Genome-wide patterns of transposon proliferation in an evolutionary young hybrid fish

Dennenmoser, S., Sedlazeck, F. J., Schatz, M. C., Altmuller, J., Zytnicki, M., Nolte, A. W. (December 2018) Genome-wide patterns of transposon proliferation in an evolutionary young hybrid fish. Mol Ecol, 28 (6). pp. 1491-1505. ISSN 0962-1083

Abstract

Hybridization can induce transposons to jump into new genomic positions, which may result in their accumulation across the genome. Alternatively, transposon copy numbers may increase through non-allelic (ectopic) homologous recombination in highly repetitive regions of the genome. The relative contribution of transposition bursts versus recombination-based mechanisms to evolutionary processes remains unclear because studies on transposon dynamics in natural systems are rare. We assessed the genome-wide distribution of transposon insertions in a young hybrid lineage ("invasive Cottus", n=11) and its parental species Cottus rhenanus (n=17) and Cottus perifretum (n=9) using a reference genome assembled from long single molecule PacBio reads. An inventory of transposable elements was reconstructed from the same data and annotated. Transposon copy numbers in the hybrid lineage increased in 120 (15.9%) out of 757 transposons studied here. The copy number increased on average by 69% (range: 10 - 197%). Given the age of the hybrid lineage, this suggests that they have proliferated within a few hundred generations since admixture began. However, frequency spectra of transposon insertions revealed no increase of novel and rare insertions across assembled parts of the genome. This implies that transposons were added to repetitive regions of the genome that remain difficult to assemble. Future studies will need to evaluate whether recombination-based mechanisms rather than genome-wide transposition may explain the majority of the recent transposon proliferation in the hybrid lineage. Irrespectively of the underlying mechanism, the observed over-abundance in repetitive parts of the genome suggests that gene-rich regions are unlikely to be directly affected. This article is protected by copyright. All rights reserved.

Item Type:	Paper
Subjects:	bioinformatics bioinformatics > genomics and proteomics > genetics & nucleic acid processing > DNA, RNA structure, function, modification > DNA expression bioinformatics > genomics and proteomics > genetics & nucleic acid processing > DNA, RNA structure, function, modification bioinformatics > genomics and proteomics > genetics & nucleic acid processing bioinformatics > genomics and proteomics Investigative techniques and equipment organism description > animal Investigative techniques and equipment > assays organism description > animal > fish organism description > plant bioinformatics > genomics and proteomics > genetics & nucleic acid processing > DNA, RNA structure, function, modification > DNA expression > transposable elements Investigative techniques and equipment > assays > whole genome sequencing
CSHL Authors:	Schatz, Michael C.
Communities:	CSHL labs > Schatz lab
Depositing User:	Matthew Dunn
Date:	5 December 2018
Date Deposited:	20 Dec 2018 19:39
Last Modified:	20 Feb 2024 18:32
Related URLs:	https://onlinelibrary.wiley.com/doi/10.1...
URI:	https://repository.cshl.edu/id/eprint/37515

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