Chromosome-scale genome assembly of the rough periwinkleLittorina saxatilis

Abstract

AbstractThe intertidal gastropodLittorina saxatilisis a model system to study speciation and local adaptation. The repeated occurrence of distinct ecotypes showing different levels of genetic divergence makesL. saxatilisparticularly suited to study different stages of the speciation continuum in the same lineage. A major finding is the presence of several large chromosomal inversions associated with the divergence of ecotypes and, specifically, the species offers a system to study the role of inversions in this divergence. The genome ofL. saxatilisis 1.35Gb and composed of 17 chromosomes. The first reference genome of the species was assembled using Illumina data, was highly fragmented (N50 of 44kb) and was quite incomplete, with a BUSCO completeness of 80.1% on the Metazoan dataset. A linkage map of one full-sibling family enabled the placement of 587 Mbp of the genome into 17 linkage groups corresponding to the haploid number of chromosomes, but the fragmented nature of this reference genome limited the understanding of the interplay between divergent selection and gene flow during ecotype formation. Here we present a newly generated reference genome that is highly contiguous, with a N50 of 67 Mb and 90.4% of the total assembly length placed in 17 super-scaffolds. It is also highly complete with a BUSCO completeness of 94.1 % of the Metazoa dataset. This new reference will allow for investigations into the genomic regions implicated in ecotype formation as well as better characterization of the inversions and their role in speciation.SignificanceThe rough periwinkle,L. saxatilishas become a model to study adaptation, evolutionary innovation and speciation, including the role of chromosomal inversions in these processes. Chromosomal inversions have also been identified in other species ofLittorinaproviding a valuable opportunity for investigating their origin and evolution. Here, we present a new chromosome-scale reference genome ofL. saxatilisgenerated from long reads and HiC chromatin proximity mapping replacing an earlier highly fragmented genome. This will enable detailed investigations of how inversions contribute to adaptation and reproductive isolation inL. saxatilisand related taxa, including studies of the effects of individual loci within and outside inversions.