The effects of terrestrial dissolved organic matter on phytoplankton biomass and productivity in boreal lakes

The effects of terrestrial dissolved organic matter on phytoplankton biomass and productivity in boreal lakes

Abstract Allochthonous dissolved organic matter (DOM) structures many physical, chemical, and biological properties of lakes including key variables that control productivity at the base of freshwater food webs. A growing number of studies have documented increasing DOM concentrations within lakes a...

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Bibliographic Details
Published in:Freshwater biology Vol. 68; no. 12; pp. 2109 - 2119
Main Authors: Sherbo, Bryanna A. H., Tonin, Joseph, Paterson, Michael J., Hann, Brenda J., Kozak, Julia, Higgins, Scott N.
Format: Journal Article
Language:English
Published: Oxford Wiley Subscription Services, Inc 01-12-2023
Subjects:
Acclimation
Acclimatization
Acid rain
Acidic soils
Allochthonous deposits
Biological properties
Biomass
Carbon
Carbon dioxide
Catchment area
Chemical properties
Chemicophysical properties
Chlorophyll
Chlorophyll a
Climate change
Dissolved organic carbon
Dissolved organic matter
Food chains
Food webs
Freshwater
Inland water environment
Lakes
Microscopy
Mixed layer depth
Nutrients
Partial pressure
Phosphorus
Phytoplankton
Plankton
Primary production
Productivity
Rainfall
Thermocline
Water depth
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Summary:Abstract Allochthonous dissolved organic matter (DOM) structures many physical, chemical, and biological properties of lakes including key variables that control productivity at the base of freshwater food webs. A growing number of studies have documented increasing DOM concentrations within lakes across Europe and North America, including boreal lakes. Such increases are associated with the recovery of catchment soils from acid rain and rising precipitation linked to climate change. We examined phytoplankton biomass, productivity, and their drivers across eight pristine boreal lakes with DOM ranging from 3.5 to 9.5 mg dissolved organic carbon/L. Physical and chemical properties were assessed using standard limnological methods. Phytoplankton biomass was assessed using both chlorophyll a (Chl‐ a ) and via microscopy. Phytoplankton productivity was assessed using change in partial pressure of carbon dioxide within in vitro incubations. Increases in DOM were associated with significant increases in epilimnetic nitrogen, phosphorus and Chl‐ a concentrations suggesting that nutrients associated with DOM stimulated phytoplankton biomass and productivity. Such results were misleading; there was no significant relationship between Chl‐ a and phytoplankton biomass. Chl‐ a :biomass and Chl‐ a :carbon ratios indicated that increases in Chl‐ a with DOM were driven by photo‐acclimation to declining light availability. Further, results presented as epilimnetic concentrations would not account for concurrent declines in thermocline depth or euphotic depth driven by DOM. Increases in DOM led to large declines in thermocline ( c. 50%) and euphotic ( c. 75%) depths, and depth‐integrated phytoplankton biomass ( c. 70%) and primary production ( c. 70%). Our results indicate that DOM plays a structuring role for key physical, chemical, and biological properties of lakes, including productivity, at a landscape level. Further, practitioners should be cautious when using Chl‐ a as an indicator of phytoplankton biomass in studies using DOM or water clarity gradients, report results using depth integrated units due to changes in volumes of thermal layers induced by DOM, and incorporate estimates of sub‐epilimnetic productivity when evaluating DOM effects.
ISSN:0046-5070
1365-2427
DOI:10.1111/fwb.14178