| Literature DB >> 33539889 |
Laura Helou1, Linda Beauclair1, Hugues Dardente1, Benoît Piégu1, Louis Tsakou-Ngouafo2, Thierry Lecomte3, Alex Kentsis4, Pierre Pontarotti5, Yves Bigot6.
Abstract
The vertebrate piggyBac derived transposase 5 (PGBD5) encodes a domesticated transposase, which is active and able to transpose its distantly related piggyBac-like element (pble), Ifp2. This raised the question whether PGBD5 would be more effective at mobilizing a phylogenetically closely related pble element. We aimed to identify the pble most closely related to the pgbd5 gene. We updated the landscape of vertebrate pgbd genes to develop efficient filters and identify the most closely related pble to each of these genes. We found that Tcr-pble is phylogenetically the closest pble to the pgbd5 gene. Furthermore, we evaluated the capacity of two murine and human PGBD5 isoforms, Mm523 and Hs524, to transpose both Tcr-pble and Ifp2 elements. We found that both pbles could be transposed by Mm523 with similar efficiency. However, integrations of both pbles occurred through both proper transposition and improper PGBD5-dependent recombination. This suggested that the ability of PGBD5 to bind both pbles may not be based on the primary sequence of element ends, but may involve recognition of inner DNA motifs, possibly related to palindromic repeats. In agreement with this hypothesis, we identified internal palindromic repeats near the end of 24 pble sequences, which display distinct sequences.Entities:
Keywords: DNA binding; domestication; molecular evolution; transposable element; transposition
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Year: 2021 PMID: 33539889 PMCID: PMC8404143 DOI: 10.1016/j.jmb.2021.166839
Source DB: PubMed Journal: J Mol Biol ISSN: 0022-2836 Impact factor: 5.469