Extensive symmetrical transcription of Simian Virus 40 DNA in virus-yielding cells

Invading viral DNA triggers dsRNA synthesis by RNA polymerase II to activate antiviral RNA interference in Drosophila

dsRNA sensing triggers antiviral responses against RNA and DNA viruses in diverse eukaryotes. In Drosophila, Invertebrate iridescent virus 6 (IIV-6), a large DNA virus, triggers production of small interfering RNAs (siRNAs) by the dsRNA sensor Dicer-2. Here, we show that host RNA polymerase II (RNAPII) bidirectionally transcribes specific AT-rich regions of the IIV-6 DNA genome to generate dsRNA. Both replicative and naked IIV-6 genomes trigger production of dsRNA in Drosophila cells, implying direct sensing of invading DNA. Loquacious-PD, a Dicer-2 co-factor essential for the biogenesis of endogenous siRNAs, is dispensable for processing of IIV-6-derived dsRNAs, which suggests that they are distinct. Consistent with this finding, inhibition of the RNAPII co-factor P-TEFb affects the synthesis of endogenous, but not virus-derived, dsRNA. Altogether, our results suggest that a non-canonical RNAPII complex recognizes invading viral DNA to synthesize virus-derived dsRNA, which activates the antiviral siRNA pathway in Drosophila.

Adenovirus prevents dsRNA formation by promoting efficient splicing of viral RNA

Eukaryotic cells recognize intracellular pathogens through pattern recognition receptors, including sensors of aberrant nucleic acid structures. Sensors of double-stranded RNA (dsRNA) are known to detect replication intermediates of RNA viruses. It has long been suggested that annealing of mRNA from symmetrical transcription of both top and bottom strands of DNA virus genomes can produce dsRNA during infection. Supporting this hypothesis, nearly all DNA viruses encode inhibitors of dsRNA-recognition pathways. However, direct evidence that DNA viruses produce dsRNA is lacking. Contrary to dogma, we show that the nuclear-replicating DNA virus adenovirus (AdV) does not produce detectable levels of dsRNA during infection. In contrast, abundant dsRNA is detected within the nucleus of cells infected with AdV mutants defective for viral RNA processing. In the presence of nuclear dsRNA, the cytoplasmic dsRNA sensor PKR is relocalized and activated within the nucleus. Accumulation of viral dsRNA occurs in the late phase of infection, when unspliced viral transcripts form intron/exon base pairs between top and bottom strand transcripts. We propose that DNA viruses actively limit dsRNA formation by promoting efficient splicing and mRNA processing, thus avoiding detection and restriction by host innate immune sensors of pathogenic nucleic acids.

The herpes simplex virus host shutoff (vhs) RNase limits accumulation of double stranded RNA in infected cells: Evidence for accelerated decay of duplex RNA

The herpes simplex virus virion host shutoff (vhs) RNase destabilizes cellular and viral mRNAs and blunts host innate antiviral responses. Previous work demonstrated that cells infected with vhs mutants display enhanced activation of the host double-stranded RNA (dsRNA)-activated protein kinase R (PKR), implying that vhs limits dsRNA accumulation in infected cells. Confirming this hypothesis, we show that partially complementary transcripts of the UL23/UL24 and UL30/31 regions of the viral genome increase in abundance when vhs is inactivated, giving rise to greatly increased levels of intracellular dsRNA formed by annealing of the overlapping portions of these RNAs. Thus, vhs limits accumulation of dsRNA at least in part by reducing the levels of complementary viral transcripts. We then asked if vhs also destabilizes dsRNA after its initial formation. Here, we used a reporter system employing two mCherry expression plasmids bearing complementary 3’ UTRs to produce defined dsRNA species in uninfected cells. The dsRNAs are unstable, but are markedly stabilized by co-expressing the HSV dsRNA-binding protein US11. Strikingly, vhs delivered by super-infecting HSV virions accelerates the decay of these pre-formed dsRNAs in both the presence and absence of US11, a novel and unanticipated activity of vhs. Vhs binds the host RNA helicase eIF4A, and we find that vhs-induced dsRNA decay is attenuated by the eIF4A inhibitor hippuristanol, providing evidence that eIF4A participates in the process. Our results show that a herpesvirus host shutoff RNase destabilizes dsRNA in addition to targeting partially complementary viral mRNAs, raising the possibility that the mRNA destabilizing proteins of other viral pathogens dampen the host response to dsRNA through similar mechanisms.

Essentially all viruses produce double-stranded RNA (dsRNA) during infection. Host organisms therefore deploy a variety of dsRNA receptors to trigger innate antiviral defenses. Not surprisingly, viruses in turn produce an array of antagonists to block this host response. The best characterized of the viral antagonists function by binding to and masking dsRNA and/or blocking downstream signaling events. Other less studied viral antagonists appear to function by reducing the levels of dsRNA in infected cells, but exactly how they do so remains unknown. Here we show that one such viral antagonist, the herpes simplex virus vhs ribonuclease, reduces dsRNA levels in two distinct ways. First, as previously suggested, it dampens the accumulation of partially complementary viral mRNAs, reducing the potential for generating dsRNA. Second, it helps remove dsRNA after its formation, a novel and surprising activity of a protein best known for its activity on single-stranded mRNA. Many other viral pathogens produce proteins that target mRNAs for rapid destruction, and it will be important to determine if these also limit host dsRNA responses in similar ways.

Visualizing Virus-Derived dsRNA Using Antibody-Independent and -Dependent Methods

Long double-stranded (ds) RNA molecules are produced as a byproduct of viral replication. Studying virus-derived dsRNA is important for understanding virus replication, understanding host responses to virus infections, and as a diagnostic tool for virus presence and replication. Here, we describe four different techniques for visualizing dsRNA; two antibody-dependent methods (immunoblotting and immunocytochemistry), as well as two antibody-independent methods (differential digestion and acridine orange staining). The benefits and disadvantages of each technique are also discussed.

Cellular 5'-3' mRNA exonuclease Xrn1 controls double-stranded RNA accumulation and anti-viral responses

By accelerating global mRNA decay, many viruses impair host protein synthesis, limiting host defenses and stimulating virus mRNA translation. Vaccinia virus (VacV) encodes two decapping enzymes (D9, D10) that remove protective 5′ caps on mRNAs, presumably generating substrates for degradation by the host exonuclease Xrn1. Surprisingly, we find VacV infection of Xrn1-depleted cells inhibits protein synthesis, compromising virus growth. These effects are aggravated by D9 deficiency and dependent upon a virus transcription factor required for intermediate and late mRNA biogenesis. Considerable double-stranded RNA (dsRNA) accumulation in Xrn1-depleted cells is accompanied by activation of host dsRNA-responsive defenses controlled by PKR and 2′-5′ oligoadenylate synthetase (OAS), which respectively inactivate the translation initiation factor eIF2 and stimulate RNA cleavage by RNase L. This proceeds despite VacV-encoded PKR and RNase L antagonists being present. Moreover, Xrn1 depletion sensitizes uninfected cells to dsRNA treatment. Thus, Xrn1 is a cellular factor regulating dsRNA accumulation and dsRNA-responsive innate immune effectors.

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Vaccinia virus (VacV) replication requires the host Xrn1 mRNA decay enzyme

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The 5′-3′ mRNA exonuclease Xrn1 limits dsRNA accumulation

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In the absence of Xrn1, host dsRNA-responsive innate immune defenses are activated

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VacV antagonists of dsRNA-responsive host defenses are Xrn1 dependent

Activation of innate immune defense mechanisms contributes to polyomavirus BK-associated nephropathy

Polyomavirus-associated nephropathy (PVAN) is a significant complication after kidney transplantation, often leading to premature graft loss. In order to identify antiviral responses of the renal tubular epithelium, we studied activation of the viral DNA and the double-stranded RNA (dsRNA) sensors Toll-like receptor 3 (TLR3) and retinoic acid inducible gene-I (RIG-I) in allograft biopsy samples of patients with PVAN, and in human collecting duct cells in culture after stimulation by the dsRNA mimic polyriboinosinic:polyribocytidylic acid (poly(I:C)), cytokines, or infection with BK virus. Double staining using immunofluorescence for BK virus and TLR3 showed strong signals in epithelial cells of distal cortical tubules and the collecting duct. In biopsies microdissected to isolate tubulointerstitial lesions, TLR3 but not RIG-I mRNA expression was found to be increased in PVAN. Collecting duct cells in culture expressed TLR3 intracellularly, and activation of TLR3 and RIG-I by poly(I:C) enhanced expression of cytokine, chemokine, and IFN-β mRNA. This inflammatory response could be specifically blocked by siRNA to TLR3. Finally, infection of the collecting duct cells with BK virus enhanced the expression of cytokines and chemokines. This led to an efficient antiviral immune response with TLR3 and RIG-I upregulation without activation of IL-1β or components of the inflammasome pathway. Thus, PVAN activation of innate immune defense mechanisms through TLR3 is involved in the antiviral and anti-inflammatory response leading to the expression of proinflammatory cytokines and chemokines.

dsRNA and the innate antiviral immune response

Innate immunity is the first line of defense against viral infections. It is based on a mechanism of sensing pathogen-associated molecular patterns through host germline-encoded pattern recognition receptors. dsRNA is arguably the most important viral pathogen-associated molecular pattern due to its expression by almost all viruses at some point during their replicative cycle. Viral dsRNA has been studied for over 55 years, first as a toxin, then as a type I interferon inducer, a viral mimetic and an immunomodulator for therapeutic purposes. This article will focus on dsRNA, its structure, generation (both endogenous and viral), host sensing mechanisms and induction of type I interferons. The possible therapeutic applications of these findings will also be discussed. The goal of this article is to give an overview of these mechanisms, highlighting novel findings, while providing a historical perspective.

The upstream area of the chicken α-globin gene domain is transcribed in both directions in the same cells

It was demonstrated previously that in erythroid chicken cells an extended upstream area of the alpha-globin gene domain is transcribed in both directions as a part of ggPRX gene and a part of a full domain transcript of the alpha-globin gene domain. Here, we show that both DNA chains of the above-mentioned region are transcribed in the same cells and that the corresponding transcripts coexist in nuclei. The data obtained suggest that cells possess a molecular mechanism which in some cases prevents the formation of dsRNA and subsequent destruction of both transcripts in spite of the presence of complementary RNA chains in the cell nucleus.

Antisense RNA: function and fate of duplex RNA in cells of higher eukaryotes

There is ample evidence that cells of higher eukaryotes express double-stranded RNA molecules (dsRNAs) either naturally or as the result of viral infection or aberrant, bidirectional transcriptional readthrough. These duplex molecules can exist in either the cytoplasmic or nuclear compartments. Cells have evolved distinct ways of responding to dsRNAs, depending on the nature and location of the duplexes. Since dsRNA molecules are not thought to exist naturally within the cytoplasm, dsRNA in this compartment is most often associated with viral infections. Cells have evolved defensive strategies against such molecules, primarily involving the interferon response pathway. Nuclear dsRNA, however, does not induce interferons and may play an important posttranscriptional regulatory role. Nuclear dsRNA appears to be the substrate for enzymes which deaminate adenosine residues to inosine residues within the polynucleotide structure, resulting in partial or full unwinding. Extensively modified RNAs are either rapidly degraded or retained within the nucleus, whereas transcripts with few modifications may be transported to the cytoplasm, where they serve to produce altered proteins. This review summarizes our current knowledge about the function and fate of dsRNA in cells of higher eukaryotes and its potential manipulation as a research and therapeutic tool.

Nuclear and polysomal transcripts of T-DNA in octopine crown gall suspension and callus cultures

To establish a detailed map of the transcribed parts of the T-DNA in two octopine crown gall lines grown in suspension culture, T-DNA-derived steady-state nuclear and polysomal RNA as well as RNA synthesized in isolated nuclei purified from the crown gall tissues, was analyzed by southern blot hybridization to specific fragments of the T-region of the octopine plasmid pTi ACH5. In addition total RNA isolated from the same lines grown as callus tissue on solid agar, was analyzed for T-DNA specific transcripts. The results show that all of the T-DNA is transcribed although different segments are transcribed to significantly different extents. Roughly the same hybridization pattern was found for nuclear and polysomal poly-A+ and poly-A- RNA. The transcription pattern was found to be different for cells in the stationary phase of growth compared with actively growing cells.

Simian virus 40 transcriptional complexes incorporate mercurated nucleotides into RNA in vitro

Simian virus 40 Sarkosyl transcriptional complexes incorporated mercurated nucleotide precursors into preinitiated RNA chains. Synthesis with mercurated precursors was three- to fivefold slower than with nonmercurated nucleotides (12 to 20 pmol per 10(6) cells per h at 25 degrees C), and 50 to 70% of the RNA product bound specifically to sulfhydryl-agarose. The amount of mercurated CMP incorporated into RNA was measured by specific binding of [35S]cysteine to the mercury residues. More than 90% of the mercurated RNA hybridized to simian virus 40 DNA.

On pre-messenger RNA and transcriptions. A review

From the present review integrating old and new data emerge a few principles of gene expression in eukaryotes, and an infinite variety of possible mechanistic details generating the overal pattern. The few principles, most of which are not fundamentally new, may thus be summarized. 1) The eukaryotic genome is subdivided into transcriptional units: into transcriptons which are subject to individual activation controlled at DNA level. 2) Viral genomes may contain one or a few transcriptons, while cells of multicellular organisms contain from 3 x 10(3) in diptera up to an estimated 2 x 10(5) in birds and mammals. 3) Transcriptons may include one or several coding sequences. 4) Transcriptons vary considerably in size: in mammals and birds their size spectrum falls into the 2,000 to 20,000 bp range. 5) Units of coding information constituting one message (genes) and, possibly, units of regulative information are frequently broken up and stored within the transcripton in sub-genic blocks (of so far unknown significance) in general located at a certain distance from the 5' and 3' transcript terminals which are determined by the promotor and terminator signals. 6) The gene, in its specific definition as the functional unit underlying the phenotype, is in general constituted posttranscriptionally by the processing mechanisms from the mosaic of its genomic subunits in the transcripton; segments of coding, service and regulative sequences are recombined within themselves and with each other, polygenic transcripts separate into their unit messages. 7) Activated transcriptons produce pre-mRNA; these primary transcripts are colinear with the DNA of the transcriptional unit. 8) Primary pre-mRNA is processed into secondary pre-mRNA's by extragenic cleavage and intragenic ("splicing") processing, giving rise stepwise to functional mRNA. During this process chemical modifications as methylation, 5'-terminal capping and 3'-terminal polyadenylation take place. 9) Translation yields either potentially functional polypeptides or polycistronic polyproteins subject to further processing. 10) Processing is a regulated process; it involves many of the possible phases and mechanisms of post-transcriptional regulation (cf. 39, 40).

Intermolecular duplexes formed from polyadenylylated vaccinia virus RNA

Approximately 15% of the polyadenylic acid-containing cytoplasmic RNA labeled from 5 to 7 h after vaccinia virus infection formed intermolecular duplex structures characterized as double-stranded RNA by RNase resistance, density in Cs2SO4, base composition, chromatography on cellulose, and ability to inhibit reticulocyte cell-free protein synthesis. Both sucrose gradient sedimentation and electron microscopic analysis indicated that the double-stranded regions were several hundred to more than a thousand nucleotide base pairs long. The double-stranded RNA, after denaturation, hybridized to approximately 25% of the vaccinia virus genome, whereas total late RNA hybridized to 42%. The finding that the duplex RNA, after denaturation, hybridized to most HindIII restriction endonuclease fragments of vaccinia virus DNA indicated that symmetrical transcription is not confined to the terminal inverted repeat sequence or to one contiguous region of the genome. Although relatively little labeled, early, polyadenylic acid-containing RNA formed RNase-resistant hybrids upon self-annealing, the percentage increased upon addition of unlabeled late RNA, indicating that the latter contains "anti-early" sequences.

Evidence that the RNA polymerase usually does not make a complete transcript of the late strand of simian virus 40 DNA

An important model for the transcription of the late (L) strand of simian virus 40 DNA is that, late after infection of permissive monkey cells, the RNA polymerase makes a complete transcript of the L DNA strand before terminating transcription. The purpose of the current work was to test a prediction of this model, namely, that the rate of synthesis of all RNA sequences from the L DNA strand should be equal. About one-half of the L DNA strand is transcribed into late mRNA sequences and the other half into late dRNA sequences, which do not leave the nucleus. Using glucosamine to reduce the size of the intracellular UTP pool before and after a pulse-label with radioactive uridine, a pulse-chase experiment was performed to determine the half-lives of these sequences. The half-life of the late dRNA sequences was determined to be 4 min. The late mRNA sequences were degraded more slowly, on the average, than the late dRNA sequences. In a parallel experiment with similarly treated cells, it was shown that after a 2-min label with radioactive uridine there was only 0.2 times as much radioactivity in the late dRNA sequences as in the late mRNA sequences in the total cellular RNA population. The results could be combined to calculate that the rate of synthesis of the late dRNA sequences was at most 0.3 times that of the late mRNA sequences. Consequently they provide strong evidence that when the RNA polymerase transcribes the late mRNA sequences, it usually terminates transcription before all the late dRNA sequences are transcribed.

Proteins bound to heterogeneous nuclear RNA of simian-virus-40-infected cells

Heterogeneous nuclear RNA . protein (hnRNA . protein) complexes from simian-virus-40 (SV40)-infected cells late in infection contain 7--10% RNA sequences specific to SV40 DNA. The SV40 nuclear RNA . protein complexes sediment at 60--70 S. The reality and specificity of the RNA-protein association is shown in metrizamide gradients. Protein and RNA lebels of hnRNA . protein-particles in SV40-infected cells follow a parallel pattern with a peak at 1.28 g/cm2 whereas a mixture of ribosomal RNA and soluble cytoplasmic proteins is separated according to the different densities in metrizamide. Analysis of hnRNA . protein from infected cells by two-dimensional gel electrophoresis shows the presence of a number of new proteins. It is demonstrated that three of these proteins are cellular ones induced by the virus infection and hence constitute good candidates to be specific RNA . protein particles for virus nuclear RNA. The presence of actin in hnRNA . protein particles from normal and SV40-infected cells and the presence of the major capsid protein VP1 in hnRNA . protein particles from SV40-infected cells is discussed.

Characterization of early simian virus 40 transcriptional complexes: late transcription in the absence of detectable DNA replication

Isolation of early viral transcriptional complexes and incorporation in vitro of radiolabeled precursors into nascent RNA has permitted an analysis of early simian virus 40 (SV40) transcription. Under conditions such that viral DNA replication was undetectable, both early and late SV40 RNA were synthesized. This finding provides evidence that viral DNA replication is not an absolute requirement for late transcription and supports earlier observations that late viral RNA is synthesized in SV40-infected nonpermissive mouse cells. The majority of the early viral transcriptional activity can be solubilized, indicating that a substantial portion of this RNA is transcribed from free rather than integrated templates. Sedimentation analysis of the transcriptional complexes resulted in the detection of two separate peaks of activity, suggesting the possibility of two distinct types of early SV40 templates.

The control of SV40 transcription during a lytic infection: late RNA synthesis in the presence of inhibitors of DNA replication

The transition from early to late transcription of SV40 DNA in productively infected BSC-1 cells was analyzed using both inhibitors of DNA replication, and early (Group A) temperature sensitive (ts) mutants of SV40. Late virus specific cytoplasmic RNA sedimenting at 16S in neutral sucrose gradients and complementary to the plus (L) DNA strand of SV40 was detected in cultures infected in the presence of three inhibitors of DNA replication (Ara-C, FdU, and chloroquine), even though the inhibition of viral DNA replication appeared to be essentially complete. After infection with the early SV40 mutant tsA58, no DNA replication was detected at the restrictive temperature (41 degrees C) and no significant late RNA complementary to the plus (L) strand was found, in either the cytoplasm or nuclei of infected cells. These data support the concept that expression of late viral functions requires the initiation of viral DNA synthesis or a functional gene A protein, or both.

Molecular and genetic approaches to the analysis of the informational content of the mitochondrial genome in mammalian cells

Our laboratory has been involved in the last few years in investigations aiming at analysing by molecular approaches the informational content of the mitochondrial genome in mammalian cells and the mechanisms and control of its expression, H eLa cells and other mammalian cell lines have been utilized for these studies. These investigations, as well as work carried out in other laboratories, have yielded a considerable amount of information concerning the mechanism, products and regulation of transcription of mitochondrial DNA (mit-DNA), the apparatus and products of mitochondria-specific protein synthesis in animal cells, and the number and topology of the sites on mit-DNA which code for the primary gene products identified so far. It is the purpose of the present report to summarize the latest observations in this area, as well as some recent results on the isolation and characterization of chloramphenicol-resistant variants of a human cell line. Reference is made to previous review articles 1,2,3 for the earlier work.

Isolation and characterization of DNA-DNA and DNA-RNA

A simple method for the isolation and characterization of DNA-DNA and DNA-RNA hybrid molecules formed in solution was developed. It was based on the fact that, in appropriate salt concentration, such as 5% Na2HPO4, DNA in either double-stranded (DNA-DNA or DNA-RNA) or single-stranded forms, but not free nucleotides, can bind to diethylaminoethylcellulose disc filters (DE81). Thus tested samples were treated with the single-strand-specific nuclease S1 and then applied to DE81 filters. The free nucleotides, resulting from degrading the single-stranded molecules, were removed by intensive washing with 5% Na2HPO4, leaving only the hybrid molecules on the filters. The usefulness of this method was illustrated in dissociation and reassociation studies of viral (SV40) or cellular (NIH/3T3) DNAs and DNA-RNA hybrid molecules. Using this technique the reassociation of denatured SV40 DNA was found to be a very rapid process. Dissociation studies revealed that the melting curves of tested DNAs were dependent on salt concentration. Thus the melting temperatures (tm) obtained for SV40 DNA were 76 degrees C at 1 X SSC (0.15 M NaCl-0.015 M sodium citrate) and 65 degrees C at 0.1 X SSC, and for NIH/3T3 DNA 82 degrees C at 1 X SSC and 68 degrees C at 0.1 X SSC. MuLV DNA-RNA hybrid molecules were formed by annealing in vitro synthesized MuLV DNA with 70S MuLV RNA at 68 degrees C. The melting temperature of this hybrid in the annealing solution was 87 degrees C. Another important feature of this procedure was that, after being selectively bound to the filters, the hybrid molecules could efficiently be recovered by heating the filters for 5 min at 60 degrees C in 1.5-1.7 M KCl. The recovered molecules were intact hybrids as they were found to be completely resistant to S1 nuclease.

RNA complementary to the genome of RNA tumor viruses in virions and virus-producing cells

Cells producing type C (avain sarcoma virus) or type B (mouse mammary tumor virus) RNA tumor viruses contain small amounts of RNA complementary to the viral genomes. The negative strands are complementary to at least 30 to 45% of the viral genomes and are found as RNA-RNA duplexes in the nucleus and cytoplasm of infected cells and in mature virions.

Genome localization of simian virus 40 RNA species

The topographical locations on the simian virus 40 (SV40) genome of the templates for virus-specific RNA species present late in the lytic infection were determined by RNA-DNA hybridization experiments with the Hind restriction enzyme fragments. Two classes of late virus-specific cytoplasmic mRNA's can be separated on the basis of either sedimentation properties in neutral sucrose or electrophoretic mobility in polyacrylamide gels. In the 16S class, two species of RNA were identified by hybridization experiments. One of these species was complementary to sequences of the early template on the minus (E) strand (0.175 to 0.655 map units), and the other more abundant species was complementary to sequences present in the late template on the plus (L) strand (0.655 to 0.175 map units). In addition two species were detected in the 16S class of late cytoplasmic virus-specific mRNA. One of these species was the major late RNA detected and consisted of a polyadenylated transcript complementary to the plus (L) DNA strands of Hind fragments K, F, J, and G (0.945 to 0.175 map units). This species appears to specify the major capsid protein (VP1). A less abundant nonpolyadenylated 16S RNA species complementary to the plus (L) strands of Hind fragments C, D, and E (0.655 to 0.945 map units) may result from post-transcriptional processing or nonspecific degradation of the 19S viral RNA complementary to the plus (L) strand.

Orientation of the complementary strands of polyoma virus DNA with respect to the DNA physical map

The chemical polarities of the two strands of polyoma virus DNA with respect to the DNA physical map have been determined by hybridization of restriction endonuclease fragments specifically labeled with [125I]dCMP at their 3' termini to asymmetric polyoma complementary RNA (the product of in vitro transcription of viral DNA by Escherichia coli RNA polymerase). The orientations of the polyoma-specific stable RNA transcripts present in the cytoplasm of productively linfected mouse cells have been deduced from this result: the 5' ends of the early and late viral transcripts map very near the origin of viral DNA replication.

Strand-specific transcription of polyoma virus DNA-early in productive infection and in transformed cells

The DNA strand origin of nuclear and cytoplasmic polyoma-specific RNA in productively infected mouse cells and in a line of polyoma-transformed hamster cells was determined by hybridization of unlabeled RNA with radioactively labeled separated strands of polyoma DNA. Early in the productive cycle (10 h postinfection) nuclear viral RNA is complementary to only about 40% of the E strand of viral CNA. No RNA complementary to the L strand was detected even when the RNA was first self-annealed to enrich for possible minor species. Early cytoplasmic RNA is complementary to the same 40% of the E strand. Thus, only that part of the poloma genome which codes for early virual messenger RNA appears to be transcribed. Late in infection, nuclear viral RNA is complementary to most or all of the L strand and to at least 60% of the E strand. Late cytoplasmic viral RNA hybridizes to 40 to 45% of the E strand and 50 to 55% of the L strand. The transformed cell nuclear viral RNA is complementary to 60% of the E strand, whereas cytoplasmic RNA is complementary to 40% of the E strand and comprises the same polyoma-specific sequences as are found in RNA early in productive infection. No L strand transcripts could be detected. Thus, in the transformed cells and late in productive infection, viral RNA sequences in the cytoplasm are a specific subset of those in the nucleus.

Transcription of simian virus 40. V. Regulattion of simian virus 40 gene expression

RNA "exhaustion type" hybridization was used to measure the complementarity of nuclear and cytoplasmic viral RNA to the early (E) and late (L) simian virus 40 (SV40) DNA strands. This type of hybridization measures the amount of labeled RNA complementary to each of the two DNA strands, rather than the fraction of each SV40 DNA strand that is homologous to SV40 RNA. At 48 h after infection, about 5% of the nuclear newly synthesized viral RNA was complementary to the E-strand (- strand) and 95% was complementary to the L-strand (+ strand). This proportion was independent of the labeling time, indicating similar accumulation of the E- and L-RNA transcripts in the nucleus. The nuclear E- and L-viral RNA transcripts sedimented in a similar manner on sucrose gradients. Of the cytoplasmic viral RNA only about 1% was complementary to the E-strand, these molecules sedimenting at 19S, whereas 99% were complementary to the L-strand and sedimented at 19S and 16S. The abundance of E-RNA transcripts in nuclei of cells infected with serially passaged virus was about four times higher than that in nuclei of cells infected with plaque-purified virus; however, the size and proportion of the corresponding cytoplasmic E- and L-RNA transcripts was independent of the type of virus used to infect the cells. According to these results at least two control mechanisms regulate viral gene expression in productively infected cells, one operates at the trnascriptional level and the second at the post-transcriptional level.

RNAs of simian virus 40 in productively infected monkey cells: kinetics of formation and decay in enucleate cells

We demonstrate here the usefulness of cytochalasin B enucleate cells for the study of the metabolism of cytoplasmic mRNA and for determining its half-life in animal cells. Simian virus 40 infected monkey cells in which the RNA had been labeled with [3H]uridine were enucleated, and the decay of the two prominent RNAs of simian virus 40, the 19S and 16S species, was measured by analysis on sucrose gradients. The results of these experiments, together with kinetic analysis of nuclear and cytoplasmic viral RNA, indicate a precursor-product relationship between the 19S and 16S cytoplasmic viral RNA species, which decay by first-order kinetics with a mean half-life of about 3 hr and 6 hr, respectively.

Methylated simian virus 40-specific RNA from nuclei and cytoplasm of infected BSC-1 cells

Host cell and virus-specific poly(A)-containing RNAs isolated from nuclei and cytoplasm of monkey kidney cells infected with simian virus 40 contain different methylated nucleotides. In the cytoplasmic simian virus 40-specific RNA, about 75% of the radioactivity derived from (methyl-3-H)methionine was in N-6-methyladenosine (N-6mA) after digestion with Penicillium nuclease and bacterial alkaline phosphatase. The remainder was in a negatively charge component with properties of 5'-terminal structures, i.e., digestion with nucleotide pyrophosphatase and bacterial alkaline phosphatase released 2'-O-methyladenosine (A-m), 2'-O-methylguanosine (G-m), and 7-methylguanosine (m-7-G), consistent with a 5'-terminal structure of the type, m7-GpppNm. The nuclear virus-specific RNA contained N6mA, GM, 2'-O-methyluridine (U-m), and a smaller proportion (10%) of nuclease-, phosphatase-resistant presumptive 5' termini that also yielded A-m, G-m, and m7-G upon further hydrolysis. The infected cell nuclear and cytoplasmic RNAs that did not hybridize to DNA of simian virus 40 contained all four 2'-O-methylnucleosides. The possible role of methylation in the processing and translation of simian virus 40-specific mRNA is discussed.

Properties of cells transformed by DNA tumor viruses

Transformation by the papovaviruses, SV40 and polyoma, is reviewed briefly, including factors that affect the frequency of transformation. Virus markers useful in the determination of the etiology of virus-free tumors are described, including viral DNA, viral mRNA, virus-induced antigens, and the rescue of infectious virus. Finally, the evidence that viral genes are involved in the maintenance of transformation is presented.

RNA synthesis in cells infected with herpes simplex virus. X. Properties of viral symmetric transcripts and of double-stranded RNA prepared from them

HEp-2 cells infected with herpes simplex 1 virus contain RNA transcripts capable of forming double-stranded (DS) RNA on annealing. The properties of purified DS RNA were as follows (i) DS RNA is resistant to depolymerization by RNase A or T-1 in 2 times 0.15 M NaCl, plus 0.015 M sodium citrate (SSC) but not 0.1 times SSC or following thermal denaturation. (ii) The Tm of the viral DS RNA was 100 C in 0.1 times SSC. (iii) Undenatured DS RNA does not hybridize with viral DNA: upon denaturation, excess unlabeled RNA drove 50 to 55% of labeled DNA into DNA-RNA hybrid. The kinetics of hybridization indicate that the DS RNA consists of at least two populations of transcripts arising from 29 and 26% of viral DNA and differing 40-fold in molar concentration.

Posttranscriptional selection of simian virus 40-specific RNA

Analysis of the viral-specific RNA in simian virus 40(SV40)-infected monkey kidney cells indicated the extensive transcription of both DNA strands. These symmetrically transcribed sequences were localized in the nucleus of infected cells, whereas only the "true" early and late SV40 transcripts were found in the cytoplasm. These results suggest that selective posttranscriptional degradation and/or transport occurs after transcription of the viral DNA. On the basis of hybridization experiments with cytoplasmic RNA and the separated strands of the SV40 Hin fragments, the early SV40 region appears to include all of Hin fragments A, H, I, and B (48% of the genome), whereas the late region is represented in Hin fragments C, D, E, K, F, J, and G (52% of the genome).

RNA synthesis in cells infected with herpes simplex virus. IX. Evidence for accumulation of abundant symmetric transcripts in nuclei

RNA extracted from nuclei of 8-h infected cells drove approximately 50% of herpes virus DNA into DNA-RNA hybrid. The same RNA, preannealed under conditions which allowed base pairing to take place, drove only 35% of the DNA into DNA-RNA hybrid; further annealing of the RNA did not diminish the amount of RNA sequences remaining available for subsequent hybridization with DNA. Upon denaturation of the preannealed RNA, the RNA sequences sequestered during preannealing became available again for hybridization with DNA. The base pairing that occurred during preincubation of the RNA was inter-molecular, since it was RNA concentration dependent and was not affected by limited alkaline hydrolysis. The nuclear viral transcripts that remained available for hybridization, after preannealing of the RNA, were subset of the RNA sequences that accumulated in the cytoplasm of infected cells. In addition, a small amount (derived from 5% or less of the viral DNA) of complementary transcripts was detected in the cytoplasm.

Synthesis of complementary RNA sequences during productive adenovirus infection

Liquid RNA.DNA hybridization with separated strands of adenovirus type 2 DNA revealed that late nuclear RNA can hybridize to about 85% of the 1-strand and 10-15% of the h-strand, whereas late cytoplasmic RNA hybridizes to 65-70% and 25% of the l- and h-strand, respectively. With separated strands from the six EcoRI fragments of adenovirus type 2 DNA as probes, it was shown that late nuclear RNA hydridizes to 85-90% of the l-strand from all six EcoRI fragments. Since late cytoplasmic RNA hybridizes to 40-50% of the h-strand from both fragments EcoRI-B and EcoRI-C, complementary viral RNA sequences are synthesized during adenovirus infection. Complementarity between nuclear and cytoplasmic RNA could also be demonstrated by showing that late cytoplasmic RNA which had been preincubated with late nuclear RNA hybridized to a smaller fraction of the h-strand of fragment EcoRI-C than without preincubation. Double-stranded RNA which contains sequences that correspond to at least 60% of the viral genome was isolated from infected cells. However, less than 2% of the newly synthesized late RNA became double-stranded after incubation under annealing conditions, which suggests that RNA derived from one of the strands is present at a low concentration. Accordingly, it was shown that nearly all viral cytoplasmic RNA which is synthesized late after infection is derived from the l-strand.

Viral DNA-RNA hybrids in cells infected with simian virus: the simian virus 40 transcriptional intermediates

Brief labeling of cells infected with simian virus 40 with tritiated uridine resulted in the incorporation of part of the label into material that was soluble in 1 M NaCl and sensitive to KOH, with a buoyant density close to that of DNA. The properties of this material suggest that it represents single-stranded nascent molecules of messenger RNA of simian virus 40 hydrogen-bonded over a small portion of their length to viral DNA templates. The name "simian virus 40 transcriptional intermediate molecules" is suggested for these naturally occurring DNA.RNA hybrid molecules. The DNA in the hybrid seems to be in the form of replicative intermediate molecules.

Studies of nondefective adenovirus 2-simian virus 40 hybrid viruses. IX. Template topography in the early region of simian virus 40

The DNAs of the five nondefective adenovirus 2 (Ad2)-simian virus 40 (SV40) hybrid viruses contain overlapping segments of the early region of wild-type SV40 DNA. The complementary DNA strands of these five viruses have been separated with synthetic polyribonucleotides in isopycnic cesium chloride gradients. The relative amounts of early and late SV40 template in the DNA of each virus were determined by RNA-DNA hybridization with late lytic SV40 RNA, which contains sequences complementary to both templates. From the distribution of early and late templates in the five overlapping SV40 segments, we conclude that either the entire early region of SV40 is symmetrically transcribed in vivo, or, more probably, that the early SV40 templates are not contiguous.

Nucleotide sequences of RNA transcribed in infected cells and by Escherichia coli RNA polymerase from a segment of simian virus 40 DNA

The nucleotide sequence of 180 residues of an RNA transcript of DNA of simian virus 40 has been deduced. This sequence adjoins a preferred initiation site for E. coli RNA polymerase. Comparison of this sequence with that of complementary RNA of simian virus 40 from infected cells has shown that this site also adjoins the apparent 3' terminus of some of the cytoplasmic complementary RNA of simian virus 40.