Vulnerability of mixotrophic algae to nutrient pulses and UVR in an oligotrophic Southern and Northern Hemisphere lake

CARRILLO, P.; BULLEJOS, F.J.; SOUZA, M.S.; CARRILLO, P.; BULLEJOS, F.J.; SOUZA, M.S.; VILLAR-ARGAIZ, M.; MEDINA-SÁNCHEZ, J.M.; BASTIDAS-NAVARRO, M.; DURÁN, C.; MODENUTTI, B.E.; VILLAR-ARGAIZ, M.; BALSEIRO, E.G.; BASTIDAS-NAVARRO, M.; MEDINA-SÁNCHEZ, J.M.; DURÁN, C.; MODENUTTI, B.E.; BALSEIRO, E.G.

Scientific Reports

Nature Publishing Group

Año: 2017 vol. 7

Nutrient inputs and ultraviolet radiation (UVR) are global factors affecting the structure and functioning of aquatic ecosystems, particularly clear-water ecosystems. We performed experiments in two model lakes highly exposed to UVR fluxes in order to test the effect that future increases in mineral nutrients transported by dust aerosol might exert on primary producers depending on the likelihood of atmospheric inputs. Lake La Caldera (Northern Hemisphere) has been receiving recurrent dust inputs from the Sahara Desert while lake Los Cántaros (Southern Hemisphere) has been less affected by dust aerosol. UVR × Nutrient synergistically stimulated primary production (PP), chlorophyll a (Chl a), with a smaller increase in phytoplanktonic biomass in La Caldera, but not in Los Cántaros, where nutrient addition unmasked the UVR inhibitory effect on phytoplankton. The proportional decrease of mixotrophic nanoflagellates (MNFs) after the nutrient pulse (in Los Cántaros) and the long-term decline of MNFs in La Caldera associated with the increase in aerosol-dust intrusions from the Sahara during the last 40 years suggest that a future scenario of intensified aerosol events from desert and desertified areas would not only reduce functional diversity with the decline of MNFs, but would ultimately alter the C flux towards the grazing chain in oligotrophic ecosystems.