Polymorphism of the migration of double-stranded RNA genome segments of avian reoviruses

A number of field isolates of avian reovirus were characterized by analysis of the migration pattern of their genomic double-stranded RNA (dsRNA) segments upon polyacrylamide gel electrophoresis. Comparison of the various isolates has demonstrated (i) no relationship between serotype and migration of any individual dsRNA segment, (ii) marked polymorphism of migration patterns of all dsRNA segments among isolates of the same serotype as well as among different serotypes, (iii) no correlation between genotype and disease state, (iv) less marked variability in migration pattern from isolates within a restricted geographic locale compared to isolates from distant locales, (v) the presence of a single genotype in local outbreaks of disease, and (vi) the relative invariant migration of several dsRNA segments among the avian reoviruses, one of which (S1) may serve to distinguish the avian from the mammalian reoviruses.     

Capped and conserved terminal structures in human rotavirus genome double-stranded RNA segments.

Both 3'- and 5'-terminal structures of human rotavirus genome double-stranded RNA segments were determined. RNAs were labeled at the 3'-termini with [32P]pCp by incubation with RNA ligase and at the 5'-termini with [32P]phosphate by polynucleotide kinase or, in the case of 5' caps, with 3H by chemical modification with [3H]NaBH4. Examination of radiolabeled termini released by digestion with several base-specific RNases revealed that rotavirus RNA segments are base paired end-to-end and contain the same terminal structures: (formula; see text)     

An identical 3'-terminal sequence in the ten reovirus genome RNA segments

An identical oligonucleotide, PyrpApApC, is released from the 3′-ends of all ten reovirus genome double-stranded RNA segments by digestion with pancreatic RNase. This sequence may be the recognition site for the virion-associated RNA polymerase or involved in linking the genome segments within the virion.     

The genome of infectious bursal disease virus consists of two segments of double-stranded RNA.

The RNA of infectious bursal disease virus was reexamined in a detailed analysis. It could be established that its genome consists of two segments of double-stranded RNA. The RNA is RNase resistant and has a sedimentation coefficient of 14S and a buoyant density of 1.62 g/ml. The purine/pyrimidine ratio is nearly 1; the guanine plus cytosine content is 55.3%; the Tm is 95.5 degrees C. The molecular weights of the two double-stranded segments were determined to be 2.2 x 10(6) and 2.5 x 10(6).     

The action of ribonuclease T1 on reovirus double-stranded RNA.

A small number of nucleotides are released from highly purified reovirus double-stranded RNA by ribonuclease T₁ in the presence of 0.3 m NaCl. These nucleotides include ppGp, which is quantitatively released from the RNA, and lesser amounts of ApUpGp, Gp, and ApGp. The same products are released from each of the three size classes of double-stranded RNA segments. In experiments involving specific labeling of termini, the only demonstrable sites of hydrolysis were at the 5′ termini of the minus strands. The limited extent of ribonuclease T₁ hydrolysis and localization of its action at the 5′ termini of the minus strands are compatible with a perfect duplex structure for the double-stranded RNA segments wherein the secondary structure of the termini is less stable than that of internal regions.     

Complete genome sequence of a double-stranded RNA virus from avocado

A number of avocado (Persea americana) cultivars are known to contain high-molecular-weight double-stranded RNA (dsRNA) molecules for which a viral nature has been suggested, although sequence data are not available. Here we report the cloning and complete sequencing of a 13.5-kbp dsRNA virus isolated from avocado and show that it corresponds to the genome of a new species of the genus Endornavirus (family Endornaviridae), tentatively named Persea americana endornavirus (PaEV).     

Gene-coding assignments of rotavirus double-stranded RNA segments 10 and 11

The gene-coding assignments for genome segments 10 and 11 of a simian virus and two human rotaviruses were determined. For those viruses having a “long” RNA gel pattern (electropherotype), segments 10 and 11 encoded proteins NS₃ and O₄, respectively. The human virus with a “short” electropherotype had the opposite assignments and also differed in (enzyme-linked immunosorbent assay) serotype from the human virus with a long electropherotype.     

Rotavirus RNA polymerase requires the core shell protein to synthesize the double-stranded RNA genome.

Rotavirus cores contain the double-stranded RNA (dsRNA) genome, RNA polymerase VP1, and guanylyltransferase VP3 and are enclosed within a lattice formed by the RNA-binding protein VP2. Analysis of baculovirus-expressed core-like particles (CLPs) has shown that VP1 and VP2 assemble into the simplest core-like structures with replicase activity and that VP1, but not VP3, is essential for replicase activity. To further define the role of VP1 and VP2 in the synthesis of dsRNA from viral mRNA, recombinant baculoviruses containing gene 1 (rBVg1) and gene 2 (rBVg2) of SA11 rotavirus were generated and used to express recombinant VP1 (rVP1) and rVP2, respectively. After purification, the proteins were assayed individually and together for the ability to catalyze the synthesis of dsRNA in a cell-free replication system. The results showed that dsRNA was synthesized only in assays containing rVP1 and rVP2, thus establishing that both proteins are essential for replicase activity. Even in assays containing a primer-linked mRNA template, neither rVP1 nor rVP2 alone directed RNA synthesis. Characterization of the cis-acting replication signals in mRNA recognized by the replicase of rVP1 and rVP2 showed that they were the same as those recognized by the replicase of virion-derived cores, thus excluding a role for VP3 in recognition of the mRNA template by the replicase. Analysis of RNA-protein interactions indicated that the mRNA template binds strongly to VP2 in replicase assays but that the majority of the dsRNA product neither is packaged nor stably associates with VP2. The results of replicase assays performed with mutant VP2 containing a deletion in its RNA-binding domain suggests that the essential role for VP2 in replication is linked to the protein's ability to bind the mRNA template for minus-strand synthesis.     

Presence of double-stranded RNA and virus-like particles in Rhizopus isolates

Fungal isolates belonging to four Rhizopus species were screened for the presence of double-stranded RNA (dsRNA) molecules. Five (two R. stolonifer, two R. microsporus, and one R. oryzae) of the 27 isolates examined harboured such genetic elements. Electrophoresis of the nucleic acids revealed five RNA patterns, with 1-5 discrete dsRNA bands. The molecular sizes corresponding to these bands were 2.2-14.8 kb. Gel electrophoresis of purified virus-like particles (VLPs) indicated only one capsid of similar size in all virus-harbouring strains; when investigated by electron microscopy, they were found to be polyhedral VLPs 40 nm in diameter. In one of the R. microsporus isolates an uncapsidated large dsRNA segment (14.8 kb) was observed. No phenotypic differences were observed between uninfected and virus-harbouring Rhizopus isolates.     

Separation of the plus and minus strands of cytoplasmic polyhedrosis virus and human reovirus double-stranded genome RNAs by gel electrophoresis.

The complementary strands of most of the genome double-stranded RNA segments of insect cytoplasmic polyhedrosis virus (CPV) and human reovirus are separated for the first time by agarose gel electrophoresis in in the presence of 7 M urea. CPV (+) strands and most reovirus (-) strands migrate faster than the corresponding strands of opposite polarity. Glyoxal treatment, which modifies guanine residues and prevents G-C basepairing, results in a loss of strand resolution and concomitantly a significant decrease in electrophoretic mobilities. Reovirus mRNAs synthesized in vitro with ITP substituted for GTP show similar decreased electrophoretic mobilities as the glyoxalated mRNAs. These results clearly indicate that the basis for (+) and (-) strand resolution is the presence of secondary structure formed mainly by G-C(U) base-pairs that are maintained during gel electrophoresis in the presence of 7 M urea. When the plus and minus strands of CPV genomes were separated and compared for protein synthesizing activity, it was found that only the plus strands were able to form stable 80S ribosome-RNA initiation complexes in wheat germ cell-free extracts.     

The effect of poly-L-lysine on the uptake of reovirus double-stranded RNA in macrophages in vitro

The effect of polycations on cultured mouse peitoneal macrophages has been examined. Polycations, at concentrations greater than 5 µg/ml, are toxic for macrophages) as measured by failure of the cells to exclude vital dyes. At toxic concentrations polycations bind in large amounts to nuclei and endoplasmic reticulum, while at nontoxic levels polycations bind selectively to the cell surface. Nontoxic concentrations of polycations stimulate binding of reovirus double-stranded (ds) RNA to the macrophages by forming polycation-dsRNA complexes either in the medium or at the cell surface. These complexes enter the cell in endocytic vacuoles and are concentrated in secondary lysosomes. Despite exposure to the acid hydrolases within this cell compartment, the dsRNA and the polycation (poly-L-lysine) are conserved in a macromolecular form within the vacuolar system. The mechanism(s) by which the uptake of infectious nucleic acids and the induction of interferon by dsRNA are stimulated by polycations are discussed.