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@inproceedings{1527963, author = {Lexa, Matej and Lapár, Radovan and Jedlička, Pavel and Vanát, Ivan and Červeňanský, Michal and Kejnovský, Eduard}, address = {Neuveden}, booktitle = {Proceedings 2018 IEEE International Conference on Bioinformatics and Biomedicine (BIBM)}, doi = {http://dx.doi.org/10.1109/BIBM.2018.8621071}, editor = {Zheng Huiru}, keywords = {bioinformatics; software; LTR-retrotransposons; sequence analysis; genome evolution}, howpublished = {elektronická verze "online"}, language = {eng}, location = {Neuveden}, isbn = {978-1-5386-5488-0}, pages = {2776-2778}, publisher = {IEEE}, title = {TE-nester: a recursive software tool for structure-based discovery of nested transposable elements}, year = {2018} }
TY - JOUR ID - 1527963 AU - Lexa, Matej - Lapár, Radovan - Jedlička, Pavel - Vanát, Ivan - Červeňanský, Michal - Kejnovský, Eduard PY - 2018 TI - TE-nester: a recursive software tool for structure-based discovery of nested transposable elements PB - IEEE CY - Neuveden SN - 9781538654880 KW - bioinformatics KW - software KW - LTR-retrotransposons KW - sequence analysis KW - genome evolution N2 - ukaryotic genomes are generally rich in repetitive sequences. LTR retrotransposons are the most abundant class of repetitive sequences in plant genomes. They form segments of genomic sequences that accumulate via individual events and bursts of retrotransposition. A limited number of tools exist that can identify fragments of repetitive sequences that likely originate from a longer, originally unfragmented element, using mostly sequence similarity to guide reconstruction of fragmented sequences. Here, we use a slightly different approach based on structural (as opposed to sequence similarity) detection of unfragmented full-length elements, which are then recursively eliminated from the analyzed sequence to repeatedly uncover unfragmented copies hidden underneath more recent insertions. This approach has the potential to detect relatively old and highly fragmented copies. We created a software tool for this kind of analysis called TE-nester and applied it to a number of assembled plant genomes to discover pairs of nested LTR retrotransposons of various age and fragmentation state. TEnester will allow us to test hypotheses about genome evolution, TE life cycle and insertion history. The software, still under improvement, is available for download from a repository at https://gitlab.fi.muni.cz/lexa/nested. ER -
LEXA, Matej, Radovan LAPÁR, Pavel JEDLIČKA, Ivan VANÁT, Michal ČERVEŇANSKÝ and Eduard KEJNOVSKÝ. TE-nester: a recursive software tool for structure-based discovery of nested transposable elements. Online. In Zheng Huiru. \textit{Proceedings 2018 IEEE International Conference on Bioinformatics and Biomedicine (BIBM)}. Neuveden: IEEE, 2018, p.~2776-2778. ISBN~978-1-5386-5488-0. Available from: https://dx.doi.org/10.1109/BIBM.2018.8621071.
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