Abstract
Freshwater aquatic systems are biogeochemical hotspots, with heterotrophic bacteria rapidly cycling the compounds that pass through them. P is a key nutrient that controls primary production in many freshwater ecosystems and is important for understanding eutrophication in lakes. Previous work has often focused on the dynamics of inorganic phosphorus and its impact on primary production, however, the role of nutrients bound in more complex organic forms (such as dissolved organic phosphorus, DOP) in supporting primary production and harmful algal blooms has been neglected. Here, we quantify the bioavailability of dissolved organic carbon (DOC) and DOP in 27 aquatic systems across the Upper Midwest United States. Using exponential decay models, long-term nutrient degradation assays revealed that decay constants for DOP ranged from- 0.001 per day to -0.12 per day with a median value of -0.01 per day. These rates were geographically variable and were as high or higher than DOC decay constants, which ranged from -0.003 per day to -.024 per day with a median value of -0.01 per day. Additionally, total bioavailability of DOP ranged from 0% to 100% with a median value of 78% of the DOP pool, demonstrating that DOP bioavailability was highly variable across systems. In contrast, bioavailable DOC was more tightly constrained with values ranging from 4.37% to 53.81% of the total DOC pool with a median value of 24.95%. DOP bioavailability was strongly correlated with the DOC:DOP of the organic matter pool, suggesting that bioavailable DOP is drawn down in systems that are more likely to be C limited. Finally, we show that including estimates of DOC and DOP bioavailability reduces estimates of elemental imbalance experienced by aquatic bacteria.
Highlights
Freshwater systems are incredibly active biogeochemical hot spots, with regards to the processing of organic matter (Cole et al, 2007; Tranvik et al, 2009)
The 27 systems studied covered a trophic gradient with chlorophyll-a values ranging from 0.25 μg/L to 57.19 μg/L and total dissolved phosphorus concentrations ranging from 0.07 μM to 2.31 μM (Table 1)
We found that the dissolved organic carbon (DOC):DOP ratio was a significant predictor of both absolute and relative BDOP (Figures 7, 8), with higher DOC:DOP ratios correlated to lower BDOP concentrations and percentages and a higher BDOC:BDOP ratio relative to the DOC:DOP pool (Figure 11)
Summary
Freshwater systems are incredibly active biogeochemical hot spots, with regards to the processing of organic matter (Cole et al, 2007; Tranvik et al, 2009). Humans have had profound impacts on the global P cycle by increasing the annual flux of P through ecosystems by a factor of 4–8 (Falkowski, 2000; Schlesinger and Bernhardt, 2013) This has important biogeochemical implications and has resulted in the eutrophication of freshwater systems worldwide leading to degraded water quality on a global scale. Eutrophication is a biogeochemical imbalance, where excess nutrients, often P in freshwater (Schindler et al, 2008), result in excessive accumulation of carbon (C) in the form of increased algal biomass This continued anthropogenic modification of freshwater nutrient and organic matter pools, together with observations of shifts in planktonic community composition and organic nutrient pools (Teubner et al, 2003) suggest that the bioavailability of organic nutrient pools could an important factor affecting auto-heterotrophic coupling as well as harmful algal blooms
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