Metabolic Responses of Subtropical Microplankton After a Simulated Deep-Water Upwelling Event Suggest a Possible Dominance of Mixotrophy Under Increasing CO2 Levels
Mayte Tames-Espinosa, Ico Martínez, Vanesa Romero-Kutzner, Josep Coca, María Algueró‐Muñiz, Henriette G. Horn, Andrea Ludwig, Jan Taucher, Lennart T. Bach, Ulf Riebesell, Theodore T. Packard, May Gómez
Abstract
In the autumn of 2014, nine large mesocosms were deployed in the oligotrophic subtropical North-Atlantic coastal waters off Gran Canaria (Spain). Their deployment was designed to address the acidification effects from 400μatm CO2 to 1400μatm CO2, on a plankton community experiencing upwelling of nutrient-rich deep water. Among other parameters, chlorophyll a (chl-a), potential respiration (Φ), and proteinaceous biomass (B) were measured in the microplankton community (0.7-50 μm) during an oligotrophic phase (Phase I), a phytoplankton-bloom phase (Phase II) and a post-bloom phase (Phase III). Here, we explore the use of the Φ/chl-a ratio in monitoring shifts in the microplankton community composition and its metabolism. Φ/chl-a values below 2.5μLO2h−1(μgchl-a)−1 indicated a community dominated by photoautotrophs. When Φ/chl-a ranged higher, between 2.5-7μLO2h−1(μgchl-a)−1, it indicated a mixed community of phytoplankton, microzooplankton, and heterotrophic prokaryotes. When Φ/chl-a rose above 7μLO2h−1(μgchl-a)−1, it indicated a community where microzooplankton proliferated (>10μLO2h−1(μg chl-a)−1), because heterotrophic dinoflagellates bloomed. The first derivative of B, as a function of time (dB/dt), indicates the rate of protein build-up when positive and the rate of protein loss, when negative. It revealed that the maximum increase in particulate protein (biomass) occurred between one and two days before the chl-a peak. A day after this peak, the trough revealed the maximum net biomass loss. This analysis did not detect significant changes in particulate protein, neither in Phase I nor in Phase III. Integral analysis of Φ, chl-a and B, over the duration of each phase, for each mesocosm, reflected a positive relationship between Φ and pCO2 during Phase II (α=230 10-5 μLO2h−1L−1 (μatmCO2)−1(phase-day)−1, R2=0.3009) and between chl-a and pCO2 during Phase III (α=100 10-5 μg chl-aL−1(μ atmCO2)−1 (phase-day)−1, R2=0.8444). At the end of Phase II, a harmful algal species (HAS), Vicicitus globosus, bloomed in the high pCO2 mesocosms. In these mesocosms, microzooplankton did not proliferate, and chl-a retention time in the water column increased. In these V. globosus-disrupted communities, the Φ/chl-a ratio (4.1±1.5μLO2h−1(μg chl-a)−1) was similar to the Φ/chl-a ratio in a mixed plankton community than to a photoautotroph-dominated one.