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| Main Authors: | , , , , , |
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| Format: | Artículo científico |
| Language: | en |
| Published: |
Ecology
2025
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| Subjects: | |
| Online Access: | https://pubmed.ncbi.nlm.nih.gov/39853755/ |
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| _version_ | 1868266252619743233 |
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| author | Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad |
| author_facet | Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad |
| collection | PubMed - marine biology |
| contents | Nitrogen fixation may not alleviate stoichiometric imbalances that limit primary production in eutrophic lake ecosystems. Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad Lakes Nitrogen Fixation Nitrogen Phosphorus Eutrophication Phytoplankton Ecosystem Ecosystem-scale primary production may be proximately limited by nitrogen (N) but ultimately limited by phosphorus (P) because N fixation contributes new N that accumulates relative to P at ecosystem scales. However, the duration needed to transition between proximate N limitation and ultimate P limitation remains unknown for most ecosystems, including lakes. Here we present the results of a fully replicated, multi-annual lake mesocosm experiment that permitted full air-water-sediment interactions that mimicked lake ecosystem ecology. We manipulated N supply relative to P to achieve a gradient of N:P stoichiometry. Despite N fixation contributing as much as 80% of reactive N in the low N treatments, phytoplankton biomass in these treatments was not different from the unfertilized controls. This suggests that primary production remained N limited in the lowest N treatments, even when N fixation was substantial. Although fixed N inputs reduced the N imbalance relative to P in the low N treatments seasonally, fixed N did not accumulate over multiple years. Additionally, reactive N did not readily accumulate in the high N treatments. Instead, water column stoichiometry was proportional to the experimental N and P additions, suggesting a strong influence from external nutrient loading. Thus, we found no evidence that N accumulation from N fixation was sufficient to trigger a transition to ultimate P limitation seasonally or across our 3-year experiment. Rather, our results indicate that proximate N limitation perpetuates in eutrophic lakes, likely due to N export being proportional to its inputs. These findings offer new insight regarding the biogeochemical controls on ecosystem stoichiometry and their influence on the timeframe for proximate N limitation and ultimate P limitation in freshwater, marine, and terrestrial ecosystems. |
| format | Artículo científico |
| id | pubmed_39853755 |
| institution | PubMed |
| language | en |
| publishDate | 2025 |
| publisher | Ecology |
| record_format | pubmed |
| spellingShingle | Nitrogen fixation may not alleviate stoichiometric imbalances that limit primary production in eutrophic lake ecosystems. Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad Lakes Nitrogen Fixation Nitrogen Phosphorus Eutrophication Phytoplankton Ecosystem Nitrogen fixation may not alleviate stoichiometric imbalances that limit primary production in eutrophic lake ecosystems. Andersen, Isabelle M Taylor, Jason M Kelly, Patrick T Hoke, Alexa K Robbins, Caleb J Scott, J Thad Lakes Nitrogen Fixation Nitrogen Phosphorus Eutrophication Phytoplankton Ecosystem Ecosystem-scale primary production may be proximately limited by nitrogen (N) but ultimately limited by phosphorus (P) because N fixation contributes new N that accumulates relative to P at ecosystem scales. However, the duration needed to transition between proximate N limitation and ultimate P limitation remains unknown for most ecosystems, including lakes. Here we present the results of a fully replicated, multi-annual lake mesocosm experiment that permitted full air-water-sediment interactions that mimicked lake ecosystem ecology. We manipulated N supply relative to P to achieve a gradient of N:P stoichiometry. Despite N fixation contributing as much as 80% of reactive N in the low N treatments, phytoplankton biomass in these treatments was not different from the unfertilized controls. This suggests that primary production remained N limited in the lowest N treatments, even when N fixation was substantial. Although fixed N inputs reduced the N imbalance relative to P in the low N treatments seasonally, fixed N did not accumulate over multiple years. Additionally, reactive N did not readily accumulate in the high N treatments. Instead, water column stoichiometry was proportional to the experimental N and P additions, suggesting a strong influence from external nutrient loading. Thus, we found no evidence that N accumulation from N fixation was sufficient to trigger a transition to ultimate P limitation seasonally or across our 3-year experiment. Rather, our results indicate that proximate N limitation perpetuates in eutrophic lakes, likely due to N export being proportional to its inputs. These findings offer new insight regarding the biogeochemical controls on ecosystem stoichiometry and their influence on the timeframe for proximate N limitation and ultimate P limitation in freshwater, marine, and terrestrial ecosystems. |
| title | Nitrogen fixation may not alleviate stoichiometric imbalances that limit primary production in eutrophic lake ecosystems. |
| topic | Lakes Nitrogen Fixation Nitrogen Phosphorus Eutrophication Phytoplankton Ecosystem |
| url | https://pubmed.ncbi.nlm.nih.gov/39853755/ |