Sequencing, Chromosome-scale Assembly, and Annotation of the Genome of the Halophilic Nanoflagellate Halocafeteria seosinensis
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Compared with bacterial and archaeal extremophiles, single-celled eukaryotes living in extreme habitats are understudied and underrepresented in genomic databases. An exception is the obligately halophilic stramenopile Halocafeteria seosinensis strain EHF34. A transcriptome-focused analysis of this extremophilic protist s revealed the importance of organic osmolyte regulation and transport in its adaptation to hypersaline environments. However, genomic resources for H. seosinensis are currently limited to a highly fragmented assembly generated by short-read sequencing, which has hindered further investigation of the genome biology and evolution of this fascinating organism. Here, we used long-read Oxford Nanopore sequencing to generate a highly contiguous, chromosome-scale genome assembly for H. seosinensis . The assembly is 38.8 megabase pairs (Mbp) in size and contains 60 nuclear contigs, making it the most contiguous genome for a member of the order Bicosoecida. Approximately 19% of the genome is comprised of transposable elements. Of the 11,684 predicted protein-coding genes, many appear to be associated with DNA mobility-related functions, and several may be linked to adaptation to a hypersaline environment. Analysis of the H. seosinensis long-read genome assembly presented herein will facilitate our understanding of the ways in which protists have adapted to extreme environments.
Significance
Halocafeteria seosinensis is an extremophilic protist adapted to hypersaline environments. Previous analyses of a transcriptome and short-read draft genome assembly for this organism provided insights into the molecular mechanisms underlying osmotic regulation, which facilitate its adaptation to high-salt conditions. However, the lack of contiguity and quality of the draft assembly prevented the characterization of complex genomic regions, including transposable elements and viral insertions, as well as genomic comparisons with related species. Here we present a highly contiguous, chromosome-scale genome assembly for H. seosinensis that enables accurate gene prediction, detailed analysis of repeat content, and comparative genomic analysis. This long-read genome assembly will serve as a valuable resource for studying one of the few tractable halophilic protists sequenced to date.