Multiplication of parvovirus LuIII in a synchronized culture system. III. Replication of viral DNA.

The replication of the single-stranded DNA (ssDNA) of parvovirus LuIII was studied in synchronized HeLa cells. After infection of the cells in early S phase, synthesis of a replicative form (RF) DNA became detectable as early as 9 h postinfection, i.e., after display of the cellular helper function(s) indispensable for the replication of LuIII virus. According to digestion with nuclease S1, hybridization studies, and electron microscopy, RF DNA is a linear, double-stranded molecule comparable in length to mature ssDNA. It sedimented around 15S in neutral solution and banded at 1.714 g/ml in CsCl. Moreover, replication of LuIII DNA obviously includes a further replicative intermediate DNA which sedimented in front of RF DNA and bore single-stranded side-chains. Newly synthesized DNA disappeared from pools containing both RF DNA and replicative intermediate DNA within 5 min and reappeared in progeny virions only after 15 min. Intranuclear accumulation of significant amounts of progeny ssDNA could not be detected. It was postulated, therefore, that newly synthesized ssDNA is immediately enclosed in a stable maturation complex and resists extraction by the method of Hirt (1967).     

A cis-acting sequence promotes removal of simian virus 40 DNA from the replication pool.

Pulse-labeled simian virus 40 (SV40) DNA is removed from the pool of molecules available for replication (i.e., it ceases to reenter replication) a few hours after synthesis. We studied this cessation of reentry with mutants containing different deletions in the structural genes of SV40. The DNAs of two independent deletion mutants, dl-1007 (24% deletion) and dl-1003 (8% deletion), were used as templates for further DNA synthesis (i.e., they reentered replication) to a greater extent than was wild-type DNA. The alteration in reentry kinetics was not because the DNAs were smaller; other deletion mutations that were from 76 to 85% of the length of wild-type DNA (dl-BE and dl-1133 with a deletion in the late region and F8dl with a deletion in the early region) did not reenter replication to a greater extent than the wild type did. Cotransfection experiments showed that the mutant phenotypes of dl-1007 and dl-1003 were poorly complemented, if at all, by the wild type. Thus, we propose that there is a cis-acting sequence located in the HindIII E fragment of SV40, not present in either of these mutants, that promotes the efficient removal of DNA from the replication pathway.     

Ultraviolet irradiation inhibits encapsidation of simian virus 40 chromatin.

During normal maturation and majority of pulse-labeled simian virus 40 DNA progresses from chromatin to previrions and virions within 5 h. UV light inhibits this progression. In heavily irradiated cultures (108 J m-2) most of the simian virus 40 DNA synthesized immediately before irradiation remains as chromatin for at least 5 h. This inhibition of maturation seems to be a result of the inhibition of protein synthesis. The data suggest that the pool of proteins required for maturation is sufficient to convert one-third of the simian virus 40 DNA molecules labeled in a 10-min pulse (at 33 h postinfection) from chromatin to previrions and virions and is exhausted within 1 h.     

Protein synthesized early after infection is linked to the termini of adenovirus type 2 DNA synthesized in vivo and in vitro.

The human adenovirus DNA genome contains a protein (CBP, or covalently bound protein) linked to each 5' terminus. To assess whether CBP is synthesized early, infected cells were incubated with hydroxyurea from 1 to 18 h postinfection, the hydroxyurea was removed, cycloheximide was added, and viral DNA was labeled with [3H]thymidine from 18 to 23 h postinfection. Removal of hydroxyurea at 18 h postinfection permits the synthesis of viral DNA, whereas cycloheximide maintains the block in late viral protein synthesis. Three lines of evidence are presented to show that viral 3H-labeled DNA prepared by this procedure was linked to CBP: (I) the DNA sedimented more rapidly than protein-free DNA (i.e., protinase treated) in neutral sucrose gradients containing guanidine hydrochloride; (ii) the DNA banded at a lower density than protein-free DNA in CsCl gradients containing guanidine hydrochloride; and (iii) neither the 3H-labeled DNA nor the end fragments produced by EcoRI digestion entered a 1.4% agarose gel during electrophoresis. These experiments are strong evidence that CBP is not a product of a late viral gene and is therefore the product of either an early viral gene or a cell gene. Experiments were performed to test whether CBP is attached to viral DNA synthesized in vitro by a soluble complex that synthesizes exclusively viral DNA as completed viral genomes in vitro. In vitro-labeled DNA was analyzed by velocity sedimentation, equilibrium sedimentation, and agarose gel electrophoresis as described above. Our results indicate that the majority of in vitro-synthesized DNA molecules were attached to CBP. These results, which indicate that CBP is synthesized early after infection and is attached to viral DNA labeled in vitro by a soluble replication complex, are consistent with the idea that CBP may play a role in viral DNA replication.     

Nucleic Acid Synthesis in Cytoplasm of Yaba Monkey Tumor Virus-Infected Cells

Yaba tumor virus progeny appeared in cynomolgus monkey kidney cells at 24 h postinfection and reached a plateau at 72 h in the first cycle of replication. Viral DNA synthesis was first detected at about 3 h and reached a peak in 18 h. Maximum coating of viral DNA in infected cells occurred at 4 days postinfection. Rapidly labeled RNA was synthesized in the cytoplasm of virus-infected cells. At 6 h postinfection 7 to 10S RNA was present; this species was present in greater amount at 12 h; at 24 h a truncated peak indicated the presence of 14 to 15S as well as 7 to 10S RNA. Hybridization data indicated that the largest peak of messenger RNA synthesis occurred at 11 to 13 h postinfection and a second, slightly smaller, peak occurred at 21 to 23 h.     

Temporal association of the herpes simplex virus genome with histone proteins during a lytic infection

Previous work has determined that there are nucleosomes on the herpes simplex virus (HSV) genome during a lytic infection but that they are not arranged in an equally spaced array like in cellular DNA. However, like in cellular DNA, the promoter regions of several viral genes have been shown to be associated with nucleosomes containing modified histone proteins that are generally found associated with actively transcribed genes. Furthermore, it has been found that the association of modified histones with the HSV genome can be detected at the earliest times postinfection (1 h postinfection) and increases up to 3 h postinfection. However from 3 h to 6 h postinfection (the late phase of the replication cycle), the association decreases. In this study we have examined histone association with promoter regions of all kinetic classes of genes. This was done over the time course of an infection in Sy5y cells using sucrose gradient sedimentation, bromodeoxyuridine labeling, chromatin immunoprecipitation assays, Western blot analysis, trypsin and DNase digestion, and quantitative real-time PCR. Because no histones were detected inside HSV type 1 capsids, the viral genome probably starts to associate with histones after being transported from infecting virions into the host nucleus. Promoter regions of all gene classes (immediate early, early, and late) bind with histone proteins at the start of viral gene expression. However, after viral DNA replication initiates, histones appear not to associate with newly synthesized viral genomes.     

Transcription of the genome of adenovirus type 12. Viral mRNA in productively infected KB cells.

In human KB cells productively infected with adenovirus type 12, viral DNA replication starts between 12 and 14h postinfection. Virus-specific, polysome-associated mRNA was investigated early (6-8h) and late (26-28h) after infection. Most of the viral mRNA was polyadenylated and accounted for 0.46% and 24.1% of the mRNA synthesized early and late postinfection, respectively. The viral-specific mRNA isolated both early and late after infection falls into several distinct size-classes, ranging in molecular weights between 0.3X10(6) and 1.5X10(6) for the early RNA and between 0.6X10(6) and 2.3X10(6) for the RNA synthesized late in the infection.     

Baculovirus lef-12 is not required for viral replication

The baculovirus lef-12 (orf41) gene is required for transient expression of baculovirus late genes. To analyze the role of LEF-12 in the context of infected cells, two mutant viruses were constructed. Both mutants were viable in Trichoplusia ni High 5 and Spodoptera frugiperda Sf9 cells. Single-step growth curves, however, indicated that virus yields were reduced approximately fivefold in the absence of LEF-12. Pulse-labeling of infected cells revealed that LEF-12 mutant viruses entered the late phase and synthesized late proteins at levels equivalent to or only twofold lower than those of wild-type virus-infected cells. Western blot analyses confirmed that LEF-12 was not synthesized in cells infected with mutant virus. In wild-type virus-infected cells, LEF-12 was not detected until 18 h postinfection, and accumulation of LEF-12 peaked at 24 to 36 h postinfection. Primer extension mapping revealed that lef-12 mRNA was synthesized by 12 h postinfection and peaked between 18 and 24 h postinfection. Furthermore, synthesis of lef-12 mRNA and LEF-12 protein were inhibited by the addition of aphidicolin, indicating that lef-12 is expressed after DNA replication.     

Biosynthesis of adenovirus type 2 i-leader protein.

The i-leader is a 440-base-pair sequence located between 21.8 and 23.0 map units on the adenovirus type 2 genome and is spliced between the second and third segments of the major tripartite leader in certain viral mRNA molecules. The i-leader contains an open translational reading frame for a hypothetical protein of Mr about 16,600, and a 16,000-Mr polypeptide (16K protein) has been translated in vitro on mRNA selected with DNA containing the i-leader (A. Virtanen, P. Alestr?m, H. Persson, M. G. Katze, and U. Pettersson, Nucleic Acids Res. 10:2539-2548, 1982). To determine whether the i-leader protein is synthesized during productive infection and to provide an immunological reagent to study the properties and functions of the i-leader protein, we prepared antipeptide antibodies directed to a 16-amino acid synthetic peptide which is encoded near the N terminus of the hypothetical i-leader protein and contains a high acidic amino acid and proline content. Antipeptide antibodies immunoprecipitated from extracts of adenovirus type 2-infected cells a major 16K protein that comigrated with a 16K protein translated in vitro. Partial N-terminal amino acid sequence analysis by Edman degradation of radiolabeled 16K antigen showed that methionine is present at residue 1 and leucine is present at residues 8 and 10, as predicted from the DNA sequence, establishing that the 16K protein precipitated by this antibody is indeed the i-leader protein. Thus, the i-leader protein is a prominent species that is synthesized during productive infection. The i-leader protein is often seen as a doublet on polyacrylamide gels, suggesting that either two related forms of i-leader protein are synthesized in infected cells or that a posttranslational modification occurs. Time course studies using immunoprecipitation analysis with antipeptide antibodies revealed that the E1A 289R T antigen and the E1B-19K (175R) T antigen are synthesized beginning at 2 to 3 and 4 to 5 h postinfection, respectively, whereas the i-leader protein is synthesized starting at about 8 h postinfection and continues unabated until at least 25 h postinfection. The i-leader protein is very stable, as determined by pulse-chase labeling experiments, and accumulates continuously from 8 to 25 h postinfection, as shown by immunoblot analysis. The synthesis of i-leader protein does not depend upon viral DNA replication. Thus, the i-leader protein is a viral gene product of unknown function and high stability that is made in large quantities at intermediate times of productive infection.(ABSTRACT TRUNCATED AT 400 WORDS)     

The lef-3 gene of Autographa californica nuclear polyhedrosis virus encodes a single-stranded DNA-binding protein.

The Autographa californica nuclear polyhedrosis virus (AcNPV) replicates in the nuclei of infected cells and encodes several proteins required for viral DNA replication. As a first step in the functional characterization of viral replication proteins, we purified a single-stranded DNA-binding protein (SSB) from AcNPV-infected insect cells. Nuclear extracts were chromatographed on single-stranded DNA agarose columns. An abundant protein with an apparent molecular weight of 43,000 was eluted from the columns at 0.9 to 1.0 M NaCl. This protein was not evident in extracts prepared from control cells, suggesting that the SSB was encoded by the virus. SSB bound to single-stranded DNA in solution, and binding was nonspecific with respect to base sequence, as single-stranded vector DNA competed as efficiently as single-stranded DNA containing the AcNPV origin of DNA replication. Competition binding experiments indicated that SSB showed a preference for single-stranded DNA over double-stranded DNA. To determine whether SSB was encoded by the lef-3 gene of AcNPV, the lef-3 open reading frame was cloned under the control of the bacteriophage T7 promoter. Immunochemical analyses indicated that LEF-3 produced in bacteria or in rabbit reticulocyte lysates specifically reacted with antiserum produced by immunization with purified SSB. Immunoblot analyses of infected cell extracts revealed that SSB/LEF-3 was detected by 4 h postinfection and accumulated through 48 h postinfection.     

Topoisomerase II cleavage of herpes simplex virus type 1 DNA in vivo is replication dependent

The genome of herpes simplex virus type 1 contains a large number of recognition sites for eucaryotic DNA type II topoisomerase. Topoisomerase II sites were identified by means of the consensus sequence described previously (J.R. Spitzner and M.T. Muller, Nucleic Acids Res. 16:5553-5556, 1988) and then confirmed by sequencing DNA cleavages introduced by purified topoisomerase II. In vivo, host topoisomerase II also introduced double-stranded DNA breaks in the viral genome at sites predicted by the consensus sequence. Host topoisomerase II acted on all immediate-early genes as well as on genes from other temporal classes; however, cleavages were not detected until 4 to 5 h postinfection and were most intense at 10 h postinfection. Topoisomerase II cleavages were not detected when viral DNA replication was prevented with phosphonoacetic acid. These data indicate that, although progeny viral genomes are acted upon by host topoisomerase II, this enzyme either does not act on parental viral genomes before DNA replication or acts on them with such low efficiency that cleavages are beyond our limit of detection. The findings suggest that host topoisomerase II is involved in aspects of viral replication at late times in the infectious cycle.     

Sequential Formation of Vaccinia Virus Proteins and Viral Deoxyribonucleic Acid Replication

In vaccinia virus-infected cell cultures, cellular protein synthesis was inhibited 50% at 2 hr postinfection (PI) and 80 to 90% by 4 hr PI. Input virus was responsible for this inhibition. Five early proteins, coded for by the viral genome, could be detected at 2 to 3 hr PI. Normally, their synthesis did not continue beyond 6 hr PI, at which time synthesis of a different set of proteins began. When DNA replication was blocked, synthesis of these early proteins continued until 9 to 12 hr PI. The bulk of the proteins which were incorporated into mature virus were synthesized at 8 hr PI and thereafter. The time of their formation was close to the time at which virus maturation occurred. However, 15% of the protein found in mature virus was synthesized early in the infectious cycle. The quantity of “early viral protein” which was not incorporated into mature virus was almost as large as the quantity of viral protein which did appear in mature virus. The “early” and “late” proteins could be shown to have separate and distinct immunological properties. The role of this large quantity of “early” protein is discussed.     

Adenovirus DNA Replication I. Requirement for Protein Synthesis and Isolation of Nuclear Membrane Fractions Containing Newly Synthesized Viral DNA and Proteins

Nuclear membrane fractions were prepared by two procedures from KB cells pulse labeled with [(3)H]thymidine for 5 min late after infection with adenovirus 2: (i) the M-band technique, which yields a sharp peak containing most of the newly synthesized viral DNA, and (ii) the discontinuous sucrose gradient method, which yields three membrane fractions, one which bands at the interface between sucrose layers at density 1.18 and 1.20 g/ml and contains most of the newly synthesized viral DNA. Studies using cycloheximide to inhibit protein synthesis showed that proteins whose synthesis begins early after infection and occurs in the absence of viral DNA replication are required for viral DNA synthesis late after infection. To study the nature of these proteins, nuclear membrane fractions were isolated from cells labeled with [(3)H]leucine from 6 to 24 h postinfection in the presence of arabinosyl cytosine to block viral DNA replication, and were analyzed by electrophoresis in sodium dodecyl sulfate polyacrylamide gels. Two proteins of molecular weights 75,000 and 45,000 were the major labeled polypeptides in the nuclear membrane fractions prepared from infected cells both by the M-band and the discontinuous sucrose gradient methods. These two proteins were not found in nuclear membrane fractions from uninfected cells. It is suggested that the 75,000 and 45,000 proteins may be early viral gene products that may play a role in the viral DNA replication.     

p21(Cip1) and p27(Kip1) regulate cell cycle reentry after hypoxic stress but are not necessary for hypoxia-induced arrest

We investigated the role of the cyclin-dependent kinase inhibitors p21(Cip1) and p27(Kip1) in cell cycle regulation during hypoxia and reoxygenation. While moderate hypoxia (1 or 0.1% oxygen) does not significantly impair bromodeoxyuridine incorporation, at very low oxygen tensions (0.01% oxygen) DNA replication is rapidly shut down in immortalized mouse embryo fibroblasts. This S-phase arrest is intact in fibroblasts lacking the cyclin kinase inhibitors p21(Cip1) and p27(Kip1), indicating that these molecules are not essential elements of the arrest pathway. Hypoxia-induced arrest is accompanied by dephosphorylation of pRb and inhibition of cyclin-dependent kinase 2, which results in part from inhibitory phosphorylation. Interestingly, cells lacking the retinoblastoma tumor suppressor protein also display arrest under hypoxia, suggesting that pRb is not an essential mediator of this response. Upon reoxygenation, DNA synthesis resumes by 3.5 h and reaches aerobic levels by 6 h. Cells lacking p21, however, resume DNA synthesis more rapidly upon reoxygenation than wild-type cells, suggesting that this inhibitor may play a role in preventing premature reentry into the cell cycle upon cessation of the hypoxic stress. While p27 null cells did not exhibit rapid reentry into the cell cycle, cells lacking both p21 and p27 entered S phase even more aggressively than those lacking p21 alone, revealing a possible secondary role for p27 in this response. Cdk2 activity is also restored more rapidly in the double-knockout cells when returned to normoxia. These studies reveal that restoration of DNA synthesis after hypoxic stress, but not the S phase arrest itself, is regulated by p21 and p27.     

Vaccinia Virus DNA Replication Occurs in Endoplasmic Reticulum-enclosed Cytoplasmic Mini-Nuclei

Vaccinia virus (vv), a member of the poxvirus family, is unique among most DNA viruses in that its replication occurs in the cytoplasm of the infected host cell. Although this viral process is known to occur in distinct cytoplasmic sites, little is known about its organization and in particular its relation with cellular membranes. The present study shows by electron microscopy (EM) that soon after initial vv DNA synthesis at 2 h postinfection, the sites become entirely surrounded by membranes of the endoplasmic reticulum (ER). Complete wrapping requires ~45 min and persists until virion assembly is initiated at 6 h postinfection, and the ER dissociates from the replication sites. [(3)H]Thymidine incorporation at different infection times shows that efficient vv DNA synthesis coincides with complete ER wrapping, suggesting that the ER facilitates viral replication. Proteins known to be associated with the nuclear envelope in interphase cells are not targeted to these DNA-surrounding ER membranes, ruling out a role for these molecules in the wrapping process. By random green fluorescent protein-tagging of vv early genes of unknown function with a putative transmembrane domain, a novel vv protein, the gene product of E8R, was identified that is targeted to the ER around the DNA sites. Antibodies raised against this vv early membrane protein showed, by immunofluorescence microscopy, a characteristic ring-like pattern around the replication site. By electron microscopy quantitation the protein concentrated in the ER surrounding the DNA site and was preferentially targeted to membrane facing the inside of this site. These combined data are discussed in relation to nuclear envelope assembly/disassembly as it occurs during the cell cycle.     

Specific alterations in the pattern of histone-3 synthesis during conversion of human leukemic cells to terminally differentiated cells in culture

The presence of nano- to micromolar concentrations of 12-0-tetradecanoyl-phorbol-13-acetate (TPA) in suspension cultures of human promyelocytic leukemia cells, HL-60, or human monocytic leukemia cells, THP-1, resulted in the appearance of macrophage-like cells attached to the substratum. The terminally TPA-differentiated cells continued to synthesize histones at a low rate even though DNA replication had ceased. The pattern of synthesis of histone variants in differentiated cells differed from that in undifferentiated cells and resembled that of quiescent or density-arrested cells. In undifferentiated cells, all three histone-H3 variants are synthesized, while in quiescent cells, only the H3.3 variant is synthesized. When TPA-differentiated macrophages were placed in normal medium, the pattern of histone synthesis was not altered, thus substantiating previous findings that the differentiation is irreversible. Further, TPA-differentiated macrophages and macrophages isolated from a normal human donor exhibited identical pattern of histone synthesis. Altogether, the results indicate that changes in the synthetic rates of histones during the TPA-induced maturation of human leukemic cells is not directly due to TPA or terminal cell differentiation per se but is due to the cessation of cell proliferation and DNA replication.     

Identification and characterization of a porcine parvovirus nonstructural polypeptide.

Sera from porcine parvovirus (PPV)-infected swine fetuses immunoprecipitated and 84- to 86-kilodalton polypeptide in addition to the A and B virion structural proteins. This polypeptide, designated NS-1, was present in PPV-infected cell lysates but not in purified virions. Partial proteolysis mapping revealed that NS-1 was not related to the A and B viral structural proteins. All three proteins in infected cells were phosphorylated at serine residues, and NS-1 also contained phosphothreonine. From pulse-labeling experiments with either 32Pi or [35S]methionine, NS-1 was found to first appear 5 to 7 h postinfection, whereas the viral structural polypeptides were first synthesized 9 to 11 h postinfection. Pulse-chase experiments revealed that NS-1 initially appeared as an 84-kilodalton protein and was subsequently structurally modified to forms of slower electrophoretic mobilities. The time of appearance of NS-1 after virus infection coincided with the initiation of viral DNA synthesis, suggesting that this polypeptide (and the modified forms thereof) may be involved in PPV replication.     

Herpes Simplex Virus 1 DNA Is in Unstable Nucleosomes throughout the Lytic Infection Cycle,and the Instability of the Nucleosomes Is Independent of DNA Replication

Herpes simplex virus 1 (HSV-1) DNA is chromatinized during latency and consequently regularly digested by micrococcal nuclease (MCN) to nucleosome-size fragments. In contrast, MCN digests HSV-1 DNA in lytically infected cells to mostly heterogeneous sizes. Yet HSV-1 DNA coimmunoprecipitates with histones during lytic infections. We have shown that at 5 h postinfection, most nuclear HSV-1 DNA is in particularly unstable nucleoprotein complexes and consequently is more accessible to MCN than DNA in cellular chromatin. HSV-1 DNA was quantitatively recovered at this time in complexes with the biophysical properties of mono- to polynucleosomes following a modified MCN digestion developed to detect potential unstable intermediates. We proposed that most HSV-1 DNA is in unstable nucleosome-like complexes during lytic infections. Physiologically, nucleosome assembly typically associates with DNA replication, although DNA replication transiently disrupts nucleosomes. It therefore remained unclear whether the instability of the HSV-1 nucleoprotein complexes was related to the ongoing viral DNA replication. Here we tested whether HSV-1 DNA is in unstable nucleosome-like complexes before, during, or after the peak of viral DNA replication or when HSV-1 DNA replication is inhibited. HSV-1 DNA was quantitatively recovered in complexes fractionating as mono- to polynucleosomes from nuclei harvested at 2, 5, 7, or 9 h after infection, even if viral DNA replication was inhibited. Therefore, most HSV-1 DNA is in unstable nucleosome-like complexes throughout the lytic replication cycle, and the instability of these complexes is surprisingly independent of HSV-1 DNA replication. The specific accessibility of nuclear HSV-1 DNA, however, varied at different times after infection.     

Fusion of the termini of the murine cytomegalovirus genome after infection.

The genome of murine cytomegalovirus, extracted from extracellular virions, is a linear double-stranded DNA molecule ca. 240 kilobase pairs long. In our initial cloning of subgenomic fragments of the murine cytomegalovirus genome, we obtained a HindIII clone which contained fused HindIII-terminal fragments. By hybridizing this cloned DNA fragment to infected-cell DNA, we identified an intracellular restriction fragment which was the length of the sum of the two authentic termini. This fusion fragment was not present in virion DNA but could be detected as early as 2 h postinfection and reached its highest level shortly after the onset of DNA replication at 16 h postinfection. The prereplicative increase of fused ends was not inhibited by a level of phosphonoacetic acid which effectively shut off viral DNA synthesis, nor was the early conversion from free to fused ends prevented by inhibitors of protein or RNA synthesis. The results are consistent with the fused state of viral DNA being a replicative intermediate and precursor to DNA synthesis.