Abstract
BackgroundTeleost fish genome size has been repeatedly demonstrated to positively correlate with the proportion of transposable elements (TEs). This finding might have far-reaching implications for our understanding of the evolution of nucleotide composition across vertebrates. Genomes of fish and amphibians are GC homogenous, with non-teleost gars being the single exception identified to date, whereas birds and mammals are AT/GC heterogeneous. The exact reason for this phenomenon remains controversial. Since TEs make up significant proportions of genomes and can quickly accumulate across genomes, they can potentially influence the host genome with their own GC content (GC%). However, the GC% of fish TEs has so far been neglected.ResultsThe genomic proportion of TEs indeed correlates with genome size, although not as linearly as previously shown with fewer genomes, and GC% negatively correlates with genome size in the 33 fish genome assemblies analysed here (excluding salmonids). GC% of fish TE consensus sequences positively correlates with the corresponding genomic GC% in 29 species tested. Likewise, the GC contents of the entire repetitive vs. non-repetitive genomic fractions correlate positively in 54 fish species in Ensembl. However, among these fish species, there is also a wide variation in GC% between the main groups of TEs. Class II DNA transposons, predominant TEs in fish genomes, are significantly GC-poorer than Class I retrotransposons. The AT/GC heterogeneous gar genome contains fewer Class II TEs, a situation similar to fugu with its extremely compact and also GC-enriched but AT/GC homogenous genome.ConclusionOur results reveal a previously overlooked correlation between GC% of fish genomes and their TEs. This applies to both TE consensus sequences as well as the entire repetitive genomic fraction. On the other hand, there is a wide variation in GC% across fish TE groups. These results raise the question whether GC% of TEs evolves independently of GC% of the host genome or whether it is driven by TE localization in the host genome. Answering these questions will help to understand how genomic GC% is shaped over time. Long-term accumulation of GC-poor(er) Class II DNA transposons might indeed have influenced AT/GC homogenization of fish genomes and requires further investigation.
Highlights
Teleost fish genome size has been repeatedly demonstrated to positively correlate with the proportion of transposable elements (TEs)
We included the spotted gar (Lepisosteus oculatus), i.e., a deepbranching non-teleost ray-finned fish that has not undergone any further wholegenome duplication (WGD) after the two basal vertebrate ones but that shows the mammalian-like situation of AT/GC heterogeneity [36]
Here we have shown that nucleotide composition of TEs and their interplay with host genomes is an unexplored part of genome biology
Summary
Teleost fish genome size has been repeatedly demonstrated to positively correlate with the proportion of transposable elements (TEs). This finding might have far-reaching implications for our understanding of the evolution of nucleotide composition across vertebrates. 41–45% of GC, H2 46–52% and the “heaviest” H3 with > 53% of GC [2] In this regard, fish and amphibian genomes are overall AT/GC homogenous because they contain only the GC-poor(er) isochores with a substantially narrower range of GC%, i.e., usually only two neighbouring ones such as L1 and L2 or L2 and H1. Avian and mammalian genomes contain all five isochores and their broad range of GC% results in overall GC heterogeneity [2]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
