Abstract
Species delimitation in protists is still a challenge, attributable to the fact that protists are small, difficult to observe and many taxa are poor in morphological characters, whereas most current phylogenetic approaches only use few marker genes to measure genetic diversity. To address this problem, we assess genome-level divergence and microevolution in strains of the protist Poteriospumella lacustris, one of the first free-living, nonmodel organisms to study genome-wide intraspecific variation. Poteriospumella lacustris is a freshwater protist belonging to the Chrysophyceae with an assumed worldwide distribution. We examined three strains from different geographic regions (New Zealand, China, and Austria) by sequencing their genomes with the Illumina and PacBio platforms.The assembled genomes were small with 49–55 Mb but gene-rich with 16,000–19,000 genes, of which ∼8,000 genes could be assigned to functional categories. At least 68% of these genes were shared by all three species. Genetic variation occurred predominantly in genes presumably involved in ecological niche adaptation. Most surprisingly, we detected differences in genome ploidy between the strains (diploidy, triploidy, and tetraploidy).In analyzing intraspecific variation, several mechanisms of diversification were identified including SNPs, change of ploidy and genome size reduction.
Highlights
Genetic variation permits flexibility and survival of a population under changing environmental conditions (Reed and Frankham 2003) and leads over time to genetic differences between strains or populations from different geographic regions or environments
Poteriospumella lacustris is a freshwater protist belonging to the Chrysophyceae with an assumed worldwide distribution
We examined three strains from different geographic regions (New Zealand, China, and Austria) by sequencing their genomes with the Illumina and PacBio platforms
Summary
Genetic variation permits flexibility and survival of a population under changing environmental conditions (Reed and Frankham 2003) and leads over time to genetic differences between strains or populations (diversification) from different geographic regions or environments. Genetic variation provides insights into the evolutionary history of a species (Knoll 1994; Darling et al 2004). Recent studies of intraspecific genetic variation using DNA fingerprinting techniques in aquatic phytoplankton have identified high levels of diversity. Several further studies demonstrated a surprisingly high intraspecific genetic diversity in both marine and limnic species (John et al 2004; Evans et al 2005; Rynearson and Armbrust 2005; Hayhome et al 2007). These experiments were all based on microsatellites or DNA fingerprinting and reflect only a small part of the entire intraspecific variation in microeukaryotes
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
