Position effects in Saccharomyces cerevisiae

Glutamine-rich domains activate transcription in yeast Saccharomyces cerevisiae

Activation domains of eukaryotic transcription factors can be classified into at least three distinct types based on their amino acid composition: acidic, proline-rich, and glutamine-rich. Acidic activators, such as yeast GAL4 and GCN4 and herpes simplex virus VP16, have been shown to stimulate transcription in various higher and lower eukaryotic cells. Similarly, proline-rich activators also function in both mammalian and yeast cells. These activators are regarded to possess "universal" activating potentials. By contrast, several studies have suggested that glutamine-rich activators such as human Sp1 are active in higher (mammalian) but not lower (yeast) eukaryotic cells. One interpretation is that lower eukaryotic cells lack a critical co-factor necessary for a glutamine-rich domain. This reasoning is counter-intuitive because many native yeast activator proteins contain glutamine-rich domains. Here, we have investigated the activity of a glutamine-rich GAL4-Sp1 domain A (Sp1A) hybrid protein in yeast Saccharomyces cerevisiae. We show that GAL4-Sp1A activated a GAL1-lacZ reporter by more than 200-fold over basal when the reporter was carried on a 2mu vector. The generality of the Sp1A results is supported by our finding that yeast glutamine-rich domains from HAP2 and MCM1 are also transcriptionally active in S. cerevisiae. Interestingly, we found that glutamine-rich domains are considerably less potent when responsive promoters (i.e. GAL1-lacZ) are integrated into yeast chromosome. Thus our results segregate the inherent transcriptional activity of a glutamine-rich domain in yeast S. cerevisiae from its apparent lack of activity when assayed on chromosomally embedded promoters.

RPC53 encodes a subunit of Saccharomyces cerevisiae RNA polymerase C (III) whose inactivation leads to a predominantly G1 arrest

RPC53 is shown to be an essential gene encoding the C53 subunit specifically associated with yeast RNA polymerase C (III). Temperature-sensitive rpc53 mutants were generated and showed a rapid inhibition of tRNA synthesis after transfer to the restrictive temperature. Unexpectedly, the rpc53 mutants preferentially arrested their cell division in the G1 phase as large, round, unbudded cells. The RPC53 DNA sequence is predicted to code for a hydrophilic M(r)-46,916 protein enriched in charged amino acid residues. The carboxy-terminal 136 amino acids of C53 are significantly similar (25% identical amino acid residues) to the same region of the human BN51 protein. The BN51 cDNA was originally isolated by its ability to complement a temperature-sensitive hamster cell mutant that undergoes a G1 cell division arrest, as is true for the rpc53 mutants.

RPC53 encodes a subunit of Saccharomyces cerevisiae RNA polymerase C (III) whose inactivation leads to a predominantly G1 arrest

RPC53 is shown to be an essential gene encoding the C53 subunit specifically associated with yeast RNA polymerase C (III). Temperature-sensitive rpc53 mutants were generated and showed a rapid inhibition of tRNA synthesis after transfer to the restrictive temperature. Unexpectedly, the rpc53 mutants preferentially arrested their cell division in the G1 phase as large, round, unbudded cells. The RPC53 DNA sequence is predicted to code for a hydrophilic M(r)-46,916 protein enriched in charged amino acid residues. The carboxy-terminal 136 amino acids of C53 are significantly similar (25% identical amino acid residues) to the same region of the human BN51 protein. The BN51 cDNA was originally isolated by its ability to complement a temperature-sensitive hamster cell mutant that undergoes a G1 cell division arrest, as is true for the rpc53 mutants.

Characterization of a centromere-linked recombination hot spot in Saccharomyces cerevisiae

A 1.5-kilobase-pair SalI-HindIII (SH) restriction fragment from the region of Saccharomyces cerevisiae chromosome XIV immediately adjacent to the centromere appears to contain sequences that act as a hot spot for mitotic recombination. The presence of SH DNA on an autonomously replicating plasmid stimulates homologous genetic exchange between yeast genomic sequences and those present on the plasmid. In all recombinants characterized, exchange occurs in plasmid yeast sequences adjacent to rather than within the SH DNA. Hybridization analyses reveal that SH-containing plasmids are present in linear as well as circular form in S. cerevisiae and that linear forms are generated by cleavage at specific sites. Presumably, it is the linear form of the plasmid that is responsible for the stimulation of genetic exchange. Based on these observations, it is proposed that this DNA fragment contains a centromere-linked recombination hot spot and that SH-stimulated recombination occurs via a mechanism similar to double-strand-gap repair (J. W. Szostak, T. Orr-Weaver, J. Rothstein, and F. Stahl, Cell 33:25-35 1983).

Characterization of a centromere-linked recombination hot spot in Saccharomyces cerevisiae

A 1.5-kilobase-pair SalI-HindIII (SH) restriction fragment from the region of Saccharomyces cerevisiae chromosome XIV immediately adjacent to the centromere appears to contain sequences that act as a hot spot for mitotic recombination. The presence of SH DNA on an autonomously replicating plasmid stimulates homologous genetic exchange between yeast genomic sequences and those present on the plasmid. In all recombinants characterized, exchange occurs in plasmid yeast sequences adjacent to rather than within the SH DNA. Hybridization analyses reveal that SH-containing plasmids are present in linear as well as circular form in S. cerevisiae and that linear forms are generated by cleavage at specific sites. Presumably, it is the linear form of the plasmid that is responsible for the stimulation of genetic exchange. Based on these observations, it is proposed that this DNA fragment contains a centromere-linked recombination hot spot and that SH-stimulated recombination occurs via a mechanism similar to double-strand-gap repair (J. W. Szostak, T. Orr-Weaver, J. Rothstein, and F. Stahl, Cell 33:25-35 1983).

RAD7 gene of Saccharomyces cerevisiae: transcripts, nucleotide sequence analysis, and functional relationship between the RAD7 and RAD23 gene products

The RAD7 gene of Saccharomyces cerevisiae was cloned on a 4.0-kilobase (kb) DNA fragment and shown to provide full complementation of a rad7-delta mutant strain. The nucleotide sequence of a 2.2-kb DNA fragment which contains the complete RAD7 gene was determined. Transcription of the RAD7 gene initiates at multiple sites in a region spanning positions -61 to -8 of the DNA sequence. The 1.8-kb RAD7 mRNA encodes a protein of 565 amino acids with a predicted size of 63.7 kilodaltons. The hydropathy profile of the RAD7 protein indicates a highly hydrophilic amino terminus and a very hydrophobic region toward the carboxyl terminus. A RAD7 subclone deleted for the first 99 codons complements the rad7-delta mutation, but not the rad7-delta rad23-delta double mutation, indicating that the RAD23 protein can compensate for the function that is missing in the amino-terminally deleted RAD7 protein. The RAD7 and RAD23 genes in multicopy plasmids do not complement the rad23-delta and rad7-delta mutations, respectively. These observations could mean that although the two proteins might share a common functional domain, they must also perform distinct functions. Alternatively, an interaction between the RAD7 and RAD23 proteins could also account for these observations.

RAD7 gene of Saccharomyces cerevisiae: transcripts, nucleotide sequence analysis, and functional relationship between the RAD7 and RAD23 gene products

The RAD7 gene of Saccharomyces cerevisiae was cloned on a 4.0-kilobase (kb) DNA fragment and shown to provide full complementation of a rad7-delta mutant strain. The nucleotide sequence of a 2.2-kb DNA fragment which contains the complete RAD7 gene was determined. Transcription of the RAD7 gene initiates at multiple sites in a region spanning positions -61 to -8 of the DNA sequence. The 1.8-kb RAD7 mRNA encodes a protein of 565 amino acids with a predicted size of 63.7 kilodaltons. The hydropathy profile of the RAD7 protein indicates a highly hydrophilic amino terminus and a very hydrophobic region toward the carboxyl terminus. A RAD7 subclone deleted for the first 99 codons complements the rad7-delta mutation, but not the rad7-delta rad23-delta double mutation, indicating that the RAD23 protein can compensate for the function that is missing in the amino-terminally deleted RAD7 protein. The RAD7 and RAD23 genes in multicopy plasmids do not complement the rad23-delta and rad7-delta mutations, respectively. These observations could mean that although the two proteins might share a common functional domain, they must also perform distinct functions. Alternatively, an interaction between the RAD7 and RAD23 proteins could also account for these observations.

Expression of the major heat shock gene of Drosophila melanogaster in Saccharomyces cerevisiae

A copy of the gene which encodes the major heat shock protein (hsp70) of D. melanogaster was integrated in both orientations into the genome of S. cerevisiae at the leu2 locus. The level of transcript from the D. melanogaster gene was measured under both normal conditions and conditions which are known to give rise to the heat shock response in S. cerevisiae. In both orientations the D. melanogaster gene gave rise to an abundant transcript in uninduced cells. The level of this transcript was increased transiently on heat shock, peaking after about 30 min at the elevated temperature. The average induction observed was around 5-fold. Although the D. melanogaster gene is heat inducible in S. cerevisiae, the transcripts are initiated at several sites which lie between 10 and 40 base pairs downstream of the initiation site in D. melanogaster. Thus, the transcriptional apparatus of S. cerevisiae appears to recognize the promoter and regulatory elements of the D. melanogaster major heat shock gene, although the manner in which transcription is initiated differs between the two species.

Sequences upstream of the STE6 gene required for its expression and regulation by the mating type locus in Saccharomyces cerevisiae

The STE6 gene of Saccharomyces cerevisiae is an a-specific gene; it is repressed in alpha cells by the alpha 2 product of the mating type locus. To study the role of sequences upstream of STE6 in its regulation and expression, we have determined the DNA sequence of the promoter region, identified the start sites for the STE6 transcript, and identified sequences governing its transcription. Deletions that remove DNA upstream of the STE6 gene were produced and assayed for effects on regulation and expression. The deletions defined two intervals upstream of the STE6 transcription initiation sites. One contains all or part of a negative element; the other contains all or part of a positive element. The negative element is required for repression of STE6 by alpha 2: deletions lacking this element express STE6 constitutively. Such deletions remove a 31-base-pair site, located 135 base pairs upstream of the first transcript start site, that is highly homologous to sites present in the upstream regions of four other genes repressed by alpha 2. These sites are presumably responsible for repression of the a-specific genes by alpha 2. The positive element (a putative upstream activation site) is required for expression of STE6. The deletions define the left boundary of the proposed upstream activation site. Sequence homologies between STE6 and other a-specific genes are found in this region and may mediate activation of this set of genes.

Deletion analysis identifies a region, upstream of the ADH2 gene of Saccharomyces cerevisiae, which is required for ADR1-mediated derepression

Deletion analysis was used to identify sequences upstream of the ADH2 gene of Saccharomyces cerevisiae that are required for its regulation. 5' and 3' internal deletions of the ADH2 control region were created in vitro, and the fragments were ligated adjacent to the ADH1 promoter and structural gene. Hybrid genes with 3' deletions extending from -119 to -216 (the start site of ADH2 transcription is designated +1) were fully repressed and derepressed to high levels. Hybrid genes with 3' deletions extending from -119 to -257 were repressed but failed to significantly derepress. Hybrid genes lacking the -216 to -257 region also failed to respond to ADR1-5c, a mutant allele of the unlinked regulatory gene ADR1, which confers constitutive expression on ADH2. This implies that the region between these deletion endpoints, which includes a 22-base-pair sequence of dyad symmetry, is required for efficient derepression of an adjacent promoter. Internal deletions extending in the 3' direction from position -1141 confirmed these results. Deletion mutants lacking the region -1141 to -259 were normally regulated, whereas deletions extending from -1141 to -115 were not derepressible. These results support the hypotheses that the ADH2 promoter may normally be in an inactive conformation in the yeast chromosome and that derepression of ADH2 requires positive activation mediated through an upstream activation sequence located between 216 and 257 base pairs 5' to the start site of ADH2 transcription. No evidence for a DNA sequence mediating repression was obtained.

Deletion analysis identifies a region, upstream of the ADH2 gene of Saccharomyces cerevisiae, which is required for ADR1-mediated derepression

Deletion analysis was used to identify sequences upstream of the ADH2 gene of Saccharomyces cerevisiae that are required for its regulation. 5' and 3' internal deletions of the ADH2 control region were created in vitro, and the fragments were ligated adjacent to the ADH1 promoter and structural gene. Hybrid genes with 3' deletions extending from -119 to -216 (the start site of ADH2 transcription is designated +1) were fully repressed and derepressed to high levels. Hybrid genes with 3' deletions extending from -119 to -257 were repressed but failed to significantly derepress. Hybrid genes lacking the -216 to -257 region also failed to respond to ADR1-5c, a mutant allele of the unlinked regulatory gene ADR1, which confers constitutive expression on ADH2. This implies that the region between these deletion endpoints, which includes a 22-base-pair sequence of dyad symmetry, is required for efficient derepression of an adjacent promoter. Internal deletions extending in the 3' direction from position -1141 confirmed these results. Deletion mutants lacking the region -1141 to -259 were normally regulated, whereas deletions extending from -1141 to -115 were not derepressible. These results support the hypotheses that the ADH2 promoter may normally be in an inactive conformation in the yeast chromosome and that derepression of ADH2 requires positive activation mediated through an upstream activation sequence located between 216 and 257 base pairs 5' to the start site of ADH2 transcription. No evidence for a DNA sequence mediating repression was obtained.

Proline utilization in Saccharomyces cerevisiae: analysis of the cloned PUT2 gene

The PUT2 gene was isolated on a 6.5-kilobase insert of a recombinant DNA plasmid by functional complementation of a put2 (delta 1-pyrroline-5-carboxylate dehydrogenase-deficient) mutation in Saccharomyces cerevisiae. Its identity was confirmed by a gene disruption technique in which the chromosomal PUT2+ gene was replaced by plasmid DNA carrying the put2 gene into which the S. cerevisiae HIS3+ gene had been inserted. The cloned PUT2 gene was used to probe specific mRNA levels: full induction of the PUT2 gene resulted in a 15-fold increase over the uninduced level. The PUT2-specific mRNA was approximately 2 kilobases in length and was used in S1 nuclease protection experiments to locate the gene to a 3-kilobase HindIII fragment. When delta 1-pyrroline-5-carboxylate dehydrogenase activity levels were measured in strains carrying the original plasmid, as well as in subclones, similar induction ratios were found as compared with enzyme levels in haploid yeast strains. Effects due to increased copy number or position were also seen. The cloned gene on a 2 mu-containing vector was used to map the PUT2 gene to chromosome VIII.

Proline utilization in Saccharomyces cerevisiae: analysis of the cloned PUT2 gene

The PUT2 gene was isolated on a 6.5-kilobase insert of a recombinant DNA plasmid by functional complementation of a put2 (delta 1-pyrroline-5-carboxylate dehydrogenase-deficient) mutation in Saccharomyces cerevisiae. Its identity was confirmed by a gene disruption technique in which the chromosomal PUT2+ gene was replaced by plasmid DNA carrying the put2 gene into which the S. cerevisiae HIS3+ gene had been inserted. The cloned PUT2 gene was used to probe specific mRNA levels: full induction of the PUT2 gene resulted in a 15-fold increase over the uninduced level. The PUT2-specific mRNA was approximately 2 kilobases in length and was used in S1 nuclease protection experiments to locate the gene to a 3-kilobase HindIII fragment. When delta 1-pyrroline-5-carboxylate dehydrogenase activity levels were measured in strains carrying the original plasmid, as well as in subclones, similar induction ratios were found as compared with enzyme levels in haploid yeast strains. Effects due to increased copy number or position were also seen. The cloned gene on a 2 mu-containing vector was used to map the PUT2 gene to chromosome VIII.

Topological modifications and template activation are induced in chimaeric plasmids by inserted sequences

The effect of the insertion of foreign genes or gene systems in closed DNA domains has been investigated in vitro in purified systems. We observe that in chimaeric plasmids two apparently independent classes of modifications, (1) functional and (2) topological, do take place in defined instances. (1) Among the screened yeast gene systems, examples have been found of DNA sequences that upon insertion cause activation of in vitro transcription of distant genes. (2) Foreign DNA sequences may lead to new topological features of the harbouring plasmids; it is shown that more than one S1-sensitive secondary structure may be contemporaneously present on the same chimaeric plasmid. DNA superhelicity is a prerequisite of these modifications. The two classes of effects (1) functional and (2) topological are not a priori directly related one to the other but appear to be two independent consequences of the same cause: the insertion of foreign DNA sequences into closed DNA domains. These observations suggest a regulatory model of gene expression based on alternative topologies of closed DNA domains.

Sequence organization in Dictyostelium: unique structure at the 5'-ends of protein coding genes

We have compared the sequences which lie 5' to the coding regions of 15 Dictyostelium genes transcribed by RNA polymerase II. These sequences are extremely (approximately 90%) A + T rich and contain extensive homopolymeric regions. Like most eukaryotic genes, those in Dictyostelium possess a TATA or Goldberg-Hogness Box approximately 25-35bp 5' to the site of transcription initiation. In addition, each gene contains an oligo (dT) stretch between the TATA Box and mRNA start site; this oligo (dT) sequence is, thus far, unique to Dictyostelium. We suggest that the TATA-oligo (dT) structure is an essential component of the Dictyostelium promoter. The general sequence structure of coding, non-coding and untranscribed flanking regions in Dictyostelium is also discussed.

One-step gene disruption in yeast

The one-step gene disruption techniques described here are versatile in that a disruption can be made simply by the appropriate cloning experiment. The resultant chromosomal insertion is nonreverting and contains a genetically linked marker. Detailed knowledge of the restriction map of a fragment is not necessary. It is even possible to "probe" a fragment that is unmapped for genetic functions by constructing a series of insertions and testing each one for its phenotype.

Cloned ural locus of Schizosaccharomyces pombe propagates autonomously in this yeast assuming a polymeric form

DNA segments cloned from Schizosaccharomyces pombe by the ability to complement Escherichia coli pyrB mutations are shown to complement a ural mutation in S. pombe, thereby demonstrating that ural is the structural gene for aspartate transcarbamylase of S. pombe. Further, such segments combined with parts or all of pBR322 are shown to be capable of autonomous propagation in S. pombe. This suggests the existence of an autonomously replicating sequence (ars) in the vicinity of ural. Unlike the TRP1 segment cloned from Saccharomyces cerevisiae [Struhl, K., Stinchcomb, D. T., Scherer, S. & Davis, R. W. (1979) Proc. Natl. Acad. Sci. USA 76, 1035-1039], plasmids carrying the ural locus do not multiply as monomers but assume a polymeric form as large as a decamer to an icosamer in the yeast. Monomers are tandemly arranged in the polymer. Inversion of an inserted fragment or insertion of another segment into a competent plasmid greatly decreases the efficiency of such transformation, implying a role of the tertiary structure of the plasmids in the establishment of transformation of this kind.

The yeast his3 promoter contains at least two distinct elements

Phenotypic analysis of 65 mutations indicates that the yeast his3 promoter is composed of at least two separate regions of DNA. Each is necessary, but neither is sufficient for wild-type levels of his3 expression. Deletion mutations that destroy either promoter element express his3 poorly or not at all. The upstream element is located between 112 and 155 base pairs before the site of transcriptional initiation (nucleotides -112 to -155). A comparison of derivatives strongly suggests that the downstream element maps somewhere between nucleotides -32 and -52 and includes a sequence between nucleotides -45 and -52. This location coincides with sequences conserved before most eukaryotic genes(the TATA box region). By using derivatives in which his3 sequences are replaced by a small fragment of coliphage M13 DNA, three properties of the his3 promoter were established. First, his3 TATA box deletions fail to express his3 because they lack specific sequences and not because they disrupt spacing relationships between other sequences. Second, the TATA box region can be replaced functionally by the one orientation of the M13 DNA fragment that contains a TATA-like sequence. Third, the distance between the two elements (normally 90 base pairs) can be varied between 40 and 160 base pairs without markedly affecting promoter function. These results strongly suggest that yeast RNA polymerase II, unlike its Escherichia coli counterpart, does not bind simultaneously to both promoter elements, and they add further support to the view that the upstream element is not part of a transcriptionally competent binding site. This ability of the his3 upstream promotor element to act at a long and variable distance is similar to properties of viral enhancer sequences and is reminiscent of position effects in yeast.