Chromosome ends in Chironomus pallidivittatus contain different subfamilies of telomere-associated repeats

Tandemly repeated 340 bp sequences, TA repeats, are present in seven of the eight pairs of chromosome ends in Chironomus pallidivittatus, being absent from the telocentric left end of chromosome four. We have previously shown that the family of TA repeats consists of four main subfamilies. One subfamily is composed of a master unit and the other three contain derived units, each of which has a small region where the master sequence is highly mutated. Here we find that there are considerable variations in numbers of TA repeats between animals and for the same telomere in different animals. We also show that the seven telomere pairs containing TA repeats differ with regard to the content of derived subfamilies. The master unit is probably present in all seven pairs. Two of the derived units are exclusively present in two telomere pairs. The third derived unit shows a more irregular distribution. Some of the telomeres have highly variable contents of such units among animals. Subfamilies thus have different behaviour as reflected in their stable and variable patterns of distribution between individual telomeres.W. Hennig     

Human telomeres contain at least three types of G-rich repeat distributed non-randomly.

Using a combination of different oligonucleotides and restriction enzymes we have examined the gross organisation of repeats within the most distal region of human chromosomes. We demonstrate here that human telomeres do not contain a pure uniform 6 base pair repeat unit but that there are at least three types of repeat. These three types of repeat are present at the ends of most or all human chromosomes. The distribution of each type of repeat appears to be non-random. Each human telomere has a similar arrangement of these repeats relative to the ends of the chromosome. This could reflect differences in the functions that they perform, or might result from the mutation and correction processes occurring at human telomeres. The number of repeat units, the repeat types and arrangement differs at mouse telomeres. Analysing the change in length of the telomeric repeat region between an individuals blood and germline DNA reveals that this is due to variable amounts of the TTAGGG repeat and not the other repeat types. This organization of repeat units at human telomeres will only be confirmed upon the isolation and sequencing of full length (10-15 kb), intact human telomeres.     

Interspersed DNA element restricted to a specific group of telomeres in the dipteran Chironomus pallidivittatus.

Telomeres in the dipteran Chironomus pallidivittatus terminate with 340bp tandem DNA repeats belonging to different subfamilies with characteristic intertelomeric distribution. We have now found, interspersed between such repeats, a composite element of approx. 1400bp present in two similar size variants, with several components of nontelomeric origin. There were about 50 copies of the element, predominantly or exclusively present in a previously defined group of telomeres, characterized by a unique set of telomeric tandem repeat subfamilies. Elements were integrated at irregular distances from each other, and intervening telomeric tandem repeat DNA was variable in composition. Nevertheless, the flanks immediately surrounding the elements were identical for different elements; in other words, there was a site-specific insertion. We suggest that this selective invasion of a small part of the genome by an interspersed, probably rapidly evolving element is best explained by repeated gene conversions.     

Structure and variability of human chromosome ends.

Mammalian telomeres are thought to be composed of a tandem array of TTAGGG repeats. To further define the type and arrangement of sequences at the ends of human chromosomes, we developed a direct cloning strategy for telomere-associated DNA. The method involves a telomere enrichment procedure based on the relative lack of restriction endonuclease cutting sites near the ends of human chromosomes. Nineteen (TTAGGG)n-bearing plasmids were isolated, two of which contain additional human sequences proximal to the telomeric repeats. These telomere-flanking sequences detect BAL 31-sensitive loci and thus are located close to chromosome ends. One of the flanking regions is part of a subtelomeric repeat that is present at 10 to 25% of the chromosome ends in the human genome. This sequence is not conserved in rodent DNA and therefore should be a helpful tool for physical characterization of human chromosomes in human-rodent hybrid cell lines; some of the chromosomes that may be analyzed in this manner have been identified, i.e., 7, 16, 17, and 21. The minimal size of the subtelomeric repeat is 4 kilobases (kb); it shows a high frequency of restriction fragment length polymorphisms and undergoes extensive de novo methylation in somatic cells. Distal to the subtelomeric repeat, the chromosomes terminate in a long region (up to 14 kb) that may be entirely composed of TTAGGG repeats. This terminal segment is unusually variable. Although sperm telomeres are 10 to 14 kb long, telomeres in somatic cells are several kilobase pairs shorter and very heterogeneous in length. Additional telomere reduction occurs in primary tumors, indicating that somatic telomeres are unstable and may continuously lose sequences from their termini.     

Mutant Telomeric Repeats in Yeast Can Disrupt the Negative Regulation of Recombination-Mediated Telomere Maintenance and Create an Alternative Lengthening of Telomeres-Like Phenotype

Some human cancers maintain telomeres using alternative lengthening of telomeres (ALT), a process thought to be due to recombination. In Kluyveromyces lactis mutants lacking telomerase, recombinational telomere elongation (RTE) is induced at short telomeres but is suppressed once telomeres are moderately elongated by RTE. Recent work has shown that certain telomere capping defects can trigger a different type of RTE that results in much more extensive telomere elongation that is reminiscent of human ALT cells. In this study, we generated telomeres composed of either of two types of mutant telomeric repeats, Acc and SnaB, that each alter the binding site for the telomeric protein Rap1. We show here that arrays of both types of mutant repeats present basally on a telomere were defective in negatively regulating telomere length in the presence of telomerase. Similarly, when each type of mutant repeat was spread to all chromosome ends in cells lacking telomerase, they led to the formation of telomeres produced by RTE that were much longer than those seen in cells with only wild-type telomeric repeats. The Acc repeats produced the more severe defect in both types of telomere maintenance, consistent with their more severe Rap1 binding defect. Curiously, although telomerase deletion mutants with telomeres composed of Acc repeats invariably showed extreme telomere elongation, they often also initially showed persistent very short telomeres with few or no Acc repeats. We suggest that these result from futile cycles of recombinational elongation and truncation of the Acc repeats from the telomeres. The presence of extensive 3′ overhangs at mutant telomeres suggests that Rap1 may normally be involved in controlling 5′ end degradation.     

A mammalian factor that binds telomeric TTAGGG repeats in vitro.

We have identified a DNA-binding activity with specificity for the TTAGGG repeat arrays found at mammalian telomeres. This factor, called TTAGGG repeat factor (TRF), is present in nuclear extracts of human, mouse, and monkey cells. TRF from HeLa cells was characterized in detail by electrophoretic mobility shift assays. It binds double-stranded TTAGGG repeats in linear and circular DNAs. Single-stranded repeats are not recognized. The optimal site for TRF appears to contain more than six contiguous TTAGGG repeats. Tandem arrays of TAGGG, TTTAGGG, TTTTAGGG, TTGGGG, and TTAGGC repeats do not bind TRF well, indicating that TRF preferentially recognizes the telomeric repeat sequence present at mammalian chromosome ends. The apparent molecular mass of this factor, based on recovery of TRF from sodium dodecyl sulfate-polyacrylamide gels, is approximately 50 kDa. We suggest that TRF binds along the length of mammalian telomeres.     

t-loops at trypanosome telomeres

Mammalian telomeres form large duplex loops (t-loops) that may sequester chromosome ends by invasion of the 3' TTAGGG overhang into the duplex TTAGGG repeat array. Here we document t-loops in Trypanosoma brucei, a kinetoplastid protozoan with abundant telomeres due to the presence of many minichromosomes. These telomeres contained 10-20 kb duplex TTAGGG repeats and a 3' TTAGGG overhang. Electron microscopy of psoralen/UV cross-linked DNA revealed t-loops in enriched telomeric restriction fragments and at the ends of isolated minichromosomes. In mammals, t-loops are large (up to 25 kb), often comprising most of the telomere. Despite similar telomere lengths, trypanosome t-loops were much smaller (approximately 1 kb), indicating that t-loop sizes are regulated. Coating of non-cross-linked minichromosomes with Escherichia coli single-strand binding protein (SSB) often revealed 3' overhangs at both telomeres and several cross-linked minichromosomes had t-loops at both ends. These results suggest that t-loops and their prerequisite 3' tails can be formed on the products of both leading and lagging strand synthesis. We conclude that t-loops are a conserved feature of eukaryotic telomeres.     

In vitro interactions of Caenorhabditis elegans dystrophin with dystrobrevin and syntrophin

HeT-A elements are non-long terminal repeat retrotransposons added onto the Drosophila chromosome ends. We have investigated the formation in vitro of higher order structures by oligonucleotides derived from the 3' non-coding region of HeT-A elements and found that they are capable of forming G-quadruplex DNA. These results suggest that the 3' repeat region of HeT-A may structurally behave as the telomeric repeats common to a majority of eukaryotes. The presence of structural motifs shared by telomeres and centromeres and the implications of these findings for chromosome evolution are discussed.     

Chromosome-specific subfamilies within human alphoid repetitive DNA

Nucleotide sequence data of about 20 X 10(3) base-pairs of the human tandemly repeated alphoid DNA are presented. The DNA sequences were determined from 45 clones containing EcoRI fragments of alphoid DNA isolated from total genomic DNA. Thirty of the clones contained a complete 340 base-pair dimer unit of the repeat. The remaining clones contained alphoid DNA with fragment lengths of 311, 296, 232, 170 and 108 base-pairs. The sequences obtained were compared with an average alphoid DNA sequence determined by Wu & Manuelidis (1980). The divergences ranged from 0.6 to 24.6% nucleotide changes for the first monomer and from 0 to 17.8% for the second monomer of the repeat. On the basis of identical nucleotide changes at corresponding positions, the individual repeat units could be shown to belong to one of several distinct subfamilies. The number of nucleotide changes defining a subfamily generally constitutes the majority of nucleotide changes found in a member of that subfamily. From an evaluation of the proportion of the total amount of alphoid DNA, which is represented by the clones studied, it is estimated that the number of subfamilies of this repeat may be equal to or exceed the number of chromosomes. The expected presence of only one or a few distinct subfamilies on individual chromosomes is supported by the study, also presented, of the nucleotide sequence of 17 cloned fragments of alphoid repetitive DNA from chromosome 7. These chromosome-specific repeats all contain the characteristic pattern of 36 common nucleotide changes that defines one of the subfamilies described. A unique restriction endonuclease (NlaIII) cleavage site present in this subfamily may be useful as a genetic marker of this chromosome. A family member of the interspersed Alu repetitive DNA was also isolated and sequenced. This Alu repeat has been inserted into the human alphoid repetitive DNA, in the same way as the insertion of an Alu repeat into the African green monkey alphoid DNA.     

Intrachromosomal location of the telomeric repeat (TTAGGG)n

Eukaryotic telomeres are specialized DNA-protein structures that are thought to ensure chromosomal stability and complete replication of the chromosome ends. All telomeres which have been studied consist of a tandem array of G-rich repeats which seem to be sufficient for telomere function. Originally, the human telomeric repeat (TTAGGG)_n was assumed to be exclusively located at the very end of all human chromosomes. More recent evidence, however, suggests an extension into proterminal regions. Very little is known about the interstitial distribution of telomeric repeats. Here we present evidence for the presence of (TTAGGG)_n repeats in internal loci on the long and short arms of different human chromosomes. In addition, we studied the genomic organization of these repeats in more detail and discuss possible functions of interstitial telomeric repeats in the human genome.     

Molecular and evolutionary analysis of two divergent subfamilies of a novel miniature inverted repeat transposable element in the yellow fever mosquito, Aedes aegypti

A novel family of miniature inverted repeat transposable elements (MITEs) named Pony was discovered in the yellow fever mosquito, Aedes aegypti. It has all the characteristics of MITEs, including terminal inverted repeats, no coding potential, A+T richness, small size, and the potential to form stable secondary structures. Past mobility of PONY: was indicated by the identification of two Pony insertions which resulted in the duplication of the TA dinucleotide targets. Two highly divergent subfamilies, A and B, were identified in A. aegypti based on sequence comparison and phylogenetic analysis of 38 elements. These subfamilies showed less than 62% sequence similarity. However, within each subfamily, most elements were highly conserved, and multiple subgroups could be identified, indicating recent amplifications from different source genes. Different scenarios are presented to explain the evolutionary history of these subfamilies. Both subfamilies share conserved terminal inverted repeats similar to those of the Tc2 DNA transposons in Caenorhabditis elegans, indicating that Pony may have been borrowing the transposition machinery from a Tc2-like transposon in mosquitoes. In addition to the terminal inverted repeats, full-length and partial subterminal repeats of a sequence motif TTGATTCAWATTCCGRACA represent the majority of the conservation between the two subfamilies, indicating that they may be important structural and/or functional components of the Pony elements. In contrast to known autonomous DNA transposons, both subfamilies of PONY: are highly reiterated in the A. aegypti genome (8,400 and 9, 900 copies, respectively). Together, they constitute approximately 1. 1% of the entire genome. Pony elements were frequently found near other transposable elements or in the noncoding regions of genes. The relative abundance of MITEs varies in eukaryotic genomes, which may have in part contributed to the different organizations of the genomes and reflect different types of interactions between the hosts and these widespread transposable elements.     

The clustering of four subfamilies of satellite DNA at individual chromosome ends in Silene latifolia.

The satellite DNA (satDNA) on the ends of chromosomes has been isolated and characterized in the dioecious plant Silene latifolia. BAC clones containing large numbers of repeat units of satDNA in a tandem array were isolated to examine the clustering of the repeat units. satDNA repeat units were purified from each isolated BAC clone and sequenced. To investigate pairwise similarities among the repeat units, a phylogenetic tree was constructed using the neighbor-joining algorithm. The repeat units derived from 7 BAC clones were grouped into SacI, KpnI, #11F02, and #16E07 subfamilies. The SacI and KpnI subfamilies have been reported previously. Multicolored fluorescence in situ hybridization (FISH) using SacI or KpnI subfamily probes resulted in different signal intensities and locations at the chromosomal ends, indicating that each chromosomal end has a unique composition of subfamilies of satDNA. For example, the p arm of the X chromosome exhibited signal composition similar to that on the pseudo autosomal region (PAR) of the Y chromosome, but not to that on the q arm of the X chromosome. The satDNA has not been completely homogenized in the S. latifolia genome. Each subfamily is available for a probe of FISH karyotyping.     

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.     

Cloning of telomere-associated DNA using single-specific-primer polymerase chain reaction provides evidence for a conserved sequence directly adjacent to Theileria parva telomeric repeats

Telomere-associated (TA) DNA sequences of the intracellular protozoan parasite Theileria parva were isolated by a novel strategy using a modified version of single-specific-primer polymerase chain reaction (SSP-PCR). Nucleotide sequences of non-coding TA DNA from three telomeres (6017bp, 2435bp and 4859bp) contained no extensive tracts of repetitive DNA. Long open reading frames (ORFs) were present at the centromeric ends of two of the TA sequences, the 3' ends of the closest ORFs being only 2670bp and 2719bp from the telomeric repeats. There were regions of significant similarity between the nucleotide sequences of the non-coding regions of different telomeres. The longest region of similarity was a virtually identical 1650bp domain, located directly adjacent to the telomeric repeats of two separate telomeres. Comparison of the telomere proximal sequences defined in this study and two additional T. parva telomeres, whose sequences were determined previously, resulted in identification of a single copy 141bp conserved sequence directly adjacent to the telomeric repeats. The conserved sequence is present at all five T. parva telomeres that have been characterised. The only organism currently known to have a single copy conserved sequence located adjacent to the telomeric repeats is another intracellular protozoan, Leishmania braziliensis.     

Mammalian meiotic telomeres: protein composition and redistribution in relation to nuclear pores

Mammalian telomeres consist of TTAGGG repeats, telomeric repeat binding factor (TRF), and other proteins, resulting in a protective structure at chromosome ends. Although structure and function of the somatic telomeric complex has been elucidated in some detail, the protein composition of mammalian meiotic telomeres is undetermined. Here we show, by indirect immunofluorescence (IF), that the meiotic telomere complex is similar to its somatic counterpart and contains significant amounts of TRF1, TRF2, and hRap1, while tankyrase, a poly-(ADP-ribose)polymerase at somatic telomeres and nuclear pores, forms small signals at ends of human meiotic chromosome cores. Analysis of rodent spermatocytes reveals Trf1 at mouse, TRF2 at rat, and mammalian Rap1 at meiotic telomeres of both rodents. Moreover, we demonstrate that telomere repositioning during meiotic prophase occurs in sectors of the nuclear envelope that are distinct from nuclear pore-dense areas. The latter form during preleptotene/leptotene and are present during entire prophase I.     

Interspersed repeats in the horse (Equus caballus); spatial correlations highlight conserved chromosomal domains

The interspersed repeat content of mammalian genomes has been best characterized in human, mouse and cow. In this study, we carried out de novo identification of repeated elements in the equine genome and identified previously unknown elements present at low copy number. The equine genome contains typical eutherian mammal repeats, but also has a significant number of hybrid repeats in addition to clade-specific Long Interspersed Nuclear Elements (LINE). Equus caballus clade specific LINE 1 (L1) repeats can be classified into approximately five subfamilies, three of which have undergone significant expansion. There are 1115 full-length copies of these equine L1, but of the 103 presumptive active copies, 93 fall within a single subfamily, indicating a rapid recent expansion of this subfamily. We also analysed both interspersed and simple sequence repeats (SSR) genome-wide, finding that some repeat classes are spatially correlated with each other as well as with G+C content and gene density. Based on these spatial correlations, we have confirmed that recently-described ancestral vs. clade-specific genome territories can be defined by their repeat content. The clade-specific Short Interspersed Nuclear Element correlations were scattered over the genome and appear to have been extensively remodelled. In contrast, territories enriched for ancestral repeats tended to be contiguous domains. To determine if the latter territories were evolutionarily conserved, we compared these results with a similar analysis of the human genome, and observed similar ancestral repeat enriched domains. These results indicate that ancestral, evolutionarily conserved mammalian genome territories can be identified on the basis of repeat content alone. Interspersed repeats of different ages appear to be analogous to geologic strata, allowing identification of ancient vs. newly remodelled regions of mammalian genomes.     

Satellite-DNA diversification and the evolution of major lineages in Cardueae (Carduoideae Asteraceae)

In a previous work, we characterized the HinfI satellite DNA family in the subtribe Centaureinae (Cardueae) demonstrating that a “library” of eight HinfI subfamilies would exist in the common ancestor of all Centaureinae, which were differentially amplified in different lineages. Now, we extend our study by analyzing a total of 219 additional repeats from fifteen species belonging to Carlininae, Echinopsinae and Carduinae, and comparing them to those of Centaureinae. Most HinfI sequences belonged to the subfamily II, although a few sequences of other subfamilies were detected in some species. Additionally, a new subfamily characteristic of several Carduinae species was discovered. Although phylogenetic trees grouped sequences by subfamily affinity instead of species provenance, when comparing repeats of the same subfamily, the degree of divergence between any pair of sequences was related to the evolutionary distance between the species compared in most cases. Exceptions were in comparisons between sequences of some Centaureinae species, and between sequences of some Carduinae species and those of Centaureinae. Our results demonstrate that: (1) At least nine HinfI subfamilies would exist in the common ancestor of Cardueae, each one differentially amplified in different lineages; (2) After differential spreading, sequences of each subfamily evolved concertedly through molecular drive, resulting in the gradual divergence of repeats between different species; (3) The rate to which concerted evolution occurred was different between lineages according to the evolutionary history of each one.     

Telomere-associated repeats in Chironomus form discrete subfamilies generated by gene conversion

Summary In dipteran insects the most distal telomere-associated DNA known to exist consists of long, complex tandem repeats. We have classified the 340-bp tandemly arranged repeats in Chironomus pallidivittatus. The repeats are distributed in a small number of subfamilies. One type of the repeat has the character of a master unit from which other main units can be derived usually by simple changes. The derived subfamilies contain segments that are degenerate versions of the corresponding segment in the master sequence. Such segments can also occur together in one and the same repeat unit in different combinations. There is a complete absence of subfamily-specific base variants in regions lying outside of the degenerate segments. Homogenization takes place between DNA sequences that are often smaller than a whole repeat unit. The mosaic structure of the repeat arrays suggests that gene conversion is an important force in the generation and maintenance of this family of repeats.Offprint requests to: M. Cohn