Repression of lambda-Associated Enzyme Synthesis After lambda(vir) Superinfection of Lysogenic Hosts.

Lisio, Arnold L. (National Institutes of Health, Bethesda, Md.), and Arthur Weissbach. Repression of lambda-associated enzyme synthesis after lambda(vir) superinfection of lysogenic hosts. J. Bacteriol. 90:661-666. 1965.-Phage lambda(vir) is a multiple mutant of lambda which is capable of overcoming the immunity of a host lysogenic for lambda, and initiating normal vegetative replication of the superinfecting phage genome. Superinfection of Escherichia coli K-112 (lambda(22)) with lambda(vir) results in a normal phage yield, lysis time, and H(3)-thymine incorporation compared with infection of the sensitive host, K-112 (S). However, the production of the lambda phage-specific early protein, lambda-exonuclease, after superinfection of E. coli K-112 (lambda(22)) with lambda(vir) is only 25 to 50% of that obtained from corresponding infection of a nonlysogenic host, E. coli K-112 (S). This repression of lambda-exonuclease synthesis is dependent on the C(1) cistron of the prophage and is overcome if the lysogenic host cells are induced prior to superinfection. The data are interpreted as evidence for partial repression of lambda(vir) by the host immunity.     

Synthesis of recA protein and induction of bacteriophage lambda in single-strand deoxyribonucleic acid-binding protein mutants of Escherichia coli.

We investigated the capacity of Escherichia coli mutants defective in the single-strand deoxyribonucleic acid (DNA)-binding protein to amplify the synthesis of the recA protein, induce prophage lambda, and degrade their DNA after treatment with ultraviolet radiation, mitomycin C, or bleomycin. The thermosensitive ssbA1 strain induced recA protein and lambda phage normally at 30 degrees C, but no induction was observed at 42 degrees C when ultraviolet radiation or mitomycin C was used. The lexC113 mutant did not amplify recA protein synthesis or induce phage lambda at either 30 or 42 degrees C with those agents. Bleomycin was able to elicit induction of recA and phage lambda in both mutants at any temperature. After induction with ultraviolet radiation at the elevated temperature, no DNA degradation was observed for 40 min, but at later times there was increased degradation in the lexC113 strain, compared with the wild type, and even greater degradation in the ssbA1 mutant. We discuss the role of single-strand DNA-binding protein in induction and the possibility that the lexC product may exert its influence on recA and lambda induction at the level of the single-strand DNA gap.     

Effect of ribonucleic acid phage superinfection on lysis-inhibited Escherichia coli

Groman, Neal B. (University of Washington, Seattle), and Grace Suzuki. Effect of ribonucleic acid phage superinfection on lysis-inhibited Escherichia coli. J. Bacteriol. 90:1007-1012. 1965.-Induced culturesof Escherichia coli K-12(lambda112)F(+) were superinfected with ribonucleic acid phage f2 at various times to test for the specificity of lysis inhibition and the concurrent inhibition of growth. When f2 superinfection occurred within 90 min after induction, lysis was observed in normally lysis-inhibited cultures. Later superinfections produced very little lysis. Following early superinfection, both lambda112 and f2 phages were produced in induced cells. When superinfection occurred during the period in which growth was inhibited, f2 production was totally inhibited. The inhibition of f2 was not due to its inability to adsorb, nor was it due to damage inflicted on cells by ultraviolet irradiation or to exhaustion of the medium. The data suggest that inhibition of lysis of induced K-12(lambda112)F(+) is phage-specific, whereas the accompanying inhibition of growth is nonspecific.     

Amplification of Epstein-Barr virus (EBV) DNA by superinfection with a strain of EBV derived from nasopharyngeal carcinoma.

Epstein-Barr virus (EBV) from a nasopharyngeal carcinoma (NPC) hybrid cell line (NPC-KT) lacking defective viral DNA molecules superinfected Raji cells and induced EBV early antigens (EA), as did virus from P3HR-1 cells, which contained defective molecules. The EBV polypeptides induced by NPC-KT appeared to be identical to those induced by P3HR-1 virus. The ability of NPC-KT virus to induce EA was enhanced more than 10-fold by treatment of superinfected cells with dimethyl sulfoxide; however, dimethyl sulfoxide treatment did not enhance superinfection by P3HR-1 virus. After infection, DNA synthesis of both the superinfecting NPC-KT virus and the resident Raji viral genome was induced. In addition to amplified Raji EBV episomal DNA, a fused terminal fragment of NPC-KT viral DNA was detected. The detection of fused terminal DNA fragments suggests that the superinfecting virion DNA either circularizes or polymerizes after superinfection and is possibly amplified through circular or concatenated replicative intermediates.     

The kinetics of bacterial DNA synthesis during indirect induction of prophage lambda

Summary The possibility that the processes of direct and indirect induction of prophage can be unified on the basis of a temporary inhibition of bacterial DNA synthesis has been examined. The kinetics of DNA synthesis in non-lysogenic bacteria were not significantly affected during a 60 min mating with UV-irradiated ColI drd donor cells. In contrast, direct irradiation of the bacteria with a UV dose which induced phage development with an efficiency similar to that obtained by indirect induction caused an abrupt cessation of DNA synthesis lasting for about 12 min. It is concluded that indirect induction of prophage differs from most treatments which induce directly in that it is not associated with an inhibition of host DNA synthesis.     

Differential cell killing by lymphomagenic murine leukemia viruses occurs independently of p53 activation and mitochondrial damage

Upon inoculation into AKR mice, mink cell focus-forming murine leukemia virus (MCF MLV) accelerates thymic lymphoma formation. During the preleukemic phase of disease, we observed the induction of apoptosis in thymic lymphocytes. A similar induction of apoptosis was observed for cultured mink epithelial cells after MCF13 MLV infection. In this study, the relevance of viral pathogenicity to cell killing was determined by testing the susceptibility of various cell types from different species to lymphomagenic MLVs. We observed that the cytopathic effect of lymphomagenic MLVs was restricted to mink cells. Southern blot analysis of MLV-infected cells revealed an accumulation of the linear form of unintegrated viral DNA, particularly in mink cells after MCF13 MLV infection. Thus, a strong correlation was observed between viral superinfection, which results in the accumulation of high levels of unintegrated viral DNA, and cell killing. Immunoblot analysis for MCF13 MLV-infected mink epithelial cells did not show a significant change in total p53 levels or its phosphorylated form at Ser-15 compared with that in mock-treated cells. Moreover, a time course analysis for mink epithelial cells infected with MCF13 MLV did not reveal mitochondrial depolarization or a significant change in Bax levels. These results demonstrate that MCF13 MLV induces apoptosis preferentially in cells in which superinfection occurs, and the mechanism involved is independent of p53 activation and mitochondrial damage.     

The rex genes of bacteriophage lambda can inhibit cell function without phage superinfection

The rexA and rexB genes of bacteriophage lambda are expressed from the prophage and cause the exclusion of many superinfecting mutant phages. We cloned the rexA and rexB genes into a multicopy plasmid so that they were overexpressed from the inducible tac promoter. No obvious phenotypes were associated with overexpressing both rexA and rexB or overexpressing rexA in the absence of rexB expression. However, induction of rexA in the presence of limiting rexB activity caused an immediate cessation of cell growth. All macromolecular synthesis abruptly ceased and amino acid transport was severely inhibited. Intracellular levels of adenosine 5'-triphosphate also dropped. These phenotypes are similar to those observed after phage superinfection, leading us to propose that at least some of the exclusion caused by the Rex proteins could be due to a change in their ratio following superinfection.     

Sedimentation characteristics of newly synthesized Epstein-Barr viral DNA in superinfected cells.

Replicating Epstein-Barr virus (EBV) DNA molecules isolated from superinfected Raji cells were shown to consist of 80S to 65S and 58S (mature) molecules Pulse-chase experiments showed that radioactive label of DNAS molecules with the larger sedimentation coefficients was partially chased into 58S labeled forms. Formation of large concatemers of viral DNA could not be detected at any time after superinfection. The continuous presence of the 65S viral DNA intermediate throughout the replicative cycle combined with the observed inhibition of EBV DNA synthesis by addition of nontoxic levels of ethidium bromide to the superinfected cell culture led us to propose that EBV replication proceeds via a relaxed circular DNA intermediate.     

Mechanisms of infection with Epstein-Barr virus. I. Viral DNA replication and formation of noninfectious virus particles in superinfected Raji cells.

Human lymphoblastoid Raji cells, which do not produce virus, supported replication of Epstein-Barr virus (EBV) upon superinfection. Early antigen, viral capsid antigen, and virions were produced in Raji cells superinfected with EBV. Viral DNA replicated under complete inhibition of host cell DNA synthesis to the extent that a few micrograms of EBV DNA were recovered from 107 superinfected Raji cells, corresponding to 5,000 viral genomes/cell. Homology of the synthesized viral DNA to parental EBV DNA was more than 90%. Virions produced by the Raji cells contained a 55S DNA but failed to induce early antigen, viral capsid antigen, and viral DNA synthesis after a second superinfection of Raji cells.     

In situ studies on incorporation of nucleic acid precursors into Chlamydia trachomatis DNA.

Chlamydiae are obligate intracellular bacteria that are dependent on eukaryotic host cells for ribonucleoside triphosphates. The purpose of the present study was to determine whether Chlamydia trachomatis obtains deoxyribonucleotides from the host cell. The study was aided by the finding that host and parasite DNA synthesis activity could be distinguished by their differing sensitivities to aphidicolin and norfloxacin. Results from isotope incorporation experiments indicated that any nucleobase or ribonucleoside that could serve as a precursor for host DNA synthesis could also be utilized by C. trachomatis for DNA replication. C. trachomatis utilized only those precursors which the host cell converted to the nucleotide level. Pyrimidine deoxyribonucleotides were efficient precursors for host DNA synthesis; however, they were not used by C. trachomatis. On the other hand, purine deoxyribonucleosides are rapidly catabolized by host cells, it is necessary to regulate their metabolism to determine whether they serve as direct precursors for C. trachomatis DNA synthesis. This was partially achieved by using a hypoxanthine-guanine phosphoribosyltransferase-negative cell line and using deoxycoformycin and 8-aminoguanosine as inhibitors of (deoxy)adenosine deaminase and purine nucleoside phosphorylase, respectively. The results indicated that purine deoxyribonucleosides are efficiently utilized for host cell DNA synthesis even if degradation pathways are inhibited and salvage to ribonucleotides is minimized. In sharp contrast, the purine deoxyribonucleosides were utilized by C. trachomatis as precursors for DNA synthesis only when host catabolic pathways and salvage reactions were intact. High-pressure liquid chromatographic analysis of nucleotide pools extracted from host cells pulsed with radiolabeled precursors suggests that infected cells transport and phosphorylate all deoxynucleosides as effectively as mock-infected control cultures. In aggregate, these results show that chlamydiae do not take up deoxyribonucleotides from the host cells.     

Functional organization of the Harvey murine sarcoma virus genome.

The comparative infectivity of Harvey murine sarcoma virus (Ha-MuSV) DNA for NIH 3T3 cells was determined for supercoiled Ha-MuSV DNA molecularly cloned in lambda phage and pBR322 at its unique EcoRI site (which is located near the middle of the 6-kilobase pair [kbp] unintegrated linear viral DNA) and for two cloned subgenomic fragments: one was 3.8 kbp and lacked about 1 kbp from each side of the EcoRI site, and the second did not contain the 3 kbp of the unintegrated linear viral DNA located on the 3' side of the EcoRI site. Each subgenomic DNA induced foci of transformed cells, but with a lower relative efficiency then genomic DNA. Transfection with intact vector Ha-MuSV DNA yielded results similar to those obtained after separation of Ha-MuSV DNA from vector DNA. Cells lines were then derived from individual foci transformed with each type of viral DNA. Focus-forming virus was recovered from transformed cells after superinfection with a helper-independent virus, but the efficiency varied by several orders of magnitude. For several transformed lines, the efficiency of recovery of focus-forming virus was correlated with the structure of the Ha-MuSV DNA in the cells before superinfection. When 32P-labeled Ha-MuSV DNA probes specific for sequences on either the 3' or 5' side of the EcoRI site were used to analyze the viral RNA in the transformed cell lines, all lines were found to hybridize with the 5' probe, but some lines did not hybridize with the 3' probe. The transformed lines contained high levels of the Ha-MuSV-coded p21 or its associated GDP-binding activity. We conclude that the transforming region and the sequences that code for the viral p21 protein are both located within the 2 kilobases closest to the 5' end of the Ha-MuSV genome.     

Inducible permissive cells transformed by a temperature-sensitive polyoma virus: superinfection does not allow excision of the resident viral genome.

After exposure of mouse embryo cells to the early temperature-sensitive mutant tsP155 of polyoma virus (Py), a transformed cell line (Cyp line) that can be readily induced to synthesize Py by transfer to 33 degrees C was isolated at 39 degrees C (7). Virus production and synthesis of free viral DNA occurring after temperature shiftdown or superinfection with wild-type Py or both were studied in several clonal isolates of the Cyp cell line. Measurements of virus yields indicated that, although some could be induced more effectively than others, all cell clones behaved as highly permissive when subjected to superinfection. We analyzed the origin of free viral DNA accumulating in the superinfected cultures, taking advantage of (i) the unique physical properties of the low-molecular-weight DNA which, in the case of one of the Cyp clones, accumulates during temperature shiftdown, and (ii) the differences between resident and superinfecting viral genomes in their susceptibilities towards restriction endonucleases. At 33 degrees C, both viral genomes were found to accumulate in all clones studied whereas in the case of the clones with lower inducibility, the replication of the resident genome appeared to be enhanced by superinfection. At 39 degrees C, however, accumulation of the superinfecting genome was not accompanied by that of the resident genome, unless it had already been initiated before superinfection. These findings demonstrate that, when routinely cultivated at 39 degrees C, Cyp cells contain few viral DNA molecules readily available for autonomous replication and that, upon transfer to 33 degrees C, therefore, excision must first take place before the resident genome can accumulate as free viral DNA. Our findings also suggest that, unlike the P155 gene product provided by the resident viral genome upon induction, the allelic gene product supplied by the superinfecting genome may be less effective in triggering excision than in promoting replication.     

Effect of cycloheximide on pools of deoxyribonucleoside triphosphates

Inhibition of protein synthesis by cycloheximide blocks DNA replication in many eukaryotic cells. To test whether this effect was mediated through enzymes furnishing DNA precursors, pool sizes of deoxyribonucleoside triphosphates were measured following cycloheximide treatment in the synchronous mitotic cycle of Physarum. It was found that cycloheximide either did not affect the pool size of DNA precursors (dATP and dGTP) or it led to a pool expansion (dCTP and dTTP). It is concluded that the arrest of DNA replication by inhibitors of protein synthesis is not due to a lack of precursors.     

Induction of prophage lambda does not require full induction of RecA protein synthesis

In mitomycin C-treated lambda lysogens, even though the rate of synthesis of RecA protein was greatly reduced by a low concentration of rifampicin (4 microgram/ml), induction of prophage lambda occurred readily as assessed by (i) cell lysis of the lysogens, (ii) production of progeny phage, and (iii) extensive cleavage of lambda repressor. The extent and the rate of cleavage of lambda repressor were not significantly affected by the low rate of synthesis of RecA protein resulting from rifampicin action. However, the yield of phage progeny was reduced and lysis of the cells was slightly delayed. We conclude that in RecA+ bacteria, induction of prophage lambda does not require full induction of RecA protein synthesis.     

Toxicity and mutagenicity of plumbagin and the induction of a possible new DNA repair pathway in Escherichia coli.

Actively growing Escherichia coli cells exposed to plumbagin, a redox cycling quinone that increases the flux of O2- radicals in the cell, were mutagenized or killed by this treatment. The toxicity of plumbagin was not found to be mediated by membrane damage. Cells pretreated with plumbagin could partially reactivate lambda phage damaged by exposure to riboflavin plus light, a treatment that produces active oxygen species. The result suggested the induction of a DNA repair response. Lambda phage damaged by H2O2 treatment were not reactivated in plumbagin-pretreated cells, nor did H2O2-pretreated cells reactivate lambda damaged by treatment with riboflavin plus light. Plumbagin treatment did not induce lambda phage in a lysogen, nor did it cause an increase in beta-galactosidase production in a dinD::Mu d(lac Ap) promoter fusion strain. Cells pretreated with nonlethal doses of plumbagin showed enhanced survival upon exposure to high concentrations of plumbagin, but were unchanged in their susceptibility to far-UV irradiation. polA and recA mutants were not significantly more sensitive than wild type to killing by plumbagin. However, xth-1 mutants were partially resistant to plumbagin toxicity. It is proposed that E. coli has an inducible DNA repair response specific for the type of oxidative damage generated during incubation with plumbagin. Furthermore, this response appears to be qualitatively distinct from the SOS response and the repair response induced by H2O2.     

Expression of the replication region of phage lambda DNA cloned into pBR322 in E. coli minicells

Replication region of bacteriophage lambda DNA was cloned into pBR322 plasmid by the use of two restriction enzymes--PstI and HindIII. The restriction analysis of four obtained plasmids revealed that lambda DNA was cloned in both orientations. Recombinant plasmids were transferred to the minicell-producing strain of E. coli and synthesis of the plasmid-mediated proteins was analysed by polyacrylamide-gel electrophoresis. All four recombinant plasmids produced lambda DNA replication proteins pO and pP as well as some proteins specific for pBR322. The orientation of cloned fragment did not affect the synthesis of lambda DNA replication proteins.     

DNA replication as a prerequisite for the induction of primary antibody response

Studies were carried out to test whether the induction of a primary production of antibodies is determined by DNA replication. An in vitro system for the induction of antibody to dinitrophenyl (DNP) determinants following immunization with α-DNP-poly-l-lysine was employed. Cytosine arabinoside (CA), at doses which inhibited DNA synthesis, yet did not affect viability of cells, was applied at different time intervals following antigenic stimulation. Inhibition of DNA synthesis during 36–48 hr following antigenic stimulation prevented the appearance of antibody producing cells. On the other hand, CA applied during the first 36 hr or at 48 hr did not prevent antibody production. Thus, one critical cycle of DNA replication seems to determine antibody production. The lag period prior to the CA-sensitive period is antigen determined.     

Inhibition of Mitosis and Macromolecular Synthesis in Rat Embryo Cells by Kilham Rat Virus

The effects of Kilham rat virus multiplication were studied in cultured rat embryo cells to examine the mechanisms by which virus infection might be related to developmental defects in rats and hamsters. The virus was found to inhibit motosis and deoxyribonucleic acid (DNA) synthesis within 2 to 10 hr after infection. However, total ribonucleic acid synthesis was relatively unaffected until about 20 hr after infection, and total protein synthesis did not decline significantly until loss of viable cells was apparent in the cultures. No effect on chromosomes was detected. The effect of Kilham rat virus on DNA synthesis appears to be due to inhibition of macromolecular synthesis rather than to an inhibition of uptake of precursors into cells. The effect of the virus on mitosis may be an addition to the effect on DNA synthesis, since mitosis is inhibited even in cultures in which cells are able to divide at the time of infection and which have presumably completed DNA synthesis.