TY  - JOUR
A1  - Stoof-Leichsenring, Kathleen Rosemarie
A1  - Pestryakova, Luidmila Agafyevna
A1  - Epp, Laura Saskia
A1  - Herzschuh, Ulrike
T1  - Phylogenetic diversity and environment form assembly rules for Arctic diatom genera
BT  - a study on recent and ancient sedimentary DNA
JF  - Journal of Biogeography
N2  - Aim This study investigates taxonomic and phylogenetic diversity in diatom genera to evaluate assembly rules for eukaryotic microbes across the Siberian tree line. We first analysed how phylogenetic distance relates to taxonomic richness and turnover. Second, we used relatedness indices to evaluate if environmental filtering or competition influences the assemblies in space and through time. Third, we used distance-based ordination to test which environmental variables shape diatom turnover. Location Yakutia and Taymyria, Russia: we sampled 78 surface sediments and a sediment core, extending to 7,000 years before present, to capture the forest-tundra transition in space and time respectively. Taxon Arctic freshwater diatoms. Methods We applied metabarcoding to retrieve diatom diversity from surface and core sedimentary DNA. The taxonomic assignment binned sequence types (lineages) into genera and created taxonomic (abundance of lineages within different genera) and phylogenetic datasets (phylogenetic distances of lineages within different genera). Results Contrary to our expectations, we find a unimodal relationship between phylogenetic distance and richness in diatom genera. We discern a positive relationship between phylogenetic distance and taxonomic turnover in spatially and temporally distributed diatom genera. Furthermore, we reveal positive relatedness indices in diatom genera across the spatial environmental gradient and predominantly in time slices at a single location, with very few exceptions assuming effects of competition. Distance-based ordination of taxonomic and phylogenetic turnover indicates that lake environment variables, like HCO3- and water depth, largely explain diatom turnover. Main conclusion Phylogenetic and abiotic assembly rules are important in understanding the regional assembly of diatom genera across lakes in the Siberian tree line ecotone. Using a space-time approach we are able to exclude the influence of geography and elucidate that lake environmental variables primarily shape the assemblies. We conclude that some diatom genera have greater capabilities to adapt to environmental changes, whereas others will be putatively replaced or lost due to the displacement of the Arctic tundra biome under recent global warming.
KW  - ancient sedimentary DNA
KW  - Arctic lakes
KW  - assembly rules
KW  - climate change
KW  - diatoms
KW  - environmental filtering
KW  - phylogenetic diversity
KW  - Siberian tree line
Y1  - 2020
U6  - https://doi.org/10.1111/jbi.13786
SN  - 0305-0270
SN  - 1365-2699
VL  - 47
IS  - 5
SP  - 1166
EP  - 1179
PB  - Wiley-Blackwell
CY  - Oxford
ER  - 
TY  - JOUR
A1  - König, Christian
A1  - Weigelt, Patrick
A1  - Taylor, Amanda
A1  - Stein, Anke
A1  - Dawson, Wayne
A1  - Essl, Franz
A1  - Pergl, Jan
A1  - Pyšek, Petr
A1  - Kleunen, Mark van
A1  - Winter, Marten
A1  - Chatelain, Cyrille
A1  - Wieringa, Jan J.
A1  - Krestov, Pavel
A1  - Kreft, Holger
T1  - Source pools and disharmony of the world’s island floras
JF  - Ecography
N2  - Island disharmony refers to the biased representation of higher taxa on islands compared to their mainland source regions and represents a central concept in island biology. Here, we develop a generalizable framework for approximating these source regions and conduct the first global assessment of island disharmony and its underlying drivers. We compiled vascular plant species lists for 178 oceanic islands and 735 mainland regions. Using mainland data only, we modelled species turnover as a function of environmental and geographic distance and predicted the proportion of shared species between each island and mainland region. We then quantified the over- or under-representation of families on individual islands (representational disharmony) by contrasting the observed number of species against a null model of random colonization from the mainland source pool, and analysed the effects of six family-level functional traits on the resulting measure. Furthermore, we aggregated the values of representational disharmony per island to characterize overall taxonomic bias of a given flora (compositional disharmony), and analysed this second measure as a function of four island biogeographical variables. Our results indicate considerable variation in representational disharmony both within and among plant families. Examples of generally over-represented families include Urticaceae, Convolvulaceae and almost all pteridophyte families. Other families such as Asteraceae and Orchidaceae were generally under-represented, with local peaks of over-representation in known radiation hotspots. Abiotic pollination and a lack of dispersal specialization were most strongly associated with an insular over-representation of families, whereas other family-level traits showed minor effects. With respect to compositional disharmony, large, high-elevation islands tended to have the most disharmonic floras. Our results provide important insights into the taxon- and island-specific drivers of disharmony. The proposed framework allows overcoming the limitations of previous approaches and provides a quantitative basis for incorporating functional and phylogenetic approaches into future studies of island disharmony.
KW  - assembly processes
KW  - biotic filtering
KW  - dispersal filtering
KW  - environmental filtering
KW  - generalized dissimilarity modelling
KW  - island disharmony
KW  - island syndromes
KW  - source regions
KW  - vascular plants
Y1  - 2020
VL  - 44
IS  - 1
PB  - Wiley-Blackwell
CY  - Oxford
ER  -