FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2294672007> ?p ?o ?g. }

• W2294672007 endingPage "140" @default.
• W2294672007 startingPage "127" @default.
• W2294672007 abstract "MEPS Marine Ecology Progress Series Contact the journal Facebook Twitter RSS Mailing List Subscribe to our mailing list via Mailchimp HomeLatest VolumeAbout the JournalEditorsTheme Sections MEPS 543:127-140 (2016) - DOI: https://doi.org/10.3354/meps11568 Interactive effects of ocean acidification and nitrogen limitation on two bloom-forming dinoflagellate species Tim Eberlein1, Dedmer B. Van de Waal1,2,*, Karen M. Brandenburg1,2, Uwe John1, Maren Voss3, Eric P. Achterberg4, Björn Rost1 1Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Am Handelshafen 12, 27570 Bremerhaven, Germany 2Netherlands Institute of Ecology (NIOO-KNAW), PO Box 50, 6700 AB, Wageningen, The Netherlands 3Leibniz Institute for Baltic Sea Research Warnemünde, Seestrasse 15, 18119 Rostock, Germany 4GEOMAR Helmholtz Centre for Ocean Research, Wischhofstraße 1–3, 24148 Kiel, Germany *Corresponding author: d.vandewaal@nioo.knaw.nl ABSTRACT: Global climate change involves an increase in oceanic CO2 concentrations as well as thermal stratification of the water column, thereby reducing nutrient supply from deep to surface waters. Changes in inorganic carbon (C) or nitrogen (N) availability have been shown to affect marine primary production, yet little is known about their interactive effects. To test for these effects, we conducted continuous culture experiments under N limitation and exposed the bloom-forming dinoflagellate species Scrippsiella trochoidea and Alexandrium fundyense (formerly A. tamarense) to CO2 partial pressures ( pCO2) ranging between 250 and 1000 µatm. Ratios of particulate organic carbon (POC) to organic nitrogen (PON) were elevated under N limitation, but also showed a decreasing trend with increasing pCO2. PON production rates were highest and affinities for dissolved inorganic N were lowest under elevated pCO2, and our data thus demonstrate a CO2-dependent trade-off in N assimilation. In A. fundyense, quotas of paralytic shellfish poisoning toxins were lowered under N limitation, but the offset to those obtained under N-replete conditions became smaller with increasing pCO2. Consequently, cellular toxicity under N limitation was highest under elevated pCO2. All in all, our observations imply reduced N stress under elevated pCO2, which we attribute to a reallocation of energy from C to N assimilation as a consequence of lowered costs in C acquisition. Such interactive effects of ocean acidification and nutrient limitation may favor species with adjustable carbon concentrating mechanisms and have consequences for their competitive success in a future ocean. KEY WORDS: Dinoflagellates · Ocean acidification · Nitrogen limitation · Paralytic shellfish poisoning · PSP toxins Full text in pdf format PreviousNextCite this article as: Eberlein T, Van de Waal DB, Brandenburg KM, John U, Voss M, Achterberg EP, Rost B (2016) Interactive effects of ocean acidification and nitrogen limitation on two bloom-forming dinoflagellate species. Mar Ecol Prog Ser 543:127-140. https://doi.org/10.3354/meps11568 Export citation RSS - Facebook - Tweet - linkedIn Cited by Published in MEPS Vol. 543. Online publication date: February 03, 2016 Print ISSN: 0171-8630; Online ISSN: 1616-1599 Copyright © 2016 Inter-Research." @default.
• W2294672007 created "2016-06-24" @default.
• W2294672007 creator A5014772924 @default.
• W2294672007 creator A5028428509 @default.
• W2294672007 creator A5053654036 @default.
• W2294672007 creator A5060266476 @default.
• W2294672007 creator A5068215732 @default.
• W2294672007 creator A5080243878 @default.
• W2294672007 creator A5091905555 @default.
• W2294672007 date "2016-02-03" @default.
• W2294672007 modified "2023-10-16" @default.
• W2294672007 title "Interactive effects of ocean acidification and nitrogen limitation on two bloom-forming dinoflagellate species" @default.
• W2294672007 cites W1927225475 @default.
• W2294672007 cites W1928213401 @default.
• W2294672007 cites W1972440446 @default.
• W2294672007 cites W1977139974 @default.
• W2294672007 cites W1978886837 @default.
• W2294672007 cites W1980583674 @default.
• W2294672007 cites W1990873350 @default.
• W2294672007 cites W1998694284 @default.
• W2294672007 cites W2000743242 @default.
• W2294672007 cites W2004392281 @default.
• W2294672007 cites W2004491948 @default.
• W2294672007 cites W2007140118 @default.
• W2294672007 cites W2007736859 @default.
• W2294672007 cites W2009070584 @default.
• W2294672007 cites W2010154609 @default.
• W2294672007 cites W2010226892 @default.
• W2294672007 cites W2010557655 @default.
• W2294672007 cites W2012547151 @default.
• W2294672007 cites W2019301230 @default.
• W2294672007 cites W2030604405 @default.
• W2294672007 cites W2036233390 @default.
• W2294672007 cites W2036677156 @default.
• W2294672007 cites W2039643762 @default.
• W2294672007 cites W2047986616 @default.
• W2294672007 cites W2049144909 @default.
• W2294672007 cites W2050386030 @default.
• W2294672007 cites W2051487307 @default.
• W2294672007 cites W2051571587 @default.
• W2294672007 cites W2052501806 @default.
• W2294672007 cites W2053022429 @default.
• W2294672007 cites W2055141095 @default.
• W2294672007 cites W2060012482 @default.
• W2294672007 cites W2065775367 @default.
• W2294672007 cites W2066250226 @default.
• W2294672007 cites W2067186899 @default.
• W2294672007 cites W2072229261 @default.
• W2294672007 cites W2074731222 @default.
• W2294672007 cites W2079866397 @default.
• W2294672007 cites W2081240405 @default.
• W2294672007 cites W2085903824 @default.
• W2294672007 cites W2086700422 @default.
• W2294672007 cites W2088416610 @default.
• W2294672007 cites W2090011988 @default.
• W2294672007 cites W2090157291 @default.
• W2294672007 cites W2093222646 @default.
• W2294672007 cites W2100068233 @default.
• W2294672007 cites W2104525656 @default.
• W2294672007 cites W2109298191 @default.
• W2294672007 cites W2113892199 @default.
• W2294672007 cites W2114124026 @default.
• W2294672007 cites W2120589401 @default.
• W2294672007 cites W2121675877 @default.
• W2294672007 cites W2122570065 @default.
• W2294672007 cites W2122608170 @default.
• W2294672007 cites W2125776675 @default.
• W2294672007 cites W2129450594 @default.
• W2294672007 cites W2134452938 @default.
• W2294672007 cites W2144813983 @default.
• W2294672007 cites W2145543484 @default.
• W2294672007 cites W2148980777 @default.
• W2294672007 cites W2153995609 @default.
• W2294672007 cites W2154237171 @default.
• W2294672007 cites W2155353497 @default.
• W2294672007 cites W2155941232 @default.
• W2294672007 cites W2159414529 @default.
• W2294672007 cites W2163607213 @default.
• W2294672007 cites W2164087962 @default.
• W2294672007 cites W2174615974 @default.
• W2294672007 cites W2312205405 @default.
• W2294672007 cites W2504196632 @default.
• W2294672007 cites W2614283331 @default.
• W2294672007 cites W4213327538 @default.
• W2294672007 cites W4254995003 @default.
• W2294672007 cites W575080533 @default.
• W2294672007 doi "https://doi.org/10.3354/meps11568" @default.
• W2294672007 hasPublicationYear "2016" @default.
• W2294672007 type Work @default.
• W2294672007 sameAs 2294672007 @default.
• W2294672007 citedByCount "38" @default.
• W2294672007 countsByYear W22946720072016 @default.
• W2294672007 countsByYear W22946720072017 @default.
• W2294672007 countsByYear W22946720072018 @default.
• W2294672007 countsByYear W22946720072019 @default.
• W2294672007 countsByYear W22946720072020 @default.
• W2294672007 countsByYear W22946720072021 @default.
• W2294672007 countsByYear W22946720072022 @default.

• next