The Saccharomyces cerevisiae chromosome III left telomere has a type X, but not a type Y', ARS region

DMC1 functions in a Saccharomyces cerevisiae meiotic pathway that is largely independent of the RAD51 pathway

Meiotic recombination in the yeast Saccharomyces cerevisiae requires two similar recA-like proteins, Dmc1p and Rad51p. A screen for dominant meiotic mutants provided DMC1-G126D, a dominant allele mutated in the conserved ATP-binding site (specifically, the A-loop motif) that confers a null phenotype. A recessive null allele, dmc1-K69E, was isolated as an intragenic suppressor of DMC1-G126D. Dmc1-K69Ep, unlike Dmc1p, does not interact homotypically in a two-hybrid assay, although it does interact with other fusion proteins identified by two-hybrid screen with Dmc1p. Dmc1p, unlike Rad51p, does not interact in the two-hybrid assay with Rad52p or Rad54p. However, Dmc1p does interact with Tid1p, a Rad54p homologue, with Tid4p, a Rad16p homologue, and with other fusion proteins that do not interact with Rad51p, suggesting that Dmc1p and Rad51p function in separate, though possibly overlapping, recombinational repair complexes. Epistasis analysis suggests that DMC1 and RAD51 function in separate pathways responsible for meiotic recombination. Taken together, our results are consistent with a requirement for DMC1 for meiosis-specific entry of DNA double-strand break ends into chromatin. Interestingly, the pattern on CHEF gels of chromosome fragments that result from meiotic DNA double-strand break formation is different in DMC1 mutant strains from that seen in rad50S strains.

The chromosome ends of Saccharomyces cerevisiae

Yeast chromosome ends are similar in structure and function to chromosome ends in most, if not all, eukaryotic organisms. There is a G-rich terminal repeat at the ends which is maintained by telomerase. In addition to the classical functions of protecting the end from degradation and end-to-end fusions, and completing replication, yeast telomeres have several interesting properties including: non-nucleosomal chromatin structure; transcriptional position effect variegation for genes with adjacent telomeres; nuclear peripheral localization; apparent physical clustering; non-random recombinational interactions. A number of genes have been identified that are involved in modifying one or more of these properties. These include genes involved in general DNA metabolism, chromatin structure and telomere maintenance. Adjacent to the terminal repeat is a mosaic of middle repetitive elements that exhibit a great deal of polymorphism both between individual strains and among different chromosome ends. Much of the sequence redundancy in the yeast genome is found in the sub-telomeric regions (within the last 25 kb of each end). The sub-telomeric regions are generally low in gene density, low in transcription, low in recombination, and they are late replicating. The only element which appears to be shared by all chromosome ends is part of the previously defined X element containing an ARS consensus. Most of the 'core' X elements also contain an Abf1p binding site and a URS1-like element, which may have consequences for the chromatin structure, nuclear architecture and transcription of native telomeres. Possible functions of sub-telomeric repeats include: fillers for increasing chromosome size to some minimum threshold level necessary for chromosome stability; barrier against transcriptional silencing; a suitable region for adaptive amplification of genes; secondary mechanism of telomere maintenance via recombination when telomerase activity is absent.

RTM1: a member of a new family of telomeric repeated genes in yeast

We have isolated a new yeast gene called RTM1 whose overexpression confers resistance to the toxicity of molasses. The RTM1 gene encodes a hydrophobic 34-kD protein that contains seven potential transmembrane-spanning segments. Analysis of a series of industrial strains shows that the sequence is present in multiple copies and in variable locations in the genome. RTM loci are always physically associated with SUC telomeric loci. The SUC-RTM sequences are located between X and Y' subtelomeric sequences at chromosome ends. Surprisingly RTM sequences are not detected in the laboratory strain X2180. The lack of this sequence is associated with the absence of any SUC telomeric gene previously described. This observation raises the question of the origin of this nonessential gene. The particular subtelomeric position might explain the SUC-RTM sequence amplification observed in the genome of yeasts used in industrial biomass or ethanol production with molasses as substrate. This SUC-RTM sequence dispersion seems to be a good example of genomic rearrangement playing a role in evolution and environmental adaptation in these industrial yeasts.

TEL+CEN antagonism on plasmids involves telomere repeat sequences tracts and gene products that interact with chromosomal telomeres

In Saccharomyces cerevisiae, circular plasmids that include either a centromere (CEN-plasmids) or a telomere sequence (TEL-plasmids) segregate more efficiently than circular ARS-plasmids. In contrast, circular plasmids that include both telomere and centromere sequences were unstable, a property we term TEL+CEN antagonism. TEL+CEN antagonism required a telomere repeat tract longer than 49 bp although the distance and relative orientation of the centromere and telomere sequences was not critical. TEL+CEN antagonism was alleviated in strains carrying different rap1 alleles including rap1ts, rap1s, and rap1t alleles. Mutations SIR2, SIR3, SIR4, NAT1 and ARD1, genes that influence transcriptional silencing at telomeres and at the silent mating type loci, abolished TEL+CEN antagonism Mutation of SIR1 also partially alleviated TEL-CEN antagonism. In some sir mutant strains short yeast artificial chromosomes (YACs), which are normally unstable, became more stable, suggesting that the same mechanism that caused TEL+CEN antagonism on circular plasmids may contribute to the instability of short linear plasmids.

The chromosome end in yeast: its mosaic nature and influence on recombinational dynamics

Yeast chromosome ends are composed of several different repeated elements. Among six clones of chromosome ends from two strains of Saccharomyces cerevisiae, at least seven different repeated sequence families were found. These included the previously identified Y' and X elements. Some families are highly variable in copy number and location between strains of S. cerevisiae, while other elements appear constant in copy number and location. Three repeated sequence elements are specific to S. cerevisiae and are not found in its evolutionarily close relative, Saccharomyces paradoxus. Two other repeated sequences are found in both S. cerevisiae and S. paradoxus. None of those described here is found (by low stringency DNA hybridization) in the next closest species, Saccharomyces bayanus. The loosely characterized X element is now more precisely defined. X is a composite of at least four small (ca. 45-140 bp) sequences found at some, but not all, ends. There is also a potential "core" X element of approximately 560 bp which may be found at all ends. Distal to X, only one of six clones had (TG1-3)n telomere sequence at the junction between X and Y'. The presence of these internal (TG1-3)n sequences correlates with the ability of a single Y' to expand into a tandem array of Y's by unequal sister chromatid exchange. The presence of shared repeated elements proximal to the X region can override the strong preference of Y's to recombine ectopically with other Y's of the same size class. The chromosome ends in yeast are evolutionarily dynamic in terms of subtelomeric repeat structure and variability.

Corrected sequence for the right telomere of Saccharomyces cerevisiae chromosome III

A comparison of the sequences of telomere regions from several yeast chromosomes revealed an apparent cloning artifact for the right end of chromosome III. An integrating vector containing G1-3T telomere sequences was used to clone the right end of chromosome III from a strain related to S288C. The sequence of this clone confirmed that the published sequence was incorrect and demonstrated that the right telomere region of chromosome III is similar to other telomeres.

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae at a resolution of 2.6 kilobase pairs

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae are presented. In order of increasing size, they are chromosomes I, VI, III, IX, V and VIII, comprising 2.49 megabase pairs of DNA. The maps are based on the analysis of an overlapping set of lambda and cosmid clones. Overlaps between adjacent clones were recognized by shared restriction fragments produced by the combined action of EcoRI and HindIII. The average spacing between mapped cleavage sites is 2.6 kb. Five of the six chromosomes were mapped from end to end without discontinuities; a single internal gap remains in the map of chromosome IX. The reported maps span an estimated 97% of the DNA on the six chromosomes; nearly all the missing segments are telomeric. The maps are fully cross-correlated with the previously published SfiI/NotI map of the yeast genome by A. J. Link and M. V. Olson. They have also been cross-correlated with the yeast genetic map at 51 loci.

An alternative pathway for yeast telomere maintenance rescues est1- senescence

Yeast cells lacking a functional EST1 gene show progressive shortening of the terminal G1-3T telomeric repeats and a parallel increase in the frequency of cell death. Although the majority of the cells in an est1- culture die, a minor subpopulation survives the potentially lethal consequences of the est1 mutation. We show that these est1- survivors arise as a result of the amplification and acquisition of subtelomeric elements (and their deletion derivatives) by a large number of telomeres. Hence, even when the primary pathway for telomere replication is defective, an alternative backup pathway can restore telomere function and keep the cell alive.

The complete DNA sequence of yeast chromosome III

The entire DNA sequence of chromosome III of the yeast Saccharomyces cerevisiae has been determined. This is the first complete sequence analysis of an entire chromosome from any organism. The 315-kilobase sequence reveals 182 open reading frames for proteins longer than 100 amino acids, of which 37 correspond to known genes and 29 more show some similarity to sequences in databases. Of 55 new open reading frames analysed by gene disruption, three are essential genes; of 42 non-essential genes that were tested, 14 show some discernible effect on phenotype and the remaining 28 have no overt function.

Physical mapping of the Saccharomyces cerevisiae Ap4A phosphorylase I-encoding gene by the Achilles' cleavage method

LacI-mediated Achilles' cleavage (AC) is a method for selective fragmentation of chromosomes at special lac operator sites introduced by gene targeting methods [Koob and Szybalski, Science 250 (1990) 271-273]. The Saccharomyces cerevisiae APA1 gene, coding for diadenosine 5', 5"'-P1, P4-tetraphosphate phosphorylase I, has previously been shown to be located on chromosome III [Kaushal et al., Gene 95 (1990) 79-84]. We have now used the AC method to map APA1 gene to a site 44 kb from the left terminus of the chromosome, between the HIS4 and HML genes. This location was confirmed by the comparison of restriction maps of the APA1 gene region to published restriction maps of chromosome III.

Evolutionarily recent transfer of a group I mitochondrial intron to telomere regions in Saccharomyces cerevisiae

The junctions between X and Y' subtelomeric repeats in Saccharomyces cerevisiae usually contain a stretch of telomere sequences, (G1-3T)n. Two of three cloned X-Y' junctions from strain YP1 have a replacement of about 200 bp of X, the internal telomere sequence, and 49 bp of Y' by a 292 bp sequence. The first 227 bp of this insertion sequence are 100% identical to the fourth intron of cytochrome b. The rest of the insertion has homology to an unknown dispersed nuclear sequence. Recombination among subtelomeric regions can explain the nuclear distribution of this sequence and why telomeres can trap and maintain sequences that would otherwise be lost.

Analysis of a circular derivative of Saccharomyces cerevisiae chromosome III: a physical map and identification and location of ARS elements

DNA was isolated from a circular derivative of chromosome III to prepare a library of recombinant plasmids enriched in chromosome III sequences. An ordered set of recombinant plasmids and bacteriophages carrying the contiguous 210-kilobase region of chromosome III between the HML and MAT loci was identified, and a complete restriction map was prepared with BamHI and EcoRI. Using the high frequency transformation assay and extensive subcloning, 13 ARS elements were mapped in the cloned region. Comparison of the physical maps of chromosome III from three strains revealed that the chromosomes differ in the number and positions of Ty elements and also show restriction site polymorphisms. A comparison of the physical map with the genetic map shows that meiotic recombination rates vary at least tenfold along the length of the chromosome.

Modifiers of position effect are shared between telomeric and silent mating-type loci in S. cerevisiae

Genes placed near telomeres in S. cerevisiae succumb to position-effect variegation. SIR2, SIR3, SIR4, NAT1, ARD1, and HHF2 (histone H4) were identified as modifiers of the position effect at telomeres, since transcriptional repression near telomeres was no longer observed when any of the modifier genes were mutated. These genes, in addition to SIR1, have previously been shown to repress transcription at the silent mating loci, HML and HMR. However, there were differences between transcriptional silencing at telomeres and the HM loci, as demonstrated by suppressor analysis and the lack of involvement of SIR1 in telomeric silencing. These findings provide insights into telomeric structure and function that are likely to apply to many eukaryotes. In addition, the distinctions between telomeres and the HM loci suggest a hierarchy of chromosomal silencing in S. cerevisiae.

Gene conversion tracts stimulated by HOT1-promoted transcription are long and continuous

The recombination-stimulating sequence, HOT1, corresponds to the promoter of transcription by yeast RNA polymerase I. The effect of HOT1 on mitotic interchromosomal recombination was examined in diploid strains carrying a heterozygous URA3 gene on chromosome III. The frequency of Ura- recombinants was increased 20-fold when HOT1 was inserted into the chromosome III copy marked with URA3, at a location 48 kbp centromere-proximal to URA3. Ura- recombinants were increased only 2-fold when HOT1 and URA3 were on opposite homologues. These results suggest that most HOT1-promoted Ura- recombinants result from gene conversion and that sequences on the HOT1-containing chromosome are preferentially converted. Characterization of Ura- recombinants isolated from strains carrying multiple markers on chromosome III indicates that HOT1-promoted gene conversion tracts are unusually long (often greater than 75 kbp) and almost always continuous. Furthermore, conversion tracts frequently extend to both sides of HOT1. We suggest that HOT1 promotes the formation of a double-strand break which is often followed by exonucleolytic digestion. Repair of the broken chromosome could then result from gap repair or from replicative repair primed only by the centromere-containing chromosomal fragment.

Involvement of the silencer and UAS binding protein RAP1 in regulation of telomere length

The yeast protein RAP1, initially described as a transcriptional regulator, binds in vitro to sequences found in a number of seemingly unrelated genomic loci. These include the silencers at the transcriptionally repressed mating-type genes, the promoters of many genes important for cell growth, and the poly[(cytosine)1-3 adenine] [poly(C1-3A)] repeats of telomeres. Because RAP1 binds in vitro to the poly(C1-3A) repeats of telomeres, it has been suggested that RAP1 may be involved in telomere function in vivo. In order to test this hypothesis, the telomere tract lengths of yeast strains that contained conditionally lethal (ts) rap1 mutations were analyzed. Several rap1ts alleles reduced telomere length in a temperature-dependent manner. In addition, plasmids that contain small, synthetic telomeres with intact or mutant RAP1 binding sites were tested for their ability to function as substrates for poly(C1-3A) addition in vivo. Mutations in the RAP1 binding sites reduced the efficiency of the addition reaction.

Chromosome III of Saccharomyces cerevisiae: an ordered clone bank, a detailed restriction map and analysis of transcripts suggest the presence of 160 genes

Using lambda phage vector EMBL4, we isolated 344 clones containing segments of chromosome III of Saccharomyces cerevisiae, analysed their physical structure with eight restriction enzymes and sorted the data in contiguous groups with computer programmes. Furthermore, we performed Southern hybridizations between the sorted contiguous clone groups and interrelated them into larger groups. In this way, we constructed an ordered clone bank that covers almost the whole of chromosome III with a single gap of several kilobases in length. The consensus physical map thus obtained totals 334.6 kb, which is in good agreement with the size of this chromosome estimated by pulsed-field gel electrophoresis. Southern hybridization analysis with the DNA probes containing telomere-specific sequences showed that the bank contained a telomere at a position corresponding to the right arm terminus of chromosome III. Also, five Ty elements were found to be present. To estimate the number of genes on this chromosome and to analyse their levels of expression, we performed a series of Northern hybridization experiments using total poly(A)+ RNA from vegetatively growing cells and appropriate restriction enzyme fragments from the bank. Thus, we identified a total of 156 transcripts on chromosome III, indicating, on an average, one gene in every 2 kb on this chromosome. The transcripts were visually categorized into five groups according to their apparent levels of expression. It was found that the genes located near both termini are expressed only at low levels and that highly expressed genes are rather scattered over the chromosome.

Addition of telomere-associated HeT DNA sequences "heals" broken chromosome ends in Drosophila

Stocks of D. melanogaster X chromosomes carrying terminal deletions (RT chromosomes) have been maintained for several years. Some of the chromosomes are slowly losing DNA from the broken ends (as expected if replication is incomplete) and show no telomere-associated DNA added to the receding ends. Two stocks carry chromosomes that have become "healed" and are no longer losing DNA. In both stocks the broken chromosome end has acquired a segment of HeT DNA, a family of complex repeats found only at telomeres and in pericentric heterochromatin. Although the HeT family is complex, the HeT sequence joined to the broken chromosome end is the same in both stocks. In contrast, the two chromosomes are broken in different places and have no detectable sequence similarity at the junction with the new DNA. Sequence analysis suggests that the new telomere sequences have been added by a specific mechanism that does not involve homologous recombination.

Yeast telomere length varies in response to changes in the amount of polyC1-3A in the cell

Yeast chromosomes terminate in a GC-rich tail of DNA. Previous investigations have shown that the length of this tail can change in response to genetic variation. Here we present data that show that the length can also alter in response to changes in the amount of the GC-rich DNA found elsewhere in the nucleus.

A yeast telomere binding activity binds to two related telomere sequence motifs and is indistinguishable from RAP1

Telomere Binding Activity (TBA), an abundant protein from Saccharomyces cerevisiae, was identified by its ability to bind to telomeric poly(C1-3A) sequence motifs. The substrate specificity of TBA has been analyzed in order to determine whether the activity binds to a unique structure assumed by the irregularly repeating telomeric sequences or whether the activity recognizes and binds to subset of specific sequences found within the telomere repeat tracts. Deletion analysis and DNase I protection assays demonstrate that TBA binds specifically to two poly-(C1-3A) sequences that differ by one nucleotide. The methylation of four guanine residues, located at identical relative positions within these two binding sequences, interferes with TBA binding to the substrates. A synthetic olignucleotide containing a single TBA binding site can function as a TBA binding substrate. The TBA binding site shares homology with the binding sites reported for the Repressor/Activator Protein 1 (RAP1), Translation Upshift Factor (TUF) and General Regulatory Factor (GRFI) transcription factors, and TBA binds directly to RAP1/TUF/GRFI substrate sequences. Yeast TBA preparations and the RAP1 gene product expressed in E. coli cells are both similarly sensitive to in vitro protease digestion. Affinity-purified TBA extracts include a protein indistinguishable from RAP1 in binding specificity, size, and antigenicity. The binding affinity of TBA for the two telomeric poly(C1-3A) binding sites is higher than its affinity for any of the other binding substrates used for its identification. In extracts of yeast spheroplasts prepared by incubation of yeast cells with Zymolyase, an altered, proteolyzed form, of TBA (TBA-S) is present. TBA-S has a faster mobility in gel retardation assays and SDS-PAGE gels, yet it retains the DNA binding properties of standard TBA preparations: it binds to RAP1/TUF/GRFI substrates with the same relative binding affinity and protects poly(C1-3A) tracts from DNase I digestion with a "footprint" identical to that of standard TBA preparations.

Time of replication of yeast centromeres and telomeres

The time of replication of centromeres and telomeres of the yeast S. cerevisiae was determined by performing Meselson-Stahl experiments with synchronized cells. The nine centromeres examined become hybrid in density early in S phase, eliminating the possibility that a delay in the replication of centromeres until mitosis is responsible for sister chromatid adherence and proper chromosome segregation at anaphase. The conserved sequence element Y', present at most telomeres, replicates late in S phase, as do the unique sequences adjacent to five specific telomeres. The early and late replication times of these structural elements may be either essential for their proper function or a consequence of some architectural feature of the chromosome.

Distribution of telomere-associated sequences in yeast

Two middle repetitive DNA sequences called X and Y' are found near the telomeres of many chromosomes in Saccharomyces cerevisiae. Orthogonal field gel electrophoresis (OFAGE) was used to examine the distribution of X and Y' on different yeast chromosomes. Although the distribution of X and Y' varies among different laboratory strains of yeast, most yeast chromosomes in four different strains carry both X and Y'. However, at least one chromosome in each strain lacks the Y' element. This result indicates that Y' is not essential for replication or segregation of at least some yeast chromosomes.