The structure of transposable yeast mating type loci

A recombinant plasmid containing a MAT alpha mating type locus of Saccharomyces cerevisiae has been isolated by its ability to complement a sterile mat alpha mutation. The plasmid hybridizes to restriction fragments containing both active mating type loci (MATa and MAT alpha) and both silent mating type loci (HMRa and HML alpha). All loci therefore have common sequences. Recombinant lambda clones of the locihave been isolated by plaque hybridization and their structures have been compared by a heteroduplex analysis. At its center, each locus contains one of two apparently nonhomologous sequences. Loci concerned with the alpha phenotype (MAT alpha and HML alpha) contain and 850 bp alpha-specific sequence, whereas loci concerned with the a phenotype (MATa and HMRa) contain a 700 bp a-specific sequence. The a- or alpha-specific sequences are surrounded by DNA sequences that are common to all loci. These homologous sequences extend for 230 bp on the left and 700 bp on the right. They appear to be unrelated to each other. Surprisingly, HML alpha and HMRa differ in their extent of homology to MATa and MAT alpha outside the above regions. HMRa lacks an extensive (700 bp) DNA sequence to the right of the large right-hand homologous region, and possibly also a small (90 bp) sequence to the left of the small left-hand homologous region, both of which are present at HML alpha, MATa and MAT alpha. Hybridization studies have shown that the 700 bp sequence is present at HMLa but absent at HMR alpha alleles. It is therefore characteristic of HML, irrespective of whether it contains a- or alpha-specific sequences. The results imply that mating type interconversion is effected by transposition of DNA sequences from HML or HMR to MAT, as predicted by the controlling element model of Oshima and Takano (1971) and the Cassette model of Hicks, Strathern and Herskowitz (1977).     

Yeast silencers create domains of nuclease-resistant chromatin in an SIR4-dependent manner

Previous analysis of the repression of the silent mating type loci in Saccharomyces cerevisiae has linked the mechanism of silencing to the formation of a chromatin domain at the silenced loci. In this study, a TRP1 reporter gene was used to examine changes in chromatin structure in a neutral environment. This enabled the chromatin structure organized by yeast silencers to be compared directly with changes effected by the yeast α2 repressor. It was found that silencers mediate the formation of lengthy nuclease-resistant domains on the DNA, rather than specifically positioning nucleosomes over promoter regions as the α2 repressor does. Silencing at the TRP1 reporter gene closely resembled silencing at the HMR and HML loci. Repression of the test gene was optimal when two silencers flanking the reporter gene were used, mimicking the situation at the silent loci. In addition, both repression of the reporter gene and the formation of nuclease-resistant chromatin domains was SIR4 dependent. Received: 31 October 1996; in revised form: 6 March 1997 / Accepted: 25 March 1997     

Transposition of yeast mating type genes from two translocations of the left arm of chromosome III.

In the yeast Saccharomyces cerevisiae, the HIS4C gene lies on the left arm of chromosome III. We analyzed two chromosomal rearrangements that have HIS4C translocated either to chromosome XII or to a new translocation chromosome. Using the cmt mutation that allows expression of the normally silent copies of mating type genes, we found that both of these translocations also carried HML alpha, more than 30 map units distal to HIS4C which normally lies on chromosome III. In the case of the translocation chromosome (designated T3), we also found an exchange event between HML alpha on the translocation chromosome and HMLa on chromosome III. In diploids containing two T3 chromosomes (one carrying HML alpha and the carrying HMLa), we found that HML was 32 centimorgans from HIS4C, which was 10 centimorgans from an unknown centromere. In homothallic strains carrying HMLa MATa HMRa on chromosome III, switching from MATa to MAT alpha could occur by using the HML alpha on the translocation as the sole donor of alpha information. Transposition from HML alpha on chromosome T3 was about 20 to 40% as efficient as transposition from intact chromosome III. In contrast, transposition from the HML alpha inserted into chromosome XII was reduced about 100-fold. This reduced efficiency did not appear to be caused by an alteration in the sequences immediately surrounding HML alpha in the translocation. The translocated HML alpha sequence was located in the same size (29-kilobase) SalI fragment as was found in chromosome III, and the same EcoRI, HindIII, and BglII restriction sites were also found. Furthermore, HML alpha was still under the control of the CMT gene, which maintains HML as a silent copy of mating type information. These results suggested that the position of the HML alpha sequence plays an important role in the efficiency of mating type switching.     

Epigenetic inheritance of transcriptional states in S. cerevisiae

SIR1, one of several genes required for repression of yeast silent mating type loci, has a unique role in repression of the HML alpha locus. Single-cell assays revealed that cells with mutant alleles of SIR1, including presumptive null alleles, existed as populations of genetically identical cells whose members were in one of two different regulatory states. A minority of cells had a repressed HML alpha locus whereas the majority had a derepressed HML alpha locus. The two states were mitotically stable, although rare changes in state were observed during mitotic growth, possibly reflecting heritable changes to the HML alpha locus at or before replication. Analysis of changes in state suggests that SIR1 protein has a role in the establishment but not the maintenance of repression of silent mating type genes, whereas SIR2, SIR3, and SIR4 are required for maintenance.     

Homothallic switching of Saccharomyces cerevisiae mating type genes by using a donor containing a large internal deletion.

Homothallic switching of the mating type genes of Saccharomyces cerevisiae occurs by a gene conversion event, replacing sequences at the expressed MAT locus with a DNA segment copied from one of two unexpressed loci, HML or HMR. The transposed Ya or Y alpha sequences are flanked by homologous regions that are believed to be essential for switching. We examined the transposition of a mating type gene (hmr alpha 1-delta 6) which contains a 150-base-pair deletion spanning the site where the HO endonuclease generates a double-stranded break in MAT that initiates the gene conversion event. Despite the fact that the ends of the cut MAT region no longer share homology with the donor hmr alpha 1-delta 6, switching of MATa or MAT alpha to mat alpha 1-delta 6 was efficient. However, there was a marked increase in the number of aberrant events, especially the formation of haploid-inviable fusions between MAT and the hmr alpha 1-delta 6 donor locus.     

Donor Locus Selection during Saccharomyces Cerevisiae Mating Type Interconversion Responds to Distant Regulatory Signals

Mating type interconversion in homothallic strains of the yeast Saccharomyces cerevisiae results from directed transposition of a mating type allele from one of the two silent donor loci, HML and HMR, to the expressing locus, MAT. Cell type regulates the selection of the particular donor locus to be utilized during mating type interconversion: MATa cells preferentially select HML alpha and MAT alpha cells preferentially select HMRa. Such preferential selection indicates that the cell is able to distinguish between HML and HMR during mating type interconversion. Accordingly, we designed experiments to identify those features perceived by the cell to discriminate HML and HMR. We demonstrate that discrimination does not derive from the different structures of the HML and HMR loci, from the unique sequences flanking each donor locus nor from any of the DNA distal to the HM loci on chromosome III. Moreover, we find that the sequences flanking the MAT locus do not function in the preferential selection of one donor locus over the other. We propose that the positions of the donor loci on the left and right arms of chromosome III is the characteristic utilized by the cell to distinguish HML and HMR. This positional information is not generated by either CEN3 or the MAT locus, but probably derives from differences in the chromatin structure, chromosome folding or intranuclear localization of the two ends of chromosome III.     

Homothallic switching of yeast mating type cassettes is initiated by a double-stranded cut in the MAT locus

A double-stranded DNA cut has been observed in the mating type (MAT) locus of the yeast Saccharomyces cerevisiae in cultures undergoing homothallic cassette switching. Cutting is observed in exponentially growing cells of genotype HO HML alpha MAT alpha HMR alpha or HO HMLa MATa HMRa, which switch continuously, but not in a/alpha HO/HO diploid strains, in which homothallic switching is known to be shut off. Stationary phase cultures do not exhibit the cut. Although this site-specific cut occurs in a sequence (Z1) common to the silent HML and HMR cassettes and to MAT, only the Z1 sequence at the MAT locus is cut. The cut at MAT occurs in the absence of the HML and HMR donor cassettes, suggesting that cutting initiates the switching process. An assay for switching on hybrid plasmids containing mata- cassettes has been devised, and deletion mapping has shown that the cut site is required for efficient switching. Thus a double-stranded cut at the MAT locus appears to initiate cassette transposition-substitution and defines MAT as the recipient in this process.     

Mating type control in Saccharomyces cerevisiae: a frameshift mutation at the common DNA sequence, X, of the HML alpha locus.

A mutation defective in the homothallic switching of mating type alleles, designated hml alpha-2, has previously been characterized. The mutation occurred in a cell having the HO MATa HML alpha HMRa genotype, and the mutant culture consisted of ca. 10% a mating type cells, 90% nonmater cells of haploid cell size, and 0.1% sporogenous diploid cells. Genetic analyses revealed that nonmater haploid cells have a defect in the alpha 2 cistron at the MAT locus. This defect was probably caused by transposition of a cassette originating from the hml alpha-2 allele by the process of the homothallic mating type switch. That the MAT locus of the nonmater cells is occupied by a DNA fragment indistinguishable from the Y alpha sequence in electrophoretic mobility was demonstrated by Southern hybridization of the EcoRI-HindIII fragment encoding the MAT locus with a cloned HML alpha gene as the probe. The hml alpha-2 mutation was revealed to be a one-base-pair deletion at the ninth base pair in the X region from the X and Y boundary of the HML locus. This mutation gave rise to a shift in the open reading frame of the alpha 2 cistron. A molecular mechanism for the mating type switch associated with the occurrence of sporogenous diploid cells in the mutant culture is discussed.     

Mating-type control in Saccharomyces cerevisiae: isolation and characterization of mutants defective in repression by a1-alpha 2.

The alpha 2 protein, the product of the MAT alpha 2 cistron, represses various genes specific to the a mating type (alpha 2 repression), and when combined with the MATa1 gene product, it represses MAT alpha 1 and various haploid-specific genes (a1-alpha 2 repression). One target of a1-alpha 2 repression is RME1, which is a negative regulator of a/alpha-specific genes. We have isolated 13 recessive mutants whose a1-alpha 2 repression is defective but which retain alpha 2 repression in a genetic background of ho MATa HML alpha HMRa sir3 or ho MAT alpha HMRa HMRa sir3. These mutations can be divided into three different classes. One class contains a missense mutation, designated hml alpha 2-102, in the alpha 2 cistron of HML, and another class contains two mat alpha 2-202, in the MAT alpha locus. These three mutants each have an amino acid substitution of tyrosine or acid substitution of tyrosine or phenylalanine for cysteine at the 33rd codon from the translation initiation codon in the alpha 2 cistron of HML alpha or MAT alpha. The remaining 10 mutants make up the third class and form a single complementation group, having mutations designated aar1 (a1-alpha 2 repression), at a gene other than MAT, HML, HMR, RME1, or the four SIR genes. Although a diploid cell homozygous for the aarl and sir3 mutations and for the MATa, HML alpha, and HMRa alleles showed alpha mating type, it could sporulate and gave rise to asci containing four alpha mating-type spores. These facts indicate that the domain for alpha2 repression is separable from that for a1-alpha2 protein interaction or complex formation in the alpha2 protein and that an additional regulation gene, AAR1, is associated with the a1-alpha2 repression of the alpha1 cistron and haploid-specific genes.     

SAD mutation of Saccharomyces cerevisiae is an extra a cassette.

Sporulation of Saccharomyces cerevisiae ordinarily requires the a1 function of the a mating type locus. SAD is a dominant mutation that allows strains lacking a1 (MAT alpha/MAT alpha and mata1/MAT alpha diploids) to sporulate. We provide functional and physical evidence that SAD is an extra cassette in the yeast genome, distinct from those at HML, MAT, and HMR. The properties of SAD strains indicate that the a cassette at SAD produces a limited amount of a1 product, sufficient for promoting sporulation but not for inhibiting mating and other processes. These conclusions come from the following observations. (i) SAD did not act by allowing expression of HMRa: mata1/MAT alpha diploids carrying SAD and only alpha cassettes at HML and HMR sporulated efficiently. (ii) SAD acted as an a cassette donor in HML alpha HMR alpha strains and could heal a mata1 mutation to MATa as a result of mating type interconversion. (iii) The genome of SAD strains contained a single new cassette locus, as determined by Southern hybridization. (iv) Expression of a functions from the SAD a cassette was limited by Sir: sir- SAD strains exhibited more extreme phenotypes than SIR SAD strains. This observation indicates that SAD contains not only cassette information coding for a1 (presumably from HMRa) but also sites for Sir action.     

Identification of a functional domain within the essential core of histone H3 that is required for telomeric and HM silencing in Saccharomyces cerevisiae

Fourteen novel single-amino-acid substitution mutations in histone H3 that disrupt telomeric silencing in Saccharomyces cerevisiae were identified, 10 of which are clustered within the alpha1 helix and L1 loop of the essential histone fold. Several of these mutations cause derepression of silent mating locus HML, and an additional subset cause partial loss of basal repression at the GAL1 promoter. Our results identify a new domain within the essential core of histone H3 that is required for heterochromatin-mediated silencing.     

Coconversion of flanking sequences with homothallic switching

Homothallic switching in S. cerevisiae involves replacing the DNA of the expressed allele at the mating type locus (MAT) with a duplicate of sequences from the unexpressed loci HML or HMR. The MATa and MAT alpha alleles differ by a DNA substitution that is flanked by sequences in common to MAT, and the donor loci HML and HMR. Using restriction site polymorphisms between MAT and the donor loci, we demonstrate that the extent of MAT DNA that is replaced during switching is variable and that there is a gradient of coconversion across the X region. Coconversion events occur on both sides of the double-strand cleavage by the HO gene product. The two cells produced after a switch often differ at the flanking site, indicating a DNA heteroduplex intermediate.