Synthesis of all the gene products of the reovirus genome in vivo and in vitro

Captivating Perplexities of Spinareovirinae 5' RNA Caps

RNAs with methylated cap structures are present throughout multiple domains of life. Given that cap structures play a myriad of important roles beyond translation, such as stability and immune recognition, it is not surprising that viruses have adopted RNA capping processes for their own benefit throughout co-evolution with their hosts. In fact, that RNAs are capped was first discovered in a member of the Spinareovirinae family, Cypovirus, before these findings were translated to other domains of life. This review revisits long-past knowledge and recent studies on RNA capping among members of Spinareovirinae to help elucidate the perplex processes of RNA capping and functions of RNA cap structures during Spinareovirinae infection. The review brings to light the many uncertainties that remain about the precise capping status, enzymes that facilitate specific steps of capping, and the functions of RNA caps during Spinareovirinae replication.

Expression of wound tumor virus gene products in vivo and in vitro

Infection of Agallia constricta vector cell monolayers with wound tumor virus results in the synthesis of 12 virus-specific polypeptides. Confirmation that these polypeptides are virus encoded rather than virus induced was obtained by cell-free translation of in vitro synthesized viral mRNA. In addition, transcription by purified wound tumor virus particles was coupled with translation of the resulting transcripts in a wheat embryo cell-free extract. Six previously described structural polypeptides, one presumptive structural polypeptide, and five previously unidentified nonstructural polypeptides were synthesized in infected vector cell monolayers, in cell-free extracts directed by in vitro synthesized viral mRNA, and in the homologous plant cell-free system, in which viral transcription was coupled with translation. Pulse-chase experiments revealed no evidence of precursor-product relationships for the wound tumor virus-specific polypeptides.

Mammalian orthoreovirus particles induce and are recruited into stress granules at early times postinfection

Infection with many mammalian orthoreovirus (MRV) strains results in shutoff of host, but not viral, protein synthesis via protein kinase R (PKR) activation and phosphorylation of translation initiation factor eIF2alpha. Following inhibition of protein synthesis, cellular mRNAs localize to discrete structures in the cytoplasm called stress granules (SGs), where they are held in a translationally inactive state. We examined MRV-infected cells to characterize SG formation in response to MRV infection. We found that SGs formed at early times following infection (2 to 6 h postinfection) in a manner dependent on phosphorylation of eIF2alpha. MRV induced SG formation in all four eIF2alpha kinase knockout cell lines, suggesting that at least two kinases are involved in induction of SGs. Inhibitors of MRV disassembly prevented MRV-induced SG formation, indicating that viral uncoating is a required step for SG formation. Neither inactivation of MRV virions by UV light nor treatment of MRV-infected cells with the translational inhibitor puromycin prevented SG formation, suggesting that viral transcription and translation are not required for SG formation. Viral cores were found to colocalize with SGs; however, cores from UV-inactivated virions did not associate with SGs, suggesting that viral core particles are recruited into SGs in a process that requires the synthesis of viral mRNA. These results demonstrate that MRV particles induce SGs in a step following viral disassembly but preceding viral mRNA transcription and that core particles are themselves recruited to SGs, suggesting that the cellular stress response may play a role in the MRV replication cycle.

Multiple-color fluorescence imaging of chromosomes and microtubules in living cells

Microscopic observation of fluorescently-stained intracellular molecules within a living cell provides a straightforward approach to understanding their temporal and spatial relationships. However, exposure to the excitation light used to visualize these fluorescently-stained molecules can be toxic to the cells. Here we describe several important considerations in microscope instrumentation and experimental conditions for avoiding the toxicity associated with observing living fluorescently-stained cells. Using a computer-controlled fluorescence microscope system designed for live observation, we recorded time-lapse, multi-color images of chromosomes and microtubules in living human and fission yeast cells. In HeLa cells, a human cell line, microtubules were stained with rhodamine-conjugated tubulin, and chromosomes were stained with a DNA-specific fluorescent dye, Hoechst33342, or with rhodamine-conjugated histone. In fission yeast cells, microtubules were stained with alpha-tubulin fused with the jellyfish green fluorescent protein (GFP), and chromosomes were stained with Hoechst33342.

Reovirus sigma NS and mu NS proteins form cytoplasmic inclusion structures in the absence of viral infection

Reovirus replication occurs in the cytoplasm of infected cells and culminates in the formation of crystalline arrays of progeny virions within viral inclusions. Two viral nonstructural proteins, sigma NS and micro NS, and structural protein sigma 3 form protein-RNA complexes early in reovirus infection. To better understand the minimal requirements of viral inclusion formation, we expressed sigma NS, mu NS, and sigma 3 alone and in combination in the absence of viral infection. In contrast to its concentration in inclusion structures during reovirus replication, sigma NS expressed in cells in the absence of infection is distributed diffusely throughout the cytoplasm and does not form structures that resemble viral inclusions. Expressed sigma NS is functional as it complements the defect in temperature-sensitive, sigma NS-mutant virus tsE320. In both transfected and infected cells, mu NS is found in punctate cytoplasmic structures and sigma 3 is distributed diffusely in the cytoplasm and the nucleus. The subcellular localization of mu NS and sigma 3 is not altered when the proteins are expressed together or with sigma NS. However, when expressed with micro NS, sigma NS colocalizes with mu NS to punctate structures similar in morphology to inclusion structures observed early in viral replication. During reovirus infection, both sigma NS and mu NS are detectable 4 h after adsorption and colocalize to punctate structures throughout the viral life cycle. In concordance with these results, sigma NS interacts with mu NS in a yeast two-hybrid assay and by coimmunoprecipitation analysis. These data suggest that sigma NS and mu NS are the minimal viral components required to form inclusions, which then recruit other reovirus proteins and RNA to initiate viral genome replication.

Characterization and structural localization of the reovirus lambda 3 protein

The putative reovirus RNA polymerase, protein lambda 3, was characterized using antiserum prepared against a TrpE-lambda 3 fusion protein synthesized in Escherichia coli. Immunofluorescence microscopy showed that lambda 3 accumulated in perinuclear inclusion bodies in reovirus-infected cells. Analysis of lambda 3 accumulation in infected cells indicates that, once synthesized, lambda 3 is quite stable throughout the course of infection. Anti-lambda 3 serum did not immunoprecipitate virions, core particles or iodinated surface proteins of either virions or cores. These results indicate that lambda 3 is located in the inner part of the core. Experiments involving urea denaturation of purified reovirus cores indicate that lambda 3 cannot be selectively removed from the core without total denaturation of the core structure. When the dsRNA genome was eliminated from the core, lambda 3 remained associated with the other viral proteins in the core. Thus, lambda 3 appears to be a stable, structural component of the reovirus core, not bound to genomic dsRNA or free in soluble form inside the core.

Coding assignments of the genome of adult diarrhea rotavirus

Adult diarrhea rotavirus (ADRV) has caused epidemics of diarrhea in China since 1982 and remains the only group B rotavirus associated with widespread disease in humans. We recently characterized the proteins of ADRV and have now proceeded to identify the gene segments encoding each protein. Viral RNA transcripts were synthesized in vitro with the endogenous viral RNA polymerase and separated by electrophoresis in agarose. The individual transcripts were translated in a cell-free system using nuclease-treated rabbit reticulocyte lysates. The translation products were compared with polypeptides found in purified virus and were characterized by SDS-PAGE, immunoprecipitation, and Western blot analysis using antisera to double- and single-shelled virions, virus cores, and monoclonal antibodies. Furthermore, individual RNA transcripts were hybridized to total dsRNA to determine their genomic origin. Based on this analysis, the core polypeptides VP1, VP2 and VP3 are encoded by segments 1, 2, and 3, respectively. The main polypeptides in the inner capsid, VP6, and the outer capsid, VP4 and VP7, are encoded by segments 6, 4, and 8 respectively. Segments 5, 7, and 9 code for 60, 45, and 30 kDa nonstructural polypeptides. Two other nonstructural polypeptides (24 and 25 kDa) are derived from gene segment 11. Gene segment 10 codes for a 26 kDa polypeptide that is precipitated with serum to ADRV and may be a structural protein VP9. With this exception, gene coding assignments of ADRV are comparable to those of the group A rotaviruses. Our results have clear implications for further work in cloning, sequencing, and expression genes of ADRV and can provide direction towards understanding the origin and the evolution of this virus.

The S2 gene nucleotide sequences of prototype strains of the three reovirus serotypes: characterization of reovirus core protein sigma 2

The S2 gene nucleotide sequences of prototype strains of the three reovirus serotypes were determined to gain insight into the structure and function of the S2 translation product, virion core protein sigma 2. The S2 sequences of the type 1 Lang, type 2 Jones, and type 3 Dearing strains are 1,331 nucleotides in length and contain a single large open reading frame that could encode a protein of 418 amino acids, corresponding to sigma 2. The deduced sigma 2 amino acid sequences of these strains are very conserved, being identical at 94% of the sequence positions. Predictions of sigma 2 secondary structure and hydrophobicity suggest that the protein has a two-domain structure. A larger domain is suggested to be formed from the amino-terminal three-fourths of sigma 2 sequence, which is separated from a smaller carboxy-terminal domain by a turn-rich hinge region. The carboxy-terminal domain includes sequences that are more hydrophilic than those in the rest of the protein and contains sequences which are predicted to form an alpha-helix. A region of striking similarity was found between amino acids 354 and 374 of sigma 2 and amino acids 1008 and 1031 of the beta subunit of the Escherichia coli DNA-dependent RNA polymerase. We suggest that the regions with similar sequence in sigma 2 and the beta subunit form amphipathic alpha-helices which may play a related role in the function of each protein. We have also performed experiments to further characterize the double-stranded RNA-binding activity of sigma 2 and found that the capacity to bind double-stranded RNA is a property of the sigma 2 protein of prototype strains and of the S2 mutant tsC447.

Properties of RNA polymerase activity associated with infectious bursal disease virus and characterization of its reaction products

An RNA-dependent RNA polymerase activity of infectious bursal disease virus (IBDV) could be demonstrated without any special treatment of the virus particles. Ca2+ ions had to be removed from the reaction mixture. Mg2+ (4 mM) was essential for the polymerase activity which was optimal at pH 8.5 and 40 degrees C. The RNA products synthesized in vitro were 24S single-stranded (ss) RNA and 14S double-stranded (ds) RNA which remained closely associated with IBDV particles and which could only be released by proteolytic degradation of the virus. The positions of the two bands in polyacrylamide gels and hybridization with virion RNA identified the 14S RNA as the two genomic dsRNA segment. The 24S ssRNA also formed two bands, did not self-anneal, hybridized with virion RNA, and induced in vitro translation of virus-specific polypeptides. Therefore, this product was considered to be newly transcribed mRNA.

Poly(riboadenylic acid) preferentially inhibits in vitro translation of cellular mRNAs compared with vaccinia virus mRNAs: possible role in vaccinia virus cytopathology

Vaccinia virus-induced inhibition of host protein synthesis seems to be mediated by viral transcripts based on their differential inhibition of cellular mRNA translation in a rabbit reticulocyte lysate system. In this study, we demonstrated that the removal of poly(riboadenylic acid) [poly(A)] from the in vitro viral transcripts abolished this inhibition in the same cell-free system. This observation led us to the finding that less than 1 microM poly(A) completely inhibited HeLa cell mRNA translation in the reticulocyte lysate, whereas only 50% inhibition of vaccinia virus mRNA translation was observed at the same concentration. Similar results were also obtained in a wheat germ protein-synthesizing system. This inhibitory effect of poly(A) was totally abrogated by the addition of polydeoxythymidylate. This selective inhibition was highly specific for poly(A) since other homopolymers, including poly(G), poly(C), and poly(dA), were not capable of causing such an inhibition. Poly(U), however, had a moderate selective inhibitory effect. Among the several mRNAs tested, the translation of L-cell, encephalomyocarditis virus, and reovirus RNAs was also sensitive to poly(A). However, vesicular stomatitis virus mRNA translation was strikingly more resistant. These results suggest that poly(A), which is also synthesized by the virion-associated poly(A) polymerase may be involved in vaccinia virus-mediated host cell shutoff.

Sequence of reovirus haemagglutinin predicts a coiled-coil structure

The use of modern techniques has led to new insights into the molecular mechanisms of viral pathogenesis. Although the infectious process is quite complex, it is clear that one critical stage, the interaction of viral attachment proteins with cell-surface receptors, often has a major role in determining the pattern of infection. The mammalian reoviruses have served as useful models for understanding the molecular basis of viral pathogenesis. The mammalian reovirus haemagglutinin (sigma 1 protein), which is an outer capsid protein, has been shown to be a major factor in determining virus-host cell interactions. To further our understanding of the structure and function of the haemagglutinin, we have cloned a complementary DNA copy of the reovirus type 3 S1 double-stranded RNA gene which encodes the virus haemagglutinin and have sequenced the DNA complementary to the S1 gene. Analysis of the predicted amino-acid sequence of the virus haemagglutinin has allowed us to determine that the amino-terminal portion contains an alpha-helical coiled-coil structure and that the carboxy-terminal portion contains the receptor-interacting domains. Using this information, we propose here a model of how the reovirus haemagglutinin is attached to the virus particle.

Virus myocarditis: molecular hybridization allows the detection of virus-RNA in heart muscle after virus infection

In most patients with virus myocarditis, the diagnosis is still based on clinical data alone. Endomyocardial biopsies subjected to electron microscopy, immunofluorescence techniques and virus isolation procedures provide additional, but only occasionally conclusive information. In this communication we describe a new method which could possibly be used to improve the diagnostic possibilities in patients with suspected virus myocarditis. The method is based on the hybridization of radioactive complementary nucleotide sequences to virus-RNA. It is shown that in an experimental model (reovirus infected baby mice) this method can be used to demonstrate the virus infection of cardiac muscle. It is suggested that the method could be adapted to other viruses (e.g. coxsackie virus) and to endomyocardial biopsies derived from patients with suspected virus myocarditis.

Anti-idiotypic antibody identifies the cellular receptor of reovirus type 3

The binding and subsequent infectivity of reovirus to target cells are mediated by interaction with specific cell surface viral receptors. To gain a more detailed understanding of the biochemistry of the reovirus receptor and the cellular consequences of viral attachment, we have studied the binding of type 3 reovirus (Dearing strain) in a quantitative manner utilizing an antiidiotypic antibody probe. A syngeneic monoclonal antiidiotypic antibody (87.92.6) was prepared by immunization with hybridoma cells which secrete an antireovirus hemagglutinin-specific antibody. This antiidiotypic antibody was previously shown to specifically recognize the cell surface receptor for reovirus type 3. In this report, we demonstrate that antiidiotype mimicked reovirus tropism in binding to murine thymomas; antiidiotype inhibited the binding of reovirus to specific targets, but not the binding of anti-H-2; and cross linking of receptor-bound antiidiotype by antiimmunoglobulin induced patching, but not capping of reovirus receptors. Utilizing radiolabeled antiidiotype, we next quantitate the number of reovirus receptors on R1.1 and YAC thymoma cells and, finally, report on the preliminary identification of the reovirus receptor as a 67,000-Da membrane glycoprotein.

Discriminatory inhibition of protein synthesis in cell-free systems by vaccinia virus transcripts

The effect of vaccinia virus early transcripts on cellular (globin, HeLa, Chinese hamster ovary) and viral (vaccinia, encephalomyocarditis) mRNA function was studied in reticulocyte and wheat germ cell-free protein-synthesizing systems. Vaccinia virus transcripts of two size classes (8-10 S and 4-7 S), generated in vitro by viral cores, inhibited function of cellular and encephalomyocarditis virus mRNA but not that of vaccinia virus in reticulocyte lysate systems. Mild alkaline hydrolysis or micrococcal nuclease treatment of vaccinia virus in vitro transcripts resulted in a loss of their ability to inhibit protein synthesis directed by HeLa cell RNA. Vaccinia virus in vitro transcripts also selectively inhibited HeLa cell protein synthesis in wheat germ systems, suggesting that double-stranded RNA is not involved in this inhibition of protein synthesis. The addition, to the reticulocyte translating system, of cytoplasmic RNA obtained from infected cells in conjunction with cellular mRNA (globin, HeLa) resulted in the inhibition of synthesis of the globin or HeLa polypeptides with little or no effect on the translation of the vaccinia virus proteins. RNA extracted from vaccinia virions inhibited cellular but not vaccinia virus mRNA function when added to the reticulocyte lysate systems with uninfected or infected HeLa cell cytoplasmic RNA.

Genetic and molecular mechanisms of viral pathogenesis: implications for prevention and treatment

The pathogenesis of infection of mice by the mammalian reoviruses involves several discrete steps. Each of the three viral outer capsid proteins has a highly distinct and specialized role: one protein (sigma 1) binds to cell surface receptors; a second protein (mu 1C) determines the capacity for viral growth at mucosal surfaces; and the third protein (sigma 3) is responsible for inhibiting cell macromolecular synthesis. A detailed picture of the molecular basis of reovirus virulence and attention is now emerging.

Avian reovirus polypeptides: analysis of intracellular virus-specified products, virions, top component, and cores

Avian reovirus-specified polypeptides can be separated into three size classes: large (lambda), medium (mu), and small (sigma), similar to those of the mammalian reoviruses. A nomenclature has been proposed to indicate the individual polypeptides within each size class by progressive alphabetical subscripts. Three lambda polypeptides (lambda(A), lambda(B), and lambda(C)) are found in infectious viral particles and have molecular weights of 145,000, 130,000, and 115,000, respectively. All are present in core preparations, and two (lambda(A) and lambda(B)) appear to be exposed at the surface of the virion. Two mu polypeptides can be distinguished in purified virus (mu(A), 72,000 daltons; mu(B), 70,000 daltons), and another is occasionally evident by immunoprecipitation from infected-cell extracts (mu(NS)). mu(B) represents the major outer capsid protein and is structurally homologous to mu(1C) of the mammalian reoviruses. No additional mu proteins can be detected, and there is no evidence for a product-precursor relationship among these proteins. Three major sigma proteins are evident in viral particles. sigma(C) has the lowest molecular weight, is part of the outer capsid of the virion, and appears homologous to the mammalian sigma(1) protein. Interestingly, it demonstrates the greatest polymorphism of all the polypeptides among the different avian reoviruses examined. sigma(B) (36,000 daltons) is a major constituent of the outer capsid and, like sigma(C), is exposed to the surface of the virion. sigma(A) (39,000 daltons) appears to be an internal protein. An additional polypeptide band in the sigma class having an apparent molecular weight of 34,000 to 35,000 can be seen under three different conditions: (i) in some S1133 reovirus preparations, particularly after prolonged storage, a new band (sigma(B')) appears with a reduction in intensity of sigma(B), suggesting that sigma(B') is a degradation product of sigma(B); (ii) in polypeptides immunoprecipitated from infected-cell extracts, a major band (sigma(NS)) is apparent migrating just ahead of sigma(B); (iii) in top component preparations from all avian reoviruses examined, a band (sigma(TC)) with mobility identical to that of sigma(NS) represents a major constitutent and appears to be incorporated within the particle itself. The relationship among these three bands is not currently known. Avian reovirus polypeptides are thus in general similar to those found in mammalian reoviruses, but differences do exist which may be important for understanding viral structure and assembly.

Binding to selected regions of reovirus mRNAs by a nonstructural reovirus protein

When assembled into 13--19S particles, the reovirus nonstructural protein sigma-NS selectively binds single-stranded RNAs. Sedimentation analyses combined with binding to nitrocellulose membrane filters showed that 1--2 pmol of reovirus mRNAs from the large, medium, or small size classes saturated in vitro the binding site(s) on 13--19S particles containing 100 pmol of sigma-NS. All mRNA segments in each size class bound to particles, and no mRNAs in one size class excluded the binding of mRNAs in any other class. In competition experiments, the maximal binding of all reovirus mRNAs to particles of sigma-NS was achieved when medium and small mRNAs were bound before the large mRNAs. This preferred order of addition of mRNAs to sigma-NS resulted in a marked increase in the size of some of the complexes. This finding suggests that the addition of large mRNAs last to particles promoted the formation of complexes with more than one RNA segment bound per particle. The 13--19S particles of sigma-NS protected 20- to 40-nucleotide RNA fragments from nuclease digestion. At least one of the protected fragments from mRNAs of each size class included the 3' terminus; the remaining were from internal regions of the mRNAs. The protected RNA fragments rebound to particles during a second or third cycle of binding in a configuration in which they were fully protected from nuclease digestion. We conclude that binding of particles of sigma-NS to reovirus mRNAs was not at random sites but was to specific regions unique for members of each size class.

Synthesis of (2'-5')oligoadenylate and activation of an endoribonuclease in interferon-treated HeLa cells infected with reovirus

Treatment with interferon protected HeLa cells from infection with reovirus. This virus apparently activated an antiviral mechanism that was detected by the presence of (2'-5')oligoadenylate [(2'-5')An] in intact cells. The (2'-5')An was previously shown to activate an endoribonuclease, RNase L. We measured (2'-5')An by a sensitive competition-binding assay in cells infected at different multiplicities and for different lengths of time. Nanomolar concentrations of (2'-5')An were detected in cells infected at a multiplicity of greater than 5 after 2 h of infection, the time at which the infecting virions were uncoated. The level of (2'-5')An increased up to 6 h postinfection but declined afterward. To establish whether viral mRNAs were cleaved by RNase L, we analyzed the RNA extracted from infected cells by a highly specific hybridization assay on Northern blots. Full-sized reovirus mRNAs were detected in control infected cells, but not in interferon-treated infected cells, at 6 h postinfection. At this time, a nuclease activity could be detected in these cells by demonstration of cleavage of rRNA, degradation of cellular mRNA, and polysome breakdown in the presence of emetine. Since this inhibitor freezes ribosomes, cleavage of mRNA between ribosomes could only be accounted for by an endonuclease, presumably RNase L.

Sequences of ribosome binding sites from the large size class of reovirus mRNA

Ribosome-protected fragments from two of the large-sized reovirus mRNAs were recovered from sparsomycin-blocked 80S initiation complexes. The sequence of each protected oligonucleotide was determined. The ribosome binding site of each message includes the m7G cap and a centrally positioned AUG codon. An adenine residue occurs three nucleotides upstream from the initiator codon, thus conforming to the pattern [AG]NNAUG observed for nearly all eucaryotic initiation sites.

Localization of genes for the double-stranded RNA killer virus of yeast

The M double-stranded RNA (ds RNA) genome segment of the cytoplasmically inherited killer virus of yeast codes for two polypeptides when denatured and translated in vitro: a previously known 32,000-dalton peptide and a newly discovered 19,000-dalton peptide (NaDodSO4/polyacrylamide gel electrophoresis). An internal 190-base-pair region of the ds RNA is selectively degraded by S1 nuclease treatment at 65 degrees C, resulting in two ds RNA fragments which contain the termini of the original ds RNA. The larger fragment codes for the 32,000-dalton polypeptide and the smaller fragment codes for the 19,000-dalton polypeptide. Thus, the two gene products of M are encoded by distinct regions of this ds RNA.

Structure and function of the reovirus genome

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Small reovirus particle composed solely of sigma NS with specificity for binding different nucleic acids

We reported previously that polycytidylate [poly(C)]-dependent RNA polymerase activity was a property of small spherical or triangular reovirus-specific particles which sedimented at 13 to 19S and were composed solely of the reovirus protein, sigma NS. Depending on the fraction of cellular extracts from which they were obtained, these particles exhibited marked differences in stability. Most 13 to 19S particles from a particular fraction repeatedly disaggregated into smaller 4 to 5S subunits with no enzymatic activity. Disruption of many particles could be prevented and polymerase activity retained after these particles had bound different single-stranded (ss) RNAs. Our previous results indicated that there was heterogeneity among the 13 to 19S particles in that possession of poly(C)-dependent RNA polymerase activity was a property of only some. Support for this heterogeneity was derived from the demonstration in this report that there were at least three types of binding sites present within particles in any purified preparation: (i) those binding only poly(C); (ii) those binding only reovirus ss RNAs; and (iii) those binding one or the other, but not both at the same time. It is suggested that only those particles able to bind either poly(C) or reovirus ss RNAs had poly(C)-dependent RNA polymerase activity, as reovirus ss RNAs markedly inhibited the polymerase activity. All three size classes of reovirus ss RNAs were equally effective in binding, but once bound, they were not copied. It is possible that heterogeneity in binding capacity of different particles comprised of only one protein, sigma NS, could result from the ability of subunits containing this protein to assemble into slightly different 13 to 19S particles with specificity of binding or polymerase activity conferred by the configuration of the assembled particles. The high capacity of sigma NS to bind many different nucleic acids with some specificity suggests that these particles may act during infection as condensing agents to bring together 10 reovirus ss RNA templates in preparation for double-stranded RNA synthesis.

Role of ATP in binding and migration of 40S ribosomal subunits

Two assays have been devised to demonstrate ATP-dependent migration of 40S ribosomal subunits on messenger RNA. The first is a two-step runoff assay. Reovirus mRNA was initially loaded with 40S subunits by incubation with wheat germ ribosomes in the presence of the antibiotic edeine. During the second phase of the incubation, in which further attachment of ribosomes was inhibited, the preformed complexes were shown to dissociate (presumably by runoff) only if ATP was included in the reaction. A more direct demonstration of ATP-dependent migration of 40S subunits was carried out using 3' end-labeled brome mosaic virus mRNA. In the presence of edeine and ATP, 40S ribosomal subunits were shown to advance all the way to the 3' end of the message, as shown by protection of the labeled 3'-proximal segment against nuclease digestion. Depletion of ATP by the addition of hexokinase prevented this migration. A variety of observations has raised the possibility that attachment of eucaryotic ribosomes to messenger RNA proceeds via a "scanning mechanism." The hypothesis is that a 40S subunit binds initially at or near the 5' terminus of the message and subsequently migrates toward the interior, stopping when it encounters the first AUG triplet. If migration of 40S subunits requires ATP, as the present studies suggest, the scanning mechanism predicts that in a system depleted of ATP a single 40S ribosome should be trapped near the 5' terminus of the message--upstream of the AUG initiator codon. This prediction was confirmed by analyzing binding of wheat germ ribosomes to a synthetic ribopolymer in which the 5'-proximal region (lacking AUG codons) and the AUG-containing segment near the 3' end of the molecule were differentially labeled.

Small reovirus-specific particle with polycytidylate-dependent RNA polymerase activity

We previously reported that virus-specific particles with polycytidylate [poly(C)]-dependent RNA polymerase activity accumulated at 30 degrees C in reovirus-infected cells. These particles sedimented heterogeneously from 300 to 550S and traversed through a 40% glycerol cushion to the pellet in 3 h at 190,000 x g. In the present report, we found that smaller particles with poly(C)-dependent RNA polymerase activity remained in the glycerol cushion. These smaller, enzymatically active particles, when purified, sedimented at 15 to 1S. They were spherical or triangular with a diameter of 11 to 12 nm. They were comprised mostly, and likely solely, of one reovirus protein, sigma NS. No particles with poly(C)-dependent RNA polymerase activity were found in mock-infected cells. Chromatography on the cation exchanger, CM-Sephadex, ascertained that sigma NS was the poly(C)-dependent RNA polymerase and showed its existence in two forms. In one form, it was enzymatically active and eluted from the column at 0.5 M KCl. In the enzymatically inactive state, it did not bind to the column. Our results suggest that the enzymatically active form of sigma NS carries a greater net positive charge than the inactive form. They also suggest that both forms of sigma NS are associated with a particle which has poly(C)-dependent RNA polymerase activity.

In vitro transcription and translation of simian rotavirus SA11 gene products

Rotavirus gene products were examined, with the simian rotavirus SA11 as a model. The endogenous viral RNA-dependent RNA polymerase associated with single-shelled virus particles or with activated double-shelled particles was used to synthesize viral RNA transcripts. Sedimentation velocity sucrose gradient analysis of the RNA transcripts revealed four peaks at 9S, 12S, 14S, and 18S, whereas agarose gel electrophoresis under partially denaturing conditions revealed eight groups of RNA species ranging in molecular weight from 2 x 10(5) to 1.2 x 10(6). The transcripts synthesized in vitro were active in an mRNA-dependent cell-free translation system derived from rabbit reticulocytes. The transcripts directed the synthesis of 11 polypeptides that had molecular weights ranging from 125,000 to 20,000 when analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The products of in vitro translation were compared with polypeptides from purified virus and those synthesized in infected cells. Several of the polypeptides synthesized in vitro were designated as structural polypeptides by comparing the molecular weights determined by polyacrylamide gel electrophoresis analysis or by precipitation with hyperimmune serum prepared against purified virus. Three of the viral structural polypeptides (VP4, -5, and -5a) were not synthesized in vitro as primary gene products, demonstrating that processing must occur for the production of some structural polypeptides. Other in vitro-synthesized polypeptides were tentatively identified as either precursors to the viral glycoproteins or nonstructural polypeptides.

Assignment of reovirus mRNA ribosome binding sites to virion genome segments by nucleotide sequence analyses

All ten reovirus genome RNA segments were radiolabeled at their 3'-termini by incubation with RNA ligase and 32pCp. The extent of radiolabeling was similar for each of the double-stranded RNAs in the genome segment mixture. Radioactivity was equally distributed between the separated plus and minus strands indicating that the 5'-cap in plus strands did not block 3'-end-labeling of minus strands. The 3'-termini of the four S and three M segments included the common sequences: ...U-A-G-C in minus strands and ...U-C-A-U-C in plus strands. By comparing the minus strand 3'-sequences with 5'-sequences of reovirus mRNAs, small-size genome segments S2, S3 and S4 were correlated with the previously sequenced initiation fragments s46, s45 and s54 derived from small class mRNAs. Medium-size genome segments M1, M2 and M3 similarly were correlated with fragments m30, m52 and m44, respectively. The N-terminal amino acid sequences deduced from the mRNA nucleotide sequences can now be assigned to the nascent chains of particular reovirus proteins.

Influence of mRNA secondary structure on binding and migration of 40S ribosomal subunits

Reovirus messenger RNA was modified by reaction with bisulfite (in denaturing conditions) or by incorporation of IMP in place of GMP, thereby irreversibly unfolding the mRNA. Messenger RNA in which the secondary structure was weakened or abolished retained the ability to bind to wheat germ ribosomes, suggesting that conformational features around the AUG codon are not required for ribosome recognition of mRNA. Ribosomes were not able to attach (directly) to spurious internal sites, even in extensively unfolded RNA, indicating that the monocistronic character of eucaryotic messages (in which initiation is limited to a single 5' proximal site) is not simply due to conformational masking of all the internal AUG codons. The secondary structure in eucaryotic messages does contribute to the fidelity of the translation process, however, because when 40S ribosomal subunits were incubated with denatured mRNA they failed to stop at the 5' proximal AUG codon. Extensive migration beyond the 5' region occurred when 40S ribosomes (in the absence of 60S subunits) attached to unfolded mRNA, implying that the secondary structure in native mRNA facilitates correct translation by impeding migration of 40S subunits beyond the 5' proximal initiation region. Secondary structure in mRNA may also modulate the efficiency of translation. Studies with BrUMP-substituted mRNA, in which the secondary structure is enhanced, suggested that the efficiency of mRNA binding to ribosomes decreases as the stability of the secondary structure increases.