Yeast 20 S RNA replicon. Replication intermediates and encoded putative RNA polymerase

A novel narnavirus is widespread in Saccharomyces cerevisiae and impacts multiple host phenotypes

RNA viruses are a widespread, biologically diverse group that includes the narnaviridiae, a family of unencapsidated RNA viruses containing a single ORF that encodes an RNA-dependent RNA polymerase. In the yeast Saccharomyces cerevisiae, the 20S and 23S RNA viruses are well-studied members of the narnaviridiae, which are present at low intracellular copy numbers, unless induced by stress or unfavorable growth conditions, and are not known to affect host fitness. In this study, we describe a new S. cerevisiae narnavirus that we designate as N1199. We show that N1199 is uniquely present as a double-stranded RNA at a high level relative to other known members of this family in 1 strain background, YJM1199, and is present as a single-stranded RNA at lower levels in 98 of the remaining 100-genomes strains. Furthermore, we see a strong association between the presence of high level N1199 and host phenotype defects, including greatly reduced sporulation efficiency and growth on multiple carbon sources. Finally, we describe associations between N1199 abundance and host phenotype defects, including autophagy.

Persistence of Ambigrammatic Narnaviruses Requires Translation of the Reverse Open Reading Frame

Narnaviruses are RNA viruses detected in diverse fungi, plants, protists, arthropods, and nematodes. Though initially described as simple single-gene nonsegmented viruses encoding RNA-dependent RNA polymerase (RdRp), a subset of narnaviruses referred to as "ambigrammatic" harbor a unique genomic configuration consisting of overlapping open reading frames (ORFs) encoded on opposite strands. Phylogenetic analysis supports selection to maintain this unusual genome organization, but functional investigations are lacking. Here, we establish the mosquito-infecting Culex narnavirus 1 (CxNV1) as a model to investigate the functional role of overlapping ORFs in narnavirus replication. In CxNV1, a reverse ORF without homology to known proteins covers nearly the entire 3.2-kb segment encoding the RdRp. Additionally, two opposing and nearly completely overlapping novel ORFs are found on the second putative CxNV1 segment, the 0.8-kb "Robin" RNA. We developed a system to launch CxNV1 in a naive mosquito cell line and then showed that functional RdRp is required for persistence of both segments, and an intact reverse ORF is required on the RdRp segment for persistence. Mass spectrometry of persistently CxNV1-infected cells provided evidence for translation of this reverse ORF. Finally, ribosome profiling yielded a striking pattern of footprints for all four CxNV1 RNA strands that was distinct from actively translating ribosomes on host mRNA or coinfecting RNA viruses. Taken together, these data raise the possibility that the process of translation itself is important for persistence of ambigrammatic narnaviruses, potentially by protecting viral RNA with ribosomes, thus suggesting a heretofore undescribed viral tactic for replication and transmission. IMPORTANCE Fundamental to our understanding of RNA viruses is a description of which strand(s) of RNA are transmitted as the viral genome relative to which encode the viral proteins. Ambigrammatic narnaviruses break the mold. These viruses, found broadly in fungi, plants, and insects, have the unique feature of two overlapping genes encoded on opposite strands, comprising nearly the full length of the viral genome. Such extensive overlap is not seen in other RNA viruses and comes at the cost of reduced evolutionary flexibility in the sequence. The present study is motivated by investigating the benefits which balance that cost. We show for the first time a functional requirement for the ambigrammatic genome configuration in Culex narnavirus 1, which suggests a model for how translation of both strands might benefit this virus. Our work highlights a new blueprint for viral persistence, distinct from strategies defined by canonical definitions of the coding strand.

Viruses and prions of Saccharomyces cerevisiae

Saccharomyces cerevisiae has been a key experimental organism for the study of infectious diseases, including dsRNA viruses, ssRNA viruses, and prions. Studies of the mechanisms of virus and prion replication, virus structure, and structure of the amyloid filaments that are the basis of yeast prions have been at the forefront of such studies in these classes of infectious entities. Yeast has been particularly useful in defining the interactions of the infectious elements with cellular components: chromosomally encoded proteins necessary for blocking the propagation of the viruses and prions, and proteins involved in the expression of viral components. Here, we emphasize the L-A dsRNA virus and its killer-toxin-encoding satellites, the 20S and 23S ssRNA naked viruses, and the several infectious proteins (prions) of yeast.

A member of the virus family Narnaviridae from the plant pathogenic oomycete Phytophthora infestans

A virus that has properties consistent with inclusion in the virus family Narnaviridae was described in Phytophthora infestans, the oomycete that caused the Irish potato famine. The genome of phytophthora infestans RNA virus 4 (PiRV-4) is 2,984 nt with short complementary terminal sequences and a single open reading frame predicted to encode an RNA-dependent RNA polymerase (RdRp) most closely related to saccharomyces cerevisiae narnavirus 20S (ScNV-20S) and ScNV-23S, the members of the genus Narnavirus, family Narnaviridae. This report constitutes the first description of a member of the family Narnaviridae from a host taxon outside of the kingdom Fungi.

20S RNA narnavirus defies the antiviral activity of SKI1/XRN1 in Saccharomyces cerevisiae

20S RNA virus is a persistent positive strand RNA virus found in Saccharomyces cerevisiae. We previously observed that the virus generated in vivo from a launching vector possessed the correct RNA termini without extra sequences. Here we present evidence that the SKI1/XRN1 5'-exonuclease plays a major role in the elimination of the non-viral upstream sequences from the primary transcripts. The virus, once generated, however, is fairly unaffected by overexpression or deletion of SKI1/XRN1. By contrast, the copy number of the L-A double-stranded RNA virus in the same host is greatly increased by the deletion of SKI1/XRN1, and overexpression of the gene cured L-A virus from the cells at a high frequency. 20S RNA virus, unlike L-A virus, has a strong secondary structure at its 5'-end: the first four nucleotides are G, and they are buried at the bottom of a long stem structure, features known to inhibit the SKI1/XRN1 5'-exonuclease progression. Mutations that weakened the 5'-stem structure made 20S RNA virus vulnerable to SKI1/XRN1. These results, together with the data on L-A virus, indicate a strong anti-RNA virus activity of SKI1/XRN1. Given that 20S RNA virus resides and replicates in the cytoplasm without a protective capsid, our results suggest that the strong secondary structure at the 5'-end is crucial for the 20S RNA virus to evade the host SKI1/XRN1 defense.

Interactions of the RNA polymerase with the viral genome at the 5'- and 3'-ends contribute to 20S RNA narnavirus persistence in yeast

20S RNA narnavirus is a positive strand RNA virus found in the yeast Saccharomyces cerevisiae. The viral genome (2514 nucleotides) only encodes a single protein (p91), the RNA-dependent RNA polymerase and does not have capsid proteins to form intracellular virions. The genomic RNA has no 3' poly(A) tail and perhaps no cap structure at the 5'-end; thus resembling an intermediate of mRNA degradation. The virus, however, escapes the host surveillance and replicates in the yeast cytoplasm persistently. The viral genome is not naked but exists in the form of a ribonucleoprotein complex with p91 in a 1:1 stoichiometry. Here we investigated interactions between p91 and the viral genome. Our results indicate that p91 directly or indirectly interacts with the RNA at the 5'- and 3'-end regions and to a lesser extent at a central part. The 3'-end site is identical to or overlaps with the 3' cis signal for replication identified previously. The 5'-site is at the second stem loop structure from the 5'-end (nucleotides 72-104), and this structure also contains a cis signal for replication. Analysis of mutants in the structure revealed a tight correlation between replication and formation of complexes. These results highlight the importance of ribonucleoprotein complexes for the viral life cycle. We will discuss implications of these findings especially on how the virus escapes from mRNA degradation pathways and resides in the cytoplasm persistently despite the lack of a protective capsid.

Launching of the yeast 20 s RNA narnavirus by expressing the genomic or antigenomic viral RNA in vivo

20 S RNA virus is a persistent positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome encodes only its RNA polymerase, p91, and resides in the cytoplasm in the form of a ribonucleoprotein complex with p91. We succeeded in generating 20 S RNA virus in vivo by expressing, from a vector, genomic strands fused at the 3'-ends to the hepatitis delta virus antigenomic ribozyme. Using this launching system, we analyzed 3'-cis-signals present in the genomic strand for replication. The viral genome has five-nucleotide inverted repeats at both termini (5'-GGGGC... GCCCC-OH). The fifth G from the 3'-end was dispensable for replication, whereas the third and fourth Cs were essential. The 3'-terminal and penultimate Cs could be eliminated or modified to other nucleotides; however, the generated viruses recovered these terminal Cs. Furthermore, extra nucleotides added at the viral 3'-end were eliminated in the launched viruses. Therefore, 20 S RNA virus has a mechanism(s) to maintain the correct size and sequence of the viral 3'-end. This may contribute to its persistent infection in yeast. We also succeeded in generating 20 S RNA virus similarly from antigenomic strands provided active p91 was supplied from a second vector in trans. Again, a cluster of four Cs at the 3'-end in the antigenomic strand was essential for replication. In this work, we also present the first conclusive evidence that 20 S and 23 S RNA viruses are independent replicons.

Yeast prions [URE3] and [PSI+] are diseases

Viruses, plasmids, and prions can spread in nature despite being a burden to their hosts. Because a prion arises de novo in more than one in 10(6) yeast cells and spreads to all offspring in meiosis, its absence in wild strains would imply that it has a net deleterious effect on its host. Among 70 wild Saccharomyces strains, we found the [PIN+] prion in 11 strains, but the [URE3] and [PSI+] prions were uniformly absent. In contrast, the "selfish" 2mu DNA was in 38 wild strains and the selfish RNA replicons L-BC, 20S, and 23S were found in 8, 14, and 1 strains, respectively. The absence of [URE3] and [PSI+] in wild strains indicates that each prion has a net deleterious effect on its host.

Native replication intermediates of the yeast 20 S RNA virus have a single-stranded RNA backbone

20 S RNA virus is a positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.5 kb) only encodes its RNA polymerase (p91) and forms a ribonucleoprotein complex with p91 in vivo. A lysate prepared from 20 S RNA-induced cells showed an RNA polymerase activity that synthesized the positive strands of viral genome. When in vitro products, after phenol extraction, were analyzed in a time course, radioactive nucleotides were first incorporated into double-stranded RNA (dsRNA) intermediates and then chased out to the final single-stranded RNA products. The positive and negative strands in these dsRNA intermediates were non-covalently associated, and the release of the positive strand products from the intermediates required a net RNA synthesis. We found, however, that these dsRNA intermediates were an artifact caused by phenol extraction. Native replication intermediates had a single-stranded RNA backbone as judged by RNase sensitivity experiments, and they migrated distinctly from a dsRNA form in non-denaturing gels. Upon completion of RNA synthesis, positive strand RNA products as well as negative strand templates were released from replication intermediates. These results indicate that the native replication intermediates consist of a positive strand of less than unit length and a negative strand template loosely associated, probably through the RNA polymerase p91. Therefore, W, a dsRNA form of 20 S RNA that accumulates in yeast cells grown at 37 degrees C, is not an intermediate in the 20 S RNA replication cycle, but a by-product.

The bipartite 3'-cis-acting signal for replication is required for formation of a ribonucleoprotein complex in vivo between the viral genome and its RNA polymerase in yeast 23 S RNA virus

23 S RNA narnavirus is a persistent positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.9 kb) encodes only its RNA-dependent RNA polymerase, p104, and forms a ribonucleoprotein complex with p104 in vivo. Previously we succeeded in generating 23 S RNA virus in yeast from an expression vector containing the entire viral cDNA sequence. Using this system, we have recently identified a bipartite 3' cis-acting signal for replication. The signal consists of a stretch of four cytidines (Cs) at the 3' end and a mismatched pair of purines in a stem-loop structure that partially overlaps the terminal four Cs. Although the 3' terminal and penultimate Cs are not essential for virus launching, the generated viruses efficiently recovered these terminal nucleotides. In this work, we expressed RNA transcripts containing the entire 23 S RNA genome but incapable of generating the virus because of the presence of non-viral extra sequences at the 3' ends. These transcripts could form complexes with p104 in vivo, and a detailed analysis indicated that the mismatched pair of purines as well as the third and fourth Cs from the viral 3' end was essential for this complex-forming activity. Given that 23 S RNA virus does not have genes for capsid proteins, the binding of p104 to the viral 3' end, in addition to the efficient 3' terminal repair, may play a crucial role in virus persistence by protecting and maintaining the correct viral 3' end in vivo.

Bipartite 3'-cis-acting signal for replication in yeast 23 S RNA virus and its repair

23 S RNA narnavirus is a persistent positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome is small (2.9 kb) and only encodes its RNA-dependent RNA polymerase. Recently, we have succeeded in generating 23 S RNA virus from an expression vector containing the entire viral cDNA sequence. Using this in vivo launching system, we analyzed the 3'-cis-acting signals for replication. The 3'-non-coding region of 23 S RNA contains two cis-elements. One is a stretch of 4 Cs at the 3' end, and the other is a mismatched pair in a stem-loop structure that partially overlaps the terminal 4 Cs. In the latter element, the loop or stem sequence is not important but the stem structure with the mismatch pair is essential. The mismatched bases should be purines. Any combination of purines at the mismatch pair bestowed capability of replication on the RNA, whereas converting it to a single bulge at either side of the stem abolished the activity. The terminal and penultimate Cs at the 3' end could be eliminated or modified to other nucleotides in the launching plasmid without affecting virus generation. However, the viruses generated regained or restored these Cs at the 3' terminus. Considering the importance of the viral 3' ends in RNA replication, these results suggest that this 3' end repair may contribute to the persistence of 23 S RNA virus in yeast by maintaining the genomic RNA termini intact. We discuss possible mechanisms for this 3' end repair in vivo.

Yeast positive-stranded virus-like RNA replicons. 20 S and 23 S RNA terminal nucleotide sequences and 3' end secondary structures resemble those of RNA coliphages

Saccharomyces cerevisiae strains carry single-stranded RNAs called 20 S RNA and 23 S RNA. These RNAs and their double-stranded counterparts, W and T dsRNAs, have been cloned and sequenced. A few nucleotides at both ends, however, remained unknown. These RNAs do not encode coat proteins but their own RNA-dependent RNA polymerases that share a high degree of conservation to each other. The polymerases are also similar to the replicases of RNA coliphages, such as Qbeta. Here we have determined the nucleotide sequences of W and T dsRNAs at both ends using reverse transcriptase polymerase chain reaction-generated cDNA clones. We confirmed the terminal sequences by primer-extension and RNase protection experiments. Furthermore, these analyses demonstrated that W and T dsRNAs and their single-stranded RNA counterparts (i) are linear molecules, (ii) have identical nucleotide sequences at their ends, and (iii) have no poly(A) tails at their 3' ends. Both 20 S and 23 S RNAs have GGGGC at the 5' ends and the complementary 5-nucleotides sequence, GCCCC-OH, at their 3' ends. S1 and V1 secondary structure-mapping of the 3' ends of 20 S and 23 S RNAs shows the presence of a stem-loop structure that partially overlaps with the conserved 3' end sequence. Nucleotide sequences and stem-loop structures similar to those described here have been found at the 3' ends of RNA coliphages. These data, together with the similarity of the RNA-dependent RNA polymerases encoded among these RNAs and RNA coliphages, suggest that 20 S and 23 S RNAs are plus-strand single-stranded virus-like RNA replicons in yeast.

High-temperature inducible cell-free transcription and replication of double-stranded RNAs within the parasitic protozoan Cryptosporidium parvum

Sporozoites of the protozoan parasite, Cryptosporidium parvum, were found to contain free, full-size plus strands transcribed from two extrachromosomal, cytoplasmic, virus-like double-stranded RNAs (dsRNAs). Cell-free transcription and replication of both dsRNAs were observed in crude sporozoite lysates. RNA polymerase activity was found to be dependent upon addition of Mg2+ or Mn2+, as well as the four ribonucleoside triphosphates, and was insensitive to inhibitors of cellular DNA-dependent RNA polymerase. Semiconservative transcription of the dsRNAs (plus strand synthesis) was observed at a wide range of temperatures, with an optimum of 50 degrees C. In contrast, replication (minus strand synthesis) was detected only at 50 and 60 degrees C.

RNA-dependent RNA polymerase activity related to the 20S RNA replicon of Saccharomyces cerevisiae

Saccharomyces cerevisiae contains two double-stranded RNA (dsRNA) viruses (L-A and L-BC) and two different single-stranded (ssRNA) replicons (20S RNA and 23S RNA). Replicase (dsRNA synthesis on a ssRNA template) and transcriptase (ssRNA synthesis on a dsRNA template) activities have been described for L-A and L-BC viruses, but not for 20S or 23S RNA. We report the characterization of a new in vitro RNA replicase activity in S. cerevisiae. This activity is detected after partial purification of a particulate fraction in CsCl gradients where it migrates at the density of free protein. The activity does not require the presence of L-A or L-BC viruses or 23S RNA, and its presence or absence is correlated with the presence or absence of the 20S RNA replicon. Strains lacking both this RNA polymerase activity and 20S RNA acquire this activity when they acquire 20S RNA by cytoduction (cytoplasmic mixing). This polymerase activity converts added ssRNA to dsRNA by synthesis of the complementary strand, but has no specificity for the 3' end or internal template sequence. Although it replicates all tested RNA templates, it has a template size requirement, being unable to replicate templates larger than 1 kb. The replicase makes dsRNA from a ssRNA template, but many single-stranded products due to a terminal transferase activity are also formed. These results suggest that, in contrast to the L-A and L-BC RNA polymerases, dissociation of 20S RNA polymerase from its RNA (or perhaps some cellular factor) makes the enzyme change its specificity.

Yeast viral 20 S RNA is associated with its cognate RNA-dependent RNA polymerase

Most Saccharomyces cerevisiae strains carry in their cytoplasm 20 S RNA, a linear single-stranded RNA molecule of 2.5 kilobases in size. 20 S RNA copy number is greatly induced in stress conditions such as starvation, with up to 100,000 copies per cell. 20 S RNA has coding capacity for a protein of 91 kDa (p91) with sequences diagnostic of RNA-dependent RNA polymerases of (+) strand and double-stranded RNA viruses. We detected p91 in 20 S RNA-carrying strains with specific antisera. The amount of p91 in growing cells is higher than that of stationary cells and similar to the one in 20 S RNA-induced cells. Although 20 S RNA is not encapsidated into viral particles, p91 non-covalently forms a ribonucleoprotein complex with 20 S RNA. This suggests a role of p91 in the RNA to RNA synthesis processes required for 20 S RNA replication. Although the strain analyzed also harbors 23 S RNA, a closely related single-stranded RNA, 23 S RNA is not associated with p91 but with its putative RNA polymerase, p104. Similarly, 20 S RNA is not associated with p104 but with p91. These results suggest that 20 S RNA and 23 S RNA replicate independently using their respective cognate RNA polymerases.

Vesicle-associated double-stranded ribonucleic acid genetic elements in Agaricus bisporus

Double-stranded ribonucleic acids (dsRNAs) were isolated from fruit bodies of commercial strains of the cultivated mushroom (Agaricus bisporus) by polyethylene glycol-NaCl precipitation, differential centrifugation, rate-zonal centrifugation in sucrose, and equilibrium centrifugation in cesium sulphate. In all seven of the mushroom isolates examined, three dsRNAs were identified: two major dsRNA segments of > 13.1-kb (L-RNA) and 2.4-kb (S-RNA) and a minor segment of 5.2-kb (M-RNA). L-, M-, and S-RNAs co-purified with spherical fungal vesicles measuring approximately 75 nm in diameter. The three dsRNAs were intimately associated with the vesicles as suggested by their lower buoyant density in cesium sulphate (1.27 g/cc) compared to that of phenol-extracted dsRNAs (1.42 g/cc) and by their resistance to hydrolysis by ribonuclease at low ionic strength. Using a variety of conditions during purification, no virus-like particles were found to be associated with the dsRNAs. In Northern analysis, L-, M-, and S-RNAs failed to cross-hybridize with the genomic dsRNAs of La France isometric virus. We report here the first description of non-encapsidated, vesicle-associated, dsRNA genetic elements in the common cultivated mushroom.

A yeast antiviral protein, SKI8, shares a repeated amino acid sequence pattern with beta-subunits of G proteins and several other proteins

SKI8 is a yeast antiviral gene, essential for controlling the propagation of M double-stranded RNA (dsRNA) and thus for preventing virus-induced cytopathology. Our DNA sequence of SKI8 shows that it encodes a 397 amino acid protein containing two copies of a 31 amino acid repeat pattern first identified in mammalian beta-transducin and Cdc4p of yeast. There are also four copies of this repeat in yeast Mak11p, necessary for M dsRNA propagation, and three copies in the putative product of the Dictyostelium AAC3 gene. Analysis of 36 cases of the repeat unit shows they have a consensus predicted structure: N-helix-sheet-turn-sheet-turn-sheet-helix-C.