Cyanobacterial carbon concentrating mechanisms facilitate sustained CO2 depletion in eutrophic lakes

Phytoplankton blooms are increasing in frequency, intensity, and duration in aquatic ecosystems worldwide. In many eutrophic lakes, these high levels of primary productivity correspond to periods of CO2 depletion in surface waters. Cyanobacteria and other groups of phytoplankton have the ability to...

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Bibliographic Details
Published in:Biogeosciences 2017-06, Vol.14 (11), p.2865-2875
Main Authors: Morales-Williams, Ana M, Wanamaker, Alan D, Downing, John A
Format: Article
Language:English
Subjects:
Algae
Alkalinity
Anthropogenic factors
Aquatic ecosystems
Bacteria
Bicarbonates
Biomass
Blooms
Calibration
Carbon
Carbon dioxide
Carbon dioxide concentration
Carbonates
Cell membranes
Cyanobacteria
Depletion
Disseminated intravascular coagulation
Dissolved inorganic carbon
Eutrophic lakes
Eutrophication
Fractionation
Ice
Isotope composition
Laboratories
Lakes
Limnology
Mathematical analysis
Nitrogen
Nonlinearity
Organic carbon
Particulate organic carbon
Permeability
Phosphorus
Photosynthesis
Phytoplankton
Phytoplankton bloom
Plankton
Primary production
Signatures
Stresses
Surface water
Transport
Uptake
Water circulation
Water column
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Summary:Phytoplankton blooms are increasing in frequency, intensity, and duration in aquatic ecosystems worldwide. In many eutrophic lakes, these high levels of primary productivity correspond to periods of CO2 depletion in surface waters. Cyanobacteria and other groups of phytoplankton have the ability to actively transport bicarbonate (HCO3−) across their cell membrane when CO2 concentrations are limiting, possibly giving them a competitive advantage over algae not using carbon concentrating mechanisms (CCMs). To investigate whether CCMs can maintain phytoplankton bloom biomass under CO2 depletion, we measured the δ13C signatures of dissolved inorganic carbon (δ13CDIC) and phytoplankton particulate organic carbon (δ13Cphyto) in 16 mesotrophic to hypereutrophic lakes during the ice-free season of 2012. We used mass–balance relationships to determine the dominant inorganic carbon species used by phytoplankton under CO2 stress. We found a significant positive relationship between phytoplankton biomass and phytoplankton δ13C signatures as well as a significant nonlinear negative relationship between water column ρCO2 and isotopic composition of phytoplankton, indicating a shift from diffusive uptake to active uptake by phytoplankton of CO2 or HCO3− during blooms. Calculated photosynthetic fractionation factors indicated that this shift occurs specifically when surface water CO2 drops below atmospheric equilibrium. Our results indicate that active HCO3− uptake via CCMs may be an important mechanism in maintaining phytoplankton blooms when CO2 is depleted. Further increases in anthropogenic pressure, eutrophication, and cyanobacteria blooms are therefore expected to contribute to increased bicarbonate uptake to sustain primary production.
ISSN:1726-4170
1726-4189
DOI:10.5194/bg-14-2865-2017