Telomeric repeat [TTAGGG]n sequences of human chromosomes are conserved in chimpanzee (Pan troglodytes)

Summary Using a series of genetic parameters, attempts have been made for more than two decades to establish the close kinship of human (Homo sapiens) with chimpanzee (Pan troglodytes). Molecular and cytogenetic data presently suggest that the two species are closely related. The recent isolation of a human telomeric probe (P5097-B.5) has prompted us to cross hybridize it to chimpanzee chromosomes in order to explore convergence and/or divergence of the telomeric repeat sequences (TTAGGG)_n. On hybridization, the human probe bound to both ends (telomeres) of chimpanzee chromosomes, suggesting a concerted evolution of tandemly repeated short simple sequences (TTAGGG)_n. Even the terminal heterochromatin of chimpanzee chromosomes was found to be endowed with telomeric repeats, suggesting that evolution of heterochromatin and capping with tandemly repeated short sequences are highly complex phenomena.     

Interstitial telomeric repeats as markers of evolutionary changes in the mammalian karyotype: Human chromosome 2

The presence of conserved telomeric repeats represented by the hexamer (TTAGGG)_n at the chromosomal termini is necessary for the correct functioning and stability of chromosomes. A number of the genomes of mammals, including human, are known to contain interstitial telomeric sequences located far from the chromosomal termini. It is assumed that these repeats mark the regions of fusions or other rear-rangements of ancestral chromosomes. Exact localization of all interstitial telomeric sequences in the genome could significantly advance the understanding of the mechanisms of karyotype evolution and speciation. In this context, software was developed to search for degenerate interstitial telomeric repeats in complete sequences of mammalian chromosomes. The evolutionary significance of such repeats was demonstrated by the example of human chromosome 2. The results are available at http://www.bionet.nsc.ru/labs/theorylabmain/orlov/telomere/.     

Comparative Molecular Cytogenetic Analysis of Two Congeneric Species, <Emphasis Type="Italic">Mugil Curema</Emphasis> and <Emphasis Type="Italic">M. Liza</Emphasis> (Pisces,Mugiliformes), Characterized by Significant Karyotype Diversity

Two congeneric mullet species, Mugil liza and M. curema, respectively with an all-uniarmed and an all-biarmed karyotype, were cytogenetically studied by base-specific fluorochrome staining and FISH-mapping of 45S and 5S ribosomal RNA genes (rDNA) and the (TTAGGG)_n telomeric repeats. Whereas 45S rDNA sites might be homeologus in the two species, 5S rDNA sites are not, as they are localized on chromosome arms of different size. In both species, the (TTAGGG)_n telomeric probe hybridized to natural telomeres and was found scattered along the NORs. In metacentric chromosomes of M. curema, no pericentromeric signals of the telomeric probe were detected. Data are discussed in relation to the karyotype evolution in Mugilidae and to the mechanisms and the evolutionary implications of Robertsonian rearrangements in M. curema.     

Telomeric DNA in chromosomes of five opisthorchid species

The analysis of telomere repeat distribution in chromosomes of five opisthorchid species (Opisthorchis felineus (Rivolta, 1884), Opisthorchis viverrini (Poirier, 1886), Metorchis xanthosomus (Creplin, 1846), Metorchis bilis (Braun, 1890), Clonorchis sinensis (Cobbold, 1875)) was performed with fluorescent in situ hybridization (FISH) of labeled (TTAGGG)n DNA-probe and PNA telomere probe on mitotic and meiotic chromosomes of these species. It was shown that chromosome telomeres of all studied species contain large clusters of (TTAGGG)n telomeric repeats. Interstitial clusters of the (TTAGGG)n repeats have not been revealed in the chromosomes of any studied species even when FISH of PNA telomere probe on pachytene chromosomes was performed. Furthermore interstitial clusters of the (TTAGGG)n repeats have not been detected in the chromosomes of O. viverrini, one of chromosomes of this species is the result of a fusion of two ancestral opisthorchid chromosomes.     

Isolation and characterization of a human telomere.

A method is described that allows cloning of human telomeres in S. cerevisiae by joining human telomeric restriction fragments to yeast artificial chromosome halves. The resulting chimeric yeast-human chromosomes propagate as true linear chromosomes, demonstrating that the human telomere structure is capable of functioning in yeast and suggesting that telomere functions are evolutionarily conserved between yeast and human. One cloned human telomere, yHT1, contains 4 kb of human genomic DNA sequence next to the tandemly repeating TTAGGG hexanucleotide. Genomic hybridizations using both cloned DNA and TTAGGG repeats have revealed a common structural organization of human telomeres. This 4 kb of genomic DNA sequence is present in most, but not all, human telomeres, suggesting that the region is not involved in crucial chromosome-specific functions. However, the extent of common features among the human telomeres and possible similarities in organization with yeast telomeres suggest that this region may play a role in general chromosome behavior such as telomere-telomere interactions. Unlike the simple telomeric TTAGGG repeats, our cloned human genomic DNA sequence does not cross-hybridize with rodent DNA. Thus, this clone allows the identifications of the terminal restriction fragments of specific human chromosomes in human-rodent hybrid cells.     

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.     

Telomere Variation in Xenopus laevis

Eukaryotic telomeres are variable at several levels, from the length of the simple sequence telomeric repeat tract in different cell types to the presence or number of telomere-adjacent DNA sequence elements in different strains or individuals. We have investigated the sequence organization of Xenopus laevis telomeres by use of the vertebrate telomeric repeat (TTAGGG)_n and blot hybridization analysis. The (TTAGGG)_n-hybridizing fragments, which ranged from less than 10 to over 50 kb with frequently cutting enzymes, defined a pattern that was polymorphic between individuals. BAL 31 exonuclease treatment confirmed that these fragments were telomeric. The polymorphic fragments analyzed did not hybridize to 5S RNA sequences, which are telomeric according to in situ hybridization. When telomeric fragments from offspring (whole embryos) were compared to those from the spleens of the parents, the inheritance pattern of some bands was found to be unusual. Furthermore, in one cross, the telomeres of the embryo were shorter than the telomeres of the parents’ spleen, and in another, the male’s testis telomeres were shorter than those of the male’s spleen. Our data are consistent with a model for chromosome behavior that involves a significant amount of DNA rearrangement at telomeres and suggest that length regulation of Xenopus telomeres is different from that observed for Mus spretus and human telomeres.     

Distribution of non-telomeric sites of the (TTAGGG)n telomeric sequence in vertebrate chromosomes

The intrachromosomal distribution of non-telomeric sites of the (TTAGGG)_n telomeric repeat was determined for 100 vertebrate species. The most common non-telomeric location of this sequence was in the pericentric regions of chromosomes. A variety of species showed relatively large amounts of this sequence present within regions of constitutive heterochromatin. We discuss possible relationships between the non-telomeric distribution of the (TTAGGG)_n sequence and the process of karyotype evolution, during which these sites may provide potential new telomeres.     

Telomere shortening associated with chromosome instability is arrested in immortal cells which express telomerase activity.

Loss of telomeric DNA during cell proliferation may play a role in ageing and cancer. Since telomeres permit complete replication of eukaryotic chromosomes and protect their ends from recombination, we have measured telomere length, telomerase activity and chromosome rearrangements in human cells before and after transformation with SV40 or Ad5. In all mortal populations, telomeres shortened by approximately 65 bp/generation during the lifespan of the cultures. When transformed cells reached crisis, the length of the telomeric TTAGGG repeats was only approximately 1.5 kbp and many dicentric chromosomes were observed. In immortal cells, telomere length and frequency of dicentric chromosomes stabilized after crisis. Telomerase activity was not detectable in control or extended lifespan populations but was present in immortal populations. These results suggest that chromosomes with short (TTAGGG)n tracts are recombinogenic, critically shortened telomeres may be incompatible with cell proliferation and stabilization of telomere length by telomerase may be required for immortalization.     

A negative regulator of telomere-length protein trf1 is associated with interstitial (TTAGGG)n blocks in immortal Chinese hamster ovary cells

Telomeres of mammalian chromosomes are composed of long tandem repeats (TTAGGG)n which bind in a sequence-specific manner two proteins-TRF1 and TRF2. In human somatic cells both proteins are mostly associated with telomeres and TRF1 overexpression resulting in telomere shortening. However, chromosomes of some mammalian species, e.g., Chinese hamster, have large interstitial blocks of (TTAGGG)n sequence (IBTs) and the blocks are involved in radiation-induced chromosome instability. In normal somatic cells of these species chromosomes are stable, indicating that the IBTs are protected from unequal homologous recombination. In this study we expressed V5-epitope or green fluorescent protein (GFP)-tagged human TRF1 in different lines of mammalian cells and analyzed distribution of the fusion proteins in interphase nucleus. As expected, transient transfection of human (A549) or African green monkey cells with GFP-N-TRF1 or TRF1-C-V5 plasmids resulted in the appearance in interphase nuclei of multiple faint nuclear dots containing GFP or V5 epitope which we believe to represent telomeres. Transfection of immortalized Chinese hamster ovary (CHO) cell line K1 which have extremely short telomeres with GFP-N-TRF1 plasmid leads to the appearance in interphase nuclei of large GFP bodies corresponding in number to the number of IBTs in these cells. Simultaneous visualization of GFP and IBTs in interphase nuclei of transfected CHO-K1 cells showed colocalization of both signals indicating that expressed TRF1 actually associates with IBTs. These results suggest that TRF1 may serve as general sensor of (TTAGGG)n repeats controlling not only telomeres but also interstitial (TTAGGG)n sequences.     

Telomeric localization of the Arabidopsis‐type heptamer repeat, (TTTAGGG)n,at the chromosome ends in Saccharina japonica (Phaeophyta)

Telomeres generally consist of short repeats of minisatellite DNA sequences and are useful in chromosome identification and karyotype analysis. To date, telomeres have not been characterized in the economically important brown seaweed Saccharina japonica, thus its full cytogenetic research and genetic breeding potential has not been realized. Herein, the tentative sequence of telomeres in S. japonica was identified by PCR amplification with primers designed based on the Arabidopsis‐type telomere sequence (TTTAGGG)_n, which was chosen out of three possible telomeric repeat DNA sequences typically present in plants and algae. After PCR optimization and cloning, sequence analysis of the amplified products from S. japonica genomic DNA showed that they were composed of repeat units, (TTTAGGG)_n, in which the repeat number ranged from 15 to 63 (n = 46). This type of repeat sequence was verified by a Southern blot assay with the Arabidopsis‐type telomere sequence as a probe. The digestion of S. japonica genomic DNA with the exonuclease Bal31 illustrated that the target sequence corresponding to the Arabidopsis‐type telomere sequence was susceptible to Bal31 digestion, suggesting that the repeat sequence was likely located at the outermost ends of the kelp chromosomes. Fluorescence in situ hybridizations with the aforementioned probe provided the initial cytogenetic evidence that the hybridization signals were principally localized at both ends of S. japonica chromosomes. This study indicates that the telomeric repeat of the kelp chromosomes is (TTTAGGG)_n which differs from the previously reported (TTAGGG)_n sequence in Ectocarpus siliculosus through genome sequencing, thereby suggesting distinct telomeres in brown seaweeds.     

Human telomeres are attached to the nuclear matrix.

This report shows that human telomeres are tightly associated with the nuclear matrix. Telomere attachment is observed in several cell types and in all stages of interphase. Mapping experiments show that telomeres are anchored via their TTAGGG repeats; a subtelomeric repeat located immediately proximal to the telomeric TTAGGG repeats is quantitatively released from the nuclear matrix by restriction endonuclease cleavage. TTAGGG repeats introduced at chromosome-internal sites by DNA transfection do not behave as matrix attached loci, suggesting that the telomeric position of the repeats is required for their interaction with the nuclear matrix. These findings are consistent with the idea that telomeres function as a nucleoprotein complex.     

Distribution of telomeric (TTAGGG)<Subscript>n</Subscript> sequences in avian chromosomes

The physical ends of mammalian and other vertebrate chromosomes consist of tandemly repeated (TTAGGG)(n) hexamers, nucleating a specialized telomeric structure. However, (TTAGGG)(n) sequences can also occur at non-telomeric sites, providing important insights into karyotypic evolution. By fluorescence in situ hybridization (FISH) we studied the chromosomal distribution of (TTAGGG)(n) sequences in 16 bird species, representing seven different orders. Many species, in particular the ratites, display (TTAGGG)(n) hybridization signals in interstitial and centromeric regions of their macrochromosomes in addition to the typical telomeric signals. In some but not all species these non-telomeric sites coincide with C-band-positive heterochromatin. The retention and/or amplification of telomeric (TTAGGG)(n) repeats at interstitial and centromeric sites may indicate the fusion of ancestral chromosomes. Compared with the macrochromosomes, the microchromosomes of most species are enriched with (TTAGGG)(n) sequences, displaying heterogeneous hybridization patterns. We propose that this high density of (TTAGGG)(n) repeats contributes to the exceptionally high meiotic recombination rate of avian microchromosomes.     

Changes of telomere lengths in human intracranial tumours

The termini of human chromosomes comprise stretches of G-rich repeats that are about 5–20 kilobase (kb) in length. The size of the telomeres can be determined by hybridization with probes specific for these (ttaggg)_n sequences after digestion of chromosomal DNA with appropriate restriction enzymes and electrophoretic separation of the fragments. Here, probing with the ³²P-labelled synthetic (TTAGGG)₃ oligonucleotide revealed length changes of the telomeres occurring in intracranial tumours. Among 60 samples analysed, 41.7% showed telomere elongation, and 21.7% telomere reduction, whereas 36.7% of the tumours exhibited equal lengths compared with the patients' peripheral blood leukocytes. Most of the elongated glioma telomeres exceeded in length those of untransformed astrocytes derived from human fetal tissue.     

Conservation and characterization of unique porcine interstitial telomeric sequences

Telomeres are composed of TTAGGG repeats and located at the ends of chromosomes. Telomeres protect chromosomes from instability in mammals, including mice and humans. Repetitive TTAGGG sequences are also found at intrachromosomal sites, where they are named as interstitial telomeric sequences (ITSs). Aberrant ITSs are implicated in chromosomal instability and found in cancer cells. Interestingly, in pigs, vertebrate telomere sequences TTAGGG (vITSs) are also localized at the centromeric region of chromosome 6, in addition to the end of all chromosomes. Surprisingly, we found that botanic telomere sequences, TTTAGGG (bITSs), also localize with vITSs at the centromeric regions of pig chromosome 6 using telomere fluorescence in situ hybridization (FISH) and by comparisons between several species. Furthermore, the average lengths of vITSs are highly correlated with those of the terminal telomeres (TTS). Also, pig ITSs show a high incidence of telomere doublets, suggesting that pig ITSs might be unstable and dynamic. Together, our results show that pig cells maintain the conserved telomere sequences that are found at the ITSs from of plants and other vertebrates. Further understanding of the function and regulation of pig ITSs may provide new clues for evolution and chromosomal instability.     

Conformational Changes Induced in the Human Protein Translin and in the Single-stranded Oligodeoxynucleotides d(GT)12 and d(TTAGGG)5 Upon Binding of These Oligodeoxynucleotides by Translin

Abstract

Translin is a human single-stranded DNA and RNA binding protein that has been highly conserved in eukaryotic evolution. It consists of eight subunits having a highly helical secondary structure that assemble into a ring. The DNA and the RNA are bound inside the ring. Recently, some of us demonstrated that the human translin specifically binds the single-stranded microsatellite repeats, d(GT)_n, the human telomeric repeats, d(TTAGGG)_n, and the Tetrahymena telomeric repeats, d(GGGGTT)_n. These data suggested that translin might be involved in recombination at d(GT)_n·d(AC)_n microsatellites and in telomere metabolism [E. Jacob, L. Pucshansky, E. Zeruya, N. Baran, H. Manor. J. Mol. Biol. 344, 939–950 (2004), S. Cohen, E. Jacob, H. Manor. Biochim. Biophys. Acta. 1679, 129–140 (2004)]. Other data indicated that translin might stimulate binding of telomerase to single- stranded telomeric overhangs by unwinding secondary structures formed by the telomeric repeats [S. Cohen, E. Jacob, H. Manor. Biochim. Biophys. Acta. 1679, 129–140 (2004)]. Here we present a circular dichroism (CD) analysis of complexes formed between the human translin and the microsatellite and telomeric oligodeoxynucleotides d(GT) and d(TTAGGG)5. We report that conformational changes occur in both the translin and the oligodeoxynucleotides upon formation of the complexes. In translin octamers bound to the oligodeoxynucleotide d(GT)12, the fraction of a-helices decreases from ～67% to ～50%, while the fraction of turns and of the unordered structure increases from ～11% to ～17% and from ～19% to ～24%, respectively. In the bound oligodeoxynucleotide d(GT), we observed CD shifts which are consistent with a decrease of base stacking and a putative anti-syn switch of some guanines. The oligodeoxynucleotide d(TTAGGG)5 formed intramolecular quadruplexes under the conditions of our assays and translin was found to unfold the quadruplexes into structures consisting of a single hairpin and three unwound single-stranded d(TTAGGG) repeats. We suggest that such unfolding could account for the stimulation of telomerase activity by translin mentioned above.     

Telomere-related sequences at interstitial sites in the human genome

The ends (telomeres) of eukaryotic chromosomes are protected from degradation and from loss during DNA replication by buffers of simple tandem repetitive sequence. The nucleotide sequence of these telomeric arrays is fundamental to telomere function as a site for protein and ribonucleoprotein binding and varies only slightly in a wide range of organisms. We present evidence that arrays of this human telomeric sequence, TTAGGG, are present not only at the ends of human chromosomes but also at numerous interstitial sites. These interstitial loci share nucleotide sequence similarity outside the repetitive array, suggesting that they are related functionally or have evolved from a common progenitor locus.     

Telomeric DNA allocation in chromosomes of common shrew (Sorex araneus, eulipotyphla)

Recently, we displayed an Iberian shrew species (Sorex granarius) with telomere structures unusual for mammals. Long telomeres on the short acrocentric arms contain an average of 213 kb of telomere repeats, whereas the other chromosomal ends have only 3.8 kb (Zhdanova et al., 2005; 2007). However, it is not clear whether these telomeres are typical for all shrew species or only for S. granarius. S. granarius and common shrew Sorex araneus are sibling species. In this study, using modified Q-FISH we demonstrated that telomeres in S. araneus from various chromosomal races distinguished by their number of metacentrics contain 6.8–15.2 kb of telomeric tracts. The S. araneus telomere lengths appear to correspond to telomere lengths in the majority of both shrew species and wild mammals, whereas S. granarius has telomeres with unique or rare structures. Using DNA and RNA high-specific modified probes to telomeric repeats (PNA and LNA), we showed that interstitial telomeric sites in S. araneus chromosomes contain mainly telomeric DNA and that their localization coincide with some evolutionary breakpoints. Interstitial telomeric DNA in S. granarius chromosomes was not revealed. Thus, the distribution of telomeric DNA may be significantly different, even in closely related species whose chromosomes are composed of almost identical chromosomal arms.