Transposable Elements and Genome Expansion in Cultivated and Wild Potato and Tomato Species

AbstractGenome sequence of Tricholoma matsutake was revealed as the one of the large fungal genomes published up to date at 189.0 Mbp with 15,305 predicted genes. The unusual size of this fungal genome contained frequent colonization of transposable elements (TEs) occupying more than half of the entire genome. We identified that 702 genes were surrounded by TEs and 83.2% of those genes were never transcribed at any development stage. This observation corroborated that the insertion of transposable elements alters the transcription of the genes neighboring TEs.Repeat-induced point mutation such as C to T hypermutation with a bias over ’CpG’ dinucleotides was also recognized in this genome, representing a typical defense mechanism against TEs during evolution. Many transcription factor genes were activated in both primordia and fruiting body, which indicates that many regulatory processes are shared during developmental stages. Small secreted protein genes (<300 aa) were dominantly transcribed in hyphae, where symbiotic interactions occur with hosts. Comparative analysis with 37 Agaricomycetes genomes revealed that IstB-like domain (PF01695) was conserved in taxonomically diverse mycorrhizal genomes, where the T. matsutake genome contained four copies of this domain. Three of the IstB-like genes were overexpressed in hyphae. In the CAZyme analysis, reduced CAZyme genes were found as other ectomycorrhizal genomes including a lot of loss of glycoside hydrolase genes. Also, auxiliary activity genes were dominantly transcribed in primordia. The T. matsutake genome sequence provides insight into the large genome size and clues to understand unusual fungal genome expansion.

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Transposable elements promote the evolution of genome streamlining

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2020.0477 ◽

2021 ◽

Vol 377 (1842) ◽

Cited By ~ 1

Author(s):

Bram van Dijk ◽

Frederic Bertels ◽

Lianne Stolk ◽

Nobuto Takeuchi ◽

Paul B. Rainey

Keyword(s):

Gene Transfer ◽

Horizontal Gene Transfer ◽

Transposable Elements ◽

Genome Size ◽

In Silico ◽

Mobile Genetic Elements ◽

Theme Issue ◽

Local Interactions ◽

Genetic Elements ◽

Genome Expansion

Eukaryotes and prokaryotes have distinct genome architectures, with marked differences in genome size, the ratio of coding/non-coding DNA, and the abundance of transposable elements (TEs). As TEs replicate independently of their hosts, the proliferation of TEs is thought to have driven genome expansion in eukaryotes. However, prokaryotes also have TEs in intergenic spaces, so why do prokaryotes have small, streamlined genomes? Using an in silico model describing the genomes of single-celled asexual organisms that coevolve with TEs, we show that TEs acquired from the environment by horizontal gene transfer can promote the evolution of genome streamlining. The process depends on local interactions and is underpinned by rock–paper–scissors dynamics in which populations of cells with streamlined genomes beat TEs, which beat non-streamlined genomes, which beat streamlined genomes, in continuous and repeating cycles. Streamlining is maladaptive to individual cells, but improves lineage viability by hindering the proliferation of TEs. Streamlining does not evolve in sexually reproducing populations because recombination partially frees TEs from the deleterious effects they cause. This article is part of the theme issue ‘The secret lives of microbial mobile genetic elements’.

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