Saccharomyces cerevisiae killer virus transcripts contain template-coded polyadenylate tracts

XRN1 Is a Species-Specific Virus Restriction Factor in Yeasts

In eukaryotes, the degradation of cellular mRNAs is accomplished by Xrn1 and the cytoplasmic exosome. Because viral RNAs often lack canonical caps or poly-A tails, they can also be vulnerable to degradation by these host exonucleases. Yeast lack sophisticated mechanisms of innate and adaptive immunity, but do use RNA degradation as an antiviral defense mechanism. One model is that the RNA of yeast viruses is subject to degradation simply as a side effect of the intrinsic exonuclease activity of proteins involved in RNA metabolism. Contrary to this model, we find a highly refined, species-specific relationship between Xrn1p and the "L-A" totiviruses of different Saccharomyces yeast species. We show that the gene XRN1 has evolved rapidly under positive natural selection in Saccharomyces yeast, resulting in high levels of Xrn1p protein sequence divergence from one yeast species to the next. We also show that these sequence differences translate to differential interactions with the L-A virus, where Xrn1p from S. cerevisiae is most efficient at controlling the L-A virus that chronically infects S. cerevisiae, and Xrn1p from S. kudriavzevii is most efficient at controlling the L-A-like virus that we have discovered within S. kudriavzevii. All Xrn1p orthologs are equivalent in their interaction with another virus-like parasite, the Ty1 retrotransposon. Thus, the activity of Xrn1p against totiviruses is not simply an incidental consequence of the enzymatic activity of Xrn1p, but rather Xrn1p co-evolves with totiviruses to maintain its potent antiviral activity and limit viral propagation in Saccharomyces yeasts. Consistent with this, we demonstrated that Xrn1p physically interacts with the Gag protein encoded by the L-A virus, suggesting a host-virus interaction that is more complicated than just Xrn1p-mediated nucleolytic digestion of viral RNAs.

Identification and analysis of a Saccharomyces cerevisiae copper homeostasis gene encoding a homeodomain protein

Yeast metallothionein, encoded by the CUP1 gene, and its copper-dependent transcriptional activator ACE1 play a key role in mediating copper resistance in Saccharomyces cerevisiae. Using an ethyl methanesulfonate mutant of a yeast strain in which CUP1 and ACE1 were deleted, we isolated a gene, designated CUP9, which permits yeast cells to grow at high concentrations of environmental copper, most notably when lactate is the sole carbon source. Disruption of CUP9, which is located on chromosome XVI, caused a loss of copper resistance in strains which possessed CUP1 and ACE1, as well as in the cup1 ace1 deletion strain. Measurement of intracellular copper levels of the wild-type and cup9-1 mutant demonstrated that total intracellular copper concentrations were unaffected by CUP9. CUP9 mRNA levels were, however, down regulated by copper when yeast cells were grown with glucose but not with lactate or glycerol-ethanol as the sole carbon source. This down regulation was independent of the copper metalloregulatory transcription factor ACE1. The DNA sequence of CUP9 predicts an open reading frame of 306 amino acids in which a 55-amino-acid sequence showed 47% identity with the homeobox domain of the human proto-oncogene PBX1, suggesting that CUP9 is a DNA-binding protein which regulates the expression of important copper homeostatic genes.

Identification and analysis of a Saccharomyces cerevisiae copper homeostasis gene encoding a homeodomain protein

Yeast metallothionein, encoded by the CUP1 gene, and its copper-dependent transcriptional activator ACE1 play a key role in mediating copper resistance in Saccharomyces cerevisiae. Using an ethyl methanesulfonate mutant of a yeast strain in which CUP1 and ACE1 were deleted, we isolated a gene, designated CUP9, which permits yeast cells to grow at high concentrations of environmental copper, most notably when lactate is the sole carbon source. Disruption of CUP9, which is located on chromosome XVI, caused a loss of copper resistance in strains which possessed CUP1 and ACE1, as well as in the cup1 ace1 deletion strain. Measurement of intracellular copper levels of the wild-type and cup9-1 mutant demonstrated that total intracellular copper concentrations were unaffected by CUP9. CUP9 mRNA levels were, however, down regulated by copper when yeast cells were grown with glucose but not with lactate or glycerol-ethanol as the sole carbon source. This down regulation was independent of the copper metalloregulatory transcription factor ACE1. The DNA sequence of CUP9 predicts an open reading frame of 306 amino acids in which a 55-amino-acid sequence showed 47% identity with the homeobox domain of the human proto-oncogene PBX1, suggesting that CUP9 is a DNA-binding protein which regulates the expression of important copper homeostatic genes.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

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.

Evidence that the SKI antiviral system of Saccharomyces cerevisiae acts by blocking expression of viral mRNA

The SKI2 gene is part of a host system that represses the copy number of the L-A double-stranded RNA (dsRNA) virus and its satellites M and X dsRNA, of the L-BC dsRNA virus, and of the single-stranded replicon 20S RNA. We show that SKI2 encodes a 145-kDa protein with motifs characteristic of helicases and nucleolar proteins and is essential only in cells carrying M dsRNA. Unexpectedly, Ski2p does not repress M1 dsRNA copy number when M1 is supported by aN L-A cDNA clone; nonetheless, it did lower the levels of M1 dsRNA-encoded toxin produced. Since toxin secretion from cDNA clones of M1 is unaffected by Ski2p, these data suggest that Ski2p acts by specifically blocking translation of viral mRNAs, perhaps recognizing the absence of cap or poly(A). In support of this idea, we find that Ski2p represses production of beta-galactosidase from RNA polymerase I [no cap and no poly(A)] transcripts but not from RNA polymerase II (capped) transcripts.

Evidence that the SKI antiviral system of Saccharomyces cerevisiae acts by blocking expression of viral mRNA

The SKI2 gene is part of a host system that represses the copy number of the L-A double-stranded RNA (dsRNA) virus and its satellites M and X dsRNA, of the L-BC dsRNA virus, and of the single-stranded replicon 20S RNA. We show that SKI2 encodes a 145-kDa protein with motifs characteristic of helicases and nucleolar proteins and is essential only in cells carrying M dsRNA. Unexpectedly, Ski2p does not repress M1 dsRNA copy number when M1 is supported by aN L-A cDNA clone; nonetheless, it did lower the levels of M1 dsRNA-encoded toxin produced. Since toxin secretion from cDNA clones of M1 is unaffected by Ski2p, these data suggest that Ski2p acts by specifically blocking translation of viral mRNAs, perhaps recognizing the absence of cap or poly(A). In support of this idea, we find that Ski2p represses production of beta-galactosidase from RNA polymerase I [no cap and no poly(A)] transcripts but not from RNA polymerase II (capped) transcripts.

GCD11, a negative regulator of GCN4 expression, encodes the gamma subunit of eIF-2 in Saccharomyces cerevisiae

The eukaryotic translation initiation factor eIF-2 plays a critical role in regulating the expression of the yeast transcriptional activator GCN4. Mutations in genes encoding the alpha and beta subunits of eIF-2 alter translational efficiency at the GCN4 AUG codon and constitutively elevate GCN4 translation. Mutations in the yeast GCD11 gene have been shown to confer a similar phenotype. The nucleotide sequence of the cloned GCD11 gene predicts a 527-amino-acid polypeptide that is similar to the prokaryotic translation elongation factor EF-Tu. Relative to EF-Tu, the deduced GCD11 amino acid sequence contains a 90-amino-acid N-terminal extension and an internal cysteine-rich sequence that contains a potential metal-binding finger motif. We have identified the GCD11 gene product as the gamma subunit of eIF-2 by the following criteria: (i) sequence identities with mammalian eIF-2 gamma peptides; (ii) increased eIF-2 activity in extracts prepared from cells cooverexpressing GCD11, eIF-2 alpha, and eIF-2 beta; and (iii) cross-reactivity of antibodies directed against the GCD11 protein with the 58-kDa polypeptide present in purified yeast eIF-2. The predicted GCD11 polypeptide contains all of the consensus elements known to be required for guanine nucleotide binding, suggesting that, in Saccharomyces cerevisiae, the gamma subunit of eIF-2 is responsible for GDP-GTP binding.

GCD11, a negative regulator of GCN4 expression, encodes the gamma subunit of eIF-2 in Saccharomyces cerevisiae

The eukaryotic translation initiation factor eIF-2 plays a critical role in regulating the expression of the yeast transcriptional activator GCN4. Mutations in genes encoding the alpha and beta subunits of eIF-2 alter translational efficiency at the GCN4 AUG codon and constitutively elevate GCN4 translation. Mutations in the yeast GCD11 gene have been shown to confer a similar phenotype. The nucleotide sequence of the cloned GCD11 gene predicts a 527-amino-acid polypeptide that is similar to the prokaryotic translation elongation factor EF-Tu. Relative to EF-Tu, the deduced GCD11 amino acid sequence contains a 90-amino-acid N-terminal extension and an internal cysteine-rich sequence that contains a potential metal-binding finger motif. We have identified the GCD11 gene product as the gamma subunit of eIF-2 by the following criteria: (i) sequence identities with mammalian eIF-2 gamma peptides; (ii) increased eIF-2 activity in extracts prepared from cells cooverexpressing GCD11, eIF-2 alpha, and eIF-2 beta; and (iii) cross-reactivity of antibodies directed against the GCD11 protein with the 58-kDa polypeptide present in purified yeast eIF-2. The predicted GCD11 polypeptide contains all of the consensus elements known to be required for guanine nucleotide binding, suggesting that, in Saccharomyces cerevisiae, the gamma subunit of eIF-2 is responsible for GDP-GTP binding.

Design of peptide-acridine mimics of ribonuclease activity

A series of peptide-acridine conjugates was designed and synthesized, based on three features of the proposed catalytic mechanism of RNase A: 2'-proton abstraction by His-12, proton donation to the leaving 5'-oxygen by His-119, and stabilization of the pentacoordinated phosphorous transition state by Lys-41. The substrate binding capability of RNase A was mimicked by the intercalator, acridine. Lysine served as a linker between acridine and the catalytic tripeptide. Cleavage of target RNA was monitored by agarose gel electrophoresis and by gel-permeation chromatography. The carboxyl-amidated conjugates HGHK(Acr)-NH2, HPHK(Acr)-NH2, and GGHK(Acr)-NH2 (where Acr indicates 2-methyl-9-acridinemethylene) all had similar hydrolytic activity. The catalytic mechanism most likely involved only the abstraction of the 2'-proton and stabilization of the transition state. These RNase mimics utilized rRNA and single-stranded RNA but not double-stranded RNA and tRNA as substrates.

Expression of RNase P RNA in Saccharomyces cerevisiae is controlled by an unusual RNA polymerase III promoter

The RNA subunit of Saccharomyces cerevisiae nuclear RNase P is encoded by a single-copy, essential gene, RPR1. The 369-nucleotide mature form of the RNA has an apparent precursor with an 84-nucleotide 5' leader and approximately 33 nucleotides of additional 3' sequence. Analysis of RPR1 transcription in a strain with a temperature-sensitive lesion in RNA polymerase III shows that the gene is transcribed in vivo by RNA polymerase III. Examination of potential promoter regions using both progressive upstream deletions and point mutations indicates that at least two sequences contained within the 5' leader region are essential for expression in vivo, while sequences farther upstream influence efficiency. The required leader elements resemble tRNA gene-like A-box and B-box internal promoters in sequence and spacing. As in the tRNA genes, transcription factor TFIIIC binds to this region in vitro and binding is severely reduced by either A-box or B-box point mutations that impair expression in vivo. It thus appears that the yeast RNase P RNA gene has adopted a promoter strategy that places an RNA polymerase III "internal" promoter upstream of the mature structural domain to help drive transcription.

Characterization of RPR1, an essential gene encoding the RNA component of Saccharomyces cerevisiae nuclear RNase P

RNA components have been identified in preparations of RNase P from a number of eucaryotic sources, but final proof that these RNAs are true RNase P subunits has been elusive because the eucaryotic RNAs, unlike the procaryotic RNase P ribozymes, have not been shown to have catalytic activity in the absence of protein. We previously identified such an RNA component in Saccharomyces cerevisiae nuclear RNase P preparations and have now characterized the corresponding, chromosomal gene, called RPR1 (RNase P ribonucleoprotein 1). Gene disruption experiments showed RPR1 to be single copy and essential. Characterization of the gene region located RPR1 600 bp downstream of the URA3 coding region on chromosome V. We have sequenced 400 bp upstream and 550 bp downstream of the region encoding the major 369-nucleotide RPR1 RNA. The presence of less abundant, potential precursor RNAs with an extra 84 nucleotides of 5' leader and up to 30 nucleotides of 3' trailing sequences suggests that the primary RPR1 transcript is subjected to multiple processing steps to obtain the 369-nucleotide form. Complementation of RPR1-disrupted haploids with one variant of RPR1 gave a slow-growth and temperature-sensitive phenotype. This strain accumulates tRNA precursors that lack the 5' end maturation performed by RNase P, providing direct evidence that RPR1 RNA is an essential component of this enzyme.

ACE2, an activator of yeast metallothionein expression which is homologous to SWI5

Transcription of the Saccharomyces cerevisiae metallothionein gene CUP1 is induced in response to high environmental levels of copper. Induction requires the ACE1 gene product, which binds to specific sites in the promoter region of the CUP1 gene. In this study, we found that deleting the entire coding sequence of the ACE1 gene resulted in a decrease in basal-level transcription of CUP1 to low but detectable levels and conferred a copper-sensitive phenotype to the cells. We have isolated a gene, designated ACE2, which when present on a high-copy-number plasmid suppresses the copper-sensitive phenotype of an ace1-deletion strain. The presence of multiple copies of the ACE2 gene enhanced expression of an unlinked CUP1-lacZ fusion integrated in the yeast genome and resulted in an increase in the steady-state levels of CUP1 mRNA in an ace1-deletion background. A large deletion of the coding region of the genomic copy of ACE2 resulted in a decrease in steady-state levels of CUP1 mRNA, indicating that ACE2 plays a role in regulating basal-level expression of CUP1. The ACE2 open reading frame encodes a polypeptide of 770 amino acids, with putative zinc finger structures near the carboxyl terminus. This protein is 37% identical to the SWI5 gene product, an activator of HO gene transcription in S. cerevisiae, suggesting that ACE2 and SWI5 may have functional similarities.

Characterization of RPR1, an essential gene encoding the RNA component of Saccharomyces cerevisiae nuclear RNase P

RNA components have been identified in preparations of RNase P from a number of eucaryotic sources, but final proof that these RNAs are true RNase P subunits has been elusive because the eucaryotic RNAs, unlike the procaryotic RNase P ribozymes, have not been shown to have catalytic activity in the absence of protein. We previously identified such an RNA component in Saccharomyces cerevisiae nuclear RNase P preparations and have now characterized the corresponding, chromosomal gene, called RPR1 (RNase P ribonucleoprotein 1). Gene disruption experiments showed RPR1 to be single copy and essential. Characterization of the gene region located RPR1 600 bp downstream of the URA3 coding region on chromosome V. We have sequenced 400 bp upstream and 550 bp downstream of the region encoding the major 369-nucleotide RPR1 RNA. The presence of less abundant, potential precursor RNAs with an extra 84 nucleotides of 5' leader and up to 30 nucleotides of 3' trailing sequences suggests that the primary RPR1 transcript is subjected to multiple processing steps to obtain the 369-nucleotide form. Complementation of RPR1-disrupted haploids with one variant of RPR1 gave a slow-growth and temperature-sensitive phenotype. This strain accumulates tRNA precursors that lack the 5' end maturation performed by RNase P, providing direct evidence that RPR1 RNA is an essential component of this enzyme.

ACE2, an activator of yeast metallothionein expression which is homologous to SWI5

Transcription of the Saccharomyces cerevisiae metallothionein gene CUP1 is induced in response to high environmental levels of copper. Induction requires the ACE1 gene product, which binds to specific sites in the promoter region of the CUP1 gene. In this study, we found that deleting the entire coding sequence of the ACE1 gene resulted in a decrease in basal-level transcription of CUP1 to low but detectable levels and conferred a copper-sensitive phenotype to the cells. We have isolated a gene, designated ACE2, which when present on a high-copy-number plasmid suppresses the copper-sensitive phenotype of an ace1-deletion strain. The presence of multiple copies of the ACE2 gene enhanced expression of an unlinked CUP1-lacZ fusion integrated in the yeast genome and resulted in an increase in the steady-state levels of CUP1 mRNA in an ace1-deletion background. A large deletion of the coding region of the genomic copy of ACE2 resulted in a decrease in steady-state levels of CUP1 mRNA, indicating that ACE2 plays a role in regulating basal-level expression of CUP1. The ACE2 open reading frame encodes a polypeptide of 770 amino acids, with putative zinc finger structures near the carboxyl terminus. This protein is 37% identical to the SWI5 gene product, an activator of HO gene transcription in S. cerevisiae, suggesting that ACE2 and SWI5 may have functional similarities.

Upstream activation and repression elements control transcription of the yeast COX5b gene

The Saccharomyces cerevisiae COX5b gene is regulated at the level of transcription by both the carbon source and oxygen. To define the cis-acting elements that underlie this transcriptional control, deletion analysis of the upstream regulatory region of COX5b was performed. The results of the study suggest that at least four distinct regulatory sites are functional upstream of the COX5b transcriptional starts. One, which was precisely defined to a region of 20 base pairs, contains two TATA-like elements. Two upstream activating sequences (UAS15b and UAS2(5b)) and an upstream repression sequence (URS5b) were also found. Each of the latter three elements was able either to activate (UAS1(5b) and UAS2(5b)) or to repress URS5b) the transcription of a heterologous yeast gene. Further analysis revealed that UAS1(5b) is the site of carbon source control and may be composed of two distinct domains that act synergistically. URS5b mediates the aerobic repression of COX5b and contains two sequences that are highly conserved in other yeast genes negatively regulated by oxygen.

Upstream activation and repression elements control transcription of the yeast COX5b gene

The Saccharomyces cerevisiae COX5b gene is regulated at the level of transcription by both the carbon source and oxygen. To define the cis-acting elements that underlie this transcriptional control, deletion analysis of the upstream regulatory region of COX5b was performed. The results of the study suggest that at least four distinct regulatory sites are functional upstream of the COX5b transcriptional starts. One, which was precisely defined to a region of 20 base pairs, contains two TATA-like elements. Two upstream activating sequences (UAS15b and UAS2(5b)) and an upstream repression sequence (URS5b) were also found. Each of the latter three elements was able either to activate (UAS1(5b) and UAS2(5b)) or to repress URS5b) the transcription of a heterologous yeast gene. Further analysis revealed that UAS1(5b) is the site of carbon source control and may be composed of two distinct domains that act synergistically. URS5b mediates the aerobic repression of COX5b and contains two sequences that are highly conserved in other yeast genes negatively regulated by oxygen.

A cysteine-rich nuclear protein activates yeast metallothionein gene transcription

The ACE1 gene of the yeast Saccharomyces cerevisiae is required for copper-inducible transcription of the metallothionein gene (CUP1). The sequence of the cloned ACE1 gene predicted an open reading frame for translation of a 225-amino-acid polypeptide. This polypeptide was characterized by an amino-terminal half rich in cysteine residues and positively charged amino acids. The arrangement of many of the 12 cysteines in the configuration Cys-X-Cys or Cys-X-X-Cys suggested that the ACE1 protein may bind metal ions. The carboxyl-terminal half of the ACE1 protein was devoid of cysteines but was highly acidic in nature. The ability of a bifunctional ACE1-beta-galactosidase fusion protein to accumulate in yeast cell nuclei was consistent with the possibility that ACE1 plays a direct role in the regulation of copper-inducible transcription of the yeast metallothionein gene.

Molecular analysis of GCN3, a translational activator of GCN4: evidence for posttranslational control of GCN3 regulatory function

GCN4 encodes a transcriptional activator of amino acid biosynthetic genes in Saccharomyces cerevisiae. The GCN3 product is a positive regulator required for increased synthesis of GCN4 protein in amino acid-starved cells. GCN3 appears to act indirectly by antagonizing GCD-encoded negative regulators of GCN4 expression under starvation conditions; however, GCN3 can also suppress the effects of gcd12 mutations under nonstarvation conditions. These results imply that the GCN3 product can promote either repression or activation of GCN4 expression depending on amino acid availability. We present a complete physical description of the GCN3 gene and its transcript, plus measurements of GCN3 expression at the transcriptional and translational levels under different growth conditions. GCN3 encodes a 305-amino-acid polypeptide with no significant homology to any other known protein sequence. GCN3 mRNA contains no leader AUG codons, and no potential GCN4 binding sites were found in GCN3 5' noncoding DNA. In accord with the absence of these regulatory sequences found at other genes in the general control system, GCN3 mRNA and a GCN3-lacZ fusion enzyme are present at similar levels under both starvation and nonstarvation conditions. These data suggest that modulation of GCN3 regulatory function in response to amino acid availability occurs posttranslationally. A gcn3 deletion leads to unconditional lethality in a gcd1-101 mutant, supporting the idea that GCN3 is expressed under normal growth conditions and cooperates with the GCD1 product under these circumstances to carry out an essential cellular function. We describe a point mutation that adds three amino acids to the carboxyl terminus of GCN3, which inactivates its positive regulatory function required under starvation conditions without impairing its ability to promote functions carried out by GCD12 under nonstarvation conditions.

A cysteine-rich nuclear protein activates yeast metallothionein gene transcription

The ACE1 gene of the yeast Saccharomyces cerevisiae is required for copper-inducible transcription of the metallothionein gene (CUP1). The sequence of the cloned ACE1 gene predicted an open reading frame for translation of a 225-amino-acid polypeptide. This polypeptide was characterized by an amino-terminal half rich in cysteine residues and positively charged amino acids. The arrangement of many of the 12 cysteines in the configuration Cys-X-Cys or Cys-X-X-Cys suggested that the ACE1 protein may bind metal ions. The carboxyl-terminal half of the ACE1 protein was devoid of cysteines but was highly acidic in nature. The ability of a bifunctional ACE1-beta-galactosidase fusion protein to accumulate in yeast cell nuclei was consistent with the possibility that ACE1 plays a direct role in the regulation of copper-inducible transcription of the yeast metallothionein gene.

Copper-induced binding of cellular factors to yeast metallothionein upstream activation sequences

Copper-inducible transcription of the yeast metallothionein gene (CUP1) occurs by means of cis-acting upstream activation sequences (UAS) and trans-acting cellular factors. We have used a high-resolution chromosomal footprinting technique to detect the interaction of cellular factors with UASCUP1. Our results demonstrate that one or more cellular factors bind to UASCUP1 in a copper-inducible fashion. This copper-inducible binding is enhanced in a yeast strain that harbors several copies of the positive regulatory gene ACE1 and is not detectable in yeast cells that contain a nonfunctional (ace1-delta 1) locus. The correlation between yeast metallothionein gene activation and copper-inducible occupation of UASCUP1 sequences suggests that the binding of metallothionein transcriptional regulatory factors to cis-acting control sequences is copper-inducible.

Molecular analysis of GCN3, a translational activator of GCN4: evidence for posttranslational control of GCN3 regulatory function

GCN4 encodes a transcriptional activator of amino acid biosynthetic genes in Saccharomyces cerevisiae. The GCN3 product is a positive regulator required for increased synthesis of GCN4 protein in amino acid-starved cells. GCN3 appears to act indirectly by antagonizing GCD-encoded negative regulators of GCN4 expression under starvation conditions; however, GCN3 can also suppress the effects of gcd12 mutations under nonstarvation conditions. These results imply that the GCN3 product can promote either repression or activation of GCN4 expression depending on amino acid availability. We present a complete physical description of the GCN3 gene and its transcript, plus measurements of GCN3 expression at the transcriptional and translational levels under different growth conditions. GCN3 encodes a 305-amino-acid polypeptide with no significant homology to any other known protein sequence. GCN3 mRNA contains no leader AUG codons, and no potential GCN4 binding sites were found in GCN3 5' noncoding DNA. In accord with the absence of these regulatory sequences found at other genes in the general control system, GCN3 mRNA and a GCN3-lacZ fusion enzyme are present at similar levels under both starvation and nonstarvation conditions. These data suggest that modulation of GCN3 regulatory function in response to amino acid availability occurs posttranslationally. A gcn3 deletion leads to unconditional lethality in a gcd1-101 mutant, supporting the idea that GCN3 is expressed under normal growth conditions and cooperates with the GCD1 product under these circumstances to carry out an essential cellular function. We describe a point mutation that adds three amino acids to the carboxyl terminus of GCN3, which inactivates its positive regulatory function required under starvation conditions without impairing its ability to promote functions carried out by GCD12 under nonstarvation conditions.

ACE1 regulates expression of the Saccharomyces cerevisiae metallothionein gene

Copper resistance in Saccharomyces cerevisiae is mediated, in large part, by the CUP1 locus, which encodes a low-molecular-weight, cysteine-rich metal-binding protein. Expression of the CUP1 gene is regulated at the level of transcriptional induction in response to high environmental copper levels. This report describes the isolation of a yeast mutant, ace1-1, which is defective in the activation of CUP1 expression upon exposure to exogenous copper. The ace1-1 mutation is recessive and lies in a genetic element that encodes a trans-acting CUP1 regulatory factor. The wild-type ACE1 gene was isolated by in vivo complementation and restores copper inducibility of CUP1 expression and copper resistance to the otherwise copper-sensitive ace1-1 mutant. Linkage analysis and gene deletion experiments verified that this gene represents the authentic ACE1 locus. ACE1 maps to the left arm of chromosome VII, 9 centimorgans centromere distal to lys5. The ACE1 gene appears to play a direct or indirect positive role in activation of CUP1 expression in response to elevated copper concentrations.

ACE1 regulates expression of the Saccharomyces cerevisiae metallothionein gene

Copper resistance in Saccharomyces cerevisiae is mediated, in large part, by the CUP1 locus, which encodes a low-molecular-weight, cysteine-rich metal-binding protein. Expression of the CUP1 gene is regulated at the level of transcriptional induction in response to high environmental copper levels. This report describes the isolation of a yeast mutant, ace1-1, which is defective in the activation of CUP1 expression upon exposure to exogenous copper. The ace1-1 mutation is recessive and lies in a genetic element that encodes a trans-acting CUP1 regulatory factor. The wild-type ACE1 gene was isolated by in vivo complementation and restores copper inducibility of CUP1 expression and copper resistance to the otherwise copper-sensitive ace1-1 mutant. Linkage analysis and gene deletion experiments verified that this gene represents the authentic ACE1 locus. ACE1 maps to the left arm of chromosome VII, 9 centimorgans centromere distal to lys5. The ACE1 gene appears to play a direct or indirect positive role in activation of CUP1 expression in response to elevated copper concentrations.

Tandemly duplicated upstream control sequences mediate copper-induced transcription of the Saccharomyces cerevisiae copper-metallothionein gene

Transcription of the Saccharomyces cerevisiae copper-metallothionein gene, CUP1, inducible by copper. By analyzing deletion and fusion mutants in the CUP1 5'-flanking region, we identified two closely related, tandemly arranged copper regulatory elements. A synthetic version of one of these elements conferred efficient copper induction on a heterologous promoter when present in two tandem copies.

Tandemly duplicated upstream control sequences mediate copper-induced transcription of the Saccharomyces cerevisiae copper-metallothionein gene

Transcription of the Saccharomyces cerevisiae copper-metallothionein gene, CUP1, inducible by copper. By analyzing deletion and fusion mutants in the CUP1 5'-flanking region, we identified two closely related, tandemly arranged copper regulatory elements. A synthetic version of one of these elements conferred efficient copper induction on a heterologous promoter when present in two tandem copies.

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.

Multiple polymorphic alpha- and beta-tubulin mRNAs are present in sea urchin eggs

Multiple alpha- and beta-tubulin RNAs were found in the mature unfertilized eggs of the sea urchin Lytechinus pictus. The alpha-tubulin RNAs were polymorphic in number, size, and relative amounts in the eggs of different females. Five to seven different size classes [1.75-4.2 kilobases (kb)] were detected on RNA gel blots. All egg preparations contained variable amounts of 1.8- and 2.25-kb beta-tubulin RNAs, and a few of them contained an additional 2.9-kb beta-tubulin RNA. The total amount of alpha-tubulin RNA did not always parallel that of beta-tubulin RNA. A portion of all of the various alpha- and beta-tubulin RNAs were polyadenylylated. RNase H digestions ruled out the possibility that some of these RNAs represented a single transcript bearing different lengths of 3' poly(A). One class of alpha-tubulin RNAs (2.4-2.65 kb) was reduced to 2 kb by RNase H, suggesting the presence of internal oligo(A) regions. All of the egg beta-tubulin RNAs sedimented as free ribonucleoprotein particles. Only a small portion of the 1.75- to 3.6-kb alpha-tubulin RNAs, but most of the 4.2-kb alpha-tubulin RNA, were found on polysomes before fertilization. In the 30-min embryo, small amounts of each of the various alpha- and beta-tubulin RNAs were recruited onto polysomes. Thus, each of the multiple polymorphic alpha- and beta-tubulin RNAs in the egg represent translationally competent mRNA.

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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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.

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.