Cloning and genetic mapping of wheat telomere-associated sequences

Wheat telomere-associated sequences (TASs) were cloned using a Vectorette approach and sequenced. Reverse primers specific to the TASs were combined with labelled degenerate telomere primers in PCR reactions containing total genomic DNA as template. Amplification products were separated on sequencing gels. In total, seventeen primer combinations provided 47 polymorphic fragments. Nine of these mapped beyond the most distal RFLP markers and defined the ends of seven chromosome arms. Seven of the nine terminal fragments were derived from a 118-bp tandem repeat, indicating that subtelomeric tandem repeat sequences provide an efficient means to target chromosome ends. A telomere cloning strategy and the terminal and interstitial location of TASs are discussed. Received: 13 September 1996 / Accepted: 22 January 1997     

Analysis and location of a rice BAG clone containing telomeric DNA sequences

BAC2, a rice BAC clone containing (TTTAGGG)n homologous sequences, was analyzed by Southern hybridization and DNA sequencing of its subclones. It was disclosed that there were many tandem repeated satellite DNA sequences, called TA352, as well as simple tandem repeats consisting of TTTAGGG or its variant within the BAC2 insert. A 0. 8 kb (TTTAGGG) n-containing fragment in BAC2 was mapped in the telomere regions of at least 5 pairs of rice chromosomes by using fluorescence in situ hybridization (FISH). By RFLP analysis of low copy sequences the BAC2 clone was localized in one terminal region of chromosome 6. All the results strongly suggest that the telomeric DNA sequences of rice are TTTAGGG or its variant, and the linked satellite DNA TA352 sequences belong to telomere-associated sequences.     

Analysis and location of a rice BAG clone containing telomeric DNA sequences

BAC2, a rice BAC clone containing (TTTAGGG)_n homologous sequences, was analyzed by Southern hybridization and DNA sequencing of its subclones. It was disclosed that there were many tandem repeated satellite DNA sequences, called TA352, as well as simple tandem repeats consisting of TTTAGGG or its variant within the BAC2 insert. A 0. 8 kb (TTTAGGG)_n-containing fragment in BAC2 was mapped in the telomere regions of at least 5 pairs of rice chromosomes by using fluorescencein situ hybridization (FISH). By RFLP analysis of low copy sequences the BAC2 clone was localized in one terminal region of chromosome 6. All the results strongly suggest that the telomeric DNA sequences of rice are TTTAGGG or its variant, and the linked satellite DNA TA352 sequences belong to telomere-associated sequences.     

Analysis and location of a rice BAC clone containing telomeric DNA sequences

BAC2, a rice BAC clone containing (TTTAGGG)_n homologous sequences, was analyzed by Southern hybridization and DNA sequencing of its subclones. It was disclosed that there were many tandem repeated satellite DNA sequences, called TA352, as well as simple tandem repeats consisting of TTTAGGG or its variant within the BAC2 insert. A 0. 8 kb (TTTAGGG)_n-containing fragment in BAC2 was mapped in the telomere regions of at least 5 pairs of rice chromosomes by using fluorescencein situ hybridization (FISH). By RFLP analysis of low copy sequences the BAC2 clone was localized in one terminal region of chromosome 6. All the results strongly suggest that the telomeric DNA sequences of rice are TTTAGGG or its variant, and the linked satellite DNA TA352 sequences belong to telomere-associated sequences.     

Bal31 sensitivity of micronuclear sequences homologous to C4A4/G4T4 repeats in Oxytricha nova

The sequence similarity and functional equivalence of telomeres from macronuclear linear DNA molecules in Oxytricha and telomeric sequences of true mitotic/meiotic chromosomes suggest that the (C4A4)n/(G4T4)n sequences found at macronuclear telomeres may also function as micronuclear telomeres in Oxytricha. In this study, radioactively labeled (C4A4)n have been hybridized to micronuclear DNA samples that have been treated with the enzyme Bal31, which has double-stranded exonuclease activity. A time course of digestion shows that approximately 50% of the micronuclear sequences that hybridize to a C4A4 probe disappear with mild digestion by Bal31, suggesting that these sequences are telomeric. The remainder of the hybridizing sequences are not degraded any more rapidly than the total genomic DNA. All of the C4A4/G4T4 sequences that can be detected by hybridization of C4A4 probes to Southern-blotted restriction enzyme digests of micronuclear DNA occur in regions of the genome that are highly resistant to restriction enzyme digestion and show a clustering of sites reminiscent of telomeres in other organisms. We propose that the micronuclear C4A4 hybridizable sequences that are Bal31 resistant may be located near the telomere and within telomere-associated repetitive sequences that are immediately internal to telomeric (Bal31 sensitive) C4A4 hybridizeable sequences.     

Isolation and mapping of bacterial artificial chromosome (BAC) clone containing telomere-associated sequence

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应用PCR进行水稻染色体末端区域作图

利用RAPD引物介寻的不对称复性温度PCR的方法（RM－PCR）,发展了一种基于端粒重复序列的新型分子标记。并在一个籼粳杂交来源（窄叶青8号×京系17）的水稻双单倍体群体中进行了端粒重复相关顺序的遗传定位。在23个定位位点中,有12个定位在水稻8个染色体臂的最远端,并将所在染色体分别向外延长了7．7～22．6cM。其中有些可能是定位在亚端粒区。有5个位点被定位在着丝粒区,另外6个位点定位于染色体内其他区域。     

Telomere looping in P. sativum (common garden pea)

Telomeres vary greatly in size among plants and, in most higher plants, consist of a long array of 5'-TTTAGGG-3'/3'-AAATCCC-5' (TTTAGGG) repeats. Recently, telomeric DNA in human, mouse, oxytricha, and trypanosome chromosomes have been found arranged into loops (t-loops), proposed to sequester the telomere from unwanted repair events and prevent activation of DNA damage checkpoints. We have asked whether t-loops exist in the higher order plant Pisum sativum (garden pea). DNA was isolated from the shoots and root tips of germinating seeds. Analysis of the telomeric restriction fragments showed that DNA hybridizing to a (TTTAGGG)n probe migrated as a smear centering around 25 kb, and direct sequencing verified the repeat to be (TTTAGGG)n. Total DNA in isolated nuclei was photo-cross-linked, and the telomeric restriction fragments were purified by gel filtration. Electron microscopic (EM) analysis revealed DNA molecules arranged as t-loops with a size distribution consistent with that seen by gel electrophoresis. Some molecules had loops as large as 75 kb. These results show that the arrangement of telomeric DNA into loops occurs in higher plants.     

Rice proteins that bind single-stranded G-rich telomere DNA

In this work, we have identified and characterized proteins in rice nuclear extracts that specifically bind the single-stranded G-rich telomere sequence. Three types of specific DNA-protein complexes (I, II, and III) were identified by gel retardation assays using synthetic telomere substrates consisting of two or more single-stranded TTTAGGG repeats and rice nuclear extracts. Since each complex has a unique biochemical property and differs in electrophoretic mobility, at least three different proteins interact with the G-rich telomere sequences. These proteins are called rice G-rich telomere binding protein (RGBP) and none of them show binding affinity to double-stranded telomere repeats or single-stranded C-rich sequence. Changing one or two G's to C's in the TTTAGGG repeats abolishes binding activity. RGBPs have a greatly reduced affinity for human and Tetrahymena telomeric sequence and do not efficiently bind the cognate G-rich telomere RNA sequence UUUAGGG. Like other telomere binding proteins, RGBPs are resistant to high salt concentrations. RNase sensitivity of the DNA-protein interactions was tested to investigate whether an RNA component mediates the telomeric DNA-protein interaction. In this assay, we observed a novel complex (complex III) in gel retardation assays which did not alter the mobilities or the band intensities of the two pre-existing complexes (I and II). The complex III, in addition to binding to telomeric sequences, has a binding affinity to rice nuclear RNA, whereas two other complexes have a binding affinity to only single-stranded G-rich telomere DNA. Taken together, these studies suggest that RGBPs are new types of telomere-binding proteins that bind in vitro to single-stranded G-rich telomere DNA in the angiosperms.     

Characterisation of the telomeres at opposite ends of a 3 Mb Theileria parva chromosome.

Bacteriophage lambda clones containing Theileria parva genomic DNA derived from two different telomeres were isolated and the nucleotide sequences of the telomeric repeats and adjacent telomere-associated (TAS) DNA were determined. The T.parva telomeric repeat sequences, a tandem array of TTTTAGGG or TTTAGGG interspersed with a few variant copies, showed a high degree of sequence identity to those of the photosynthetic algae Chlamydomonas reinhardtii (97% identity) and Chlorella vulgaris (87.7% identity) and the angiosperm Arabidopsis thaliana (84.4% identity). Unlike most organisms which have been studied, no significant repetitive sequences were found in the nucleotide sequences of TAS DNA located centromere-proximal to the telomeric repeats. Restriction mapping and hybridisation analysis of lambda EMBL3 clones containing 16 kilobases of TAS DNA derived from one telomere suggested that they did not contain long regions of repetitive DNA. The cloned TAS DNAs were mapped to T.parva Muguga genomic SfiI fragments 8 and 20, which are located at opposite ends of the largest T.parva chromosome. A 126 bp sequence located directly centromere-proximal to the telomeric repeats was 94% identical between the two cloned telomeres. The conserved 126 bp sequence was present on all T.parva Muguga telomeric SfiI fragments.     

Characterization of Arabidopsis thaliana telomeres isolated in yeast.

In an effort to learn more about the genomic organization of chromosomal termini in plants we employed a functional complementation strategy to isolate Arabidopsis thaliana telomeres in the yeast, Saccharomyces cerevisiae. Eight yeast episomes carrying A. thaliana telomeric sequences were obtained. The plant sequences carried on two episomes, YpAtT1 and YpAtT7, were characterized in detail. The telomeric origins of YpAtT1 and YpAtT7 insert DNAs were confirmed by demonstrating that corresponding genomic sequences are preferentially degraded during exonucleolytic digestion. The isolated telomeric restriction fragments contain G-rich repeat arrays characteristic of A. thaliana telomeres, as well as subterminal telomere-associated sequences (TASs). DNA sequence analysis revealed the presence of variant telomeric repeats at the centromere-proximal border of the terminal block of telomere repeats. The TAS flanking the telomeric G-rich repeat in YpAtT7 corresponds to a repetitive element present at other A. thaliana telomeres, while more proximal sequences are unique to one telomere. The YpAtT1 TAS is unique in the Landsberg strain of A. thaliana from which the clone originated; however, the Landsberg TAS cross-hybridizes weakly to a second telomere in the strain Columbia. Restriction analysis with cytosine methylation-sensitive endonucleases indicated that both TASs are highly methylated in the genome.     

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.     

Minisatellite telomeres occur in the family Alliaceae but are lost in Allium

Although telomere sequences are considered to be highly conserved, there are switch-points in plant telomere evolution that are congruent with species' phylogenies. When Asparagales diverged, the Arabidopsis-type telomeric minisatellite repeat (TTTAGGG)(n) was first replaced by a human-type (TTAGGG)(n) repeat, and both were lost in Allium cepa (Alliaceae). We aimed to discover (1) when this loss occurred during divergence of Alliaceae and, (2) if (TTAGGG)(n) repeats were replaced by other known telomeric minisatellites. Slot-blot hybridization, fluorescent in situ hybridization, BAL31 digestion, asymmetric PCR, and cloning were used to identify and localize candidate telomeric sequences in species of Nothoscordum, Miersia, Ipheion, Tulbaghia, Gethyum, Gilliesia, Leucocoryne, Tristagma, and representatives of the three major Allium clades. Alliaceae genera other than Allium have human (TTAGGG)-type telomeric repeats that form telomeres. In Allium, only Tetrahymena-type (TTGGGG) repeats were ubiquitous in the genome, but they were not localized to telomeres. Likewise, the consensus telomeric repeats in Arabidopsis, human, Bombyx (TTAGG), Chlamydomonas (TTTTAGGG), and Oxytricha (TTTTGGGG) are absent in Allium telomeres. Alliaceae with human-type telomeres share telomere structures with related Asparagales species. We demonstrate that in the Allium ancestor human-type telomeric repeats were lost from telomeres and were not replaced by any investigated alternative minisatellite repeats. However, human and other types of minisatellite telomeric repeats are interspersed in some Allium genomes and their genomic signatures coincide with Allium clades.     

Genetic and physical mapping of telomeres and macrosatellites of rice

Telomeres and telomere-associated satellites of rice were genetically and physically analyzed by pulsed-field gel electrophoresis (PFGE) using Arabidopsis telomeric DNA and rice satellite sequences as probes. We demonstrate that Arabidopsis telomeric sequences hybridize to rice telomeres under the conditions of high stringency. Using the Arabidopsis probe, multiple, discrete telomeric fragments could be identified on pulsed-field gel blots of rice DNAs digested with rare-cutting restriction enzymes. Most of the telomeric bands larger than 300 kb are physically linked with satellite bands as revealed by PFGE. Some of the telomeric and satellite bands segregate in a Mendelian fashion and are highly reproducible. Three such telomeric bands have been mapped to the distal ends of RFLP linkage groups: Telsm-1 on chromosome 8, Telsa-1 on chromosome 9 and Telsm-3 on chromosome 11. One segregating satellite band was mapped to an internal region of chromosome 10. Telomeric fragments were shown not only to be genetically linked to but also physically linked (based on PFGE) to the terminal RFLP markers. The physical distance from telomeric sequences to a distal RFLP marker, r45s gene, on chromosome 9, is 200 kb while the distance from telomeric sequences to RG98, a terminal RFLP marker on chromosome 11, is 260 kb. Physical maps of the telomere regions of chromosome 9 and chromosome 11 are presented.     

Macrostructure of the tomato telomeres.

The macrostructure of the tomato telomeres has been investigated by in situ hybridization, genomic sequencing, and pulsed-field gel electrophoresis. In situ hybridizations with a cloned telomeric sequence from Arabidopsis thaliana indicated that the telomeric repeat of tomato cross-hybridizes with that of Arabidopsis and is located at all telomeres. Bal31 digestion kinetics confirmed that the tomato telomeric repeat represents the outermost DNA sequence of each tomato chromosome. Genomic sequencing of enriched tomato telomeric sequences, using primers derived from the Arabidopsis sequence, revealed that the consensus sequence of the tomato telomeric repeat is TT(T/A)AGGG compared with the Arabidopsis consensus sequence of TTTAGGG. Furthermore, as shown by pulsed-field gel electrophoresis, the telomeric repeat of tomato is separated by not more than a few hundred kilobases from a previously described 162-base pair satellite DNA repeat of tomato (TGR I) at 20 of the 24 telomeres. Together, these sequences are found in the heterochromatic terminal knob observed in pachytene chromosomes. Therefore, these two repeats determine the structure of 20 of the 24 tomato chromosome ends over approximately 2% of the total chromosome length.     

Visual verification of close disposition between a rice A genome-specific DNA sequence (TrsA) and the telomere sequence

A rice A genome-specific tandem repeat sequence (TrsA) and telomeric nucleotide sequences, (TTTAGGG)_n, were simultaneously detected by multicolor fluorescence in situ hybridization (McFISH) using rice prometaphase chromosomes. Six pairs of TrsA sites visualized by fluorescence signals were all localized on the long arms close to the telomeric regions. Differences in the copy number of TrsA at the different sites were visualized both by the size of the telomeric condensation block stained with Giemsa solution and the signal intensity after FISH with TrsA. McFISH analyses using interphase nuclei could resolve close disposition of TrsA and telomere and also gave rough estimation of the distance between them. The functional significance of the close disposition of TrsA and telomere is discussed.     

Telomere and 45S rDNA sequences are structurally linked on the chromosomes in <Emphasis Type="Italic">Chrysanthemum segetum</Emphasis> L.

Some reports have shown that nucleolar organizer regions are located at the telomeric region and have a structural connection with telomeres at the cellular level in many organisms. In this study, we found that all 45S ribosomal DNA (rDNA) signals were located at telomeric regions on the chromosomes in Chrysanthemum segetum L., and the 45S rDNA showed distinct signal patterns on different metaphase chromosome spreads. The bicolor fluorescence in situ hybridization experiment on the extended fibers revealed that telomere repeats were structurally connected with or interspersed into rDNA sequences. The close cytological structure relation between rDNA and telomere sequences led us to use PCR with combinations of the telomere primer and the rDNA primer to obtain some fragments, which were flanked by different rDNA and telomere primer sequences. One representative clone CHS2 contains closely connected rDNA and telomere sequences, suggesting that the telomere sequence invaded into the conserved rDNA sequence. In addition, the sequences of some PCR clones were flanked by the single telomeric primer sequence or the rDNA primer sequence. These results suggested that homologous recombination occurred between tandem repeat units of rDNA sequences or telomere repeats at the chromosome terminus.     

Chromosome-specific distribution of nucleotide substitutions in telomeric repeats of rice (Oryza sativa L.)

Examination of the genomic sequence of the telomere region makes it possible to understand the evolution of the structure of chromosomal ends. We compared the genomic sequences of 14 chromosomal ends of rice, Oryza sativa, L., on the basis of the variation in TTTAGGG repeats. In the proximal telomere repeats, nucleotide substitution occurred more frequently than in the more distal repeats. The most significant diversity was observed at the 1st, 2nd, or 3rd position of TTTAGGG, suggesting that T has been a target of mutation preferentially. Copies of ATTAGGG, CTTAGGG, GTTAGGG, TTCAGGG, TTGAGGG, or TATAGGG were arrayed in tandem, or the same subtypes were located close to each other. The substituted variants were accumulated in chromosomes 2L, 3L, 7L, and 10S but not in the ends of the other chromosomes. In contrast, deletion variants, almost all of which were TTTAGGG to TTAGGG, were dispersed over approximately 4.9% of the sequenced telomere repeats. In summary, the rice proximal telomeric arrays were composed of blocks of at least 6 types of substituted variants and the canonical sequence in a chromosome-specific manner. These results suggest that the variants might arise from the rapid expansion of a single mutation rather than from the gradual accumulation of random mutations.     

Solution structure of telomere binding domain of AtTRB2 derived from Arabidopsis thaliana

Telomere homeostasis is regulated by telomere-associated proteins, and the Myb domain is well conserved for telomere binding. AtTRB2 is a member of the SMH (Single-Myb-Histone)-like family in Arabidopsis thaliana, having an N-terminal Myb domain, which is responsible for DNA binding. The Myb domain of AtTRB2 contains three α-helices and loops for DNA binding, which is unusual given that other plant telomere-binding proteins have an additional fourth helix that is essential for DNA binding. To understand the structural role for telomeric DNA binding of AtTRB2, we determined the solution structure of the Myb domain of AtTRB2 (AtTRB2_1–64) using nuclear magnetic resonance (NMR) spectroscopy. In addition, the inter-molecular interaction between AtTRB2_1–64 and telomeric DNA has been characterized by the electrophoretic mobility shift assay (EMSA) and NMR titration analyses for both plant (TTTAGGG)n and human (TTAGGG)n telomere sequences. Data revealed that Trp28, Arg29, and Val47 residues located in Helix 2 and Helix 3 are crucial for DNA binding, which are well conserved among other plant telomere binding proteins. We concluded that although AtTRB2 is devoid of the additional fourth helix in the Myb-extension domain, it is able to bind to plant telomeric repeat sequences as well as human telomeric repeat sequences.     

Isolation of telomeric DNA from the filamentous fungus Podospora anserina and construction of a self-replicating linear plasmid showing high transformation frequency.

It has been previously shown that linear plasmids bearing Tetrahymena telomeric sequences are able to replicate autonomously in the filamentous fungus Podospora anserina (1). However, autonomous replication occurs in only 50-70% of the transformants, suggesting a defect in the recognition of the Tetrahymena telomeric template by the putative P. anserina telomerase so that only a fraction of entering DNA is stabilized into linear extrachromosomal molecules. We have cloned DNA sequences added to the Tetrahymena (T2G4)n ends of the linear plasmid. Nucleotide sequencing showed that these sequences are exclusively composed of T2AG3 repeat units. Hybridization experiments of Bal31 treated DNA showed that T2AG3 repeats are confined within 200 bp in chromosomal P. anserina telomeres. A new plasmid has been constructed so that after linearization, the terminal sequences contain T2AG3 repeats. This linear molecule transforms P. anserina with a high frequency (up to 1.75 x 10(4) transformants/micrograms), autonomous replication occurs in 100% of the transformants and the plasmid copy number is about 2-3 per nucleus. These results underscore the importance of the telomeric repeat nucleotide sequence for efficient recognition as functional telomeric DNA in vivo and provide the first step toward the development of an artificial chromosome cloning system for filamentous fungi.