Abstract
BackgroundTelomere replication in Drosophila depends on the transposition of a domesticated retroelement, the HeT-A retrotransposon. The sequence of the HeT-A retrotransposon changes rapidly resulting in differentiated subfamilies. This pattern of sequence change contrasts with the essential function with which the HeT-A is entrusted and brings about questions concerning the extent of sequence variability, the telomere contribution of different subfamilies, and whether wild type and mutant Drosophila stocks show different HeT-A scenarios.ResultsA detailed study on the variability of HeT-A reveals that both the level of variability and the number of subfamilies are higher than previously reported. Comparisons between GIII, a strain with longer telomeres, and its parental strain Oregon-R indicate that both strains have the same set of HeT-A subfamilies. Finally, the presence of a highly conserved splicing pattern only in its antisense transcripts indicates a putative regulatory, functional or structural role for the HeT-A RNA. Interestingly, our results also suggest that most HeT-A copies are actively expressed regardless of which telomere and where in the telomere they are located.ConclusionsOur study demonstrates how the HeT-A sequence changes much faster than previously reported resulting in at least nine different subfamilies most of which could actively contribute to telomere extension in Drosophila. Interestingly, the only significant difference observed between Oregon-R and GIII resides in the nature and proportion of the antisense transcripts, suggesting a possible mechanism that would in part explain the longer telomeres of the GIII stock.
Highlights
Telomere replication in Drosophila depends on the transposition of a domesticated retroelement, the HeT-A retrotransposon
HeT-A sequence variability Available information on telomere composition in Drosophila is partial (Additional files 1, 2); in order to investigate the nature and the extent of sequence variability in HeT-A, we decided to carry out a genome wide study analyzing two different regions along the retrotransposon, inside the HeT-A ORF and the 3’ Untranslated Region (UTR)
We demonstrate that the size variability is due to several splicing processes to which most antisense transcripts (91% in GIII and 74% in Oregon-R) are subjected
Summary
Telomere replication in Drosophila depends on the transposition of a domesticated retroelement, the HeT-A retrotransposon. The sequence of the HeT-A retrotransposon changes rapidly resulting in differentiated subfamilies. Instead of using the telomerase holoenzyme as most eukaryotes, Drosophila replenishes the telomeres by specific transpositions onto the end of the chromosomes of three retrotransposons, HeT-A, TART and TAHRE [1,2]. Previous studies have attempted to classify the genomic copies of the HeT-A element in several subfamilies according to their variability in the 3’UTR [6] and in the ORF [7]. These studies found four subfamilies considering ORF variability and two considering 3’UTR variability. Taking into account that those studies were based in a limited number of genomic copies, our first objective was to perform an exhaustive survey at genomic level in order to obtain a more accurate picture of the real variability of the HeT-A element
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