Light and dissolved phosphorus interactively affect microbial metabolism, stoichiometry and decomposition of leaf litter

Halvorson, Halvor M.; Scott, Erin E.; Entrekin, Sally A.; Evans‐White, Michelle A.; Scott, J. Thad

doi:10.1111/fwb.12763

Cited by 40 publications

(53 citation statements)

References 66 publications

(189 reference statements)

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“…Foremost, our study reiterates the question of why negative priming occurs in some settings, whereas positive priming occurs in others (Bengtsson et al, ). In two previous litter decomposition studies, increased algal biomass under high nutrients erased positive algal‐induced priming (Danger et al, ; Halvorson et al, ). Our findings may be attributable to high nutrient availability which, combined with high light, could raise algal exudation to fully support, rather than augment, heterotrophic C demands (Guenet et al, ; Wagner et al, ; Wyatt et al, ).…”

Section: Discussionmentioning

confidence: 94%

“…Our experiment provides empirical evidence of negative priming because algae increased fungal production but suppressed leaf litter dry mass loss rates—a notable decoupling, since aquatic fungi (i.e., hyphomycetes which dominate in flowing environments) are considered major drivers of plant litter decomposition in stream ecosystems (Gessner et al, ; Kuehn, ; Romaní et al, ; Suberkropp & Chauvet, ). At a mechanistic level, algae may suppress litter decomposition through two effects, one apparent and one actual: (a) accrual of new algal biomass could counterbalance mass lost due to heterotrophic degradation of litter C, thereby reducing apparent decomposition, and (b) preferential substrate use of algal‐derived labile C substrates by heterotrophs could reduce actual heterotrophic decomposition of litter (Guenet et al, ; Halvorson et al, ). Both mechanisms occurred in our experiment.…”

Section: Discussionmentioning

confidence: 99%

“…Under no or negative priming, labile C may stimulate heterotrophic decomposer activity, yet this stimulation is not coupled to increased recalcitrant C turnover because microbial heterotrophs likely allocate labile C towards growth, respiration or reproduction instead of degradative enzymes and decomposition (Catalán et al, ; Kuzyakov, ). Priming strength in aquatic systems may depend on the relative size of labile and recalcitrant C pools (Danger et al, ; Halvorson, Scott, Entrekin, Evans‐White, & Scott, ; Wagner, Bengtsson, Findlay, Battin, & Ulseth, ). However, additional tests of priming are needed, especially those extending beyond closed micro‐ and mesocosm studies to flow‐through conditions of streams and rivers (Fabian et al, ), where there also is a pressing need to quantify the microbial interactions that determine mechanisms and directions of priming (Catalán et al, ; Guenet et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Increased light availability enhances C lability through photolytic (ultraviolet‐induced) degradation of recalcitrant C compounds (e.g., humic acids) into fatty acids and carbohydrate monomers (King, Brandt, & Adair, ; Wetzel, Hatcher, & Bianchi, ), but considerably less emphasis has been placed on the potential for light‐mediated effects via algal growth and C exudation and its subsequent stimulation of heterotrophic decomposers (Danger et al, ; Kuehn et al, ). On leaf litter, active periphytic algae can double bacterial and fungal growth rates (Kuehn et al, ), and enhance C‐ and nitrogen (N)‐acquiring enzyme activities (Rier, Kuehn, & Francoeur, ), and speed decomposition by 20%–126% (Danger et al, ; Halvorson et al, ; Lagrue et al, ). Algae can also increase overall microbial biomass in the litter‐periphyton complex, and because algae are N‐ and phosphorus (P)‐rich relative to litter, this increases nutrient uptake and reduces C:N and C:P ratios (Danger et al, ; Halvorson et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Periphytic algae decouple fungal activity from leaf litter decomposition via negative priming

et al. 2018

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1. Well-documented in terrestrial settings, priming effects describe stimulated heterotrophic microbial activity and decomposition of recalcitrant carbon by additions of labile carbon. In aquatic settings, algae produce labile exudates which may elicit priming during organic matter decomposition, yet the directions and mechanisms of aquatic priming effects remain poorly tested. 2. We tested algal-induced priming during decomposition of two leaf species of contrasting recalcitrance, Liriodendron tulipifera and Quercus nigra, in experimental streams under light or dark conditions. We measured litter-associated algal, bacterial, and fungal biomass and activity, stoichiometry, and litter decomposition rates over 43 days. 3. Light increased algal biomass and production rates and increased bacterial abundance 141–733% and fungal production rates 20–157%. Incubations with a photosynthesis inhibitor established that algal activity directly stimulated fungal production rates in the short-term. 4. Algal-stimulated fungal production rates on both leaf species were not coupled to long-term increases in fungal biomass accrual or litter decomposition rates, which were 154–157% and 164–455% greater in the dark, respectively. The similar patterns on fast- vs. slow-decomposing L. tulipifera and Q. nigra, respectively, indicated that substrate recalcitrance may not mediate priming strength or direction. 5. In this example of negative priming, periphytic algae decoupled fungal activity from decomposition, likely by providing labile carbon invested toward greater fungal growth and reproduction instead of recalcitrant carbon degradation. If common, algal-induced negative priming could stimulate heterotrophy reliant on labile carbon yet suppress decomposition of recalcitrant carbon, modifying energy and nutrients available to upper trophic levels and enhancing organic carbon storage or export in well-lit aquatic habitats.

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Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Periphytic algae decouple fungal activity from leaf litter decomposition via negative priming

et al. 2018

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“…Moreover, cellulose degradation rate was found to be significantly moderated by litter initial P concentration, which can explain up to 64.4%-74.8% of the variation depending on ecosystem types (Table 4). This may be attributed to the fact that P is an important nutrient for microorganisms and the enzymes related to cellulose degradation [38]. Apart from the influences of litter quality on cellulose degradation, ecosystem type, and decomposition period, which were expressed as local-scale environment factors in the present study, appeared to be of significance as well.…”

Section: Discussionmentioning

confidence: 54%

Cellulose Dynamics during Foliar Litter Decomposition in an Alpine Forest Meta-Ecosystem

Yue

Yang

et al. 2016

Forests

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Abstract:To investigate the dynamics and relative drivers of cellulose degradation during litter decomposition, a field experiment was conducted in three individual ecosystems (i.e., forest floor, stream, and riparian zone) of an alpine forest meta-ecosystem on the eastern Tibetan Plateau. Four litter species (i.e., willow: Salix paraplesia, azalea: Rhododendron lapponicum, cypress: Sabina saltuaria, and larch: Larix mastersiana) that had varying initial litter chemical traits were placed separately in litterbags and then incubated on the soil surface of forest floor plots or in the water of the stream and riparian zone plots. Litterbags were retrieved five times each year during the two-year experiment, with nine replicates each time for each treatment. The results suggested that foliar litter lost 32.2%-89.2% of the initial dry mass depending on litter species and ecosystem type after two-year's incubation. The cellulose lost 60.1%-96.8% of the initial mass with degradation rate in the order of stream > riparian zone > forest floor. Substantial cellulose degradation occurred at the very beginning (i.e., in the first pre-freezing period) of litter decomposition. Litter initial concentrations of phosphorus (P) and lignin were found to be the dominant chemical traits controlling cellulose degradation regardless of ecosystems type. The local-scale environmental factors such as temperature, pH, and nutrient availability were important moderators of cellulose degradation rate. Although the effects of common litter chemical traits (e.g., P and lignin concentrations) on cellulose degradation across different individual ecosystems were identified, local-scale environmental factors such as temperature and nutrient availability were found to be of great importance for cellulose degradation. These results indicated that local-scale environmental factors should be considered apart from litter quality for generating a reliable predictive framework for the drivers of cellulose degradation and further on litter decomposition at a global scale.

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Nutrient and stoichiometry dynamics of decomposing litter in stream ecosystems: A global synthesis

Robbins

Manning

Halvorson

et al. 2023

Ecology

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Decomposing organic matter forms a substantial resource base, fueling the biogeochemical function and secondary production of most aquatic ecosystems. However, detrital N (nitrogen) and P (phosphorus) dynamics remain relatively unexplored in aquatic ecosystems relative to terrestrial ecosystems, despite fundamentally linking microbial processes to ecosystem function across broad spatial scales. We synthesized 217 published time series of detrital carbon (C), N, P, and their stoichiometric ratios (C:N, C:P, N:P) from stream ecosystems to analyze the temporal nutrient dynamics of decomposing litter using generalized additive models. Model results indicated that detritus was a net source of N (irrespective of inorganic or organic form) to the environment, regardless of initial N content. In contrast, P sink/source dynamics were more strongly influenced by the initial P content, in which P‐poor litters were sinks for nutrients until these shifted to net P mineralization after ~40% mass loss. However, large variations surrounded both the N and P predictions, suggesting the importance of nonmicrobial factors such as fragmentation by invertebrates. Detrital C:N ratios converged and became more similar toward the end of the decomposition, suggesting predictable microbial functional effects throughout detrital ontogeny. C:P and N:P ratios also converged to some degree, but these model predictions were less robust than for C:N, due in part to the lower number of published detrital C:P time series. The explorations of environmental covariate effects were frequently limited by a few coincident covariate measurements across studies, but temperature, N availability, and P tended to accelerate the existing ontogenetic patterns in C:N. Our analysis helps to unite organic matter decomposition across aquatic–terrestrial boundaries by describing the basic patterns of elemental flows catalyzed by decomposition in streams, and points to a research agenda with which to continue addressing gaps in our knowledge of detrital nutrient dynamics across ecosystems.

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Light and dissolved phosphorus interactively affect microbial metabolism, stoichiometry and decomposition of leaf litter

Cited by 40 publications

References 66 publications

Periphytic algae decouple fungal activity from leaf litter decomposition via negative priming

Periphytic algae decouple fungal activity from leaf litter decomposition via negative priming

Cellulose Dynamics during Foliar Litter Decomposition in an Alpine Forest Meta-Ecosystem

Nutrient and stoichiometry dynamics of decomposing litter in stream ecosystems: A global synthesis

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