1. Growth, ammonium metabolism, and photosynthetic properties of Ulva australis (Chlorophyta) under decreasing pH and ammonium enrichment
- Author
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Andrew T. Revill, Leah B. Reidenbach, Fanny Noisette, Janet E. Kübler, Catriona L. Hurd, Christina M. McGraw, Pablo P. Leal, and Pamela A. Fernández
- Subjects
Chlorophyll ,Pigments ,0106 biological sciences ,Atmospheric Science ,Chloroplasts ,Photoinhibition ,Light ,010504 meteorology & atmospheric sciences ,Photosystem II ,Carbonates ,Marine and Aquatic Sciences ,lcsh:Medicine ,Plant Science ,Chlorophyta ,Oceanography ,Biochemistry ,01 natural sciences ,Ulva ,chemistry.chemical_compound ,Ammonium Compounds ,Photosynthesis ,lcsh:Science ,Multidisciplinary ,biology ,Plant Biochemistry ,Ocean Acidification ,Physics ,Electromagnetic Radiation ,Eukaryota ,food and beverages ,Hydrogen-Ion Concentration ,Plants ,Chemistry ,Physical Sciences ,Carbon dioxide ,Cellular Structures and Organelles ,Cellular Types ,Elementary Particles ,Research Article ,inorganic chemicals ,Algae ,Nitrogen ,Plant Cell Biology ,Materials Science ,Greenhouse Gases ,Animal science ,Sea Water ,Plant Cells ,Botany ,Environmental Chemistry ,Seawater ,Ammonium ,14. Life underwater ,Particle Physics ,Materials by Attribute ,0105 earth and related environmental sciences ,Photons ,Organic Pigments ,010604 marine biology & hydrobiology ,Ecology and Environmental Sciences ,lcsh:R ,Organisms ,Chemical Compounds ,Aquatic Environments ,Biology and Life Sciences ,Cell Biology ,Carbon Dioxide ,biology.organism_classification ,Marine Environments ,Photosynthetic capacity ,Carbon ,chemistry ,Atmospheric Chemistry ,Earth Sciences ,lcsh:Q - Abstract
The responses of macroalgae to ocean acidification could be altered by availability of macronutrients, such as ammonium (NH4+). This study determined how the opportunistic macroalga, Ulva australis responded to simultaneous changes in decreasing pH and NH4+ enrichment. This was investigated in a week-long growth experiment across a range of predicted future pHs with ambient and enriched NH4+ treatments followed by measurements of relative growth rates (RGR), NH4+ uptake rates and pools, total chlorophyll, and tissue carbon and nitrogen content. Rapid light curves (RLCs) were used to measure the maximum relative electron transport rate (rETRmax) and maximum quantum yield of photosystem II (PSII) photochemistry (Fv/Fm). Photosynthetic capacity was derived from the RLCs and included the efficiency of light harvesting (α), slope of photoinhibition (β), and the light saturation point (Ek). The results showed that NH4+ enrichment did not modify the effects of pH on RGRs, NH4+ uptake rates and pools, total chlorophyll, rETRmax, α, β, Fv/Fm, tissue C and N, and the C:N ratio. However, Ek was differentially affected by pH under different NH4+ treatments. Ek increased with decreasing pH in the ambient NH4+ treatment, but not in the enriched NH4+ treatment. NH4+ enrichment increased RGRs, NH4+ pools, total chlorophyll, rETRmax, α, β, Fv/Fm, and tissue N, and decreased NH4+ uptake rates and the C:N ratio. Decreased pH increased total chlorophyll content, rETRmax, Fv/Fm, and tissue N content, and decreased the C:N ratio. Therefore, the results indicate that U. australis growth is increased with NH4+ enrichment and not with decreasing pH. While decreasing pH influenced the carbon and nitrogen metabolisms of U. australis, it did not result in changes in growth.
- Published
- 2017