Abstract
Meiotic drive elements cause their own preferential transmission following meiosis. In fungi, this phenomenon takes the shape of spore killing, and in the filamentous ascomycete Neurospora sitophila, the Sk-1 spore killer element is found in many natural populations. In this study, we identify the gene responsible for spore killing in Sk-1 by generating both long- and short-read genomic data and by using these data to perform a genome-wide association test. We name this gene Spk-1 Through molecular dissection, we show that a single 405-nt-long open reading frame generates a product that both acts as a poison capable of killing sibling spores and as an antidote that rescues spores that produce it. By phylogenetic analysis, we demonstrate that the gene has likely been introgressed from the closely related species Neurospora hispaniola, and we identify three subclades of N. sitophila, one where Sk-1 is fixed, another where Sk-1 is absent, and a third where both killer and sensitive strain are found. Finally, we show that spore killing can be suppressed through an RNA interference-based genome defense pathway known as meiotic silencing by unpaired DNA. Spk-1 is not related to other known meiotic drive genes, and similar sequences are only found within Neurospora These results shed light on the diversity of genes capable of causing meiotic drive, their origin and evolution, and their interaction with the host genome.
Highlights
| | | meiotic drive genomic conflict spore killer Neurospora different functional domains [10]
Spk-1 is a class of spore killer genes and we demonstrate that RNA interference (RNAi) can protect against meiotic drivers in fungi
We have identified the gene responsible for the Sk-1 spore killer phenotype in N. sitophila
Summary
| | | meiotic drive genomic conflict spore killer Neurospora different functional domains [10]. In Schizosaccharomyces pombe, the large and highly diverse wtf gene family causes drive by producing poison and antidote products from overlapping transcripts generated from two different start codons [12, 13]. As exemplified by the wtf genes, meiotic drive can often reduce the fertility of the organism This puts the KMD in conflict with the rest of the genome, and suppressors are expected to evolve. In order to successfully drive, the poison and antidote must always be inherited together and a target must never be inherited with a killer For this reason many KMDs are found in regions of low recombination, such as inversions or on sex chromosomes [6,7,8]. These results shed light on the diversity of selfish genes in terms of origin, evolution, and host interactions
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