Identification of Saint Louis encephalitis virus mRNA.

Saint Louis encephalitis (SLE) virus-specific RNA was recovered from infected HeLa cells by sodium dodecyl sulfate (SDS)-phenol-chloroform extraction, and the molecular species were resolved by SDS-sucrose gradient centrifugation and agarose gel electrophoresis. Sucrose gradient centrifugation revealed the presence of a 45S species, minor 20 to 30S heterogeneous species, and an 8 to 10 S RNA species in the cytoplasmic extract. Analysis of the same samples by electrophoresis on agarose gels, under both nondenaturing and denaturing conditions, revealed only two virus-specific RNA molecules, the 45S genome-sized RNA and an 8 to 10S species. Varying the gel concentration to facilitate analysis of nucleic acids with molecular weights ranging from 25,000 to 25 X 10(6) failed to reveal additional RNA species, although low levels of a putative double-stranded replicative form could conceivably have escaped detection. From our observations it appears that the heterogeneous RNA species and presumably the 20S RNase-resistant species reported in other investigations of flavivirus RNA are degradation products or conformers of the 45S molecule. Polysomes from SLE virus-infected cells were prepared and separated from contaminating nucleocapsid by centrifugation on discontinuous sucrose gradients. RNA extracted from these polysome preparations was analyzed by sucrose gradient centrifugation and agarose gel electrophoresis. The 45S SLE virus genome-size molecule was found to be the only RNA species associated with the polysomes. This molecule was sensitive to RNase digestion and was released from polysomes by EDTA and puromycin treatment. These findings provide direct evidence that the 45 S SLE virus RNA serves as the messenger during virus replication, in contrast to the 26S RNA species which functions as the predominant messenger during alphavirus replication.     

Synthesis of Saint Louis Encephalitis Virus Ribonucleic Acid in BHK-21/13 Cells

Infection of baby hamster kidney cells (BHK-21/13) with Saint Louis encephalitis (SLE) virus depressed the rate of protein and ribonucleic acid (RNA) synthesis until viral RNA synthesis began 6 hr postinfection (PI). Virus-directed RNA synthesis was subsequently inhibited until 12 hr PI when virion maturation began. The rate of protein synthesis reached a peak 6 hr PI and was subsequently depressed until just before the onset of virion maturation. Density gradient analysis of phenol-extracted RNA from actinomycin-treated infected cells indicated that, at 6 to 8 hr and again at 12 to 20 hr PI, three species of viral-specific RNA were synthesized. The most rapid sedimenting form (43S) was ribonuclease-sensitive and had a base composition similar to the RNA isolated from mature virions. The 20S RNA species was ribonuclease-resistant and had a sedimentation coefficient and base composition similar to the replicative form associated with other arbovirus infections. The 26S RNA was ribonuclease-resistant (0.2 mug/ml, 0.1 m NaCl, 25 C, 30 min) and had a nucleotide base composition closer to the 20S form than to the values for 43S RNA. Five-minute pulse labeling of infected cultures during the period viral RNA synthesis was maximal resulted in labeling of only the 20S to 22S RNA fractions. With pulse-labeling periods of 10 min, both the 20S and 26S RNA species were radioactive. Periods of radioactive labeling of as long as 15 min were required before the 43S form was radioactively labeled. These results suggest that the 20S and 26S RNA may be intermediate forms in the synthesis of 43S viral RNA.     

Nucleic Acid of Rubella Virus and Its Replication in Hamster Kidney Cells

Ribonucleic acid (RNA) has been isolated from partially purified rubella virus preparations and fractionated by rate zonal centrifugation in sucrose density gradients. The bulk of the RNA sedimented as a sharp band with a sedimentation coefficient of 38S. Rubella virus RNA appears to be single-stranded on the basis of its sensitivity to the degrading action of ribonuclease. Fractionation by precipitation with 1 m NaCl, followed by chromatography on cellulose columns, and by rate zonal centrifugation in sucrose density gradients of labeled RNA isolated from actinomycin D-treated and infected baby hamster kidney cells revealed the presence of the following virus-specific types of RNA: (i) single-stranded RNA with a heterogeneous sedimentation pattern, the 38S viral RNA becoming the predominant species only after long periods of labeling late after infection; (ii) double-stranded RNA with a sedimentation coefficient of 20S; (iii) RNA apparently composed of 20S double-stranded RNA and single-stranded branches. On the basis of their properties, the last two species were tentatively identified as the replicative form and the replicative intermediate of rubella virus RNA. Rubella virus RNA was infectious.     

Two Classes of Cytoplasmic Viral RNA Synthesized Early in Productive Infection with Adenovirus 2

The RNA sequences and RNA size classes transcribed early in productive infection with adenovirus 2 were analyzed by RNA-DNA hybridization. Two independent procedures demonstrated that early cytoplasmic viral RNA is composed of two sequence classes, class I which is absent or present in greatly reduced quantities at 18 h, and class II which persists throughout the infection. When the sequences in early viral RNA were analyzed by hybridization-inhibition studies, the hybridization of early [(3)H]RNA was inhibited only 50% by RNA from cultures harvested late (18 h) in infection. Liquid hybridizations with radioactive viral DNA confirmed that early RNA includes two classes. Duplex formation of RNA with (32)P-labeled viral DNA was assayed by hydroxylapatite chromatography and resistance to S(1) nuclease digestion. Both methods showed that the cytoplasmic RNA present early in infection annealed 12 to 15% of the viral DNA; late cytoplasmic RNA hybridized 21 to 25% of the DNA. Mixtures of early plus late cytoplasmic RNAs hybridized 30 to 34% of the viral DNA, demonstrating the reduced concentration of early class I RNA in the late RNA preparations. Experiments were performed to correlate class I and class II early RNA with size-fractionated cytoplasmic RNA synthesized early in infection. Fractionation of RNA by gel electrophoresis or sucrose gradient centrifugation confirmed three major size classes, 12 to 15S, 19 to 20S, and 26S. Total cytoplasmic RNA and RNA selected on the basis of poly(A) content contained the same size classes of viral RNA. In standard electrophoresis conditions, the 19 to 20S viral RNA could be resolved into two size classes, and the distribution of 12 to 15S RNA also indicated the presence of more than one size component. Hybridization-inhibition studies under nonsaturating conditions were performed with 26S, 19 to 20S, and 12 to 15S viral RNAs fractionated by gel electrophoresis. Late RNA inhibited the hybridization of 26S RNA only 20%, 19 to 20S RNA was inhibited 45%, and 12 to 15S RNA was inhibited 50%. When 18 to 19S and 12 to 15S viral RNAs purified by sucrose gradient centrifugation were similarly analyzed, late RNA inhibited hybridization of 18 to 19S RNA 50%, and the annealing of 12 to 15S RNA was inhibited 70%.     

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.     

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.     

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.     

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.     

Size and structure of the genome of infectious pancreatic necrosis virus.

The genome of infectious pancreatic necrosis virus consists of two segments of dsRNA, in equimolar amounts, with molecular weights of 2.5 X 10(6) and 2.3 X 10(6) daltons, as determined by polyacrylamide gel electrophoresis and autoradiography. The viral RNA was resistant to ribonuclease, and in sucrose gradient it co-sedimented at 14S with RNase resistant RNA from virus infected cells. Upon denaturation in 98% formamide, the viral genome sedi-mented at 24S in formamide sucrose gradient and became sensitive to RNase. Denatured 24S viral RNA did revert to its undenatured 14S form upon recentrifugation in aquaeous sucrose gradient (0.1 M NaCL), but co-sedimented with the denatured large size class of reovirus 25S RNA. The same results were obtained if the native viral RNA was pre-treated with ribonuclease before denaturation, indicating the absence of exposed single strainded regions in the viral genome. Since infectious pancreatic necrosis virus contains only two dsRNA segments it does not belong to the family Reoviridae and may represent a new group of viruses.     

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     

The types of virus-specific structures in cells of human origin producing oncornaviruses]

In the cell cytoplasm of human tissue cultures Detroit-6 and AO which produce B type oncorna-virus, two types of virus-specific structures were revealed. Structures of type I were aggregated fibrils of 3 and 6 nm diametre. Structures of type II were nucleoids of A-particles of 70-80 nm diametre. They were rather well separated from cell components by centrifugation sucrose density gradient and repeated centrifugation in the sucrose concentration gradient. Fibrils were found in the density regions of the equilibrium gradient of 1.26 and 1.19 g/cm3, whereas A-particles were detected in the sones of the density of 1.29 and 1.23-124 g/cm3. Their sedimentation coefficients in the sucrose concentration gradients were about 150S and 250S, respectively. From both structure types similar RNA classes were extracted sedimenting in 60S, 45S and 35S regions (sucrose concentration gradient). In addition, 20S RNA was found within the 150S structures. Both structures sa. However, hydridization degree of RNA isolated from both structures with DNA synthesized enzymatically on extracellular various (DNA I) and A-particles (DNA II) was different. With DNA-I, 50-80% of RNA isolated from the type I structures and less than 20% of RNA extracted from the type II structures were hybridized. At the same time, strictly opposite situation (50-80% of RNA II and 20% of RNA I) was observed for DNA-II. These data show lack of genetic connection between these types of cytoplasmic structures and possible role of type I structures in reproduction of oncorna-virus type B.     

Isolation and Properties of a New Species of Ribonucleic Acid Synthesized in Sporulating Cells of Saccharomyces cerevisiae

A new species of ribonucleic acid (RNA) was detected in sporulating culture of Saccharomyces cerevisiae. This RNA was isolated by sucrose density gradient centrifugation and polyacrylamide gel electrophoresis and partially characterized. It has a sedimentation coefficient of approximately 20S and a nucleotide composition distinct from other known RNA species in yeast, and it hybridizes with nuclear but not with mitochondrial deoxyribonucleic acid.     

Ribonucleic Acid Synthesis in Cells Infected with Influenza Virus

Virus-specific ribonucleic acid (RNA), synthesized in influenza virus-infected cells from 3.5 to 7.5 hr after infection, was studied. After velocity centrifugation in sucrose, three peaks of virus-specific RNA could be identified: 34S, 18S, and 11S. These RNA species are predominantly single-stranded and consist of 90% viral (plus) and 10% complementary (minus) RNA strands. Most (75%) of the complementary RNA is single-stranded, i.e., not part of RNA duplexes or replicative intermediates. The 34S RNA species is an aggregate of 18S and 14S RNA species. Both 18S and 11S RNA species are relatively heterogenous compared to 18S ribosomal RNA, and these species probably contain different RNA molecules having closely related sedimentation coefficients.     

Chromatography of Arbovirus Ribonucleic Acid Forms on Columns of Benzoylated-Diethylaminoethyl Cellulose

Benzoylated-diethylaminoethyl cellulose (BD-cellulose) column chromatography was found to be useful in resolving most of the ribonucleic acid (RNA) forms from the replicative cycle of group A arbovirus Semliki Forect virus (SFV). The elution patterns were independent of molecular weight and appeared to be related to the degree of secondary structure in the molecule. Fractions of RNA were taken from a sucrose density gradient of cytoplasmic extracts of SFV-infected chick cells pretreated with actinomycin D. In a linear salt gradient, 16S material cochromatographed with the rapidly eluted ribonuclease resistant core of the double-stranded SFV-RNA and with the homopolymer duplex polyinosinic acid: polycytidylic acid. This fraction, therefore, probably contains an SFV-RNA form similar to the completely double stranded replicative form (RF) of several RNA viruses and bacteriophages. Faster moving (>20S) sucrose gradient fractions eluted more slowly, suggesting a decreasing proportion of secondary structure with increasing sedimentation value. The fractions, therefore, seemed to contain replicative intermediate (RI) structures. The two single stranded forms of SFV-RNA (42S and 26S) could only be eluted from BD-cellulose in the presence of urea or dimethyl sulfoxide, suggesting the presence of minimal secondary structure. Under these conditions, the single-stranded viral RNA forms could not be resolved. Molecular sieve chromatography of the single-stranded RNA forms, performed by passage through an agarose column, also failed to resolve these forms. The viral RNA forms containing a high degree of secondary structure, probably the RF and the RI, could, therefore, be rapidly separated from each other and from the single-stranded forms.     

RNA-dependent RNA polymerase activity associated with the yeast viral p91/20S RNA ribonucleoprotein complex.

20S RNA is a noninfectious viral single-stranded RNA found in most laboratory strains of the yeast Saccharomyces cerevisiae. 20S RNA encodes a protein of 91 kDa (p91) that contains the common motifs found among RNA-dependent RNA polymerases from RNA viruses. p91 and 20S RNA are noncovalently associated in vivo, forming a ribonucleoprotein complex. We detected an RNA polymerase activity in p91/20S RNA complexes isolated by high-speed centrifugation. The activity was not inhibited by actinomycin D nor alpha-amanitin. The majority of the in vitro products was 20S RNA and the rest was the complementary strands of 20S RNA. Because the extracts were prepared from cells accumulating 20S RNA over its complementary strands, these in vitro products reflect the corresponding activities in vivo. When the p91/20S RNA complexes were subjected to sucrose gradient centrifugation, the polymerase activity cosedimented with the complexes. Furthermore, an RNA polymerase activity was detected in the complex by an antibody-linked polymerase assay using anti-p91 antiserum, suggesting that p91 is present in the active RNA polymerase machinery. These results together indicate that p91 is the RNA-dependent RNA polymerase or a subunit thereof responsible for 20S RNA replication.     

Segmented genome and nucleocapsid of La Crosse virus.

La Crosse (LAC) virions purified by velocity and equilibrium gradient centrifugation contained three single-stranded RNA species. The three segments had sedimentation coefficients of 31S, 25S, and 12S by sodium dodecyl sulfate-sucrose gradient centrifugation. By comparison with other viral and cellular RNA species, the LAC viral RNAs had molecular weights of 2.9 x 10(6), 1.8 x 10(6), and 0.4 x 10(6). Phenol-sodium dodecyl sulfate-extracted LAC virion RNA was not infectious for BHK-21 cell cultures under conditions in which Sindbis viral RNA was infectious. Treatment of LAC virus with the nonionic detergent Triton X-100 and salt released three nucleocapsid structures, each containing one species of virion RNA. The nucleocapsids had sedimenation coefficients of 115S, 90S, and 65S. Negative-contrast electron microscopy of the nucleocapsids indicated that they were convoluted, supercoiled, and apparently circular. They had a mean diameter of 10 to 12 nm and modal lengths of 200, 510, and 700 nm (some were even longer). By chemical and enzymatic analysis of purified viral RNA, one type of 5' nucleotide (pppAp) present in the proportion of one per RNA segment was identified. After periodate oxidation, each virion RNA species was labeled by reduction with [3H]sodium borohydride. Taken together, these results suggest that although the nucleocapsids appear as closed loops, the viral RNA has free 5' and 3' ends and is, therefore, not circular.     

Quantitation of Semlike Forest virus RNAs in infected cells using 32-P equilibrium labelling.

In vitro cultured BHK and HeLa cells were labelled for several cell division cycles with 32-P-phosphate until they were equilibrated with radiophosphorus. After infection with Semliki forest virus (or mock-infection) these cells were analyzed for viral and ribosomal RNA by sucrose gradient centrifugation. From their radioactivities the mass of each RNA species was calculated. It was found that the BHK and HeLa cells contained on average 11.0 plus or minus 3.1 pg and 6.3 plus or minus 1.9 pg of ribosomal RNA (28 S + 18 S) respectively per cell. At the end of the viral growth cycle, i.e. at 8 h post infection the average mass of viral genome produced per cell was 1.0 -1.9 pg and 0.3 - 0.5 pg in BHK and HeLa cells respectively, of which only 1/10 to 1/20 was released as mature virus particles. The amount of the second major virus specific messenger, the 26 S RNA, was estimated from its ratio to the viral genome after labelling with 3-H-uridine in the presence of actinomycin D. These two viral RNAs were found to be present in roughly equimolar amounts.