The Subtelomeric Y'' Repeat Family in Saccharomyces Cerevisiae: An Experimental System for Repeated Sequence Evolution

The subtelomeric Y' repeated sequence families in two divergent strains of the yeast Saccharomyces cerevisiae have been characterized in terms of copy number, location and restriction site differences. The strain YP1 has 26 to 30 Y's that fall into two previously described, long (6.7 kb) and short (5.2 kb), size classes. These Y's reside at 19 of the 32 chromosome ends and are concentrated in the higher molecular weight chromosomes. Five ends contain tandem arrays, each of which has only one size class of Y's. There is restriction site homogeneity among the Y's of YP1 even between size classes. The Y's of strain Y55 contrast sharply with the Y's of YP1 in terms of copy number, location and sequence differences. There are 14 to 16 Y's, both long and short, most of which are found at different chromosome ends than those of YP1. None of these are tandemly arrayed. Four to six of the Y's appear degenerate in that they have homology with a telomere distal end Y' probe but no homology with sequences at the telomere proximal end. The majority of the Y55 Y's have the same restriction sites as in YP1. Despite the conservation of restriction sites among Y's, a great deal of restriction fragment length heterogeneity between the strains is observed. The characterized Y' repeated sequence families provide an experimental system in which repeated sequence interactions and subsequent evolution can be studied.     

The Structure and Evolution of Subtelomeric Y'' Repeats in Saccharomyces Cerevisiae

The subtelomeric Y' family of repeated DNA sequences in the yeast Saccharomyces cerevisiae is of unknown origin and function. Y's vary in copy number and location among strains. Eight Y's, from two strains, were cloned and sequenced over the same 3.2-kb interval in order to assess the within- and between-strain variation as well as address their origin and function. One entire Y' sequence was reconstructed from two clones presented here and a previously sequenced 833-bp region. It contains two large overlapping open reading frames (ORFs). The putative protein sequences have no strong homologies to any known proteins except for one region that has 27% identity with RNA helicases. RNA homologous to each ORF was detected. Comparison of the sequences revealed that the known long (Y'-L) and short (Y'-S) size classes, which coexist within cells, differ by several insertions and/or deletions within this region. The Y'-Ls from strain Y55 also differ from those of strain YP1 by several short deletions in the same region. Most of these deletions appear to have occurred between short (2-10 bp) direct repeats. The single base pair polymorphisms and the deletions are clustered in the first half of the interval compared. There is 0.30-1.13% divergence among Y'-Ls within a strain and 1.15-1.75% divergence between strains in the interval. This is similar to known unique sequence variation but contrasts with the 8-18% divergence among the adjacent subtelomeric repeats, X. Subsets of Y's exhibit concerted evolution; however, more than one variant appears to be maintained within strains. The observed sequence variation disrupts the first ORF in many Y's while most of the second ORF including the putative helicase region is unaffected. The structure and distribution of the Y' elements are consistent with having originated as a mobile element. However, they now appear to move via recombination. Recombination can account for the homogenization within subsets of Y's but does not account for the maintenance of different variants.     

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

A yeast Saccharomyces cerevisiae telomeric region was isolated by chromosome walking from HML alpha, the most distal known gene on the chromosome III left (IIIL) end. The terminal heterodisperse 3.3-kilobase (kb) SalI fragment on chromosome IIIL, 8.6 kb distal to HML alpha, was cloned in a circular vector to generate a telomeric probe. Southern hybridization and DNA sequencing analyses indicated that 0.6 kb (+/- 200 base pairs) of 5'-C1-3A-3' simple tandem repeat sequence, adjacent to a 1.2-kb type X ARS region, constitutes the telomere on the chromosome IIIL end, and no type Y' ARS region homologies exist between HML alpha and the IIIL terminus.     

Genome-level evolution of resistance genes in Arabidopsis thaliana

Pathogen resistance genes represent some of the most abundant and diverse gene families found within plant genomes. However, evolutionary mechanisms generating resistance gene diversity at the genome level are not well understood. We used the complete Arabidopsis thaliana genome sequence to show that most duplication of individual NBS-LRR sequences occurs at close physical proximity to the parent sequence and generates clusters of closely related NBS-LRR sequences. Deploying the statistical strength of phylogeographic approaches and using chromosomal location as a proxy for spatial location, we show that apparent duplication of NBS-LRR genes to ectopic chromosomal locations is largely the consequence of segmental chromosome duplication and rearrangement, rather than the independent duplication of individual sequences. Although accounting for a smaller fraction of NBS-LRR gene duplications, segmental chromosome duplication and rearrangement events have a large impact on the evolution of this multigene family. Intergenic exchange is dramatically lower between NBS-LRR sequences located in different chromosome regions as compared to exchange between sequences within the same chromosome region. Consequently, once translocated to new chromosome locations, NBS-LRR gene copies have a greater likelihood of escaping intergenic exchange and adopting new functions than do gene copies located within the same chromosomal region. We propose an evolutionary model that relates processes of genome evolution to mechanisms of evolution for the large, diverse, NBS-LRR gene family.     

RAD51-dependent break-induced replication in yeast

A chromosome fragmentation assay was used to measure the efficiency and genetic control of break-induced replication (BIR) in Saccharomyces cerevisiae. Formation of a chromosome fragment by de novo telomere generation at one end of the linear vector and recombination-dependent replication of 100 kb of chromosomal sequences at the other end of the vector occurred at high frequency in wild-type strains. RAD51 was required for more than 95% of BIR events involving a single-end invasion and was essential when two BIR events were required for generation of a chromosome fragment. The similar genetic requirements for BIR and gene conversion suggest a common strand invasion intermediate in these two recombinational repair processes. Mutation of RAD50 or RAD59 conferred no significant defect in BIR in either RAD51 or rad51 strains. RAD52 was shown to be essential for BIR at unique chromosomal sequences, although rare recombination events were detected between the subtelomeric Y' repeats.     

Identification of autonomously replicating circular subtelomeric Y'' elements in Saccharomyces cerevisiae.

We marked a large number of yeast telomeres within their Y' regions by transforming strains with a fragment of Y' DNA into which the URA3 gene had been inserted. A few of the Ura+ transformants obtained were very unstable and were found to contain autonomously replicating URA3-marked circular Y' elements in high copy number. These marked extrachromosomal circles were capable of reintegrating into the chromosome at other telomeric locations. In contrast, most of the Ura+ transformants obtained were quite stable mitotically and were marked at bona fide chromosomal ends. These stable transformants gave rise to mitotically unstable URA3-marked circular Y' elements at a low frequency (up to 2.5%). The likelihood that such excisions and integrations represent a natural process in Saccharomyces cerevisiae is supported by our identification of putative Y' circles in untransformed strains. The transfer of Y' information among telomeres via a circular intermediate may be important for homogenizing the sequences at the ends of yeast chromosomes and for generating the frequent telomeric rearrangements that have been observed in S. cerevisiae.     

The Saccharomyces retrotransposon Ty5 influences the organization of chromosome ends.

Retrotransposons are ubiquitous components of eukaryotic genomes suggesting that they have played a significant role in genome organization. In Saccharomyces cerevisiae, eight of 10 endogenous insertions of the Ty5 retrotransposon family are located within 15 kb of chromosome ends, and two are located near the subtelomeric HMR locus. This genomic organization is the consequence of targeted transposition, as 14 of 15 newly transposed Ty5 elements map to telomeric regions on 10 different chromosomes. Nine of these insertions are within 0.8 kb and three are within 1.5 kb of the autonomously replicating consensus sequence in the subtelomeric X repeat. This suggests that the X repeat plays an important role in directing Ty5 integration. Analysis of endogenous insertions from S.cerevisiae and its close relative S.paradoxus revealed that only one of 12 insertions has target site duplications, indicating that recombination occurs between elements. This is further supported by the observation that Ty5 insertions mark boundaries of sequence duplications and rearrangements in these species. These data suggest that transposable elements like Ty5 can shape the organization of chromosome ends through both transposition and recombination.     

Evolution in the laboratory: the genome of Halobacterium salinarum strain R1 compared to that of strain NRC-1

We report the sequence of the Halobacterium salinarum strain R1 chromosome and its four megaplasmids. Our set of protein-coding genes is supported by extensive proteomic and sequence homology data. The structures of the plasmids, which show three large-scale duplications (adding up to 100 kb), were unequivocally confirmed by cosmid analysis. The chromosome of strain R1 is completely colinear and virtually identical to that of strain NRC-1. Correlation of the plasmid sequences revealed 210 kb of sequence that occurs only in strain R1. The remaining 350 kb shows virtual sequence identity in the two strains. Nevertheless, the number and overall structure of the plasmids are largely incompatible. Also, 20% of the protein sequences differ despite the near identity at the DNA sequence level. Finally, we report genome-wide mobility data for insertion sequences from which we conclude that strains R1 and NRC-1 originate from the same natural isolate. This exemplifies evolution in the laboratory.     

Distribution of telomere-associated sequences on natural chromosomes in Saccharomyces cerevisiae.

Pulsed-field gel electrophoresis was used to examine the distribution of telomere-associated sequences on individual chromosomes in four strains of Saccharomyces cerevisiae. The pattern of X and Y' distribution was different for each strain. At least one chromosome in each strain lacked Y', and in some strains, chromosome I, the smallest yeast chromosome, lacked detectable amounts of both X and Y'.     

Mechanisms of tandem duplication in the Duchenne muscular dystrophy gene include both homologous and nonhomologous intrachromosomal recombination.

Three tandem duplications were previously identified in patients with Duchenne muscular dystrophy and were shown in each case to have a subset of dystrophin gene exons duplicated. The origin of these duplications was traced to the single X chromosome of the maternal grandfathers, suggesting that an intrachromosomal event (unequal sister chromatid exchange) was involved in the formation of these duplications. In the present study, a DNA segment containing the duplication junction and the normal DNA that corresponds to both ends of the duplicated region have been cloned. Subsequent mapping studies confirmed the tandem arrangement (head to tail) of these duplications and revealed their sizes to be 130 kb, approximately 300 kb, and 35-80 kb, respectively. Sequence analysis of the duplication junctions showed that one duplication was due to homologous recombination between two repetitive elements (Alu sequences) and the other two were due to recombination between unrelated nonhomologous sequences. In the latter cases, the preferred cleavage sites of the eukaryotic type I and II DNA topoisomerases were found at the junctions of these duplications, suggesting a possible role of these enzymes in the chromatid exchange events. This study provides the first insight into the molecular basis of gene duplications formed through unequal sister chromatid exchange in humans.     

Dependence of the regulation of telomere length on the type of subtelomeric repeat in the yeast Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, chromosomes terminate with approximately 400 bp of a simple repeat poly(TG(1-3)). Based on the arrangement of subtelomeric X and Y' repeats, two types of yeast telomeres exist, those with both X and Y' (Y' telomeres) and those with only X (X telomeres). Mutations that result in abnormally short or abnormally long poly(TG(1-3)) tracts have been previously identified. In this study, we investigated telomere length in strains with two classes of mutations, one that resulted in short poly(TG(1-3)) tracts (tel1) and one that resulted in elongated tracts (pif1, rap1-17, rif1, or rif2). In the tel1 pif1 strain, Y' telomeres had about the same length as those in tel1 strains and X telomeres had lengths intermediate between those in tel1 and pif1 strains. Strains with either the tel1 rap1-17 or tel1 rif2 genotypes had short tracts for all chromosome ends examined, demonstrating that the telomere elongation characteristic of rap1-17 and rif2 strains is Tel1p-dependent. In strains of the tel1 rif1 or tel1 rif1 rif2 genotypes, telomeres with Y' repeats had short terminal tracts, whereas most of the X telomeres had long terminal tracts. These results demonstrate that the regulation of telomere length is different for X and Y' telomeres.     

DNA amplifications and deletions in Streptomyces lividans 66 and the loss of one end of the linear chromosome

Thirty-two 2-deoxygalactose-resistant mutants with DNA amplifications were isolated from Streptomyces lividans 66 strains carrying plasmid pMT664, which carries an agarase gene (dagA) and IS466. Thirty-one of the mutants carried amplified DNA sequences from a 70 kb region about 300 kb from one end of the linear chromosome in this species. In 28 of the mutants, all the wild-type sequences between the amplified region and the start of the 30 kb inverted repeat that forms the chromosome end were deleted. Thus, there appeared to be loss of one chromosome end and its replacement by the DNA amplification. In some mutants there amplification of a previously characterised 5.7 kb sequence that lies about 600 kb from the other chromosome end was also noted.     

DNA amplifications and deletions in Streptomyces lividans 66 and the loss of one end of the linear chromosome

Thirty-two 2-deoxygalactose-resistant mutants with DNA amplifications were isolated from Streptomyces lividans 66 strains carrying plasmid pMT664, which carries an agarase gene (dagA) and IS466. Thirty-one of the mutants carried amplified DNA sequences from a 70 kb region about 300 kb from one end of the linear chromosome in this species. In 28 of the mutants, all the wild-type sequences between the amplified region and the start of the 30 kb inverted repeat that forms the chromosome end were deleted. Thus, there appeared to be loss of one chromosome end and its replacement by the DNA amplification. In some mutants there amplification of a previously characterised 5.7 kb sequence that lies about 600 kb from the other chromosome end was also noted.     

Evidence for transposition of dispersed repetitive DNA families in yeast.

Dispersed repetitive DNA sequences from yeast (Saccharomyces cerevisiae) nuclear DNA have been isolated as molecular hybrids in lambdagt. Related S. cerevisiae strains show marked alterations in the size of the restriction fragments containing these repetitive DNAs. "Ty1" is one such family of repeated sequences in yeast and consists of a 5.6 kilobase (kb) sequence including a noninverted 0.25 kb sequence of another repetitious family, "delta", on each end. There are about 35 copies of Ty1 and at least 100 copies of delta (not always associated with Ty1) in the haploid genome. A few Ty1 elements are tandem and/or circular, but most are disperse and show (along with delta) some sequence divergence between repeat units. Sequence alterations involving Ty1 elements have been found during the continual propagation of a single yeast clone over the course of a month. One region with a large number of delta sequences (SUP4) also shows a high frequency of sequence alterations when different strains are compared. One of the differences between two such strains involves the presence or absence of a Ty1 element. The novel joint is at one inverted pair of delta sequences.     

A Gene with Specific and Global Effects on Recombination of Sequences from Tandemly Repeated Genes in Saccharomyces Cerevisiae

The preservation of sequence homogeneity and copy number of tandemly repeated genes may require specific mechanisms or regulation of recombination. We have identified mutations that specifically affect recombination among natural repetitions in the yeast Saccharomyces cerevisiae. The rrm3 mutation stimulates mitotic recombination in the naturally occurring tandem repeats of the rDNA and copper chelatin (CUP1) genes. This mutation does not affect recombination of several other types of repeated genes tested including Ty elements, mating type information and duplications created by transformation. In addition to stimulating exchange among the multiple CUP1 repeats at their natural chromosomal location, rrm3 also increases recombination of a duplication of CUP1 units present at his4. This suggests that the RRM3 gene may encode a sequence-specific factor that contributes to a global suppression of mitotic exchange in sequences that can be maintained as tandem arrays.     

Characterization of the promoter controlling Mona/Gads expression in the megakaryocytic lineage

The deletion of a 260-kb segment containing all the coding DNA sequences (CDS) of chromosome 1 of Leishmania major Friedlin strain was performed through homologous recombination during a transfection experiment. This allowed the selection of a mutant clone containing a linear extra chromosome sizing 155 kb (XC155). The structure of XC155 was determined by restriction analysis and DNA cloning and sequencing of the gel-purified chromosome: it is made of a 'mirror' inverted duplication of the 'right' end of chromosome 1a (approximately 25 kb at each end), and in its central part of a complex tandem amplification of the linearized transfection vector containing the hygromycin resistance gene (over approximately 105 kb). No sequence of the coding region of chromosome 1 (including the 1.6-kb 'switch' region) was found. By contrast, XC155 contains two large (approximately 13 kb) clusters of tandemly repeated subtelomeric sequences (272-bp 'satellite' DNA) as well as telomeric hexamer repeats. This extra chromosome was found to be mitotically stable after >150 generations without selective pressure in vitro. Two sequence elements are considered which may have an effect on mitotic stability and participate to centromeric function in this extra chromosome: the amplification of the input vector and the 272-bp 'satellite' DNA bound by telomeric repeats.     

Divergent origins and concerted expansion of two segmental duplications on chromosome 16

An unexpected finding of the human genome was the large fraction of the genome organized as blocks of interspersed duplicated sequence. We provide a comparative and phylogenetic analysis of a highly duplicated region of 16p12.2, which is composed of at least four different segmental duplications spanning in excess of 160 kb. We contrast the dispersal of two different segmental duplications (LCR16a and LCR16u). LCR16a, a 20 kb low-copy repeat sequence A from chromosome 16, was shown previously to contain a rapidly evolving novel hominoid gene family (morpheus) that had expanded within the last 10 million years of great ape/human evolution. We compare the dispersal of this genomic segment with a second adjacent duplication called LCR16u. The duplication contains a second putative gene family (KIAA0220/SMG1) that is represented approximately eight times within the human genome. A high degree of sequence identity (approximately 98%) was observed among the various copies of LCR16u. Comparative analyses with Old World monkey species show that LCR16a and LCR16u originated from two distinct ancestral loci. Within the human genome, at least 70% of the LCR16u copies were duplicated in concert with the LCR16a duplication. In contrast, only 30% of the chimpanzee loci show an association between LCR16a and LCR16u duplications. The data suggest that the two copies of genomic sequence were brought together during the chimpanzee/human divergence and were subsequently duplicated as a larger cassette specifically within the human lineage. The evolutionary history of these two chromosome-specific duplications supports a model of rapid expansion and evolutionary turnover among the genomes of man and the great apes.     

The acid phosphatase genes PHO10 and PHO11 in S. cerevisiae are located at the telomeres of chromosomes VIII and I.

Of the three regulated acid phosphatase genes in S. cerevisiae (PHO5, PHO10 and PHO11) two have previously been cloned (PHO5 and PHO11). We have now identified PHO10 and show by restriction mapping that it is highly homologous to PHO11. This homology includes not only the coding sequence but also a stretch of about 2 kb upstream and 2.2 kb downstream of the genes. Analysis of strains in which either gene had been disrupted shows that the two genes are located at the telomeres of two different chromosomes. PHO10 3.6 kb from the end of a chromosome I. This makes PHO11 the gene closest to the end of a chromosome that has been physically mapped so far in S. cerevisiae. The organization of the two genes varies strongly from strain to strain consistent with a high incidence of telomere rearrangement. In one of twenty transformants examined a conversion event could be directly demonstrated that resulted in a chromosome VIII which had acquired a copy of the telomere from chromosome I.     

Cloning a fragment from the telomere of the long arm of human chromosome 9 in a YAC vector

The construction of a yeast artificial chromosome containing a human DNA insert is reported. This molecule of about 200 kb behaves as a native yeast chromosome since it has a very high mitotic stability and is present in the yeast transformant clone at a copy number similar to that of the resident chromosomes. Hybridization with the TTAGGG sequence demonstrates that this chromosome contains human telomeric sequences. In situ hybridization of the biotin-labelled artificial chromosome to metaphase human chromosomes shows that the insert occupies a telomeric position on the long arm of chromosome 9. Since the fragment was cloned as an EcoRI insert and not as a telomere, it is situated medially to the telomeric sequences and harbours telomere-associated sequences, that have been shown to contain the TTAGGG sequence. The fragment represents the end of the genetic map of chromosome 9 and thus can be used to characterize the sequence and the structure of the chromosomal region that runs from the end of the chromosome to the first gene.     

Molecular evolution of a multigene family in group A streptococci

The emm genes are members of a gene family in group A streptococci (GAS) that encode for antiphagocytic cell-surface proteins and/or immunoglobulin-binding proteins. Previously sequenced genes in this family have been named "emm," "fcrA," "enn," "arp," "protH," and "mrp"; herein they will be referred to as the "emm gene family." The genes in the emm family are located in a cluster occupying 3-6 kb between the genes mry and scpA on the chromosome of Streptococcus pyogenes. Most GAS strains contain one to three tandemly arranged copies of emm-family genes in the cluster, but the alleles within the cluster vary among different strains. Phylogenetic analysis of the conserved sequences at the 3' end of these genes differentiates all known members of this family into four evolutionarily distinct emm subfamilies. As a starting point to analyze how the different subfamilies are related evolutionarily, the structure of the emm chromosomal region was mapped in a number of diverse GAS strains by using subfamily-specific primers in the polymerase chain reaction. Nine distinct chromosomal patterns of the genes in the emm gene cluster were found. These nine chromosomal patterns support a model for the evolution of the emm gene family in which gene duplication followed by sequence divergence resulted in the generation of four major-gene subfamilies in this locus.