Download This Paper
Group II Introns in Archaeal Genomes and the Evolutionary Origin of Eukaryotic Spliceosomal Introns
38 Pages Posted: 19 Feb 2025 Publication Status: Review Complete
More...Abstract
A key attribute of eukaryotic genomes is the presence of abundant spliceosomal introns that break up many protein-coding genes into multiple exons and must be spliced out during the process of gene expression. Spliceosomal introns are related to, but clearly distinct from bacterial group II introns. One prominent hypothesis is that the spliceosomal intron arose after the endosymbiotic origin of the mitochondrion subsequent to the transfer of genes containing group II introns from the mitochondrial to nuclear genome. In this model, transfer of group II introns into the ancestral eukaryotic genome from the mitochondrion set the stage for evolution of the spliceosomal form. However, the recent discovery and sequencing of asgard archaea (Promethearcheati) — the closest archaeal relatives of extant eukaryotes — has shed new light on the likely composition of the early eukaryotic genome and calls that model into question. Using sequence analysis and structural modeling, we show here the presence of group II intron maturases in the genomes of Heimdallarchaeia and other asgard archaea. We demonstrate by phylogenetic inference that these are closely related to both eukaryotic mitochondrial group II intron maturases and the spliceosome protein PRP8. This suggests that the first intron-containing eukaryotic common ancestor (FIECA) inherited selfish group II introns from its ancestral archaeal genome – the progenitor of the nuclear genome – rather than from the mitochondrial endosymbiont. These observations suggest that the spread and diversification of introns may have occurred independently of the acquisition of the mitochondrion. To better understand the context for intron evolution, we investigate the broader occurrence of group II introns in archaea, identify archaeal clades enriched in group II introns, and perform structural modeling to examine the relationship between the archaeal group II intron maturase and the eukaryotic spliceosome. We propose a model of intron acquisition and expansion during early eukaryotic evolution that places the spread of introns prior to the acquisition of mitochondria, possibly facilitated by the separation of transcription and translation afforded by the nucleus.
Keywords: Introns, Selfish elements, eukaryogenesis, Asgard, archaea, phylogeny
Suggested Citation: Suggested Citation