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.     

Replication of Bacteriophage Ribonucleic Acid: Analysis of the Ultrastructure of the Replicative Form and the Replicative Intermediate of Bacteriophage R17

A detailed qualitative and quantitative comparison was made of the ultrastructure of single-stranded ribonucleic acid (RNA) from bacteriophage R17 and double-stranded replicative form (RF) and replicative intermediate (RI) from cells infected with this bacteriophage. The nucleic acids were prepared for electron microscopy by the protein monolayer spreading technique of Kleinschmidt. Single-stranded RNA aggregated during spreading in the absence of urea, whereas RF and RI did not. On the other hand, RF and RI appeared to be susceptible to shear during spreading, whereas R17 RNA was not. From the maximal length of RF, a base translation of 3.14 A was calculated. This value favors a 10-fold helix model of double-stranded RNA. The same base translation was found for R17 RNA, indicating a stacked base structure for single-stranded RNA spread in the presence of urea. RI is a branched structure and the branches are removed by ribonuclease treatment. The branches are believed to be nascent single-stranded viral RNA. The contour length of the branch was equal to the contour length of the main chain up to the branch point, as predicted from theoretical analysis of the replication of viral RNA. The structure of RF and the main chain of RI was also analyzed by plotting the log (end-to-end distance squared) versus log (contour length). This demonstrated structures intermediate in stiffness between a random coil and a rigid rod.     

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     

Studies on biosynthesis of tobacco mosaic virus. VII. Radioactivity of plus and minus strands in different forms of viral RNA after labelling of infected tobacco leaves

Tobacco leaves were labelled with tritiated undine for 30 or 120 minutes at different times after systemic infection with tobacco mosaic virus. RNA was extracted and separated into three fractions: one enriched in RF (replicative form), one enriched in RI (replicative intermediate), and one containing the bulk of single-stranded RNA. Radioactivity in plus strands (viral RNA) and minus strands (complementary RNA) was determined in each fraction by an isotope dilution assay. The amount of minus strands in the RP and RI fractions and the amount of plus strands in the single-stranded RNA fraction were also determined.Minus-strand synthesis was twice as high a few hours after the outbreak of visible symptoms as during the subsequent large accumulation of plus strands. At the early stage of virus production, the specific radioactivity of the minus strands was three- to fourfold that of the total RNA. Later it was about the same as that of the total RNA. As minus strands constitute a constant part of the total RNA at the later stages, this observation suggests that breakdown of minus strands is small.The specific radioactivity of minus strands was the same in corresponding RF and RI fractions. As the turn-over of minus strands appears to be small, a rapid interconversion of the two RNA types is indicated.In RF and RI the radioactivity in plus strands was between 6 and 50 times greater than that in minus strands. The specific radioactivity of plus strands was greater in RF and RI than in the single-stranded RNA, supporting the concept that both RF and RI have a precursor role for viral RNA.     

Replication of Bacteriophage Ribonucleic Acid: Some Properties of Native and Denatured Replicative Intermediate

Purified replicative form (RF) and replicative intermediate (RI) prepared from Escherichia coli cells infected with the ribonucleic acid (RNA) bacteriophage R17 were denatured with dimethyl sulfoxide at 37 C or in aqueous solvents of low ionic strength at 97 C. Denaturation was demonstrated for RF and RI by an increase in specific infectivity and a striking change in the hyperchromicity curves after treatment. RI denaturation was also demonstrated by a shift in the buoyant density in Cs(2)SO(4) from 1.619 to the buoyant density of single-stranded R17 RNA (1.627). Analysis of the denatured RI hyperchromicity curves and the equilibrium distributions of denatured RI in Cs(2)SO(4) gradients revealed, however, a residual double-stranded component. Velocity sedimentation of denatured RI was performed, and the weight distribution of S values was calculated. From the known relation between molecular weight and S values, it was possible to transform the weight distribution into a number distribution of chain lengths. This distribution was compared with that predicted from the steady-state hypothesis for RI. Deviations from the predicted distribution may be due to the residual double-stranded component.     

Structure of poliovirus replicative intermediate RNA: Electron microscope analysis of RNA cross-linked in vivo with psoralen derivative

The structure of the poliovirus replicative intermediate RNA was examined by electron microscopy after cross-linking in vivo with 4′-aminomethyl-4,5′,8-trimethylpsoralen. After purification from infected cells, undenatured RI² appeared as a double-stranded backbone of genome length, with an average of three (and occasionally up to eight) nascent, single-stranded tails. After denaturation, however, only single strands of heterogeneous length were visualized, indicating that the RI in the cell contains little or no duplex structure, and thus nascent chains are only transiently hydrogen-bonded to their template over short regions. The double-stranded backbone of undenatured RI, observed previously by others and in these experiments, is due to collapse of complementary chains during the deproteinization and purification procedures. The effectiveness of the in vivo cross-linking procedure was demonstrated by the complete inhibition of viral RNA synthesis in treated cells and by direct binding of [³H]AMT to RI molecules in vivo. Mature polio virions are impermeable to AMT; however, growth of virus in cells incubated with AMT in the dark resulted in normal yields of virus particles containing RNA genomes, whose infectivity could be subsequently photo-inactivated. The frequency of AMT-induced cross-linking was determined by analyses of double-stranded poliovirus RNA (RF). Cross-linking in vitro followed by spreading for electron microscopy under denaturing conditions yielded bubbled duplex structures with a minimum of one interstrand cross-link per 80 base-pairs. RF cross-linked in vivo also showed extensive cross-linking, decreased about fivefold from the in vitro cross-linked value. Thus, the failure to detect cross-linked RI under these conditions indicates that extensive base-pairing does not exist in vivo.     

Denaturation and Renaturation of Viral Ribonucleic Acid I. Annealing R17 Ribonucleic Acid with Denatured Replicative Form or with Denatured Replicative Intermediate

Purified replicative form (RF) and replicative intermediate (RI) prepared from Escherichia coli infected with R17 were denatured in 0.15 m NaCl, 0.015 m sodium citrate containing 65% dimethylsulfoxide. Denaturation of RF or RI was demonstrated spectrophotometrically, chromatographically, and by sedimentation analysis. Denatured RF or RI was annealed by carefully decreasing the temperature from 62 to 20 C. Annealing was accompanied by a decreased absorbance at 260 mmu. The decrease in absorbance during annealing appeared to be dependent upon the rate of cooling and the concentration of ribonucleic acid (RNA). Denatured RF or RI was annealed with R17 RNA which was labeled with (3)H-uridine. The annealed product was 73 to 82% resistant to 0.1 mug/ml of ribonuclease. Annealing R17 RNA with either denatured RF or RI resulted in the formation of a ribonuclease-resistant product with a sedimentation profile resembling that of native RI. Melting the annealed products in 85.7% dimethyl sulfoxide produced 27S single-stranded R17 RNA and a heterogeneous population of more slowly sedimenting RNA.     

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

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

Studies on the structure of replicative intermediates in bacteriophage M13 single stranded DNA synthesis.

Pulse-labeled replicative intermediates in M 13 single stranded DNA synthesis can be separated by dye-buoyant density centrifugation into two major fractions: Supercoiled molecules (RI I) containing viral strands of more than one genome length, and "relaxed" molecules (RI II) with labeled DNA chains shorter than unit length. It is postulated that RI II molecules might be formed in vivo by site-specific nicking of RF I molecules.     

RNA of mouse hepatitis virus.

The RNA of mouse hepatitis virus, a coronavirus, was isolated from the virus released early in the infection and analyzed by sucrose gradient sedimentation and electrophoresis. It was found to consist of a piece of single-stranded RNA of about 60S. Its molecular weight was estimated to be 5.4 X 10(6) by electrophoresis in methylmercury-agarose gels. At least one third of the RNA contained polyadenylated sequences. It is, therefore, probably positive stranded. The virus harvested late in the infection contained, in addition to 60S, some 30 to 50S RNA that are possibly degradation products of the 60S RNA. No difference in the electrophoretic behavior could be detected between the RNA isolated from a pathogenic (JHM) and a nonpathogenic (A59) strain.     

Lack of repair of ultraviolet light damage in Mycoplasma gallisepticum

Molecules with single-stranded tails (rolling circles) were isolated as replicating intermediates in G4 progeny single-stranded DNA synthesis. Lysates from infected cells harvested late in infection during single-stranded DNA synthesis were not deproteinised but analysed directly in caesium chloride and propidium diiodide gradients. The gradient fractionated them on the basis of tail length. If the lysates were first deproteinised however, the tailed replicative intermediates banded as a peak at a density just greater than that of replicative form II DNA (RFII) and did not spread down the gradient. The origin of synthesis of the viral strand tail was mapped by electron microscopy as 55 to 60% away from the single EcoRI cleavage site. Termination molecules finishing a round of viral strand DNA synthesis have been identified as molecules consisting of a closed single-stranded DNA circle attached by a very small region to the parent double-stranded DNA circle.     

Studies on the secondary structure of single-stranded RNA from the bacteriophage MS2. II Analysis of the RNase IV cleavage products

Single-stranded RNA from the bacteriophage MS2 was cleaved into two unequal fragments using the Escherichia coli endonuclease RNase IV. The fragments were purified by sucrose gradient centrifugation and secondary structure maps of the purified fragments were prepared after spreading the RNAs in 0·5 mmMgCl₂. Comparison of these maps with those of native RNA permitted the identification of the 5′ and 3′ ends of the maps of native single-stranded RNA. In addition, the location of the cleavage site with respect to the secondary and tertiary structure of the RNA suggests that the conformation of the RNA around this site may be important in determining the specificity of cleavage by the enzyme.The approximate location of individual viral genes within the secondary structure map has been obtained by comparing the map of native RNA with known sequence data. A new model is proposed to explain the role of secondary structure, as seen in the electron microscope, in the regulation of the synthesis of coat protein and the viral subunit of the MS2 replicase.     

Replication of Coliphage M-13 II. Intracellular Deoxyribonucleic Acid Forms Associated with M-13 Infection of Mitomycin C-treated Cells

Intracellular deoxyribonucleic acid (DNA) forms associated with bacteriophage M-13 infection have been isolated and characterized. Escherichia coli HF4704 (F⁺, hcr⁻, thy⁻) cells were treated with mitomycin C to inhibit host-cell DNA synthesis and were then infected with phage M-13. This treatment permitted radioactive labeling of phage-specific DNA forms with ³H-thymine. These labeled DNA components were characterized by sucrose density sedimentation and equilibrium density gradient centrifugation in neutral and ethidium bromide CsCl gradient. Two double-stranded circular forms were found with properties analogous to the replicative form I and replicative form II of X174. A third component, identified as single-stranded DNA, was isolated in some samples removed 45 min after phage synthesis was initiated.     

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.     

Electron Microscopical and Biochemical Characterization of Infectious Pancreatic Necrosis Virus

An electron microscopical and biochemical examination of the properties of infectious pancreatic necrosis virus (IPN) and of its ribonucleic acid (RNA) was made. The buoyant density of IPN in CsCl was found to be 1.33 g/cm³. Electron microscopical examination of the banded virus revealed structures similar in size (74 nm) and shape to reoviruses but lacking a characteristic inner capsid structure. Polyacrylamide gel electrophoretic analysis of IPN-RNA revealed a single non-segmented component of molecular weight 3.2 × 10⁶. Its susceptibility to ribonuclease, base composition, and resistance to thermal denaturation indicated a single-stranded RNA structure. However, its sedimentation behavior (16S) independent of ionic strength in sucrose gradients, partial solubility in 2 m LiCl, and ribonuclease resistance in the presence of Mg²⁺ suggest an unusual secondary structure of unknown nature. The accumulated data indicate that IPN virus does not belong to either the picornavirus or reovirus groups and may represent a new group of viruses.     

Electrophoretic Characterization of Foot-and-Mouth Disease Virus-Specific Ribonucleic Acid

Foot-and-mouth disease virus (FMDV)-specific ribonucleic acid (RNA) was analyzed by electrophoresis on 0.5% agarose gels. Four classes of RNA were resolved as a function of mobility in agarose: two classes of slowly migrating multistranded RNA, the infectious viral RNA with intermediate mobility, and a minor fast-moving class of lower-molecular-weight single-stranded RNA. The major RNA species were infectious viral RNA and the slowest migrating class of multistranded RNA. The latter RNA was polydisperse when analyzed by sucrose gradient centrifugation, it was partially ribonuclease resistant, and it was the predominant RNA species labeled during the initial period of (3)H-uridine triphosphate incorporation in the cell-free system. Heat treatment studies indicated that part of the slowest-moving RNA was degraded at 60 C and almost complete degradation was detected at 100 C. It was concluded that this RNA is the replicative intermediate in viral RNA synthesis. The second class of multistranded RNA contained both a ribonuclease-resistant RNA and a second RNA peak which was detected only after heat treatment at temperatures above 75 C. Fractions of FMDV-specific RNA isolated by sucrose gradient centrifugation were analyzed by agarose-gel electrophoresis. Infectious viral RNA was detected only in the 37S zone and was the major species of RNA in this part of the gradient. The ribonuclease-resistant RNA (the 20S zone) contained about equal amounts of multistranded RNA (both classes) and the low-molecular-weight single-stranded RNA. All sucrose gradient fractions between 20 and 40S were found to contain the replicative intermediate, although the major portion was detected in the 20 to 25S region.