Induction of yeast killer factor mutations

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.

In vivo mapping of a sequence required for interference with the yeast killer virus

The Saccharomyces cerevisiae viruses are noninfectious double-stranded RNA viruses whose segments are separately encapsidated. A large viral double-stranded RNA (L1; 4580 base pairs) encodes all required viral functions. M1, a double-stranded RNA of 1.9 kilobases, encodes an extracellular toxin (killer toxin) and cellular immunity to that toxin. Some strains contain smaller, S, double-stranded RNAs, derived from M1 by internal deletion. Particles containing these defective interfering RNAs can displace M1 particles by faster replication and thus convert the host strain to a nonkiller phenotype. In this work, we report the development of an assay in which the expression of S plus-strand from an inducible plasmid causes the loss of M1 particles. This assay provides a convenient method for identifying in vivo cis-acting sequences important in viral replication and packaging. We have mapped the sequence involved in interference to a region of 132 base pairs that includes two sequences similar to the viral binding site sequence previously identified in L1 by in vitro experiments.

Higher-order structure of Saccharomyces cerevisiae chromatin

We have developed a method for partially purifying chromatin from Saccharomyces cerevisiae (baker's yeast) to a level suitable for studies of its higher-order folding. This has required the use of yeast strains that are free of the ubiquitous yeast "killer" virus. Results from dynamic light scattering, electron microscopy, and x-ray diffraction show that the yeast chromatin undergoes a cation-dependent folding into 30-nm filaments that resemble those characteristic of higher-cell chromatin; moreover, the packing of nucleosomes within the yeast 30-nm filaments is similar to that of higher cells. These results imply that yeast has a protein or protein domain that serves the role of the histone H 1 found in higher cells; physical and genetic studies of the yeast activity could help elucidate the structure and function of H 1. Images of the yeast 30-nm filaments can be used to test crossed-linker models for 30-nm filament structure.

Overlapping genes in a yeast double-stranded RNA virus

The Saccharomyces cerevisiae viruses have a large viral double-stranded RNA which encodes the major viral capsid polypeptide. We have previously shown that this RNA (L1) also encodes a putative viral RNA-dependent RNA polymerase (D. F. Pietras, M. E. Diamond, and J. A. Bruenn, Nucleic Acids Res., 16:6226, 1988). The organization and expression of the viral genome is similar to that of the gag-pol region of the retroviruses. The complete sequence of L1 demonstrates two large open reading frames on the plus strand which overlap by 129 bases. The first is the gene for the capsid polypeptide, and the second is the gene for the putative RNA polymerase. One of the products of in vitro translation of the denatured viral double-stranded RNA is a polypeptide of the size expected of a capsid-polymerase fusion protein, resulting from a -1 frameshift within the overlapping region. A polypeptide of the size expected for a capsid-polymerase fusion product was found in virions, and it was recognized in Western blots (immunoblots) by antibodies to a synthetic peptide derived from the predicted polymerase sequence.

Construction of full-length cDNA copies of viral double-stranded RNA

A method is described for the construction of full-length cDNA clones of dsRNAs. All dsRNA viruses have a capsid-associated transcriptase that is responsible for synthesis of the plus strand that is then extruded from viral particles. We have used in vitro transcripts synthesized by the segmented Saccharomyces cerevisiae virus (ScV) as templates for first-strand cDNA synthesis. Synthesis was primed by a 33-base synthetic oligonucleotide. This contained 27 nucleotides complementary to the 3' end of the plus strand from one ScV viral dsRNA segment (S14), and 6 additional nucleotides encoding an XbaI restriction site at the 5' end. The second cDNA strand was synthesized using a similar XbaI linker-synthetic oligonucleotide and the ds cDNA was cloned by standard ligation techniques. All four cDNA plasmid isolates characterized by sequence analysis contained the complete 5' end sequence of S14. Two of these were complete at the 3' end, and one lacked a single base here. Of these four clones, one also retained the XbaI sites at either end. Preparing full-length cDNA clones with unique restriction-site linkers by the use of synthetic oligonucleotides allows for easier screening for complete cDNA clones if neither the vector nor the cDNA has the chosen restriction site. It also provides for easier sequence analysis and manipulation of the genome for later studies, such as cloning into expression vectors. This method is more efficient than any previously described for production of full-sized cDNA clones.

Conserved regions in defective interfering viral double-stranded RNAs from a yeast virus

We have completely sequenced a defective interfering viral double-stranded RNA (dsRNA) from the Saccharomyces cerevisiae virus. This RNA (S14) is a simple internal deletion of its parental dsRNA, M1, of 1.9 kilobases. The 5' 964 bases of the M1 plus strand encode the type 1 killer toxin of the yeast. S14 is 793 base pairs (bp) long, with 253 bp from the 5' region of its parental plus strand and 540 bp from the 3' region. All three defective interfering RNAs derived from M1 that have been characterized so far preserve a large 3' region, which includes five repeats of a rotationally symmetrical 11-bp consensus sequence. This 11-bp sequence is not present in the 5' 1 kilobase of the parental RNA or in any of the sequenced regions of unrelated yeast viral dsRNAs, but it is present in the 3' region of the plus strand of another yeast viral dsRNA, M2, that encodes the type 2 killer toxin. The 3' region of 550 bases of the M1 plus strand, previously only partially sequenced, reveals no large open reading frames. Hence only about half of M1 appears to have a coding function.

Conservative replication of double-stranded RNA in Saccharomyces cerevisiae by displacement of progeny single strands

Saccharomyces cerevisiae contains two double-stranded RNA (dsRNA) molecules, L and M, encapsulated in virus-like particles. After cells are transferred from dense (13C 15N) to light (12C 14N) medium, only two density classes of dsRNA are found, fully light (LL) and fully dense (HH). Cells contain single-stranded copies of both dsRNAs and, at least for L dsRNA, greater than 99% of these single strands are the positive protein-encoding strand. Single-stranded copies of L and M dsRNA accumulate rapidly in cells arrested in the G1 phase. These results parallel previous observations on L dsRNA synthesis and are consistent with a role of the positive single strands as intermediates in dsRNA replication. We propose that new positive strands are displaced from parental molecules and subsequently copied to produce the completely new duplexes.

Conservative replication of double-stranded RNA in Saccharomyces cerevisiae by displacement of progeny single strands

Saccharomyces cerevisiae contains two double-stranded RNA (dsRNA) molecules, L and M, encapsulated in virus-like particles. After cells are transferred from dense (13C 15N) to light (12C 14N) medium, only two density classes of dsRNA are found, fully light (LL) and fully dense (HH). Cells contain single-stranded copies of both dsRNAs and, at least for L dsRNA, greater than 99% of these single strands are the positive protein-encoding strand. Single-stranded copies of L and M dsRNA accumulate rapidly in cells arrested in the G1 phase. These results parallel previous observations on L dsRNA synthesis and are consistent with a role of the positive single strands as intermediates in dsRNA replication. We propose that new positive strands are displaced from parental molecules and subsequently copied to produce the completely new duplexes.

Double-stranded ribonucleic acid killer systems in yeasts

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Two new double-stranded RNA molecules showing non-mendelian inheritance and heat inducibility in Saccharomyces cerevisiae

Certain strains of Saccharomyces cerevisiae were found to have a complex nuclear defect (designated clo-) that makes cells unable to maintain some L-B and some L-C double-stranded RNAs at 25 degrees C. The clo- strains were not defective in maintenance of L-A, M1, or M2 double-stranded RNAs. Most clo-strains lacking L and M carry small amounts of two double-stranded RNA species intermediate in size between L and M and denoted T (2.7 kilobase pairs) and W (2.25 kilobase pairs). Some strains carry both T and W, some carry neither, and some carry only W; no strains carrying only T have been found. Both T and W show 4+:0 segregation in meiosis and efficient transmission by cytoplasmic mixing (cytoduction), indicating that they are non-Mendelian genetic elements. T and W do not cross-hybridize with each other or with L-A, L-B, L-C, M1, M2, or chromosomal DNA. T and W are apparently distinct from other known non-Mendelian genetic elements (2mu DNA, [rho], [psi], 20S RNA, [URE3]). In most strains the copy number of both T and W is increased about 10-fold by the growth of cells at 37 degrees C. This heat inducibility of T and W is under control of a cytoplasmic gene. T and W double-stranded RNAs are not found in a purified L-containing virus-like particle preparation from a strain containing L-B, T, and W double-stranded RNAs. The role, if any, of T or W in the killer systems is not known.

Two new double-stranded RNA molecules showing non-mendelian inheritance and heat inducibility in Saccharomyces cerevisiae

Certain strains of Saccharomyces cerevisiae were found to have a complex nuclear defect (designated clo-) that makes cells unable to maintain some L-B and some L-C double-stranded RNAs at 25 degrees C. The clo- strains were not defective in maintenance of L-A, M1, or M2 double-stranded RNAs. Most clo-strains lacking L and M carry small amounts of two double-stranded RNA species intermediate in size between L and M and denoted T (2.7 kilobase pairs) and W (2.25 kilobase pairs). Some strains carry both T and W, some carry neither, and some carry only W; no strains carrying only T have been found. Both T and W show 4+:0 segregation in meiosis and efficient transmission by cytoplasmic mixing (cytoduction), indicating that they are non-Mendelian genetic elements. T and W do not cross-hybridize with each other or with L-A, L-B, L-C, M1, M2, or chromosomal DNA. T and W are apparently distinct from other known non-Mendelian genetic elements (2mu DNA, [rho], [psi], 20S RNA, [URE3]). In most strains the copy number of both T and W is increased about 10-fold by the growth of cells at 37 degrees C. This heat inducibility of T and W is under control of a cytoplasmic gene. T and W double-stranded RNAs are not found in a purified L-containing virus-like particle preparation from a strain containing L-B, T, and W double-stranded RNAs. The role, if any, of T or W in the killer systems is not known.

A novel species of double stranded RNA in mitochondria of Saccharomyces cerevisiae

A double stranded RNA species has been detected in guanidine hydrochloride extracts of mitochondria from respiratory competent cells of Saccharomyces cerevisiae. This novel mitochondrial RNA, termed mtdsRNA, has been purified in a Cs2SO4 density gradient where it bands at a density of 1.58 g/ml. The mtdsRNA runs as a single slow moving band on agarose gels. Its double stranded RNA character was evidenced by its sensitivity to digestion by RNase III, but not by RNase H, or DNase I. Moreover the mtdsRNA hybridized to each separated strand of a petite mtDNA. It is concluded that mtdsRNA contains long transcripts derived from most regions of yeast mtDNA, because 1) its weight-average length as determined by electron microscopy was 4.5 micrometer (about 14 kb, or 20% of the wild type mtDNA genome), and 2) it hybridized to each of a series of eight petite mtDNA probes carrying sequences derived from widely different segments of mtDNA. It is proposed that prolonged transcription of both strands of yeast mtDNA can occur and that mtdsRNA arises from hybridization of these long complementary transcripts.

[HOK], a new yeast non-Mendelian trait, enables a replication-defective killer plasmid to be maintained

The K1 killer plasmid, [KIL-k1], of Saccharomyces cerevisiae is a 1.25 x 10(6) dalton linear double-stranded RNA plasmid coding for a protein toxin and immunity to that toxin. The [KIL-sd1] plasmid is a replication-defective mutant of [KIL-k1] that depends on one of the recessive chromosomal superkiller (ski-) mutations for its maintenance (Toh-e and Wickner 1979). This report concerns a means by which [KIL-sd1] can be stably maintained in a SKI+ host. Strains carrying a plasmid we call [HOK] (helper of killer) stably maintain [KIL-sd1]. [HOK] segregates 4 [HOK]:0 in meiotic crosses and is efficiently transferred by cytoplasmic mixing (heterokaryon formation). [HOK] depends for its maintenance on the products of PET18, MAK3, and MAK10, three chromosomal genes needed to maintain [KIL-k1], but is independent of 10 other MAK genes and of MKT1. [HOK] is not mitochondrial DNA and is unaffected by agents which convert psi+ strains to psi-. [HOK] is also distinct from the previously described plasmids [URE3], 20S RNA, 2 mu DNA, and [EXL]. Strains lacking [HOK] consistently have a four-fold lower copy number of L double-stranded RNA than strains carrying [HOK].

Sequences at the 3' ends of yeast viral dsRNAs: proposed transcriptase and replicase initiation sites

ScV is a double-stranded RNA virus of yeast consisting of two separately encapsidated dsRNAs (L and M). ScV-1 and ScV-2 are two dsRNA viruses present in two different yeast killer strains, K1 and K2. Our 3' end sequence analysis shows that the two sets of viral dsRNAs from ScV-1 and ScV-2 are very similar. Consensus sequences for transcriptase and replicase initiation are proposed. A stem and loop structure with a 3' terminal AUGC sequence, like that of several plant virus plus strand RNAs, is present at the putative replicase initiation site of one of the yeast viral RNA plus strands.

Intergeneric transfer of deoxyribonucleic acid killer plasmids, pGKl1 and pGKl2, from Kluyveromyces lactis into Saccharomyces cerevisiae by cell fusion

Two novel linear deoxyribonucleic acid plasmids, pGKl1 and pGKl2, were isolated from the yeast Kluyveromyces lactis. K. lactis strains harboring the pGK1 plasmids killed a certain group of yeasts, including Saccharomyces cerevisiae, Saccharomyces italicus, Saccharomyces rouxii, K. lactis, Kluyveromyces thermotolerans, Kluyvermyces vanudenii, Torulopsis glabrata, Candida utilis, and Candida intermedia. In this experiment, the pGKl1 and pGKl2 plasmids were intergenerically transferred from a K. lactis killer strain into a non-killer (killer-sensitive) strain of S. cerevisiae by the use of a protoplast fusion technique. Both of the pGKl plasmids replicated autonomously and stably in the new host cells of S. cerevisiae and could coexist with the resident 2-micrometers deoxyribonucleic acid plasmid. The S. cerevisiae cells which accepted the pGKl plasmids expressed the same killer phenotype as that of the donor K. lactis killer and became resistant to the K. lactis killer. The pGKl plasmids existing in the S. cerevisiae cells were cured by treatment with ethidium bromide, and the killer and resistance characters were simultaneously lost. From there results, it was concluded that both the killer and the resistance genes are located on the pGKl plasmids.

Yeast viral double-stranded RNAs have heterogeneous 3' termini

The yeast virus, ScV, is communicated only by mating. It has two separately encapsidated dsRNAs. One of these, L, codes for the major capsid polypeptide. The other, M, codes for a polypeptide toxic to yeasts without ScV-M particles. Defective interfering particles containing fragments of M (S) displace ScV-M when they arise. We have shown that five independently isolated S dsRNAs are all derived by internal deletion of M. The 3' ends of all the ScV dsRNAs are markedly heterogeneous. For instance, half of the first 35 nucleotides at one 3' end of M and S are variable. Conserved sequences at the 3' ends of M and S are AAACACCCAUCAOH and AUUUCUUUAUUUUUCAOH. Conserved sequences at the 3' ends of L are UAAAAAUUUUUCAOH and AAAAAUXCAOH, where X is variable. We propose that the sequence AUUUUUCAOH is a recognition sequence for the capsid-associated single-stranded RNA polymerase activity. Since all the viral RNAs have pppGp 5' termini, their 3' termini probably extended one nucleotide beyond the terminal pppGp.