High nutrient loads amplify carbon cycling across California and New York coastal wetlands but with ambiguous effects on marsh integrity and sustainability

Watson, E. B.; Rahman, Farzana I.; Woolfolk, Andrea; Meyer, R. L.; Maher, Nicole; Wigand, Cathleen; Gray, Andrew B.

doi:10.1371/journal.pone.0273260

Cited by 4 publications

(2 citation statements)

References 97 publications

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Section: Discussionmentioning

confidence: 99%

“…Further, this result implies that under low nutrients, the function of these microbial communities is less likely to change with warming unless there is a concomitant increase in nutrient levels to allow for increased function 96 . Alternatively, increased respiration rates due to nutrient enrichment could indicate increased metabolic activity in organisms due to increased turnover 97,98 . Moreover, while temperature, nutrient levels, and ciliate presence interactively influenced prokaryotic biomass (Figure 1), only nutrient levels significantly impacted total respiration (Figure 2).…”

Section: Discussionmentioning

confidence: 99%

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Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

DeWitt,

Carrell,

Rocca

et al. 2024

Preprint

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Temperature significantly impacts microbial communities' composition and function, which subsequently plays a vital role in the global carbon cycle that ultimately fuels climate change. Interactions between different microorganisms might be critical in shaping how these communities react to both temperature changes. Additionally, rising temperatures are occurring in the context of increasingly nutrient-rich ecosystems due to human activity. Nonetheless, we lack a comprehensive understanding of how predation influences microbial communities in future climate scenarios and an increasingly nutrient-rich world. Here, we assess whether predation by key bacterial consumers—ciliates—influences a microbial community's freshwater temperature and nutrient response regarding biomass, diversity, structure, and function. In a three-week microcosm experiment, we exposed mostly prokaryotic microbial communities to a community of ciliate predators at two different temperature scenarios (ambient and +3°C, i.e., a conservative projection of climate change by 2050) and nutrient levels (low and elevated). Nutrients, temperature, and ciliate presence influenced microbial biomass and function separately, but their interaction had the largest explanatory power over the observed changes in microbial community biomass, structure, and function. Our study supports previous findings that temperature and nutrients are essential drivers of microbial community structure and function but also demonstrates that the presence of predators can mediate these effects, indicating that the biotic context is as important as the abiotic context to understand microbial responses to novel climates.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

DeWitt,

Carrell,

Rocca

et al. 2024

Preprint

View full text Add to dashboard Cite

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Estuarine Sediment Microbiomes from a Chronosequence of Restored Urban Salt Marshes

et al. 2023

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Suboptimal Rootzone Growth Prevents Long Island (NY) Salt Marshes from Keeping Pace with Sea Level Rise

Maher,

Starke

2023

Estuaries and Coasts

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Salt marsh habitat loss and conversion are well documented across the marine-coastal district of New York. Regionally, these losses are characterized by marsh edge erosion, ditch and creek widening, internal ponding, and conversion from irregularly flooded marsh to regularly flooded marsh and intertidal mudflats. These changes in horizontal extent and shifts in vegetation composition suggest that NY’s salt marshes may not be keeping pace with sea level rise. To evaluate elevation building processes, deep rod surface elevation tables, marker horizons, and shallow rod surface elevation tables (SET-MHs and shallow RSETs) were installed as a network across Long Island, NY. Contributions of surface, shallow subsurface, and deeper processes to overall elevation changes were observed from 2008 to 2022. Using a linear mixed model approach, surface accretion, shallow subsurface rootzone growth, and deeper below-ground processes were evaluated against regional sea level rise, nutrient loading, and marsh area trends. We found that marshes on Long Island are not keeping pace with sea level rise because they lack vertical elevation growth within the rootzone. Optimizing conditions for belowground growth of native salt marsh plants and preservation of organic matter within the peat matrix is key for restoring salt marshes to a positive elevation trajectory relative to sea level rise. Much like a retirement savings account, knowing whether our marshes are increasing in elevation is important, but understanding the full suite of deposits and withdrawals is critical for managing this valuable resource for the future.

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High nutrient loads amplify carbon cycling across California and New York coastal wetlands but with ambiguous effects on marsh integrity and sustainability

Cited by 4 publications

References 97 publications

Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

Estuarine Sediment Microbiomes from a Chronosequence of Restored Urban Salt Marshes

Suboptimal Rootzone Growth Prevents Long Island (NY) Salt Marshes from Keeping Pace with Sea Level Rise

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