High quality genome assembly of the anhydrobiotic midge provides insights on a single chromosome-based emergence of extreme desiccation tolerance.
Yuki YoshidaNurislam ShaikhutdinovOlga S KozlovaMasayoshi ItohMichihira TagamiMitsuyoshi MurataHiromi Nishiyori-SuekiMiki Kojima-IshiyamaShohei NomaAlexander CherkasovGuzel GazizovaAigul NasibullinaRuslan M DeviatiiarovElena I ShagimardanovaAlina RyabovaKatsushi YamaguchiTakahiro BinoShuji ShigenobuShoko TokumotoYugo MiyataRichard CornetteTakahiro G YamadaAkira FunahashiMasaru TomitaOleg A GusevTakahiro KikawadaPublished in: NAR genomics and bioinformatics (2022)
Non-biting midges (Chironomidae) are known to inhabit a wide range of environments, and certain species can tolerate extreme conditions, where the rest of insects cannot survive. In particular, the sleeping chironomid Polypedilum vanderplanki is known for the remarkable ability of its larvae to withstand almost complete desiccation by entering a state called anhydrobiosis. Chromosome numbers in chironomids are higher than in other dipterans and this extra genomic resource might facilitate rapid adaptation to novel environments. We used improved sequencing strategies to assemble a chromosome-level genome sequence for P. vanderplanki for deep comparative analysis of genomic location of genes associated with desiccation tolerance. Using whole genome-based cross-species and intra-species analysis, we provide evidence for the unique functional specialization of Chromosome 4 through extensive acquisition of novel genes. In contrast to other insect genomes, in the sleeping chironomid a uniquely high degree of subfunctionalization in paralogous anhydrobiosis genes occurs in this chromosome, as well as pseudogenization in a highly duplicated gene family. Our findings suggest that the Chromosome 4 in Polypedilum is a site of high genetic turnover, allowing it to act as a 'sandbox' for evolutionary experiments, thus facilitating the rapid adaptation of midges to harsh environments.