No homology between double-stranded RNA and nuclear DNA of yeast

The evolution of novel fungal genes from non-retroviral RNA viruses

Background

Endogenous derivatives of non-retroviral RNA viruses are thought to be absent or rare in eukaryotic genomes because integration of RNA viruses in host genomes is impossible without reverse transcription. However, such derivatives have been proposed for animals, plants and fungi, often based on surrogate bioinformatic evidence. At present, there is little known of the evolution and function of integrated non-retroviral RNA virus genes. Here, we provide direct evidence of integration by sequencing across host-virus gene boundaries and carry out phylogenetic analyses of fungal hosts and totivirids (dsRNA viruses of fungi and protozoans). Further, we examine functionality by tests of neutral evolution, comparison of residues that are necessary for viral capsid functioning and assays for transcripts, dsRNA and viral particles.

Results

Sequencing evidence from gene boundaries was consistent with integration. We detected previously unknown integrated Totivirus-like sequences in three fungi (Candida parapsilosis, Penicillium marneffei and Uromyces appendiculatus). The phylogenetic evidence strongly indicated that the direction of transfer was from Totivirus to fungus. However, there was evidence of transfer of Totivirus-like sequences among fungi. Tests of selection indicated that integrated genes are maintained by purifying selection. Transcripts were apparent for some gene copies, but, in most cases, the endogenous sequences lacked the residues necessary for normal viral functioning.

Conclusions

Our findings reveal that horizontal gene transfer can result in novel gene formation in eukaryotes despite miniaturized genomic targets and a need for co-option of reverse transcriptase.

RNA dependent RNA polymerase activity associated with the double-stranded RNA virus of Giardia lamblia

Giardia lamblia, a parasitic protozoan, can contain a double-stranded RNA (dsRNA) virus, GLV (1). We have identified an RNA polymerase activity present specifically in cultures of GLV infected cells. This RNA polymerase activity is present in crude whole cell lysates as well as in lysates from GLV particles purified from the culture medium. The RNA polymerase has many characteristics common to other RNA polymerases (e.g. it requires divalent cations and all four ribonucleoside triphosphates), yet it is not inhibited by RNA polymerase inhibitors such as alpha-amanitin or rifampicin. The RNA polymerase activity synthesizes RNAs corresponding to one strand of the GLV genome, although under the present experimental conditions, the RNA products of the reaction are not full length viral RNAs. The in vitro products of the RNA polymerase reaction co-sediment through sucrose gradients with viral particles; and purified GLV viral particles have RNA polymerase activity. The RNA polymerase activities within and outside of infected cells closely parallel the amount of virus present during the course of viral infection. The similarities between the RNA polymerase of GLV and the polymerase associated with the dsRNA virus system of yeast are discussed.

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.

Nucleotide phosphotransferase, nucleotide kinase and inorganic pyrophosphatase activities of killer virions of yeast

The intracellular killer virions of yeast co-purify with an RNA polymerase activity which catalyzes the synthesis of full-length transcripts of the two viral genomic double-stranded RNA segments. This polymerase utilizes ribonucleoside diphosphates or triphosphates as substrates. The virions have other associated nucleotide-metabolizing enzyme activities, including nucleoside diphosphate kinase, adenosine monophosphate kinase, and nucleoside triphosphate phosphotransferase, an activity which catalyzes the exchange of gamma-phosphate from any ribonucleoside triphosphate with any ribonucleoside or deoxyribonucleoside triphosphate. The purified virions also contain an inorganic pyrophosphatase activity. These enzymes may allow the virus to utilize nucleotide pools distinct from those utilized in host cell transcription.

Double-stranded ribonucleic acid killer systems in yeasts

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Cloning of cDNA to a yeast viral double-stranded RNA and comparison of three viral RNAs

We have constructed recombinant DNA clones containing small complementary DNA (cDNA) sequences homologous to portions of a 4.8-kb yeast viral double-stranded RNA (dsRNA) (L1) that codes for the viral capsid polypeptide. Neither the viral dsRNA nor its in vitro transcript is polyadenylated; hence the cDNAs were synthesized by reverse transcriptase on the in vitro mRNA transcript made by the viral transcriptase, using sheared salmon sperm DNA as a random primer. This is the first reported cloning of cDNA homologous to a viral double-stranded RNA. This method should be of general utility for dsRNA viruses, since all have a capsid-associated transcriptase activity. The lengths of the overlapping cDNA inserts varied from 100 to 800 bp. About 40% of them mapped to the 5' end of the in vitro transcript, and these have been ordered. At least 1485 bp of this end of L1 is represented in the cloned cDNAs characterized. Using the cloned cDNAs as probes, we have shown that the L dsRNAs of two viral subtypes are similar at the transcription initiation site and dissimilar elsewhere.

Localization of genes for the double-stranded RNA killer virus of yeast

The M double-stranded RNA (ds RNA) genome segment of the cytoplasmically inherited killer virus of yeast codes for two polypeptides when denatured and translated in vitro: a previously known 32,000-dalton peptide and a newly discovered 19,000-dalton peptide (NaDodSO4/polyacrylamide gel electrophoresis). An internal 190-base-pair region of the ds RNA is selectively degraded by S1 nuclease treatment at 65 degrees C, resulting in two ds RNA fragments which contain the termini of the original ds RNA. The larger fragment codes for the 32,000-dalton polypeptide and the smaller fragment codes for the 19,000-dalton polypeptide. Thus, the two gene products of M are encoded by distinct regions of this ds RNA.

Yeast deRNA viral transcriptase pause products: identification of the transcript strand

ScV-L is a double-stranded RNA virus of the yeast Saccharomyces cerevisiae. The virus possesses a capsid-associated transcriptase activity the product of which is a single-stranded RNA complementary to only one strand of the double-stranded RNA template (L). We show that the U-rich 3' terminus of L is the initiation site of transcription and that a number of pause products are made. One prominent product has the sequence pppGAAAAAUUUUUAAAUUCAUAUAACUOH.

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.

Double-stranded RNA

High molecular weight, fully double-stranded RNA (dsRNA) has been recognized as the genetic material of many plant, animal, fungal, and bacterial viruses (Diplornaviruses): virusspecific dsRNA is also found in cells infected with single-stranded RNA viruses. DsRNA has identified in a variety of apparently normal eucaryotic cells and is associated with the "killer" character of certain strains of Saccaromyces cerevisiae.

Yeast viral RNA polymerase is a transcriptase

ScV-L is a simple double-stranded RNA virus of yeast, consisting of a 4.8 kilobase pair double-stranded RNA (L) encapsidated in isometric particles composed mainly of one polypeptide (ScV-Pl) of 88,000 daltons. L encodes ScV-Pl. There is a capsid-associated RNA polymerase that synthesizes in vitro predominantly single-stranded RNA. We show that this polymerase activity is a transcriptase, at the least one product of which is the mRNA for ScV-Pl. The transcript, like its template, is uncapped.

Encapsidation of yeast killer double-stranded ribonucleic acids: dependence of M on L

Virus-like particles containing either L or M double-stranded ribonucleic acid (dsRNA) were isolated from a killer toxin-producing strains of Saccharomyces cerevisiae (K+ R+). At least 95% of M- and 87% of L-dsRNA were recovered in virus-like particle-containing fractions. The major capsid polypeptides (ScV-P1) of both L and M virus-like particles were shown to be identical, and 95% of the cellular ScV-P1 was found in the virus-like particle-containing fractions. Since L-dsRNA encodes ScV-P1, provision of this protein for encapsidation of M-dsRNA defines at least one functional relationship between these dsRNA genomes and associates the L-dsRNA with the killer character. If encapsidation of M-dsRNA is essential for its replication or expression, then L-dsRNA plays an essential role in maintenance or expression of the killer phenotype. The relationship between the L- and M-dsRNA genomes would be analogous to that between a helper and a defective virus. The presence of only minor quantities or uncomplexed dsRNA and ScV-P1 suggests that their production is stringently coupled.

Transcription of killer virion double-stranded RNA in vitro

Intracellular virions of stationary phase ethanol-grown cells of a killer strain of Saccharomyces cerevisiae contain encapsulated M (1.1 x 10(6) dalton) and L (3.2 x 10(6) dalton) double-stranded RNA plasmids. These virions also contain RNA polymerase activity which catalyzes the synthesis of full-length, single-stranded, asymmetric transcripts (denoted m and l) of the virion double-stranded RNAs. Product m is made by M-containing particles and shows complete sequence homology to M but not to L. Product l is made by L-containing particles and shows complete homology only to L. The products show no self-homology, indicating asymmetric transcription. Therefore, the polymerase appears to function in vitro as a double-stranded RNA transcriptase. The lack of sequence homology between M and L is confirmed.

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.

Evolution of defective-interfering double-stranded RNAs of the yeast killer virus

We have characterized by T1 fingerprint analysis several defective interfering (DI) double-stranded RNAs of the simple yeast virus ScV. A common sequence of about 0.5 to 0.6 kilobase pairs, including both 3' termini of the parental RNA, was present in each DI RNA. Several DI RNAs had novel T1 oligonucleotides not present in their parental RNA.