Separation and sequence of the 3' termini of M double-stranded RNA from killer yeast

New Insights into the Genome Organization of Yeast Double-Stranded RNA LBC Viruses

The yeasts Torulaspora delbrueckii (Td) and Saccharomyces cerevisiae (Sc) may show a killer phenotype that is encoded in dsRNA M viruses (V-M), which require the helper activity of another dsRNA virus (V-LA or V-LBC) for replication. Recently, two TdV-LBCbarr genomes, which share sequence identity with ScV-LBC counterparts, were characterized by high-throughput sequencing (HTS). They also share some similar characteristics with Sc-LA viruses. This may explain why TdV-LBCbarr has helper capability to maintain M viruses, whereas ScV-LBC does not. We here analyze two stretches with low sequence identity (LIS I and LIS II) that were found in TdV-LBCbarr Gag-Pol proteins when comparing with the homologous regions of ScV-LBC. These stretches may result from successive nucleotide insertions or deletions (indels) that allow compensatory frameshift events required to maintain specific functions of the RNA-polymerase, while modifying other functions such as the ability to bind V-M (+)RNA for packaging. The presence of an additional frameshifting site in LIS I may ensure the synthesis of a certain amount of RNA-polymerase until the new compensatory indel appears. Additional 5'- and 3'-extra sequences were found beyond V-LBC canonical genomes. Most extra sequences showed high identity to some stretches of the canonical genomes and can form stem-loop structures. Further, the 3'-extra sequence of two ScV-LBC genomes contains rRNA stretches. The origin and possible functions of these extra sequences are here discussed.

Genome Features of a New Double-Stranded RNA Helper Virus (LBCbarr) from Wine Torulaspora delbrueckii Killer Strains

The killer phenotype of Torulaspora delbrueckii (Td) and Saccharomyces cerevisiae (Sc) is encoded in the genome of medium-size dsRNA viruses (V-M). Killer strains also contain a helper large size (4.6 kb) dsRNA virus (V-LA) which is required for maintenance and replication of V-M. Another large-size (4.6 kb) dsRNA virus (V-LBC), without known helper activity to date, may join V-LA and V-M in the same yeast. T. delbrueckii Kbarr1 killer strain contains the killer virus Mbarr1 in addition to two L viruses, TdV-LAbarr1 and TdV-LBCbarr1. In contrast, the T. delbrueckii Kbarr2 killer strain contains two M killer viruses (Mbarr1 and M1) and a LBC virus (TdV-LBCbarr2), which has helper capability to maintain both M viruses. The genomes of TdV-LBCbarr1 and TdV-LBCbarr2 were characterized by high-throughput sequencing (HTS). Both RNA genomes share sequence identity and similar organization with their ScV-LBC counterparts. They contain all conserved motifs required for translation, packaging, and replication of viral RNA. Their Gag-Pol amino-acid sequences also contain the features required for cap-snatching and RNA polymerase activity. However, some of these motifs and features are similar to those of LA viruses, which may explain that at least TdV-LBCbarr2 has a helper ability to maintain M killer viruses. Newly sequenced ScV-LBC genomes contained the same motifs and features previously found in LBC viruses, with the same genome location and secondary structure. Sequence comparison showed that LBC viruses belong to two clusters related to each species of yeast. No evidence for associated co-evolution of specific LBC with specific M virus was found. The presence of the same M1 virus in S. cerevisiae and T. delbrueckii raises the possibility of cross-species transmission of M viruses.

Genome Organization of a New Double-Stranded RNA LA Helper Virus From Wine Torulaspora delbrueckii Killer Yeast as Compared With Its Saccharomyces Counterparts

Wine killer yeasts such as killer strains of Torulaspora delbrueckii and Saccharomyces cerevisiae contain helper large-size (4.6 kb) dsRNA viruses (V-LA) required for the stable maintenance and replication of killer medium-size dsRNA viruses (V-M) which bear the genes that encode for the killer toxin. The genome of the new V-LA dsRNA from the T. delbrueckii Kbarr1 killer yeast (TdV-LAbarr1) was characterized by high-throughput sequencing (HTS). The canonical genome of TdV-LAbarr1 shares a high sequence identity and similar genome organization with its Saccharomyces counterparts. It contains all the known conserved motifs predicted to be necessary for virus translation, packaging, and replication. Similarly, the Gag-Pol amino-acid sequence of this virus contains all the features required for cap-snatching and RNA polymerase activity, as well as the expected regional variables previously found in other LA viruses. Sequence comparison showed that two main clusters (99.2-100% and 96.3-98.8% identity) include most LA viruses from Saccharomyces, with TdV-LAbarr1 being the most distant from all these viruses (61.5-62.5% identity). Viral co-evolution and cross transmission between different yeast species are discussed based on this sequence comparison. Additional 5' and 3' sequences were found in the TdV-LAbarr1 genome as well as in some newly sequenced V-LA genomes from S. cerevisiae. A stretch involving the 5' extra sequence of TdV-LAbarr1 is identical to a homologous stretch close to the 5' end of the canonical sequence of the same virus (self-identity). Our modeling suggests that these stretches can form single-strand stem loops, whose unpaired nucleotides could anneal to create an intramolecular kissing complex. Similar stem loops are also found in the 3' extra sequence of the same virus as well as in the extra sequences of some LA viruses from S. cerevisiae. A possible origin of these extra sequences as well as their function in obviating ssRNA degradation and allowing RNA transcription and replication are discussed.

New Insights into the Genome Organization of Yeast Killer Viruses Based on "Atypical" Killer Strains Characterized by High-Throughput Sequencing

Viral M-dsRNAs encoding yeast killer toxins share similar genomic organization, but no overall sequence identity. The dsRNA full-length sequences of several known M-viruses either have yet to be completed, or they were shorter than estimated by agarose gel electrophoresis. High-throughput sequencing was used to analyze some M-dsRNAs previously sequenced by traditional techniques, and new dsRNAs from atypical killer strains of Saccharomyces cerevisiae and Torulaspora delbrueckii. All dsRNAs expected to be present in a given yeast strain were reliably detected and sequenced, and the previously-known sequences were confirmed. The few discrepancies between viral variants were mostly located around the central poly(A) region. A continuous sequence of the ScV-M2 genome was obtained for the first time. M1 virus was found for the first time in wine yeasts, coexisting with Mbarr-1 virus in T. delbrueckii. Extra 5'- and 3'-sequences were found in all M-genomes. The presence of repeated short sequences in the non-coding 3'-region of most M-genomes indicates that they have a common phylogenetic origin. High identity between amino acid sequences of killer toxins and some unclassified proteins of yeast, bacteria, and wine grapes suggests that killer viruses recruited some sequences from the genome of these organisms, or vice versa, during evolution.

A new wine Saccharomyces cerevisiae killer toxin (Klus), encoded by a double-stranded rna virus, with broad antifungal activity is evolutionarily related to a chromosomal host gene

Wine Saccharomyces cerevisiae strains producing a new killer toxin (Klus) were isolated. They killed all the previously known S. cerevisiae killer strains, in addition to other yeast species, including Kluyveromyces lactis and Candida albicans. The Klus phenotype is conferred by a medium-size double-stranded RNA (dsRNA) virus, Saccharomyces cerevisiae virus Mlus (ScV-Mlus), whose genome size ranged from 2.1 to 2.3 kb. ScV-Mlus depends on ScV-L-A for stable maintenance and replication. We cloned and sequenced Mlus. Its genome structure is similar to that of M1, M2, or M28 dsRNA, with a 5'-terminal coding region followed by two internal A-rich sequences and a 3'-terminal region without coding capacity. Mlus positive strands carry cis-acting signals at their 5' and 3' termini for transcription and replication similar to those of killer viruses. The open reading frame (ORF) at the 5' portion codes for a putative preprotoxin with an N-terminal secretion signal, potential Kex2p/Kexlp processing sites, and N-glycosylation sites. No sequence homology was found either between the Mlus dsRNA and M1, M2, or M28 dsRNA or between Klus and the K1, K2, or K28 toxin. The Klus amino acid sequence, however, showed a significant degree of conservation with that of the product of the host chromosomally encoded ORF YFR020W of unknown function, thus suggesting an evolutionary relationship.

Cloning, sequencing and expression of a full-length cDNA copy of the M1 double-stranded RNA virus from the yeast, Saccharomyces cerevisiae

Strains of the budding yeast, Saccharomyces cerevisiae, may contain one or more cytoplasmic viruses with double-stranded RNA (dsRNA) genomes. The killer phenomenon in yeast, in which one cell secretes a killer toxin that is lethal to another cell, is dependent upon the presence of the L-A and M1 dsRNA viruses. The L-A viral genome encodes proteins for the viral capsid, and for synthesis and encapsidation of single-stranded RNA replication cycle intermediates. The M1 virus depends upon the L-A-encoded proteins for its capsid and for the replication of its killer-toxin-encoding genome. A full-length cDNA clone of an M genome has been made from a single dsRNA molecule and shown to encode functional killer and killer-immunity functions. The sequence of the clone indicates minor differences from previously published sequences of parts of the M1 genome and of the complete genome of S14 (an internal deletion derivative of M1) but no unreported amino acid variants and no changes in putative secondary structures of the single-stranded RNA. A 118-nucleotide contiguous segment of the M1 genome has not previously been reported; 92 of those nucleotides comprise a segment of A nucleotides in the AU-rich bubble that follows the toxin-encoding reading frame.

Hybridization properties of oligodeoxynucleotide pairs bridged by polyarginine peptides

The hybridization properties of a series of probes, based on two 9mer oligodeoxynucleotides (designated as I and II) having an appended oligoarginine chain (Rn) to produce peptide-oligonucleotide conjugates or peptide-bridged oligonucleotide pairs (e.g. Rn-I or II-Rn-I), were investigated. For the double-linked probes, we found that the peptide bridge induces the two 9mers to bind complementary single-stranded DNA or RNA targets with substantially enhanced thermal stability. The resulting hybrid with complementary DNA was found to assume a 1:1 complex in the B conformation as judged by UV mixing curves and CD spectroscopy. Complexes of single or double-linked probes with complementary RNA exhibited sensitivity to RNase H digestion. The influence of the identity and chirality of the repeating unit in the bridge, the length of the bridge, the gap size and the salt concentration on the hybridization properties of this new class of oligonucleotide probes was also studied. Our data reveal that these compounds exhibit properties that should prove useful in the development of antisense strategies.

Saccharomyces cerevisiae L-BC double-stranded RNA virus replicase recognizes the L-A positive-strand RNA 3' end

L-A and L-BC are two double-stranded RNA viruses present in almost all strains of Saccharomyces cerevisiae. L-A, the major species, has been extensively characterized with in vitro systems established, but little is known about L-BC. Here we report in vitro template-dependent transcription, replication, and RNA recognition activities of L-BC. The L-BC replicase activity converts positive, single-stranded RNA to double-stranded RNA by synthesis of the complementary RNA strand. Although L-A and L-BC do not interact in vivo, in vitro L-BC virions can replicate the positive, single-stranded RNA of L-A and its satellite, M1, with the same 3' end sequence and stem-loop requirements shown by L-A virions for its own template. However, the L-BC virions do not recognize the internal replication enhancer of the L-A positive strand. In a direct comparison of L-A and L-BC virions, each preferentially recognizes its own RNA for binding, replication, and transcription. These results suggest a close evolutionary relation of these two viruses, consistent with their RNA-dependent RNA polymerase sequence similarities.

Oligonucleotide-poly-L-ornithine conjugates: binding to complementary DNA and RNA

On the basis of the reported enhanced antisense activity of polylysine-oligonucleotide conjugates, a synthetic 12-mer oligodeoxyribonucleotide has been coupled at its 5' terminus to a series of positively charged (delta-ornithine)n cysteine peptides. Binding between the nucleic acid-peptide conjugate and its complementary DNA target sequence was detected by the impact of complexation on the melting temperature (Tm). It was found that the Tm for the nucleic acid-peptide gradually increased with increasing net charge on the conjugated peptide. Site-directed cleavage with RNase H demonstrates that the peptide-modified oligomer also hybridizes with its RNA target sequence. Increased affinity for target mRNA with net charge was shown by a cell-free translation arrest assay.

The internal polyadenylate tract of yeast killer virus M1 double-stranded RNA is variable in length

The 1.8-kbp M1 double-stranded (ds) RNA from type 1 killer strains of Saccharomyces cerevisiae contains an internal 200-bp adenine- and uracil-rich region. We have previously demonstrated that this region consists primarily of adenine residues on the plus strand of M1 dsRNA and on the full-length, in vitro synthesized (+) transcript (denoted m) of M1 dsRNA, neither of which contains 3'-terminal polyadenylate. We now show that there is variability in the length of the polyadenylate tracts of m transcripts synthesized in vitro by virions purified from either of the K1 diploid killer strains A364A X S7 or A364A X 1384. This variability reflects size differences seen in the corresponding M1 dsRNA genomes which, along with other data presented, localizes the variability in the length of M1 dsRNA to the adenine- and uracil-rich region.

Yeast killer toxin: site-directed mutations implicate the precursor protein as the immunity component

Yeast killer toxin and a component giving immunity to it are both encoded by a gene specifying a single 35 kd precursor polypeptide. This precursor is composed of a leader peptide, the alpha and beta subunits of the secreted toxin, and a glycosylated gamma peptide separating the latter. The toxin subunits are proteolytically processed from the precursor during toxin secretion. Using site-directed mutagenesis, we have identified a region of the precursor gene necessary for expression of the immunity phenotype. This immunity-coding region extends through the C-terminal half of the alpha subunit into the N-terminal part of the gamma glycopeptide. Mutations in other parts of the gene allow full immunity but produce precursors that fail to be processed. The precursor can therefore confer immunity, and we propose that it does so in the wild type by competing with mature toxin for binding to a membrane receptor.

Expression of a cDNA derived from the yeast killer preprotoxin gene: implications for processing and immunity

The type I killer strains of Saccharomyces cerevisiae secrete a dimeric 19-kDa protein that kills sensitive cells by disrupting cytoplasmic membrane function. This toxin is encoded by the double-stranded RNA plasmid M1-dsRNA, which also determines specific immunity to toxin. A preprotoxin, the 35-kDA in vitro translation product of denatured M1-dsRNA, is presumed to be the primary in vivo gene product. To facilitate studies on preprotoxin structure and maturation, we have inserted a partial cDNA copy of M1-dsRNA into the yeast vector p1A1, bringing it under control of the phosphate-repressible PHO5 promoter. This in-frame gene fusion encodes all of the preprotoxin sequence except for its N-terminal secretion leader, which is replaced by the leader sequence of PHO5. Transformation of sensitive yeast strains lacking M1-dsRNA with such fusion plasmids converts them to phosphate-repressible, immune killers, demonstrating that both toxin and immunity determinants are contained within the preprotoxin molecule. L-1-Tosylamido-2-phenylethyl chloromethyl ketone retards glycosylation of preprotoxin to toxin, facilitating size comparisons and indicating that processing of the normal precursor involves three glycosylation events but does not involve cotranslational leader peptidase action. In contrast, the PHO5 leader is apparently removed from the fusion preprotoxin.

Sequence of the M1-2 region of killer virus double-stranded RNA

A full-length complementary DNA (cDNA) copy of the M1-2 region of the double-stranded genome of the yeast killer virus was synthesized by reverse transcription, utilizing the m in vitro transcript as template and synthetic primers for both strands. The sequence lacks any long open reading frames (ORFs). The internal portion of the M1-2 region includes the sequence that is linked to the subterminal 229 bases of the M1-1 homologous region in the S3 defective-interfering mutant of killer virus double-stranded RNA (dsRNA). Thus, the probable site at which the deletion occurred in S3 has been identified.

Analysis and utilization of the preprotoxin gene encoded in the M1 double-stranded RNA of yeast

The yeast type 1 toxin is a secreted protein which, along with immunity to the toxin, is encoded by an encapsidated double-stranded RNA (dsRNA) as a precursor protein, the preprotoxin. This chapter reviews recent work that has led to sequencing of complementary DNA (cDNA) copies of the preprotoxin gene, expression of toxin and toxin-immunity from cDNA, and use of the cDNA to effect secretion from yeast of a bacterial cellulase.

Structure and expression of the M2 genomic segment of a type 2 killer virus of yeast

The M2 double-stranded (ds) RNA species encodes toxin and resistance functions in Saccharomyces cerevisiae strains with the K2 killer specificity. RNA sequence analysis reveals the presence of a large open reading frame on the larger heat-cleavage product of M2 dsRNA, which is translated in vitro to yield a 28 kd polypeptide as a major product. The postulated translation initiator AUG triplet is located within a stem and loop structure near the 5' terminus of the positive strand, which also contains plausible 18S and 5.8S ribosomal RNA binding sites. These features may serve to regulate the translation of the K2 toxin precursor. The M1 (from type 1 yeast killers) and M2 dsRNA species lack extensive sequence homology, although specific features are shared, which may represent structural elements required for gene expression and replication.

Terminal sequences of the bacteriophage phi 6 segmented dsRNA genome and its messenger RNAs

The ends of the three dsRNA genome segments (L, M, and S) of bacteriophage phi 6 (strand separated and/or intact) and the 5' ends of the middle and small single-strand messenger RNAs have been sequenced by base-specific partial enzymatic digestion. Terminal sequences for the large and middle dsRNA strands extend about 60 bases. The three dsRNA segments have 18 homologous bases at the left end except for position 2, which differs in the L segment. A 17-base homology defines the right ends of L and M dsRNAs and probably S dsRNA as well. The 5' ends of middle and small messenger RNAs are identical to the corresponding viral (+) strands.

Double-stranded RNAs that encode killer toxins in Saccharomyces cerevisiae: unstable size of M double-stranded RNA and inhibition of M2 replication by M1

The sizes of M1 and M2 (but not L) change rapidly with growth, varying by perhaps as much as 33%. Size variation is seen within 76 generations. In addition, the exclusion of M2 by M1 or L-A-E [( EXL]) is mediated by inhibition of replication or segregation, not by enhanced degradation of preexisting molecules.

Sequence comparison of the 3' ends of a subgenomic RNA and the genomic RNAs of barley stripe mosaic virus

All strains of barley stripe mosaic virus examined encapsidate small amounts of an 800-nucleotide (NT) gamma-subgenomic (sg) RNA. This sgRNA has been isolated from genomic (g) RNAs of the Type and North Dakota 18 (ND18) strains and the sequence of these RNAs has been compared near the 3' end. The immediate 3' termini of the gRNAs terminate in the icosomer-GGUCCCCCAAGGGAAGACCAOH-3' and differ from the sgRNAs, which are polyadenylated. The poly(A) tracts of the sgRNAs are heterogeneous with lengths ranging from 10 to greater than 150 NT. Polyacrylamide gel electrophoresis of complementary (c) DNAs transcribed in the presence of dideoxynucleotides reveals that the sgRNAs from Type and ND18 have almost identical sequences for at least 160 NT adjacent to the 5' side of the poly(A) region. This region of the sgRNA from the ND18 strain is nearly identical to a 95-NT sequence adjacent to a poly(A) tract located at the 3' end of a 2050-base pair cDNA cloned from the gamma-genomic RNA of ND18. These results suggest that the sequences encoding the sgRNA are located upstream of an internal poly(A) region situated more than 200 NT from the 3' end of the gamma-genomic RNA.

Double-stranded RNAs that encode killer toxins in Saccharomyces cerevisiae: unstable size of M double-stranded RNA and inhibition of M2 replication by M1

The sizes of M1 and M2 (but not L) change rapidly with growth, varying by perhaps as much as 33%. Size variation is seen within 76 generations. In addition, the exclusion of M2 by M1 or L-A-E [( EXL]) is mediated by inhibition of replication or segregation, not by enhanced degradation of preexisting molecules.

Genome structure and expression of a defective interfering mutant of the killer virus of yeast

A large internal deletion in M1 double-stranded (ds) RNA from the killer virus of Saccharomyces cerevisiae generates a suppressive (S3) dsRNA molecule. Strains which harbor S3 dsRNA are defective in toxin production and immunity to the toxin. The biochemical defect in expression has been investigated and is apparently due to truncation of the protoxin polypeptide translation reading frame on S3 dsRNA. Transcription in vivo, and in isolated virions in vitro, results in the synthesis of a full-length positive polarity messenger RNA, denoted s. The s transcript contains no long poly(A) tracts as determined by its lack of affinity for oligo(dT)-cellulose, and as inferred by sequence analysis of approximately 87% of the S3 dsRNA genome. These data support a model for template coding of polyadenylate in transcripts derived from the wild-type M1 dsRNA. The orientation of the sequences conserved on S3 dsRNA with respect to M1 dsRNA has been determined. Some of the conserved sequences are likely to be required for the maintenance and replication of these viral dsRNA genomes in S. cerevisiae.

Double-stranded ribonucleic acid killer systems in yeasts

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Saccharomyces cerevisiae killer virus transcripts contain template-coded polyadenylate tracts

The M double-stranded RNA component of type 1 killer strains of the yeast Saccharomyces cerevisiae contains an internal 200-base pair adenine- and uracil-rich region. The plus strands of this viral genomic RNA contain an internal adenine-rich region which allows these strands to bind to polyuridylate-Sepharose as tightly as do polyadenylated RNAs with 3'-terminal polyadenylated tracts of 70 to 100 residues. Internal template coding of an adenine-rich tract in positive polarity in vivo and in vitro transcripts of M double-stranded RNA may serve as an alternate method of transcript polyadenylation. The 3'-terminal residue of the in vitro m transcript is a non-template-encoded purine residue. The 5' terminus of this transcript is involved in a stem-and-loop structure which includes an AUG initiation codon, along with potential 18S and 5.8S rRNA binding sites. Except for the 3'-terminal residue, transcription in in vitro shows complete fidelity.

Multiple L double-stranded RNA species of Saccharomyces cerevisiae: evidence for separate encapsidation

The L double-stranded (ds) RNA component of Saccharomyces cerevisiae may contain up to three dsRNA species, each with a distinct sequence but with identical molecular weights. These dsRNAs have been separated from each other by denaturation and polyacrylamide gel electrophoresis. The 3' terminal sequences of the major species, LA dsRNA, were determined. Secondary structural analysis supported the presence of two stem and loop structures at the 3' terminus of the LA positive strand. In strain T132B NK-3, both the LA and LC species are virion encapsidated. Two distinct classes of virions were purified from this strain, each with a different RNA polymerase activity and with distinct protein components. The heavy virions harbored LA dsRNA, whereas the LC dsRNA species co purified with the light virion peak. Thus, LA and LC dsRNAs, when present in the same cell, may be separately encapsidated.

Sequence of the preprotoxin dsRNA gene of type I killer yeast: multiple processing events produce a two-component toxin

The preprotoxin gene of the 1.9 kb M1 dsRNA genome from type I killer yeast has been sequenced employing a partial-length cDNA derived from an in vivo transcript. A single open reading frame, commencing with AUG at M1 dsRNA bases 14-16, terminates with UAG at 963-965 and codes for a 316 amino acid protein, believed to be identical to the 34 kd preprotoxin species, M1-P1, synthesized by in vitro translation of denatured M1 dsRNA. N-terminal sequencing of M1-P1 confirms this prediction. Secreted toxin is shown to consist of two dissimilar, disulfide-bonded subunits, alpha and beta, of apparent size 9.5 and 9.0 kd, respectively, whose N-terminal sequences are also found in the predicted preprotoxin sequence. Its proposed domains consist of delta, a 44 amino acid N-terminal segment, followed by alpha and beta, which are separated by gamma, a large central glycosylated segment. Processing sites, domain functions, and the potential role of gamma in immunity are discussed.

Multiple L double-stranded RNA species of Saccharomyces cerevisiae: evidence for separate encapsidation

The L double-stranded (ds) RNA component of Saccharomyces cerevisiae may contain up to three dsRNA species, each with a distinct sequence but with identical molecular weights. These dsRNAs have been separated from each other by denaturation and polyacrylamide gel electrophoresis. The 3' terminal sequences of the major species, LA dsRNA, were determined. Secondary structural analysis supported the presence of two stem and loop structures at the 3' terminus of the LA positive strand. In strain T132B NK-3, both the LA and LC species are virion encapsidated. Two distinct classes of virions were purified from this strain, each with a different RNA polymerase activity and with distinct protein components. The heavy virions harbored LA dsRNA, whereas the LC dsRNA species co purified with the light virion peak. Thus, LA and LC dsRNAs, when present in the same cell, may be separately encapsidated.

Saccharomyces cerevisiae killer virus transcripts contain template-coded polyadenylate tracts

The M double-stranded RNA component of type 1 killer strains of the yeast Saccharomyces cerevisiae contains an internal 200-base pair adenine- and uracil-rich region. The plus strands of this viral genomic RNA contain an internal adenine-rich region which allows these strands to bind to polyuridylate-Sepharose as tightly as do polyadenylated RNAs with 3'-terminal polyadenylated tracts of 70 to 100 residues. Internal template coding of an adenine-rich tract in positive polarity in vivo and in vitro transcripts of M double-stranded RNA may serve as an alternate method of transcript polyadenylation. The 3'-terminal residue of the in vitro m transcript is a non-template-encoded purine residue. The 5' terminus of this transcript is involved in a stem-and-loop structure which includes an AUG initiation codon, along with potential 18S and 5.8S rRNA binding sites. Except for the 3'-terminal residue, transcription in in vitro shows complete fidelity.

Synthesis of a double-stranded cDNA transcript of the killer toxin-coding region of the yeast M1 double-stranded RNA

Reverse transcription of methylmercuryhydroxide-treated M1 double-stranded RNA of yeast produces several discrete single-stranded and double-stranded cDNA's from oligo (dT)12-18 primer. S1 nuclease analysis shows that the longest transcript of the 1.8 kb template, a 2.2 kb molecule, is a 1.1 kb duplex terminated at one end by a hairpin-like structure. The 1.1 kb ds cDNA contains a complete copy of the M1-1, toxin-coding, sequence of M1 double-stranded RNA, and its synthesis is primed from oligo (dT)12-18 that anneals to a sequence within the internal, AU-rich, region of the template.

Characterization of a segmented double-stranded RNA virus in Drosophila Kc cells

Drosophila Kc cells contain a series of RNA fragments ranging in size from 980 to 4600 bp. The fragments copurify with a virus-like nucleoprotein particle which has a density of 1.384 g/cm3 and is a 62 nm diameter icosahedron. There are 11-13 double stranded RNAs in the particles; they are not homologous with either cultured cell or embryo genomic DNA. The particle also contains a minimum of seven polypeptides, three of which are major, and all of which continue to be synthesized in Kc cells in heat shock when normal cellular protein synthesis is shut down. This virus-like particle occurs in large enough amounts in Kc cells to confuse molecular and physiological studies, however the cells continue to multiply in its presence.

Yeast killer dsRNA plasmids are transcribed in vivo to produce full and partial-length plus-stranded RNAs

In vivo transcripts of the L (4.5 kb) and M (1.9 kb) dsRNA plasmids were examined in type I killers of Saccharomyces cerevisiae. Transcripts for both plasmids include full-length (l,m) and partial-length (la,ma) single-stranded species. Both L-dsRNA transcripts (l,la) have in vitro mRNA activity for L-P1, previously shown to be identical to ScV-P1, the 88,000 dalton major capsid protein of the virus-like particles containing L- and M1-dsRNAs. 1, but not 1a, is bound to poly(U)-sepharose and may be polyadenylated. Other L-dsRNA gene products and their transcripts may exist. For M1-dsRNA, both species (m, ma) have in vitro mRNA activity for M1-P1, the 32,000 dalton pre-protoxin encoded by M1-dsRNA. Both m and ma are bound to poly(U)-Sepharose and ma is probably a 5' terminal fragment of m. A functional model for M1-dsRNA killer plasmid structure is presented.

Reverse transcription of yeast double-stranded RNA and ribosomal RNA using synthetic oligonucleotide primers

The ability of the four oligodeoxyribonucleotide primers oligo(dT)12-18, oligo(dA)12-18, oligo(dG)12-18 and oligo(dC)12-18 to act as primers for avian myeloblastosis virus reverse transcriptase on denatured yeast double-stranded (ds) RNA templates was investigated. Oligo(dT) and oligo(dA) were found to prime the synthesis of 1.1 and 1.0 kb reverse transcripts, respectively, using denatured M dsRNA as a template. The oligo(dT)- and oligo(dA)-primed cDNAs of M dsRNA hybridized to the region of the M dsRNA that encoded the killer toxin and to each other. Addition of oligo(dT) to reverse transcription reactions of denatured L dsRNA produced a 4.3 kb cDNA. During the course of this investigation oligo(dC) was observed to be a highly efficient primer for reverse transcription of yeast 18 S ribosomal RNA. Oligo(dC) primed the synthesis of a 1.0 kb transcript of 18 S rRNA which hybridized to the large Eco RI fragment of the 18 S rRNA gene. Reverse transcription of double-stranded RNA and 25 S ribosomal RNA was found to occur to some extent in the absence of added oligonucleotide primer.

Structural and functional analysis of separated strands of killer double-stranded RNA of yeast

The two strands of the M double-stranded RNA species from a killer strain of Saccharomyces cerevisiae have been separated, and the 3'-terminal sequences of these strands have been determined. The positive strand programs the synthesis of the putative killer toxin precursor (M-p32) in a rabbit reticulocyte in vitro translation system. Only the negative strand hybridizes to the positive polarity transcript (m) synthesized in vitro by the virion-associated transcriptase activity. Secondary structural analysis of the extreme 3'-terminus of the negative strand using S1 nuclease is consistent with the presence of a large stem and loop structure previously proposed on the basis of RNA sequence data. This structure, and a similar structure at the corresponding 5'-terminus of the positive strand, may have functional significance in vivo.