10.18710/4UCFSFDybsland, Cecilie SævdalCecilie SævdalDybslandUniversity of BergenEnerstvedt, Kjersti HasleKjersti HasleEnerstvedt0000-0003-1810-0571University of BergenJordheim, MonicaMonicaJordheim0000-0002-6804-921XUniversity of BergenReplication Data for: Variation in Phenolic Chemistry in Zostera marina Seagrass along Environmental GradientsDataverseNO2021ChemistryFlavonoidrosmarinic acidPolyphenolic contentanalytical HPLCUV spectroscopyquantitative analysisZostera marinaphenolic chemistryseagrass monitoringsulfated flavonoidschemical ecologymarine natural productsmarine bioprospectingEnerstvedt, Kjersti HasleKjersti HasleEnerstvedtUniversity of BergenUniversity of BergenUniversity of BergenUniversity of Bergen2020-12-112023-09-28quantitative data10.3390/plants100203341272425462603073122358955341259522312024text/plaintext/tab-separated-valuestext/tab-separated-valuestext/plaintext/plaintext/plaintext/plaintext/plaintext/plaintext/plain2.1CC0 1.0This dataset consists of 9 files containing quantitative data (absorbance and concentration) of individual flavonoids and phenolic acids in the seagrass Zostera marina L. collected from various locations along the coast of Norway. The polyphenolic content was determined by the use of analytical HPLC with UV-Vis detection.Abstract: Chemical ecology has been suggested as a less time-consuming and more cost-efficient monitoring tool of seagrass ecosystems than traditional methods. Phenolic chemistry in Zostera marina samples was analyzed against latitude, sea depth, sample position within a seagrass meadow (periphery or center) and wave exposure. Multivariate data analysis showed that rosmarinic acid correlated moderately positively with depth, while the flavonoids had an overall strong negative correlation with increasing depth—possibly reflecting lack of stress-induced conditions with increasing depth, rather than a different response to light conditions. At a molecular level, the flavonoids were separated into two groups; one group is well described by the variables of depth and wave exposure, and the other group that was not well described by these variables—the latter may reflect biosynthetic dependencies or other unrevealed factors. A higher flavonoid/rosmarinic acid ratio was seen in the periphery of a seagrass meadow, while the contrary ratio was seen in the center. This may reflect higher plant stress in the periphery of a meadow, and the flavonoid/rosmarinic acid ratio may provide a possible molecular index of seagrass ecosystem health. Further studies are needed before the full potential of using variation in phenolic chemistry as a seagrass ecosystem monitoring tool is established.