpha-glucosyl transferase (alphg-gt), and deoxynucleotide kinase (kinase); these genes have been termed "delayed early" (DE). In contrast, when protein synthesis is inhibited by depleting aerobically grown E. coli B207 of K+, both IE and DE T4 RNA accumulate, but these transcripts do not contain functional HMase, dCTPase, alpha-gt, or kinase mRNA's. However, if E. coli is grown under conditions of limited aeration and then depleted of K+ prior to T4 infection, the T4 RNA which accumulates contains both IE and DE transcripts and functional HMase, dCTPase, and alpha-gt mRNA's. Functional kinase mRNA does not accumulate under these conditions. The results of these experiments indicate that the synthesis of functional DE RNA in the absence of simultaneous protein synthesis, depends on the physiological condition of the cells and the way in which protein synthesis is inhibited. In addition, data is presented which suggests that extensive transcription of DE genes in the absence of protein synthesis results in the inhibition of transcription of certain IE genes.

Characterization of new regulatory mutants of bacteriophage T4. II. New class of mutants

New mutants of bacteriophage T4 that overproduce the enzyme dihydrofolate reductase were investigated. Unlike previously described overproducers of this enzyme (Johnson and Hall, 1974), these mutants did not overproduce deoxycytidylate deaminase. Overproduction of dihydrofolate reductase by the new mutants occurred because enzymatic activity continued to increase for a longer period of time in cells infected by the mutants than in cells infected by wild-type phage. This continued increase occurred even in the presence of rifampin, indicating that the overproduction is probably due to a post-transcriptional event. Both these new overproducers and the previously described overproducers were studied by using polyacrylamide gel electrophoresis. The two types of overproducers appeared to be very different. The previously described overproducers showed a delay and/or reduction in the synthesis of several proteins that normally started to be made 4 to 6 min after infection. Several proteins could be seen to be overproduced on the gels. The new overproducers did not show the delay in the synthesis of some proteins and only overproduced a few proteins. The new gene defined by the new overproducers is between the gene coding for thymidine kinase and the gene coding for lysozyme.