Shared features underlying compact genomes and extreme habitat use in chironomid midges

Abstract

AbstractNon-biting midges (family Chironomidae) are found throughout the world in a diverse array of aquatic and terrestrial habitats, can often tolerate harsh conditions such as hypoxia or desiccation, and have consistently compact genomes. Yet we know little about the shared molecular basis for these attributes and how they have evolved across the family. Here, we address these questions by first creating high-quality, annotated reference assemblies forTanytarsus gracilentus(subfamily Chironominae, tribe Tanytarsini) andParochlus steinenii(subfamily Podonominae). Using these and other publicly available assemblies, we created a time-calibrated phylogenomic tree for family Chironomidae with outgroups from order Diptera. We used this phylogeny to test for features associated with compact genomes, as well as examining patterns of gene family evolution and positive selection that may underlie chironomid habitat tolerances. Our results suggest that compact genomes evolved in the most recent common ancestor of Chironomidae and Ceratopogonidae, and that this occurred mainly through reductions in non-coding regions (introns, intergenic sequences, and repeat elements). Gene families that significantly expanded in Chironomidae included biological processes that may relate to tolerance of stressful environments, such as temperature homeostasis, inflammatory response, melanization defense response, and trehalose transport. We identified a number of genes with evidence for positive selection in Chironomidae, notably sulfonylurea receptor, peroxiredoxin-1, and protein kinase D. Our results help to understand the genomic basis for the small genomes and extreme habitat use in this widely distributed group.Significance StatementChironomid midges are known for having small genomes and being able to tolerate many forms of environmental stress, yet little is known of the shared features of their genomes that may underlie these traits. We found that reductions in non-coding regions coincide with small chironomid genomes, and we identified duplicated and/or selected genes that may equip chironomids to tolerate harsh conditions. These results describe the key genomic changes in chironomid midges that may explain their ability to inhabit a range of extreme habitats across the world.