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.     

Identification of a new polypeptide coded by reovirus gene S1.

The reovirus S1 gene has recently been shown potentially to encode two polypeptides (from two overlapping reading frames) having predicted molecular weights of 49,071 and 16,143 (Nagata et al., Nucleic Acids Res. 12:8699-8710, 1984; Bassel-Duby et al., Nature [London], in press). The larger polypeptide is reovirus protein sigma 1, but synthesis of the smaller polypeptide has not been described to date. A truncated clone of the S1 gene in which the first ATG is deleted was expressed in an in vitro protein synthesis system to yield a approximately 13-kilodalton polypeptide, as determined from migration on sodium dodecyl sulfate-polyacrylamide gels. A polypeptide with a similar migration pattern on sodium dodecyl sulfate-polyacrylamide gels was present in reovirus-infected cells and absent from mock-infected cells. Comparative tryptic peptide analysis of the 13-kilodalton polypeptides produced in vivo and in vitro showed them to be identical. Thus, the s1 mRNA of reovirus type 3 is apparently bicistronic, and we suggest that the approximately 13-kilodalton polypeptide be called sigma s (standing for sigma small).     

Cloning and sequencing of the preprotoxin-coding region of the yeast M1 double-stranded RNA.

Complementary DNA (cDNA) copies of the M1-1, toxin-coding region of the yeast M1 double-stranded RNA (dsRNA) have been cloned and sequenced. These sequences, in combination with the known terminal sequence of M1-1 dsRNA, identify a translation reading frame for a 316 amino acid protein of 34.7 kd, similar in size to the preprotoxin produced from M1 dsRNA by in vitro translation. Potential glycosylation sites in the preprotoxin peptide are identified. Based on its methionine content the extracellular yeast toxin appears to be contained within the C-terminal region of the precursor.     

Identification of the gene encoding a type 1 RNase H with an N-terminal double-stranded RNA binding domain from a psychrotrophic bacterium

The gene encoding a bacterial type 1 RNase H, termed RBD-RNase HI, was cloned from the psychrotrophic bacterium Shewanella sp. SIB1, overproduced in Escherichia coli, and the recombinant protein was purified and biochemically characterized. SIB1 RBD-RNase HI consists of 262 amino acid residues and shows amino acid sequence identities of 26% to SIB1 RNase HI, 17% to E. coli RNase HI, and 32% to human RNase H1. SIB1 RBD-RNase HI has a double-stranded RNA binding domain (RBD) at the N-terminus, which is commonly present at the N-termini of eukaryotic type 1 RNases H. Gel mobility shift assay indicated that this domain binds to an RNA/DNA hybrid in an isolated form, suggesting that this domain is involved in substrate binding. SIB1 RBD-RNase HI exhibited the enzymatic activity both in vitro and in vivo. Its optimum pH and metal ion requirement were similar to those of SIB1 RNase HI, E. coli RNase HI, and human RNase H1. The specific activity of SIB1 RBD-RNase HI was comparable to that of E. coli RNase HI and was much higher than those of SIB1 RNase HI and human RNase H1. SIB1 RBD-RNase HI showed poor cleavage-site specificity for oligomeric substrates. SIB1 RBD-RNase HI was less stable than E. coli RNase HI but was as stable as human RNase H1. Database searches indicate that several bacteria and archaea contain an RBD-RNase HI. This is the first report on the biochemical characterization of RBD-RNase HI.     

Cloning and sequencing of the preprotoxin-coding of the yeast M1 double-stranded RNA

[This corrects the article on p. 107 in vol. 3, PMID: 6368221.].     

3''End labelling of RNA with 32P suitable for rapid gel sequencing.

A new general method of labelling the 2',3'-diol end of RNA with 32P has been devised suitable for gel sequencing. Poly(A) polymerase (E. coli) is incubated with the RNA and limiting amounts of alpha-32P-ATP. The mono-addition product is then cleaved with periodate and beta-eliminated with aniline, leaving the RNA terminally labelled with 3' 32P-phosphate. When applied to a model compound, tRNAPhe from E. coli, over 28 residues could be read from the 3' end.     

Nucleotide sequence of reovirus genome segment S3, encoding non-structural protein sigma NS.

This report describes the complete nucleotide sequence of human reovirus (Dearing strain) genome segment S3. Previous studies indicated that this RNA encodes the major non-structural viral polypeptide sigma NS, a protein that binds ssRNAs (Huisman & Joklik, Virology 70, 411-424, 1976) and has a poly(C)-dependent poly(G) polymerase activity (Gomatos et al., J. Virol. 39, 115-124, 1981). The genome segment consists of 1,198 nucleotides and possesses an open reading frame that extends 366 codons from the first AUG triplet (residues 28-30). There is no significant sequence homology between the plus strand of genome segment S3 and that of genome segment S2 determined previously (Cashdollar et al., PNAS 79, 7644-7648, 1982). However, S3 RNA has significant dyad symmetry and regions that can potentially hybridize (delta G = -26 KCal/mole) with S2 RNA. From the predicted amino acid sequence a possible secondary structure for sigma NS protein was determined. Structural features of reovirus RNA and sigma NS are discussed in relation to their role(s) in viral genome assembly.     

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.     

Association of the reovirus S1 gene with serotype 3-induced biliary atresia in mice.

A panel of serotype 3 (T3) reovirus strains was screened to determine their relative capacities to cause lethal infection and hepatobiliary disease following peroral inoculation in newborn mice. A wide range of 50% lethal doses (LD50s) was apparent after peroral inoculation of the different virus strains. Two of the strains, T3 Abney and T3 clone 31, caused mice to develop the oily fur syndrome associated with biliary atresia. The capacity to cause biliary atresia was not related to the capacity to cause lethal infection, however, because the LD50s of T3 Abney and T3 clone 31 were grossly disparate. Examination of liver and bile duct tissues revealed histopathologic evidence of biliary atresia and hepatic necrosis in T3 Abney-infected mice but not in mice inoculated with a T3 strain of similar virulence or with the hepatotropic T1 Lang strain. The consistency with which T3 Abney-infected mice developed biliary atresia-associated oily fur syndrome permitted us to determine the viral genetic basis of reovirus-induced biliary atresia. Analysis of reassortant viruses isolated from an in vitro coinfection with T3 Abney and T1 Lang indicated a strong association of the hepatobiliary disease-producing phenotype with the T3 Abney S1 gene, which encodes the viral cell attachment protein, sigma 1. Amino acid residues within the sigma 1 protein that were unique to disease-producing T3 strains were identified by comparative sequence analysis. Specific changes exist within two regions of the protein, one of which is thought to be involved in binding to host cell receptors. We hypothesize that changes within this region of the protein are important in determining the tropism of this virus for bile-ductular epithelium.     

Identification of a 30S RNA with properties of a defective type C virus in murine cells.

A novel species of 30S RNA has been detected in a variety of mouse cell lines. The 30S RNA is specifically packaged by helper-independent type C viruses propagated in such cells. Nucleic acid hybridization detects no homology between the 30SRNA and the genomic RNA of helper-independent mouse type C viruses. The properties of the 30S RNA suggest that it is a defective endogenous mouse type C virus and that it is analogous to a previously described class of defective endogenous rat type C virus, which has been shown previously to be the progenitor of Kirsten and Harvey murine sarcoma viruses.     

Application of a rapid gel method to the sequencing of fragments of 16S ribosomal RNA from Escherichia coli.

A gel sequencing method has been applied to two 5' end-labelled fragments of the 16S ribosomal RNA from E. coli. The procedure involves partial enzymatic hydrolysis by ribonucleases T1, U2 or A, in order to generate series of end-labelled subfragments terminating in guanine, adenine, or pyrimidine residues, respectively. The two fragments concerned were approximately 75 and 90 nucleotides in length, and both arose from the 3' region of the 16S RNA. The sequences deduced are compared with the published sequence of 16S RNA, and contribute information to the final ordering of the ribonuclease T1 oligonucleotides in the latter, as well as revealing some probable errors.     

Sequence diversity in S1 genes and S1 translation products of 11 serotype 3 reovirus strains.

The S1 gene nucleotide sequences of 10 type 3 (T3) reovirus strains were determined and compared with the T3 prototype Dearing strain in order to study sequence diversity in strains of a single reovirus serotype and to learn more about structure-function relationships of the two S1 translation products, sigma 1 and sigma 1s. Analysis of phylogenetic trees constructed from variation in the sigma 1-encoding S1 nucleotide sequences indicated that there is no pattern of S1 gene relatedness in these strains based on host species, geographic site, or date of isolation. This suggests that reovirus strains are transmitted rapidly between host species and that T3 strains with markedly different S1 sequences circulate simultaneously. Comparison of the deduced sigma 1 amino acid sequences of the 11 T3 strains was notable for the identification of conserved and variable regions of sequence that correlate with the proposed domain organization of sigma 1 (M.L. Nibert, T.S. Dermody, and B. N. Fields, J. Virol. 64:2976-2989, 1990). Repeat patterns of apolar residues thought to be important for sigma 1 structure were conserved in all strains examined. The deduced sigma 1s amino acid sequences of the strains were more heterogeneous than the sigma 1 sequences; however, a cluster of basic residues near the amino terminus of sigma 1s was conserved. This analysis has allowed us to investigate molecular epidemiology of T3 reovirus strains and to identify conserved and variable sequence motifs in the S1 translation products, sigma 1 or sigma 1s.     

Portable encapsidation signal of the L-A double-stranded RNA virus of S. cerevisiae

The (+) single-stranded RNA (ssRNA) of the L-A virus is the species packaged to form new viral particles. Empty L-A viral particles specifically bind viral (+) ssRNA, and a sequence 400 bases from the 3' end is necessary for this activity. We show that its stem-loop structure, the A residue protruding from the stem, and the loop sequence are all important for the binding, and that this 34 base region is sufficient for the binding. M1, a satellite virus of L-A, has a similar structure on its (+) strand that is likewise sufficient for the binding. Heterologous RNA with the binding sequence from L-A or M1, when expressed in vivo, was packaged in L-A viral particles. Thus, the sites necessary to bind to empty particles are encapsidation signals for the L-A virus. Since the pol domain of the 180 kd minor coat protein appears to be responsible for the binding, this result suggests that the RNA polymerase molecule recognizes the viral genome for packaging.     

S1 nuclease sensitivity of a double-stranded telomeric DNA sequence.

We examined structural properties of poly d(C4A2).d(T2G4), the telomeric DNA sequence of the ciliated protozoan Tetrahymena. Under conditions of high negative supercoiling, poly d(C4A2).d(T2G4) inserted in a circular plasmid vector was preferentially sensitive to digestion with S1 nuclease. Only the C4A2 strand was sensitive to first-strand S1 cutting, with a markedly skewed pattern of hypersensitive sites in tracts of either 46 or 7 tandem repeats. Linear poly d(C4A2).(T2G4) showed no preferential S1 sensitivity, no circular dichroism spectra indicative of a Z-DNA conformation, no unusual Tm, and no unusual migration in polyacrylamide gel electrophoresis. The S1 nuclease sensitivity properties are consistent with a model proposed previously for supercoiled poly d(CT).d(AG) (Pulleyblank et al., Cell 42:271-280, 1985), consisting of a double-stranded, protonated, right-handed underwound helix. We propose that this structure is shared by related telomeric sequences and may play a role in their biological recognition.     

Polymorphism of the migration of double-stranded RNA genome segments of reovirus isolates from humans, cattle, and mice.

A series of 94 isolates of reovirus from humans, cattle, and mice, showed extensive variability in the patterns of migration of the ten double-stranded RNA genome segments. This variation was found in all three serotypes, and involved all ten genome segments, including the segment responsible for serological specificity. Although a single pattern was present among several samples isolated from individuals and collected at a single time and place, there were often multiple genetic variants of a single serotype present in a population. Samples isolated from widely different geographic origins or different mammalian hosts showed different patterns; samples from a single species from the same area over a period of time showed more limited variations. Among most isolates, the migration of the slowest S segment, the segment that encodes the hemagglutinin and is responsible for serological specificity in laboratory strains, was similar to reference strains for type 1 and type 3 isolates. However, the type 2 isolates showed considerable variation in this segment.