Abstract
BackgroundRetrotransposons are transposable elements that proliferate within eukaryotic genomes through a process involving reverse transcription. The numbers of retrotransposons within genomes and differences between closely related species may yield insight into the evolutionary history of the elements. Less is known about the ongoing dynamics of retrotransposons, as analysis of genome sequences will only reveal insertions of retrotransposons that are fixed - or near fixation - in the population or strain from which genetic material has been extracted for sequencing. One pre-requisite for retrotransposition is transcription of the elements. Given their intrinsic sequence redundancy, transcriptome-level analyses of transposable elements are scarce. We have used recently published transcriptome data from the fission yeast Schizosaccharomyces pombe to assess the ability to detect and describe transcriptional activity from Long Terminal Repeat (LTR) retrotransposons. LTR retrotransposons are normally flanked by two LTR sequences. However, the majority of LTR sequences in S. pombe exist as solitary LTRs, i.e. as single terminal repeat sequences not flanking a retrotransposon. Transcriptional activity was analysed for both full-length LTR retrotransposons and solitary LTRs.ResultsTwo independent sets of transcriptome data reveal the presence of full-length, polyadenylated transcripts from LTR retrotransposons in S. pombe during growth phase in rich medium. The redundancy of retrotransposon sequences makes it difficult to assess which elements are transcriptionally active, but data strongly indicates that only a subset of the LTR retrotransposons contribute significantly to the detected transcription. A considerable level of reverse strand transcription is also detected. Equal levels of transcriptional activity are observed from both strands of solitary LTR sequences. Transcriptome data collected during meiosis suggests that transcription of solitary LTRs is correlated with the transcription of nearby protein-coding genes.ConclusionsPresumably, the host organism negatively regulates proliferation of LTR retrotransposons. The finding of considerable transcriptional activity of retrotransposons suggests that part of this regulation is likely to take place at a post-transcriptional level. Alternatively, the transcriptional activity may signify a hitherto unrecognized activity level of retrotransposon proliferation. Our findings underline the usefulness of transcriptome data in elucidating dynamics in retrotransposon transcription.
Highlights
Retrotransposons are transposable elements that proliferate within eukaryotic genomes through a process involving reverse transcription
From a biological point of view, we are interested in distinguishing between transcriptional activity stemming from full-length Long Terminal Repeat (LTR) retrotransposons and from solitary LTRs
Analysis of transcriptional activity was performed on these two sets of LTRs separately: 13 full-length LTR retrotransposons and the remaining 214 solitary LTR sequences
Summary
Retrotransposons are transposable elements that proliferate within eukaryotic genomes through a process involving reverse transcription. We have used recently published transcriptome data from the fission yeast Schizosaccharomyces pombe to assess the ability to detect and describe transcriptional activity from Long Terminal Repeat (LTR) retrotransposons. Transcriptional activity was analysed for both full-length LTR retrotransposons and solitary LTRs. With only a few exceptions [1,2], retrotransposons have been found in all analysed eukaryotic genomes. Repair genes (rec and rad) a) Number of sequences in set b) HybMap 60-mers mapping to sequence sets Both forward and reverse strand probes included. When plotting the signal intensities of uniquely mapping probes (red circles in Figure 2), we see that these are highly skewed towards higher intensities, suggesting that only a small number of LTR retrotransposon loci contribute to the combined transcriptional activity, and concurrently, that these retrotransposons are transcribed at high levels. The notable exceptions of two areas covering parts of the Reverse
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