Diatom endemism and taxonomic turnover: Assessment in high-altitude alpine lakes covering a large geographical range

Abstract

Diatoms are widely used as ecological indicators and show various degrees of endemism. Many studies that support the idea of endemic species integrate several climate zones, a variety of ecosystem types, and often focus on a global scale. Here, we investigated whether endemism could be detected when considering a homogeneous type of ecosystem in a single climate zone.We sampled stone biofilms at 40–50 cm depth in high-altitude lakes in the Alpine climate zone. A total of 149 samples were obtained from the French and Georgian mountains, two areas separated by ∼3000 km. Using Amplicon Sequence Variants derived from DNA metabarcoding, we assessed taxonomic turnover and Zeta-diversity (a measure of endemism). We ran haplotype networks and phylogenetic tests to measure geographical signal in the phylogenies of dominant taxa.The French and Georgian communities shared 51 % of species. Species that were not shared across both regions were mostly rare, and often not characteristic of lakes but of neighboring habitats instead. In contrast, at the sub-species level, 87 % of the genotypes showed restricted distributions. Whereas endemism was the rule at sub-species level, most species were shared across both French and Georgian lakes, suggesting that geographic barriers strongly limited dispersal at the sub-species level but not species level. Dominant species hosted higher levels of sub-specific diversity than rare species. In contrast to global-scale studies, we did not find any significant geographical structuring in the phylogeny of the investigated species. This could indicate ongoing dispersal at a frequency fast enough to prevent allopatric divergence, yet slow enough to prevent sharing most haplotypes between France and Georgia. These results have implications for biomonitoring: depending on the taxonomic level chosen, robust generic tools (species level) or tools dedicated to a region able to discriminate fine pressures differences (sub-species level) may be developed.