Mycena genomes resolve the evolution of fungal bioluminescence.
Huei-Mien KeHsin-Han LeeChan-Yi Ivy LinYu-Ching LiuMin R LuJo-Wei Allison HsiehChiung-Chih ChangPei-Hsuan WuMei-Yeh Jade LuJeng-Yi LiGaus ShangRita Jui-Hsien LuLászló G NagyPao-Yang ChenHsiao-Wei KaoIsheng Jason TsaiPublished in: Proceedings of the National Academy of Sciences of the United States of America (2020)
Mushroom-forming fungi in the order Agaricales represent an independent origin of bioluminescence in the tree of life; yet the diversity, evolutionary history, and timing of the origin of fungal luciferases remain elusive. We sequenced the genomes and transcriptomes of five bonnet mushroom species (Mycena spp.), a diverse lineage comprising the majority of bioluminescent fungi. Two species with haploid genome assemblies ∼150 Mb are among the largest in Agaricales, and we found that a variety of repeats between Mycena species were differentially mediated by DNA methylation. We show that bioluminescence evolved in the last common ancestor of mycenoid and the marasmioid clade of Agaricales and was maintained through at least 160 million years of evolution. Analyses of synteny across genomes of bioluminescent species resolved how the luciferase cluster was derived by duplication and translocation, frequently rearranged and lost in most Mycena species, but conserved in the Armillaria lineage. Luciferase cluster members were coexpressed across developmental stages, with the highest expression in fruiting body caps and stipes, suggesting fruiting-related adaptive functions. Our results contribute to understanding a de novo origin of bioluminescence and the corresponding gene cluster in a diverse group of enigmatic fungal species.