Karen L. Traverse scite author profile

The emerging sequence of the heterochromatic portion of the Drosophila melanogaster genome, with the most recent update of euchromatic sequence, gives the first genome-wide view of the chromosomal distribution of the telomeric retrotransposons, HeT-A, TART, and Tahre. As expected, these elements are entirely excluded from euchromatin, although sequence fragments of HeT-A and TART 3Ј untranslated regions are found in nontelomeric heterochromatin on the Y chromosome. The proximal ends of HeT-A/TART arrays appear to be a transition zone because only here do other transposable elements mix in the array. The sharp distinction between the distribution of telomeric elements and that of other transposable elements suggests that chromatin structure is important in telomere element localization. Measurements reported here show (1) D. melanogaster telomeres are very long, in the size range reported for inbred mouse strains (averaging 46 kb per chromosome end in Drosophila stock 2057). As in organisms with telomerase, their length varies depending on genotype. There is also slight under-replication in polytene nuclei. (2) Surprisingly, the relationship between the number of HeT-A and TART elements is not stochastic but is strongly correlated across stocks, supporting the idea that the two elements are interdependent. Although currently assembled portions of the HeT-A/TART arrays are from the most-proximal part of long arrays, ∼61% of the total HeT-A sequence in these regions consists of intact, potentially active elements with little evidence of sequence decay, making it likely that the content of the telomere arrays turns over more extensively than has been thought.

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Promoting in Tandem: The Promoter for Telomere Transposon HeT-A and Implications for the Evolution of Retroviral LTRs

Danilevskaya

Arkhipova

Pardue

et al. 1997

Cell

116

100

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HeT-A elements are non-long terminal repeat (non-LTR) retrotransposons found in head-to-tail arrays on Drosophila chromosome ends, where they form telomeres. We report that HeT-A promoter activity is located in the 3' end of the element, unlike the 5' location seen for other non-LTR retrotransposons. In HeT-A arrays the 3' sequence of one element directs transcription of its downstream neighbor. Because the upstream promoter has the same sequence as the 3' end of the transcribed element, the HeT-A promoter is effectively equivalent to a 5' LTR in both structure and function. Retroviruses and LTR retrotransposons have their promoters and transcription initiation sites in their 5' LTRs. Thus HeT-A appears to have the structure of an evolutionary intermediate between non-LTR and LTR retrotransposons.

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Drosophila telomeres: new views on chromosome evolution

et al. 1996

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The Two Drosophila Telomeric Transposable Elements Have Very Different Patterns of Transcription

Danilevskaya

Traverse

Hogan

et al. 1999

Molecular and Cellular Biology

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The transposable elements HeT-A and TART constitute the telomeres of Drosophila chromosomes. Both are non-long terminal repeat (LTR) retrotransposons, sharing the remarkable property of transposing only to chromosome ends. In addition, strong sequence similarity of their gag proteins indicates that these coding regions share a common ancestor. These findings led to the assumption that HeT-A and TART are closely related. However, we now find that these elements produce quite different sets of transcripts. HeT-A produces only sense-strand transcripts of the full-length element, whereas TART produces both sense and antisense full-length RNAs, with antisense transcripts in more than 10-fold excess over sense RNA. In addition, features of TART sequence organization resemble those of a subclass of non-LTR elements characterized by unequal terminal repeats. Thus, the ancestral gag sequence appears to have become incorporated in two different types of elements, possibly with different functions in the telomere. HeT-A transcripts are found in both nuclear and cytoplasmic cell fractions, consistent with roles as both mRNA and transposition template. In contrast, both sense and antisense TART transcripts are almost entirely concentrated in nuclear fractions. Also, TART open reading frame 2 probes detect a cytoplasmic mRNA for reverse transcriptase (RT), with no similarity to TART sequence 5 or 3 of the RT coding region. This RNA could be a processed TART transcript or the product of a "free-standing" RT gene. Either origin would be novel. The distinctive transcription patterns of both HeT-A and TART are conserved in Drosophila yakuba, despite significant sequence divergence. The conservation argues that these sets of transcripts are important to the function(s) of HeT-A and TART.Telomeres in Drosophila melanogaster are composed of multiple copies of two non-long terminal repeat (LTR) retrotransposons, HeT-A and TART, instead of the short DNA repeats generated by telomerase on the chromosome ends of most eukaryotes (13,24). Successive transpositions of HeT-A and TART yield arrays of repeats that are larger and more irregular than the repeats produced by telomerase. Nevertheless, these transpositions are, in some sense, equivalent to the telomeregenerating action of telomerase; both telomerase and the transposition of HeT-A and TART extend chromosome ends by RNA-templated additions of specific sequences.HeT-A and TART share two features that distinguish them from other known retrotransposable elements. Both transpose only to the ends of chromosomes (apparently to any chromosome end in D. melanogaster), and each contains a large segment of untranslated sequence (Fig. 1). We have recently shown that, for HeT-A, each of these distinguishing features is also conserved in related species (10), even when phylogenetic separation is great enough for the HeT-A sequences to have diverged by nearly 50%. HeT-A and TART also have some significant differences. TART encodes its own reverse transcriptase (RT); HeT-A does not. However, HeT-A...

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Karen L. Traverse

Addition of telomere-associated HeT DNA sequences “heals” broken chromosome ends in Drosophila

Genomic organization of the Drosophila telomere retrotransposable elements

Promoting in Tandem: The Promoter for Telomere Transposon HeT-A and Implications for the Evolution of Retroviral LTRs

Drosophila telomeres: new views on chromosome evolution

The Two Drosophila Telomeric Transposable Elements Have Very Different Patterns of Transcription

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