![Fig. 1. Map of sampling sites in the Atlantic Baltic-Sea transect and respective species distributions of Ulva spp.. (A) Overview map of the Atlantic-Baltic Sea transect with respective sea surface salinity. Visualization of the salinity gradient within the Baltic Sea by isohalines with particular salinity values (PSU) in circles (HELCOMdata) dropping with increasing distance from the North Sea. Red dots mark sample sites which represent the whole salinity gradient of the area. Insets B -I provide the distribution of Ulva spp. in the Atlantic-Baltic Sea transect, genetically verified within this study. The distribution of (B) U. intestinalis and U. linza, (C) U. compressa and U. prolifera, (D) U. lacinulata and U. torta, (E) U. flexuosa and U. gigantea, (F) U. fenestrata [dark and light red], U. australis [dark red], and U. californica [dark red], (G) Ulva sp. 2 [U. capillata] and Ulva sp. 3, (H) Ulva sp. 6 and Ulva sp. 8, and (I) Ulva sp. 1 (red dots), Ulva sp., 4 (orange dots), Ulva sp. 5 (yellow dots), Ulva sp. 7 (light green), Ulva sp. 9 (dark green), is presented. Full data is available in supplementary Table S1. (For interpretation of the references to colour in this figure legend, the reader is referred to the web version of this article.)](https://www.researchgate.net/profile/Sophie-Steinhagen/publication/370562169/figure/fig1/AS:11431281172120093@1688467718284/Map-of-sampling-sites-in-the-Atlantic-Baltic-Sea-transect-and-respective-species_Q320.jpg)
May 2023
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245 Reads
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19 Citations
Algal Research
Correct species identification is fundamental for assessment and understanding of biodiversity. Erroneous species identification may impede conservation management and may delay detection of invasive species. The ubiqui- tous green algal genus Ulva is known for its wide environmental tolerance, plastic morphology, occurrence of cryptic species and ambiguous species concepts that hinder clear identification. We used molecular monitoring to assess species diversity and distribution of Ulva along the full Atlantic-Baltic Sea salinity gradient (> 10,000 km). Ulva specimens were collected from Denmark, Finland, Germany, Norway, and Sweden. DNA barcoding analysis of the tufA gene revealed 20 genetic entities in total, of which 11 could be identified to species level (U. californica, U. flexuosa, U. torta, U. linza, U. prolifera, U. fenestrata, U. australis, U. intestinalis, U. compressa, U. gigantea, U. lacinulata). Nine entities (Ulva sp. 1–9; [Ulva capillata]) yielded novel sequence reads that belonged to either unidentified species, species complexes, or singletons. At least 3 of the discovered species (U. australis, U. californica, U. gigantea) are considered non-native and potentially invasive. Furthermore, considerable differences between the observed and the historically estimated species distributions were found. The highest diversity was recorded in the Atlantic and Skagerrak region whereas only two entities of taxo- nomically accepted species where found north-east the Blekinge coast. Our study shows that the species diversity of Ulva in the study area is diverging from previous reports, and that molecular methods are imperative for species identification in this morphologically plastic genus. Furthermore, the presence of non-native species indicates a necessity for further fine-scale monitoring in specific areas to e.g. mitigate formation of green tides.