Studies on the biosynthesis of TMV

Summary The replicative form and the replicative intermediate of TMV-RNA were isolated from synchronously infected tobacco leaves, labeled with H³-uridine for 1 hour. The replicative form is over 90% resistant to RNase and sediments slightly slower than the 16S ribosomal RNA. Sucrose gradient centrifugation of the thermally denatured replicative form revealed that it contains strands of the same size as single-stranded TMV-RNA. The replicative intermediate showed only partial resistance to RNase and heterogeneous sedimentation behavior in sucrose gradients. After mild RNase treatment the replicative intermediate sedimented homogeneously, and with an S value slightly lower than the replicative form.The following abbreviations are used RF replicative form - RI replicative intermediate - STE 0.1 M NaCl-1 mM Tris-HCl-1 mM EDTA, pH 7.4 - SSC 0.15 M NaCl-0.015 M sodium citrate, pH 7.0 - 10xSSC and 0.1xSSC tenfold concentrated and tenfold diluted SSC respectively - MAK methylated albumin coated kieselguhr     

Polyoma virus minichromosomes: associated DNA molecules

Electron microscopy was used to identify and quantitate DNA molecules associated with 3H-labeled polyoma minichromosomes which had been fractionated on a sucrose gradient. The percentage of replicating DNA molecules observed in the fractions of the gradient normally designated the replicative intermediate region was up to ninefold higher than in fractions from the mature region. Nevertheless, because of the higher overall concentration of polyoma DNA molecules in the mature region, nearly as many replicating DNA molecules were computed to be in the mature region as in the replicative intermediate region. The replicating molecules in the mature region was predominantly early replicative intermediates. Almost all late replicative intermediates were found in the replicative intermediate region. Under aqueous spreading conditions, a substantial fraction of the replicating DNA structures appeared to be asymmetrical or otherwise unusual, suggesting that extensive single-stranded regions may exist in replicating polyoma minichromosomes.     

In Vitro Synthesis of Poliovirus Ribonucleic Acid: Role of the Replicative Intermediate

Poliovirus ribonucleic acid (RNA) polymerase crude extracts could be stored frozen in liquid nitrogen without loss of activity or specificity. The major in vitro product of these extracts was viral single-stranded RNA. However, after short periods of incubation with radioactive nucleoside triphosphates, most of the incorporated label was found in replicative intermediate. When excess unlabeled nucleoside triphosphate was added, the label was displaced from the replicative intermediate and accumulated as viral RNA. It is concluded from this experiment that the replicative intermediate is the precursor to viral RNA. In addition, some of the label was chased into double-stranded RNA. The implications of this finding are discussed.     

Reaction of poliovirus RNAs with antibodies to double-stranded RNA demonstrated by an immunochemical binding assay.

An immunochemical binding assay was used to investigate the reactivity of radioactively labeled viral RNAs from poliovirus-infected cells with antibodies to the synthetic double-stranded RNA, poly(I)-poly(C). A RNase-free antibody-containing serum fraction was employed. Poliovirus replicative form reacted with the antibodies to poly(I)-poly(C) as well as or better than poly(I)-poly(C). Poliovirus replicative intermediate reacted with the antibodies to a greater extent than poliovirus single-stranded RNA, but both were less reactive than replicative form. The use of the immunochemical binding assay with sucrose-gradient fractions demonstrated that for both poliovirus single-stranded RNA and replicative form the peak of reactivity with the antibodies was coincident with the peak of radioactive material precipitated by trichloroacetic acid. The proportion of replicative intermediate that reacted with the antibody increased in sucrose-gradient fractions containing the more slowly sedimenting RI RNA.     

Inhibition of DNA synthesis by aphidicolin induces supercoiling in simian virus 40 replicative intermediates.

Highly torsionally stressed replicative intermediate SV40 DNA molecules are produced when ongoing replicative DNA synthesis is inhibited by aphidicolin, a specific inhibitor of DNA polymerase alpha. The high negative superhelical density of these molecules can be partially released by intercalating drugs such as chloroquine or ethidium bromide. The torsionally stressed replicative intermediates bind to monoclonal anti-Z-DNA antibodies. Electron microscopy of anti-Z-DNA cross-linked to torsionally stressed replicative intermediates shows that the antibody specifically binds close to the replication forks. The superhelical structures are not formed when SV40 DNA replication is inhibited by both aphidicolin and novobiocin, suggesting that a topoisomerase type II-like enzyme is somehow involved in the introduction of torsional strain in replicative intermediate DNA. One interpretation of our data is that fork movement continues to some rather limited extent when SV40 DNA synthesis in replicative chromatin is blocked by aphidicolin. After deproteinization, the exposed single-stranded DNA branches reassociate to form paranemic DNA structures with left-handed helical stretches, while the reduced linking number of the parental strands induces a high negative superhelical density.     

Replicative Intermediate of an Arbovirus

One hour after infection of chick fibroblasts with Semliki Forest virus (SFV), a viral ribonucleic acid (RNA) structure is present which has many of the properties described for the replicative intermediate of several RNA bacteriophages. These properties include a polydisperse nature on sucrose density gradient analysis, ribonuclease resistance, a variation in sedimentation pattern associated with changes in salt concentration, and recovery of infectious viral RNA upon denaturation. Most of the replicative intermediate present in SFV infection appears to be membrane-associated.     

Polyadenylic acid on poliovirus RNA. II. poly(A) on intracellular RNAs.

The content, size, and mechanism of synthesis of 3'-terminal poly(A) on the various intracellular species of poliovirus RNA have been examined. All viral RNA species bound to poly(U) filters and contained RNase-resistant stretches of poly(A) which could be analyzed by electrophoresis in polyacrylamide gels. At 3 h after infection, the poly(A) on virion RNA, relicative intermediate RNA, polyribosomal RNA, and total cytoplasmic 35S RNA was heterogeneous in size with an average length of 75 nucleotides. By 6 h after infection many of the intracellular RNA's had poly(A) of over 150 nucleotides in length, but the poly(A) in virion RNA did not increase in size suggesting that the amount of poly(A) which can be encapsidated is limited. At all times, the double-stranded poliovirus RNA molecules had poly(A) of 150 to 200 nucleotides. Investigation of the kinetics of poly(A) appearance in the replicative intermediate and in finished 35S molecules indicated that poly(A) is the last portion of the 35S RNA to be synthesized; no nascent poly(A) could be detected in the replicative intermediate. Although this result indicates that poliovirus RNA is synthesized 5' leads to 3' like other RNA's, it also suggests that much of the poly(A) found in the replicative intermediate is an artifact possibly arising from the binding of finished 35S RNA molecules to the replicative intermediate during extraction. The addition of poly(A) to 35S RNA molecules was not sensitive to guanidene.     

Analysis of Arbovirus Ribonucleic Acid Forms by Polyacrylamide Gel Electrophoresis

Viral ribonucleic acid (RNA) from Semliki Forest virus- and Sindbis virus-infected cells was analyzed by electrophoresis on polyacrylamide gels. In contrast to earlier results obtained by sucrose density gradient centrifugation, all of the known viral RNA forms (i.e., the 42S, 26S, replicative form, and replicative intermediate) were very clearly separated. The high resolution of the electrophoretic method permitted the identification of two new single-stranded RNA species. In addition, the replicative form was shown to be heterogeneous and to consist of at least two forms. The results suggested that the replicative forms occur in vivo although in relatively small amounts.     

Polyomavirus minichromosomes: associated DNA topoisomerase II and DNA ligase activities.

Polyomavirus minichromosomes were isolated and fractionated as described previously (B. B. Gourlie, M. R. Krauss, A. J. Buckler-White, R. M. Benbow, and V. Pigiet, J. Virol. 38:805-814, 1981). Specific assays for DNA topoisomerase II and DNA ligase activity were carried out on each fraction. The enzymatic activity in each fraction was determined by quantitative electron microscopy and compared with the number of replicative intermediate and total polyomavirus DNA molecules in each fraction. DNA topoisomerase II activity cosedimented with polyomavirus replicative intermediate minichromosomes. DNA ligase activity cosedimented with mature polyomavirus minichromosomes.     

Rhinovirus multistranded RNA: dependence of the replicative form on the presence of actinomycin D.

The multistranded and double-stranded RNAs synthesized in HeLa cells infected with rhinovirus in the presence and in the absence of actinomycin D have been characterized by polyacrylamide gel electrophoresis and hybridization studies. The replicative form is only found in infected cells treated with actinomycin D, whereas the replicative intermediate is found in both the presence and the absence of the drug. The significance of these results is discussed.     

Rhinovirus RNA Polymerase: Products and Kinetics of Appearance in Human Diploid Cells

The kinetics of appearance of an RNA-dependent RNA polymerase activity obtained from human embryo lung cells infected with rhinovirus type 2 have been followed by analysis of the RNA synthesized by the polymerase preparation in vitro. Little single-stranded RNA was synthesized and the proportion of replicative intermediate to replicative form was over threefold greater than obtained in vivo. The polymerase activity in vivo declined in the presence of cycloheximide showing that continued protein synthesis was necessary to maintain RNA replication.     

Effect of cordycepin triphosphate on in vitro RNA synthesis by plant viral replicases

In vitro RNA synthesis by tobacco mosaic virus and cowpea chlorotic mottle virus replicase were inhibited by cordycepin triphosphate. Inhibition could be overcome with higher concentrations of ATP in assay mixtures but not with UTP. Products synthesized in vitro by tobacco mosaic virus RNA replicase in the presence of inhibitor revealed replicative form but not replicative intermediate RNAs. These results suggest that cordycepin triphosphate competes specifically with ATP and results in premature termination of viral RNA synthesis in vitro.     

Early Intracellular Events in the Replication of Bacteriophage T4 Deoxyribonucleic Acid: V. Further Studies on the T4 Protein-Deoxyribonucleic Acid Complex 1

Soon after infection parental deoxyribonucleic acid (DNA) enters a structure sedimenting fast to the bottom of a sucrose gradient. The addition of chloramphenicol (CM) prevents formation of this structure, whereas treatment with Pronase releases DNA which sediments thereafter with the speed characteristic of phenol-extracted replicative DNA. It is assumed therefore that the structure responsible for fast sedimentation of replicative DNA is a newly synthesized protein. Those fast-sedimenting complexes contain preferentially the replicative form of parental DNA; this was proven by density labeling experiments. Progeny DNA labeled with (3)H-thymidine added after infection can also be detected preferentially in this fast-sedimenting moiety. The association of the DNA with the complexing protein is of a colinear or quasi-colinear type. This was proven by introducing double-strand scissions into DNA embedded in the replicative complex; double-strand scissions do not liberate DNA from the fast-sedimenting complex. Despite the apparent intimate relation between protein and DNA, DNA residing in complexes is fully sensitive to the action of nucleases. Shortly prior to the appearance of the fast-sedimenting complex, parental DNA displays still another characteristic: at about 3 min after infection, it sediments faster than reference, but sizeably slower than the complex which appears at roughly 4 to 5 min after infection. The transition between these two fast-sedimenting types of moieties is not continuous. This fast-sedimenting intermediate, which appears at 3 min after infection, cannot be inhibited by the addition of CM either at the moment or prior to infection. Fast-sedimenting intermediate can be destroyed by sodium dodecyl sulfate, Pronase, or phenol extraction. The progeny DNA labeled with (3)H-thymidine between 3 and 3.5 min after infection can be recovered in fast-sedimenting intermediate. The contribution of newly synthesized progeny DNA is so small that it cannot be detected as a shift of the parental density in a density labeling experiment. Small fragments of progeny DNA recovered in fast-sedimenting intermediate are not covalentlv attached to parental molecules and represent both strands of T4 DNA.     

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).     

Effects of VM26, a specific inhibitor of type II DNA topoisomerase, on SV40 chromatin replication in vitro.

We have examined the influence of VM26 (teniposide), a specific inhibitor of mammalian type II DNA topoisomerase, on the replication of SV40 minichromosomes in vitro. The replication system we used consists of replicative intermediate SV40 chromatin as substrate which is converted to mature SV40 chromatin in the presence of ATP, deoxynucleotides and a protein extract from uninfected cells. The addition of 100 microM VM26 to this system reduces DNA synthesis to 70 to 80 percent of the control and leads to an accumulation of 'late replicative intermediates'. The VM26 induced block of replication was not released by the addition of large quantities of type I DNA topoisomerase. We conclude, that type II DNA topoisomerase is essential for the final replication steps leading from late Cairns structures of replicative intermediates to monomeric minichromosomes. It appears that type I DNA topoisomerase can function as a swivelase during most of the replicative elongation phase, but must later be replaced by type II DNA topoisomerase.     

Mechanism of viral replication. I. Structure of replication complexes of R17 bacteriophage

The replication of R17 bacteriophage in Escherichia coli MRE-600 cells was investigated using a new electron microscopic technique. The structures of replicating ribonucleoprotein complexes, as well as of purified replicative intermediate and replicative form, were studied. These structures are identical to those predicted by the model of Weissmann et al. (1968). From this it may be concluded that replication proceeds through essentially single-stranded inter-mediates and that double-stranded structures are either by-products or artifacts.     

Denaturation and Renaturation of Viral Ribonucleic Acid II. Characterization of the Products Resulting from Annealing R17 Ribonucleic Acid with Denatured Replicative Form or with Denatured Replicative Intermediate

The ribonucleic acid (RNA) product resulting from annealing R17 RNA with denatured replicative form or replicative intermediate could be divided into two distinct types of RNA by precipitation in 1.5 m NaCl. The RNA found in the salt supernatant fluid was resistant to digestion by ribonuclease, had a sedimentation coefficient of 15S, and displayed a sharp thermal transition. The RNA in the salt supernatant fluid appeared to be identical to replicative form. The RNA found in the salt precipitate was resistant to digestion by ribonuclease, but possessed both single- and double-stranded characteristics. The RNA sedimented as a broad band in a sucrose gradient, with a sedimentation coefficient of 15S, and displayed a melting transition characteristic of a mixture of single- and double-stranded RNA. Mild ribonuclease digestion of the salt-precipitable RNA produced a ribonuclease-resistant material with sedimentation properties identical to the RNA found in the salt supernatant fluid.     

Sindbis Virus-induced Viral Ribonucleic Acid Polymerase

A cytoplasmic structure containing the viral ribonucleic acid (RNA) polymerase has been isolated by sucrose density centrifugation from cells infected with Sindbis virus. Uninfected cells did not contain any such structure. Preliminary experiments indicated that the structure may be associated with membranes. This structure incorporated (3)H-guanosine triphosphate in vitro in the absence of added template. The RNA synthesized in vitro by the enzyme consisted of single-stranded 40S RNA, the ribonuclease-resistant replicative form, and possibly the replicative intermediate form of viral RNA. The products formed in vitro by the enzyme are identical in sedimentation rates to those formed in the infected cells in vivo.