Photosynthetic adaptation to low iron, light, and temperature in Southern Ocean phytoplankton

Phytoplankton productivity in the polar Southern Ocean (SO) plays an important role in the transfer of carbon from the atmosphere to the ocean’s interior, a process called the biological carbon pump, which helps regulate global climate. SO productivity in turn is limited by low iron, light, and temp...

Full description

Bibliographic Details
Other Authors: Strzepek, Robert, Dr (hasPrincipalInvestigator), Strzepek, Robert, Dr (pointOfContact), Institute for Marine and Antarctic Studies (IMAS), University of Tasmania (UTAS) (hasAssociationWith)
Format: Dataset
Language:unknown
Published: University of Tasmania, Australia
Subjects:
biota
iron
light
temperature
Eucampia antarctica
Proboscia inermis
Phaeocystis antarctica
Thalassiosira oceanica
Thalassiosira weissflogii
PHYTOPLANKTON
EARTH SCIENCE
BIOSPHERE
AQUATIC ECOSYSTEMS
PLANKTON
EARTH SCIENCE | BIOSPHERE | ECOSYSTEMS | MARINE ECOSYSTEMS
PHOTOSYNTHESIS
ECOLOGICAL DYNAMICS
ECOSYSTEM FUNCTIONS
Southern Ocean
Antarc*
Antarctica
Online Access:https://researchdata.ands.org.au/photosynthetic-adaptation-low-ocean-phytoplankton/1424968
http://metadata.imas.utas.edu.au:/geonetwork/srv/en/metadata.show?uuid=6fbeb554-352b-4b79-b986-debfff6e3a01
https://data.imas.utas.edu.au/attachments/6fbeb554-352b-4b79-b986-debfff6e3a01/1810886116.full.pdf
https://data.imas.utas.edu.au/attachments/6fbeb554-352b-4b79-b986-debfff6e3a01/pnas.1810886116.sapp.pdf
Description
Summary:Phytoplankton productivity in the polar Southern Ocean (SO) plays an important role in the transfer of carbon from the atmosphere to the ocean’s interior, a process called the biological carbon pump, which helps regulate global climate. SO productivity in turn is limited by low iron, light, and temperature, which restrict the ef- ficiency of the carbon pump. Iron and light can colimit productivity due to the high iron content of the photosynthetic photosystems and the need for increased photosystems for low-light acclimation in many phytoplankton. Here we show that SO phytoplankton have evolved critical adaptations to enhance photosynthetic rates under the joint constraints of low iron, light, and temperature. Under growth-limiting iron and light levels, three SO species had up to sixfold higher photosynthetic rates per photosystem II and similar or higher rates per mol of photosynthetic iron than tem- perate species, despite their lower growth temperature (3 vs. 18 °C) and light intensity (30 vs. 40 μmol quanta·m2·s−1), which should have decreased photosynthetic rates. These unexpectedly high rates in the SO species are partly explained by their unusually large photosynthetic antennae, which are among the largest ever recorded in marine phytoplankton. Large antennae are disadvan- tageous at low light intensities because they increase excitation energy loss as heat, but this loss may be mitigated by the low SO temperatures. Such adaptations point to higher SO production rates than environmental conditions should otherwise permit, with implications for regional ecology and biogeochemistry. Southern Ocean phytoplankton isolates were grown under trace metal clean conditions in a low temperature incubator under low and high iron concentrations at sub saturating continuous light. The cultures were sampled for growth rates, intracellular iron and carbon concentrations, and photosynthetic rates and composition.

Similar Items