Cis- and trans-acting influences on telomeric position effect in Drosophila melanogaster detected with a subterminal transgene

One model of telomeric position effect (TPE) in Drosophila melanogaster proposes that reporter genes in the vicinity of telomeres are repressed by subterminal telomere-associated sequences (TAS) and that variegation of these genes is the result of competition between the repressive effects of TAS and the stimulating effects of promoters in the terminal HeT-A transposon array. The data presented here support this model, but also suggest that TPE is more complex. Activity of a telomeric white reporter gene increases in response to deletion of some or all of the TAS on the homolog. Only transgenes next to fairly long HeT-A arrays respond to this trans-interaction. HeT-A arrays of 6-18 kb respond by increasing the number of dark spots on the eye, while longer arrays increase the background eye color or increase the number of spots sufficiently to cause them to merge. Thus, expression of a subtelomeric reporter gene is influenced by the telomere structure in cis and trans. We propose that the forces involved in telomere length regulation in Drosophila are the underlying forces that manifest themselves as TPE. In the wild-type telomere TAS may play an important role in controlling telomere elongation by repressing HeT-A promoter activity. Modulation of this repression by the homolog may thus regulate telomere elongation.     

Two distinct domains in Drosophila melanogaster telomeres

Telomeres are generally considered heterochromatic. On the basis of DNA composition, the telomeric region of Drosophila melanogaster contains two distinct subdomains: a subtelomeric region of repetitive DNA, termed TAS, and a terminal array of retrotransposons, which perform the elongation function instead of telomerase. We have identified several P-element insertions into this retrotransposon array and compared expression levels of transgenes with similar integrations into TAS and euchromatic regions. In contrast to insertions in TAS, which are silenced, reporter genes in the terminal HeT-A, TAHRE, or TART retroelements did not exhibit repressed expression in comparison with the same transgene construct in euchromatin. These data, in combination with cytological studies, provide evidence that the subtelomeric TAS region exhibits features resembling heterochromatin, while the terminal retrotransposon array exhibits euchromatic characteristics.     

Euchromatic and heterochromatic domains at Drosophila telomeres.

Noncoding repetitive sequences make up a large portion of eukaryotic genomes, but their function is not well understood. Large blocks of repetitive DNA-forming heterochromatin around the centromeres are required for this region to function properly, but are difficult to analyze. The smaller regions of heterochromatin at the telomeres provide an opportunity to study their DNA and protein composition. Drosophila telomere length is maintained through the targeted transposition of specific non-long terminal repeat retrotransposons to chromosome ends, where they form long tandem arrays. A subterminal telomere-associated sequence (TAS) lies immediately proximal to the terminal-retrotransposon array. Here, we review the experimental support for the heterochromatic features of Drosophila telomeres, and provide evidence that telomeric regions contain 2 distinct chromatin subdomains: TAS, which exhibits features that resemble beta heterochromatin; and the terminal array of retrotransposons, which appears euchromatic. This organization is significantly different from the telomeric organization of other eukaryotes, where the terminal telomerase-generated repeats are often folded in a t-loop structure and become part of the heterochromatin protein complex.     

Differential maintenance of DNA sequences in telomeric and centromeric heterochromatin

Repeated DNA in heterochromatin presents enormous difficulties for whole-genome sequencing; hence, sequence organization in a significant portion of the genomes of multicellular organisms is relatively unknown. Two sequenced BACs now allow us to compare telomeric retrotransposon arrays from Drosophila melanogaster telomeres with an array of telomeric retrotransposons that transposed into the centromeric region of the Y chromosome >13 MYA, providing a unique opportunity to compare the structural evolution of this retrotransposon in two contexts. We find that these retrotransposon arrays, both heterochromatic, are maintained quite differently, resulting in sequence organizations that apparently reflect different roles in the two chromosomal environments. The telomere array has grown only by transposition of new elements to the chromosome end; the centromeric array instead has grown by repeated amplifications of segments of the original telomere array. Many elements in the telomere have been variably 5'-truncated apparently by gradual erosion and irregular deletions of the chromosome end; however, a significant fraction (4 and possibly 5 or 6 of 15 elements examined) remain complete and capable of further retrotransposition. In contrast, each element in the centromere region has lost ≥ 40% of its sequence by internal, rather than terminal, deletions, and no element retains a significant part of the original coding region. Thus the centromeric array has been restructured to resemble the highly repetitive satellite sequences typical of centromeres in multicellular organisms, whereas, over a similar or longer time period, the telomere array has maintained its ability to provide retrotransposons competent to extend telomere ends.     

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.     

Structure of telomeric chromatin in <Emphasis Type="Italic">Drosophila</Emphasis>

The telomeric nucleoprotein complex protects linear chromosome ends from degradation. In contrast to most eukaryotes in which telomerase is responsible for telomere elongation by adding short DNA repeats synthesized using an RNA template, the telomere elongation in Drosophila involves transposition of specialized telomeric retroelements onto chromosome ends. Proteins that bind telomeric and subtelomeric sequences form specific telomeric chromatin, and its components are highly conserved among organisms employing different mechanisms of telomere elongation. This review is focused on the analysis of components of the Drosophila telomeric complex and its comparison with telomeric proteins in telomerase-encoded organisms. Structural and functional analysis of Drosophila telomeres suggests that there are three distinct chromatin regions: protective structure at the very end of chromosome (cap), subtelomeric region which is characterized by condensed chromatin structure, and the terminal retrotransposon array whose expression is under the control of an RNAi (RNA interference)-based mechanism. The link between RNAi and telomeric chromatin formation in germinal tissues is discussed.     

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.     

Sequencing and characterization of telomere and subtelomere regions on rice chromosomes 1S, 2S, 2L, 6L, 7S, 7L and 8S

Telomeres, which are important for chromosome maintenance, are composed of long, repetitive DNA sequences associated with a variety of telomere-binding proteins. We characterized the organization and structure of rice telomeres and adjacent subtelomere regions on the basis of cytogenetic and sequence analyses. The length of the rice telomeres ranged from 5.1 to 10.8 kb, as revealed by both fibre-fluorescent in situ hybridization and terminal restriction-fragment assay. Physical maps of the chromosomal ends were constructed from a fosmid library. This facilitated sequencing of the telomere regions of chromosomes 1S, 2S, 2L, 6L, 7S, 7L and 8S. The resulting sequences contained conserved TTTAGGG telomere repeats, which indicates that the physical maps partly covered the telomere regions of the respective chromosome arms. These repeats were organized in the order of 5'-TTTAGGG-3' from the chromosome-specific region, except in chromosome 7S, in which seven inverted copies also existed in tandem array. Analysis of the telomere-flanking regions revealed the occurrence of deletions, insertions, or chromosome-specific substitutions of single nucleotides within the repeat sequences at the junction between the telomere and subtelomere. The sequences of the 500-kb regions of the seven chromosome ends were analysed in detail. A total of 598 genes were predicted in the telomeric regions. In addition, repetitive sequences derived from various kinds of retrotransposon were identified. No significant evidence for segmental duplication could be detected within or among the subtelomere regions. These results indicate that the rice chromosome ends are heterogeneous in both sequence and characterization.     

Telomeric associated sequences of Drosophila recruit polycomb-group proteins in vivo and can induce pairing-sensitive repression

In Drosophila, relocation of a euchromatic gene near centromeric or telomeric heterochromatin often leads to its mosaic silencing. Nevertheless, modifiers of centromeric silencing do not affect telomeric silencing, suggesting that each location requires specific factors. Previous studies suggest that a subset of Polycomb-group (PcG) proteins could be responsible for telomeric silencing. Here, we present the effect on telomeric silencing of 50 mutant alleles of the PcG genes and of their counteracting trithorax-group genes. Several combinations of two mutated PcG genes impair telomeric silencing synergistically, revealing that some of these genes are required for telomeric silencing. In situ hybridization and immunostaining experiments on polytene chromosomes revealed a strict correlation between the presence of PcG proteins and that of heterochromatic telomeric associated sequences (TASs), suggesting that TASs and PcG complexes could be associated at telomeres. Furthermore, lines harboring a transgene containing an X-linked TAS subunit and the mini-white reporter gene can exhibit pairing-sensitive repression of the white gene in an orientation-dependent manner. Finally, an additional binding site for PcG proteins was detected at the insertion site of this type of transgene. Taken together, these results demonstrate that PcG proteins bind TASs in vivo and may be major players in Drosophila telomeric position effect (TPE).     

Chromatin regulation and non-coding RNAs at mammalian telomeres

In eukaryotes, terminal chromosome repeats are bound by a specialized nucleoprotein complex that controls telomere length and protects chromosome ends from DNA repair and degradation. In mammals the “shelterin” complex mediates these central functions at telomeres. In the recent years it has become evident that also the heterochromatic structure of mammalian telomeres is implicated in telomere length regulation. Impaired telomeric chromatin compaction results in a loss of telomere length control. Progressive telomere shortening affects chromatin compaction at telomeric and subtelomeric repeats and activates alternative telomere maintenance mechanisms. Dynamics of chromatin structure of telomeres during early mammalian development and nuclear reprogramming further indicates a central role of telomeric heterochromatin in organismal development. In addition, the recent discovery that telomeres are transcribed, giving rise to UUAGGG-repeat containing TelRNAs/TERRA, opens a new level of chromatin regulation at telomeres. Understanding the links between the epigenetic status of telomeres, TERRA/TelRNA and telomere homeostasis will open new avenues for our understanding of organismal development, cancer and ageing.