2015
DOI: 10.1890/14-1113.1
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Low‐to‐moderate nitrogen and phosphorus concentrations accelerate microbially driven litter breakdown rates

Abstract: Particulate organic matter (POM) processing is an important driver of aquatic ecosystem productivity that is sensitive to nutrient enrichment and.drives ecosystem carbon (C) loss. Although studies of single concentrations of nitrogen (N) or phosphorus (P) have shown effects at relatively low concentrations, responses of litter breakdown rates along gradients of low-to-moderate N and P concentrations are needed to establish likely interdependent effects of dual N and P enrichment on baseline activity in stream … Show more

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Cited by 66 publications
(57 citation statements)
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“…Regular measures of microcosm water chemistry could provide microbial uptake and release or be fit to Michaelis-Menten kinetics models (O'Brien & Dodds, 2008;Cheever et al, 2012); however, this approach would be better suited for a greater number of levels across a nutrient gradient with frequent flushing and replenishment of nutrients. The range of microbial respiration rates (0.024-0.892 lg O 2 mg À1 AFDM h À1 ) also closely resembled that of red maple in flowing experimental streams (0.066-0.597 lg O 2 mg À1 AFDM h À1 ; Kominoski et al, 2015). Contrasting decomposition across treatments also indicates insights to be gained by comparison of response variables at similar stages of decomposition (Cheever et al, 2013), but such analysis would surpass the scope of this study.…”
Section: Conclusion and Caveatsmentioning
confidence: 60%
“…Regular measures of microcosm water chemistry could provide microbial uptake and release or be fit to Michaelis-Menten kinetics models (O'Brien & Dodds, 2008;Cheever et al, 2012); however, this approach would be better suited for a greater number of levels across a nutrient gradient with frequent flushing and replenishment of nutrients. The range of microbial respiration rates (0.024-0.892 lg O 2 mg À1 AFDM h À1 ) also closely resembled that of red maple in flowing experimental streams (0.066-0.597 lg O 2 mg À1 AFDM h À1 ; Kominoski et al, 2015). Contrasting decomposition across treatments also indicates insights to be gained by comparison of response variables at similar stages of decomposition (Cheever et al, 2013), but such analysis would surpass the scope of this study.…”
Section: Conclusion and Caveatsmentioning
confidence: 60%
“…Notably, increased microbial biomass also enhances the quality of detrital C, through accumulation of microbial lipids, soluble carbohydrates, and protein that are nutritionally valuable compared to plant polysaccharides like cellulose and lignin that dominate detrital substrate C and are resistant to breakdown and assimilation (Martin et al, 1980; Chung and Suberkropp, 2009a,b). As elevated nutrients stimulate microbial growth, increased decomposition rates often accompany nutrient enrichment (Ferreira et al, 2015; Kominoski et al, 2015; Manning et al, 2015, 2016), stimulating C loss from ecosystems (Benstead et al, 2009; Rosemond et al, 2015). In this way, nutrient enrichment increases the quality (nutrient:C) of basal food resources in both green and brown food webs.…”
Section: Literature Review – Comparing Ecological Stoichiometry Of Grmentioning
confidence: 99%
“…Added N and P both accelerate C loss in detritus-based streams through enhanced organic matter breakdown and export (Benstead et al, 2009; Rosemond et al, 2015; Manning et al, 2016), as well as through substrate-specific and whole-stream ER (Suberkropp et al, 2010; Kominoski et al, 2017). Litter breakdown rates are constrained by microbial nutrient limitation (both N and P) at low-to-moderate concentrations through changes in litter C:N and C:P stoichiometry (Kominoski et al, 2015; Manning et al, 2015). These collective findings emphasize the importance of microbial processes on ecosystem C loss and the potential for long-term vulnerability to sustained C losses with sustained or increased N and P availability (Alexander and Smith, 2006), which ultimately can be linked to nutrient stoichiometry.…”
Section: Empirical Assessmentsmentioning
confidence: 99%