Effect of T4 infection on initiation of protein synthesis and messenger specificity of initiation factor 3

No alteration in the messenger specificity of initiation factor 3 (IF-3) is observed upon T4 phage infection of several strains of Escherichia coli. IF-3 present in the 1.0 m NH₄Cl washes of ribosomes from T4-infected cells supports the translation of f2 RNA and T4 late mRNA with the same degree of efficiency as the IF-3 in the ribosomal washes obtained from uninfected cells. At high concentrations the ribosomal washes obtained from T4-infected cells are more inhibitory for both f2 RNA- and T4 late mRNA-directed protein synthesis than the ribosomal washes from uninfected cells. Furthermore, this increased inhibition is also observed in the poly(U)-directed synthesis of polyphenylalanine. These data suggest that translational controls exerted at the level of IF-3 probably do not account for the alterations in protein synthesis observed upon T4 infection.     

Morphogenetic pathway of bacteriophage φ6: A flow analysis of subviral and viral particles in infected cells

Three types of virus-specific particles of double-stranded RNA bacteriophage φ6 were isolated and characterized by pulse-label and pulse-chase experiments on φ6-infected Pseudomonas phaseolicola. The first particle was “previrion I”, which consisted of early proteins P1, P2, P4 and P7, and had no RNA. It was detected immediately after labeling of proteins and the radioactivity was chased into the second structure, designated previrion II, after ten minutes. Previrion II contained three segments of double-stranded RNA in addition to the component of previrion I, and had RNA polymerase activity that produced messenger RNA species coding for late proteins. The RNA polymerase activity in the cell extract emerged nearly in parallel with the synthesis of late proteins, and this activity of previrion II was supposed to be responsible for late protein synthesis in infected cells. Via previrions I and II, the third radioactive particle was observed in infected cells after late protein synthesis started. This particle was identified as the intact virion, because it had infectivity as well as all of the viral components, including lipids. This intact virion was accumulated in the infected cell before bursting the cell.     

Early to late switch in bacteriophage T7 development: functional decay of T7 early messenger RNA

Infection of ultraviolet light-irradiated Escherichia coli with T7 phage in the presence of chloramphenicol results in synthesis of T7 early messenger RNA but not late mRNA. T7 early mRNA accumulates in terms of acid-insoluble, T7 DNA-hybridizable RNA. However, messenger activity of the same RNA decays rapidly with a half-life of about 6.5 minutes at 30 °C when tested for the ability to direct in vitro protein synthesis. This functional decay of T7 early mRNA is attributable to a loss of structural integrity of the RNA. Polyacrylamide-agarose gel electrophoresis shows that T7 early mRNAs are cleaved, generating smaller-size RNAs. Kinetics of the appearance of T7-specific RNA polymerase, one of the early gene products, during normal T7 infection show that the capacity of the cells to produce the enzyme decays very rapidly when early mRNA synthesis is terminated either by rifampicin or by a natural mechanism programmed by T7. Preferential synthesis of late proteins in the presence of chemically stable early mRNA late in T7 infection may be explained by the observed functional decay of early mRNA.     

Specificity of protein synthesis by bacterial ribosomes and initiation factors: Absence of change after phage T4 infection

Using several natural messenger RNA's—f2 RNA, Qβ RNA, T7 RNA, T4 early mRNA, T4 late mRNA and Escherichia coli RNA—ribosomes isolated from cells either 5 or 12 minutes after T4 infection direct synthesis of only 35 to 70% as much protein as do ribosomes from uninfected cells. However, with poly(U) or formaldehyde-treated f2 RNA message, both types of ribosomes work equally well. Experiments mixing salt-washed ribosomes and initiation factors from these cells show, in agreement with work of others, that the reduction with natural messages is due only to changes in the initiation factors.     

Lack of Discrimination between Early and Late T4 mRNA by Host Initiation Factors

DURING development of T4 phage in E. coli, control at the translational level may play an important part in switching the reading of early to late T4 messenger RNAs. In vitro experiments have shown that protein factors isolated from ribosomes of T4 infected cells can restrict translation of either host mRNA or R17 phage RNA, whilst permitting normal translation of late T4 mRNA^1–4. This alteration of specificity has been attributed to an initiation factor F3^5,6. It is unlikely that this switch is related to the shut-off of host protein synthesis which occurs immediately after infection^7,8, because they occur at distinctly different times in vivo^{1, 3}.     

Properties of the nonlethal recombinational repair deficient mutants of bacteriophage T4

Summary The rate at which ³H thymidine is incorporated into DNA is increased in T4w-infected cells compared to wild-type when measured late in infection under conditions of low thymidine concentration. This increased DNA synthesis is sensitive to hydroxyurea but not to mitomycin C, and can be prevented by the addition of chloramphenicol early in infection. Also, DNA replicative intermediates isolated from T4w-infected cells late in infection sediment significantly faster than those isolated from wild-type-infected cells. In contrast, DNA replicative intermediates isolated from T4x-or T4y-infected cells sediment more slowly than those produced by wild-type T4. Cells coinfected with wild-type T4⁺ and T4x, y or w; or T4w and T4x or y, produce wild-type DNA replicative intermediates. Cells coinfected with T4x and T4y produce more slowly sedimenting DNA replicative intermediates. Cells coinfected with T4w and wild-type T4 show wild-type rates of DNA synthesis while cells coinfected with T4w and T4x or T4y show increased rates of DNA synthesis over that observed with wild-type alone.     

F-Factor-mediated restriction of bacteriophage T7: protein synthesis in cell-free systems from T7-infected Escherichia coli F- and F+ cells.

A characteristic phenomenon in the F-factor-mediated inhibition of T7 phage is a virtual absence of T7 late protein synthesis in T7-infected Escherichia coli male cells, in spite of the presence of T7 late mRNA which is translatable in vitro when isolated from the cell. To determine whether the translational defect in T7-infected F+ cells is due to a T7 late mRNA-specific translational block, or to a general decrease of F+ cell translational activity, we compared the activities of cell-free, protein-synthesizing systems prepared from isogenic F- and F+ cells harvested at different times of T7 infection. The cell-free systems from uninfected F- and F+ cells translated T7late mRNA equally as well as MS2 RNA and T7early mRNA. The activity of cell-free systems from T7-infected F+ cells to translate MS2 RAN, T7 early mRNA, and T7 late mRNA decreased concomitantly at a much faster rate than that of T7-infected F- cells. Therefore, the abortive infection of F+ cells by T7 does not result from a T7 late mRNA-specific translational inhibition, although a general reduction of the translational activity appears to be a major factor for the inability of the F+ cells to produce a sufficient amount of T7 late proteins.     

TRANSPORT OF VIRAL RNA IN KB CELLS INFECTED WITH ADENOVIRUS TYPE 2

Messenger RNA transport was studied in KB cells infected with the nuclear DNA virus adenovirus type 2. Addition of 0.04 µg/ml of actinomycin completes the inhibition of ribosome synthesis normally observed late after infection and apparently does not alter the pattern of viral RNA synthesis: Hybridization-inhibition experiments indicate that similar viral RNA sequences are transcribed in cells treated or untreated with actinomycin. The polysomal RNA synthesized during a 2 hr labeling period in the presence of actinomycin is at least 60% viral specific. Viral messenger RNA transport can occur in the absence of ribosome synthesis. When uridine-³H is added to a late-infected culture pretreated with actinomycin, viral RNA appears in the cytoplasm at 10 min, but the polysomes do not receive viral RNA-³H until 30 min have elapsed. Only 25% of the cytoplasmic viral RNA is in polyribosomes even when infected cells have been labeled for 150 min. The nonpolysomal viral RNA in cytoplasmic extracts sediments as a broad distribution from 10S to 80S and does not include a peak cosedimenting with 45S ribosome subunits. The newly formed messenger RNA that is ribosome associated is not equally distributed among the ribosomes; by comparison to polyribosomes, 74S ribosomes are deficient at least fivefold in receipt of new messenger RNA molecules.     

Effect of Bacteriophage Ghost Infection on Protein Synthesis in Escherichia coli

The rate of protein synthesis by Escherichia coli markedly decreased within 1 min after phage T4 infection, whereas a complete cessation of protein synthesis was observed within at least 25 sec after T4 ghost infection. The cellular level of amino acids and aminoacyl-transfer ribonucleic acid (tRNA) did not change drastically upon infection with ghosts, indicating that the inhibition of protein synthesis took place at a step(s) beyond aminoacyl-tRNA formation. The host messenger RNA remained intact and still bound to ribosomes shortly after ghost infection. Kinetic studies of the effect of ghosts on host protein synthesis revealed that nascent peptide chains on ribosomes were not released upon ghost infection.     

Phospholipid Synthesis in Escherichia coli Infected with T4 Bacteriophages

After infection of Escherichia coli with T4 phage, phospholipid synthesis continued but at a reduced rate. The same phospholipid components were synthesized as in uninfected cells; however, the relative rates of (32)P(i) incorporation into phosphatidylglycerol (PG) and phosphatidylethanolamine (PE) were altered. This alteration was most pronounced during the first 10 min after infection. Under these conditions, the isotope incorporated into PG equaled or exceeded that found in PG from uninfected cells. Chloramphenicol (CM) added before, but not 5 min after, infection inhibited the relative increase in PG synthesis, and CM added at different times after infection indicated that a protein synthesized between 3 and 6 min was required for this change to occur. Supplies of exogenous l-serine or l-alpha-glycerol-P failed to affect the relative rates of (32)P(i) incorporation into PG and PE by infected or uninfected cells. Phospholipid synthesis was somewhat higher after infection with T4rII mutants than after infection with wild-type phage. After infection with these mutants or several amber mutants, the relative synthesis of PG and PE was characteristic of T4r(+)-infected cells. The phospholipid synthesized after infection did not rapidly turn over, but infection accelerated the loss of PG synthesized prior to infection.     

Analysis of HCF, the cellular cofactor of VP16, in herpes simplex virus-infected cells

Herpes simplex virus (HSV) immediate-early (IE) gene expression is initiated via the recruitment of the structural protein VP16 onto specific sites upstream of each IE gene promoter in a multicomponent complex (TRF.C) that also includes the cellular proteins Oct-1 and HCF. In vitro results have shown that HCF binds directly to VP16 and stabilizes TRF.C. Results from transfection assays have also indicated that HCF is involved in the nuclear import of VP16. However, there have been no reports on the role or the fate of HCF during HSV type 1 (HSV-1) infection. Here we show that the intracellular distribution of HCF is dramatically altered during HSV-1 infection and that the protein interacts with and colocalizes with VP16. Moreover, viral protein synthesis and replication were significantly reduced after infection of a BHK-21-derived temperature-sensitive cell line (tsBN67) which contains a mutant HCF unable to associate with VP16 at the nonpermissive temperature. Intracellular distribution of HCF and of newly synthesized VP16 in tsBN67-infected cells was similar to that observed in Vero cells, suggesting that late in infection the trafficking of both proteins was not dependent on their association. We constructed a stable cell line (tsBN67r) in which the temperature-sensitive phenotype was rescued by using an epitope-tagged wild-type HCF. In HSV-1-infected tsBN67r cells at the nonpermissive temperature, direct binding of HCF to VP16 was observed, but virus protein synthesis and replication were not restored to levels observed at the permissive temperature or in wild-type BHK cells. Together these results indicate that the factors involved in compartmentalization of VP16 alter during infection and that late in infection, VP16 and HCF may have additional roles reflected in their colocalization in replication compartments.     

Development of escherichia coli virus T1. ATP-mediated discrimination of gene expression

The mechanism of host shut-off following virus T1 infection was studied using Escherichia coli wild type and ATPase deficient (unc-) cells. Host protein synthesis measured either as amino acid incorporation into proteins or as enzyme synthesis is immediately inhibited in T1-infected wild type cells. In contrast, host repression in the ATPase-deficient cells is almost unaffected after T1 infection. The continuation of host macromolecule synthesis in the unc- cells is due to constant ATP concentrations after infection, whereas an immediate drop in intracellular ATP levels in T1-infected wild type cells causes repression of host protein synthesis. This result is confirmed when host protein synthesis is determined at decreasing ATP concentrations following the starvation of cells.     

Isolation and Characterization of Prototrophic Mutants of Escherichia coli Unable to Support the Intracellular Growth of T7

Mutants of E. coli B/1 were isolated which grew normally but did not permit the intracellular growth of bacteriophage T7. Two classes of mutants were studied in detail (tsnB(-) and tsnC(-)). These strains adsorbed T7 normally and were killed by the infection. Synthesis of T7 RNA and of early and late classes of T7 proteins occurred normally after infection. In T7-infected tsnB(-) cells, T7 DNA synthesis stopped prematurely shortly after its onset, suggesting that the tsnB function affects a step in the late phase of T7 DNA replication. Mutants of T7 were isolated (T7beta) which could grow on tsnB(-) cells. In T7-infected tsnC(-) cells, T7 DNA synthesis was completely blocked, suggesting that the tsnC function affects a step in an early phase of T7 DNA replication.     

Evidence for the Presence of Nontranslated T7 Late mRNA in Infected F′(PIF+) Episome-Containing Cells

The inability of T7 to develop in cells of Escherichia coli containing F(+) or substituted F' episomes is a result of the failure to synthesize late proteins; no in vivo translation of mRNA species synthesized by the T7 RNA polymerase occurs. Further experiments have been performed to measure the amount of late mRNA in T7-infected F'(PIF(+)) cells. (We have designated the property of phage inhibition of F factors as PIF; the wild-type episome is therefore F'[PIF(+)].) T7 late proteins were synthesized in vitro by using a system programed with RNA extracted from T7-infected F(-) and F'(PIF(+)) cells. The T7 lysozyme, product of gene 3.5, and the gene 10 head protein were assayed. The following results were obtained: (i) mRNA capable of supporting in vitro synthesis of lysozyme and the gene 10 head protein is present in T7-infected F'(PIF(+)) cells; (ii) lysozyme mRNA extracted from T7-infected F'(PIF(+)) cells is present at 70 to 75% of the level found in T7-infected F(-) cells; (iii) gene 10 mRNA is present at 35 to 78% of the level found in T7-infected F(-) cells. No in vivo synthesis of either lysozyme or gene 10 protein can be detected in T7-infected F'(PIF(+)) cells although normal synthesis of these proteins occurs in F(-) cells. These findings confirm that the block in T7 development in F'(PIF(+)) cells results from the failure to translate late classes of T7 RNA.     

Translational discrimination against bacteriophage T7 gene 0·3 messenger RNA

Based on genetic manipulation of T7 late messenger RNA levels in vivo, we previously hypothesized that wild-type T7 infection of Escherichia coli develops in mRNA excess and that there is translational discrimination against T7 gene 0·3 mRNA (Strome & Young, 1978). The results presented here support our hypothesis. The discrimination against 0·3 mRNA translation observed in vivo can be mimicked in a cell-free system by increasing the concentration of T7 RNA beyond the level needed to saturate the translational machinery or by translating T7 RNA with a low concentration of ribosomes. This discrimination can be overcome by adding ribosomes to the cell-free system (increasing the ribosome to mRNA ratio) or by slowing the rate of polypeptide chain elongation. In addition 0·3 mRNA activity as well as a substantial fraction of T7 late mRNA activity is found to be shifted off of polysomes late in T7 infection. Our results are indicative of a low initiation rate constant for 0·3 mRNA compared to T7 late mRNAs.