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

The late-annotated small ORF LSO1 is a target gene of the iron regulon of Saccharomyces cerevisiae

We have identified a new downstream target gene of the Aft1/2‐regulated iron regulon in budding yeast Saccharomyces cerevisiae, the late‐annotated small open reading frame LSO1. LSO1 transcript is among the most highly induced from a transcriptome analysis of a fet3‐1 mutant grown in the presence of the iron chelator bathophenanthrolinedisulfonic acid. LSO1 has a paralog, LSO2, which is constitutively expressed and not affected by iron availability. In contrast, we find that the LSO1 promoter region contains three consensus binding sites for the Aft1/2 transcription factors and that an LSO1‐lacZ reporter is highly induced under low‐iron conditions in a Aft1‐dependent manner. The expression patterns of the Lso1 and Lso2 proteins mirror those of their mRNAs. Both proteins are localized to the nucleus and cytoplasm, but become more cytoplasmic upon iron deprivation consistent with a role in iron transport. LSO1 and LSO2 appear to play overlapping roles in the cellular response to iron starvation since single lso1 and lso2 mutants are sensitive to iron deprivation and this sensitivity is exacerbated when both genes are deleted.

The mcm5-bob1 bypass of Cdc7p/Dbf4p in DNA replication depends on both Cdk1-independent and Cdk1-dependent steps in Saccharomyces cerevisiae

The roles in DNA replication of two distinct protein kinases, Cdc7p/Dbf4p and Cdk1p/Clb (B-type cyclin), were studied. This was accomplished through a genetic and molecular analysis of the mechanism by which the mcm5-bob1 mutation bypasses the function of the Cdc7p/Dbf4p kinase. Genetic experiments revealed that loss of either Clb5p or Clb2p cyclins suppresses the mcm5-bob1 mutation and prevents bypass. These two cyclins have distinct roles in bypass and presumably in DNA replication as overexpression of one could not complement the loss of the other. Furthermore, the ectopic expression of CLB2 in G1 phase cannot substitute for CLB5 function in bypass of Cdc7p/Dbf4p by mcm5-bob1. Molecular experiments revealed that the mcm5-bob1 mutation allows for constitutive loading of Cdc45p at early origins in arrested G1 phase cells when both kinases are inactive. A model is proposed in which the Mcm5-bob1 protein assumes a unique molecular conformation without prior action by either kinase. This conformation allows for stable binding of Cdc45p to the origin. However, DNA replication still cannot occur without the combined action of Cdk1p/Clb5p and Cdk1p/Clb2p. Thus Cdc7p and Cdk1p kinases catalyze the initiation of DNA replication at several distinct steps, of which only a subset is bypassed by the mcm5-bob1 mutation.

Characterization of an RNA-dependent RNA polymerase activity associated with La France isometric virus

Purified preparations of La France isometric virus (LIV), an unclassified, double-stranded RNA (dsRNA) virus of Agaricus bisporus, were associated with an RNA-dependent RNA polymerase (RDRP) activity. RDRP activity cosedimented with the 36-nm isometric particles and genomic dsRNAs of LIV during rate-zonal centrifugation in sucrose density gradients, suggesting that the enzyme is a constituent of the virion. Enzyme activity was maximal in the presence of all four nucleotides, a reducing agent (dithiothreitol or beta-mercaptoethanol), and Mg2+ and was resistant to inhibitors of DNA-dependent RNA polymerases (actinomycin D, alpha-amanitin, and rifampin). The radiolabeled enzyme reaction products were predominantly (95%) single-stranded RNA (ssRNA) as determined by cellulose column chromatography and ionic-strength-dependent sensitivity to hydrolysis by RNase A. Three major size classes of ssRNA transcripts of 0.95, 1.3, and 1.8 kb were detected by agarose gel electrophoresis, although the transcripts hybridized to all nine of the virion-associated dsRNAs. The RNA products synthesized in vitro appeared to be of a single polarity, as they hybridized to an ssDNA corresponding to one strand of a genomic dsRNA and not to the complementary strand. Similarly, reverse transcription-PCR with total cellular ssRNA as a template and strand-specific primers targeting a genomic dsRNA during synthesis of cDNA suggested that only the coding strand was transcribed in vivo. Our data indicate that the RDRP activity associated with virions of LIV is probably a transcriptase engaged in the synthesis of ssRNA transcripts corresponding to each of the virion-associated dsRNAs.

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.

New developments in fungal virology

Although viruses are widely distributed in fungi, their biological significance to their hosts is still poorly understood. A large number of fungal viruses are associated with latent infections of their hosts. With the exception of the killer-immune character in the yeasts, smuts, and hypovirulence in the chestnut blight fungus, fungal properties that can specifically be related to virus infection are not well defined. Mycoviruses are not known to have natural vectors; they are transmitted in nature intracellularly by hyphal anastomosis and heterokaryosis, and are disseminated via spores. Because fungi have a potential for plasmogamy and cytoplasmic exchange during extended periods of their life cycles and because they produce many types of propagules (sexual and asexual spores), often in great profusion, mycoviruses have them accessible to highly efficient means for transmission and spread. It is no surprise, therefore, that fungal viruses are not known to have an extracellular phase to their life cycles. Although extracellular transmission of a few fungal viruses have been demonstrated, using fungal protoplasts, the lack of conventional methods for experimental transmission of these viruses have been, and remains, an obstacle to understanding their biology. The recent application of molecular biological approaches to the study of mycoviral dsRNAs and the improvements in DNA-mediated fungal transformation systems, have allowed a clearer understanding of the molecular biology of mycoviruses to emerge. Considerable progress has been made in elucidating the genome organization and expression strategies of the yeast L-A virus and the unencapsidated RNA virus associated with hypovirulence in the chestnut blight fungus. These recent advances in the biochemical and molecular characterization of the genomes of fungal viruses and associated satellite dsRNAs, as they relate to the biological properties of these viruses and to their interactions with their hosts are the focus of this chapter.

Yeast killer virus transcription initiation in vitro

Killer virions isolated from infected Saccharomyces cerevisiae cells contain an RNA polymerase activity which catalyzes the transcription in vitro of positive polarity RNAs from the L-A and M double-stranded RNA genomic segments of the virus. The RNA polymerase can initiate transcription in vitro with gamma-thio-GTP, whose thiophosphate group is found on the 5' terminus of transcripts. Transcripts produced in vitro by the virion-associated RNA polymerase in the presence of 7mGpppG are significantly more active as translational templates than are transcripts produced in its absence. However, unlike Escherichia coli RNA polymerase transcripts from viral cDNA made in the presence of 7mGpppG, transcripts produced by viral RNA polymerase in the presence of 7mGpppG fail to bind to antibody against 7mG.

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.

Semiconservative strand-displacement transcription of the M2 dsRNA segment of Ustilago maydis virus

The P1 strain of the Ustilago maydis virus (UmV) is a segmented dsRNA virus with segments designated H1, H2, M1, M2, and L. Incubation of purified virus with a mixture of nucleotides containing 32P-UTP resulted in labeled dsRNA which was retained in the capsid and labeled ssRNA which was released from the capsid. This in vitro transcription reaction was dependent on Mg2+ ion and the optimum concentration for maximum incorporation was 10 mM. The pH and temperature optima were 8.0 and 30 degrees C, respectively. The ssRNA transcripts were precipitated from the supernatant solution of the reaction mixture after ultracentrifugation to separate the virus. Transcription products from supernatant solution hybridized with all five virion dsRNAs. Further studies of the M2 segment indicated that it was labeled within 2 h and the label was completely chased out in 2 h. Analysis of the labeled M2 dsRNA segment by strand-separation gel showed that only one strand (slow moving) was labeled. When both strands were tested in an in vitro translation system, only the slow-moving strand was translated to produce a 24 kDa product. Thus the M2 dsRNA segment of UmV P1 transcribes by a semiconservative strand-displacement mechanism.

Gene overlap results in a viral protein having an RNA binding domain and a major coat protein domain

L-A double-stranded RNA (dsRNA) replicates in vivo in yeast in a conservative, asynchronous (first [+] strand then [-] strand), intraviral process. New particles are formed by packaging (+) strands. Added viral (+) single-stranded RNA (ssRNA) is specifically bound by empty virus-like particles (VLPs) and, in a reaction requiring a host factor, is converted in vitro to dsRNA. We find that the isolated binding complex replicates only if it was formed in the presence of the host factor. The VLP minor 180 kd protein, but not the major coat protein, has ssRNA binding activity on Western blots. The 180 kd protein shares a common antigenic domain with the major coat protein, the latter known to be encoded by L-A dsRNA. The 180 kd protein, but not the major coat protein, also shares an antigenic domain with a sequence encoded by the 3' end of the L-A (+) strand. Thus the 180 kd protein is also encoded by L-A dsRNA and consists of a major coat protein domain and a ssRNA binding domain.

Conservative mechanism of the in vitro transcription of killer virus of yeast

A conservative mechanism of transcription has been proposed for the RNA polymerase activity of the killer virus of yeast, both in vivo and in vitro. This model is supported by the conservation of radioactivity in template double-stranded RNA during transcription in vitro.

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.

Isolation of two genes that affect mitotic chromosome transmission in S. cerevisiae

Two DNA sequences that reduce mitotic fidelity of chromosome transmission have been identified: MIF1 and MIF2. MIF1 is a unique sequence located on the right arm of chromosome XII that stimulates loss and recombination for both chromosomes V and VII when present in a high copy number plasmid. MIF1 is not essential for cell division but is necessary for the normal fidelity of chromosome transmission. MIF2 is a unique sequence located 15 cM distal to HIS6 on chromosome IX that induces a high frequency of chromosome VII loss and a lower frequency of chromosome V loss when present in high copy number; it has no effect on mitotic recombination. Disruption of the genomic MIF2 locus was lethal and cells lacking this function arrested division with a terminal phenotype characteristic of a block in DNA replication or nuclear division.

Overview of double-stranded RNA replication in Saccharomyces cerevisiae

There are five families of double-stranded RNA (dsRNA) in strains of Saccharomyces cerevisiae, called L-A, L-BC, M, T, and W. Of these, L-A, L-BC, and M are found in intracellular virus-like particles (VLPs). Their replication is controlled by over 40 chromosomal genes; some (called MAK genes) promote dsRNA replication or maintenance, others (called SKI genes) negatively control dsRNA replication. Extensive genetic interactions among the dsRNAs and the chromosomal genes are known. The VLPs containing dsRNA produce a message (+) strand RNA copy in vitro, while the VLPs containing a (+) strand synthesize a (-) strand copy to make dsRNA. The genes MAK10 and PET18 (= MAK31 + MAK32) are necessary for the structural stability of L-A dsRNA-containing particles, but not of those containing L-A (+) strand RNA. The M1 VLPs can have either one or two M1 dsRNA molecules per particle, a fact that we explain by a sort of "head-full" hypothesis. [D] (for disease) is a new cytoplasmic genetic element which, when introduced into a ski M1 strain, makes the strain unable to grow at 20 degrees C or at 37 degrees C. [D] is not located on L-A, L-BC, M, or W dsRNA. Element [D] is heat-curable, and chromosomal mutants unable to maintain [D] (mad-) have been isolated. They can maintain M1 and L-A. [B] is a cytoplasmic genetic element which suppresses the usual need of M1 for MAK11 and several other MAK genes. Element [B] is not located on L-A or M and is distinct from [D].