Increased Forest Soil CO2 and N2O Emissions During Insect Infestation

Grüning, Maren Marine; Germeshausen, Franziska; Thies, Carsten; L.-M.-Arnold, Anne

doi:10.3390/f9100612

Cited by 8 publications

(4 citation statements)

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“…Insect herbivory increased overall C and N mineralization (H 3 , Figure ), which was expected due to higher input of more labile substrates to the soil (e.g. Grüning, Germeshausen, Thies, & le‐Mellec‐Arnold, ; Grüning et al, ; Lovett et al, ). However, following severe outbreaks, decreased soil respiration has been observed in subarctic systems (Parker et al, ; Sandén et al, ).…”

Section: Discussionmentioning

confidence: 86%

“…In a global change perspective, this implies that particularly in high latitude systems, where the climate models predict warmer and wetter climates (ACIA, ), which in turn allows insect herbivores to expand their ranges (Jepsen et al, ), immediate below‐ground responses to insect herbivory might cause a positive climate warming feedback (e.g. Grüning et al, ; Heliasz et al, ; Kristensen et al, ).…”

Section: Discussionmentioning

confidence: 99%

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Below‐ground responses to insect herbivory in ecosystems with woody plant canopies: A meta‐analysis

2019

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1. Insect herbivory can have important consequences for the functioning of terrestrial ecosystems. Despite a growing recognition of the role of herbivores in above-ground-below-ground interactions, our current understanding is mainly restricted to studies of vertebrates in grassland and tundra ecosystems, while ecosystems with tree-like canopies (termed forests below) and invertebrates remain understudied.2. Here, we assess the current state of knowledge of one key aspect of plant-herbivore interactions by conducting a meta-analysis of the peer-reviewed literature on the below-ground consequences of above-ground insect herbivory in forest ecosystems. Main results are reported as aggregated relative effect sizes (Cohen's d).3. We find that above-ground insect herbivory reduced below-ground carbon (C) allocation by plants to roots (−0.56) and root exudation (−0.85), causing shifts in root-symbiont communities, for example, a decrease (−0.67) in the abundance of ectomycorrhizal fungi. Microbial decomposer abundances showed no significant responses, while soil faunal abundances increased (0.50). C and nitrogen (N) mineralization rates (C: 0.48, N: 0.48) along with nutrient leaching (C: 0.30, N: 0.77) increased, with a stronger response to outbreak relative to background insect densities. The negative responses increased in strength in colder and dryer biomes while positive responses were reinforced in warmer and wetter biomes, thus extending previously shown effects for vertebrate herbivores to also include insect herbivory. The positive response by soil fauna to insect herbivory was the notable exception. This may be associated with the limited physical soil disturbance caused by insects compared to ungulates. Furthermore, we identified an underrepresentation in the literature of large areas of boreal and tropical biomes calling for research priorities to fill these knowledge gaps. We present three recommendations for future research: addressing (a) biological drivers of biogeochemistry and response pathways, (b) knowledge gap from boreal and tropical forests, and (c) heterogeneity of herbivore disturbances.4. Synthesis. Insect herbivores significantly accelerate soil C and N cycling during outbreaks in forest ecosystems, but we lack knowledge on the underlying biological drivers. Overall, below-ground responses to insect herbivory are similar to vertebrate herbivory responses, which may simplify implementing herbivory effects 918 | Journal of Ecology KRISTENSEN ET al.

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Section: Discussionmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 99%

Below‐ground responses to insect herbivory in ecosystems with woody plant canopies: A meta‐analysis

2019

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“…Application of manure with a larger content of easily degradable organic C substrates tended to generate higher N 2 O emissions than those with more recalcitrant organic C, confirming that both C and N are major controls of N 2 O emissions from agricultural soils (Zhou et al, 2017). Increased losses of greenhouse gases from soils after frass application are likely, due to its high share of easily available N and C. Accordingly, increased CO 2 and N 2 O fluxes from forest soil amended with feces of the nun moth (Lymantria monacha L.) or feces and Scots pine needles (Pinus sylvestris L.) have been measured under laboratory conditions (Grüning et al, 2018). Information about CO 2 and N 2 O emissions of frass from commercially reared insects applied to soils is lacking.…”

Section: Introductionmentioning

confidence: 86%

Black Soldier Fly Diet Impacts Soil Greenhouse Gas Emissions From Frass Applied as Fertilizer

Rummel

Beule

Hemkemeyer

et al. 2021

Front. Sustain. Food Syst.

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Increased global production of animal-based protein results in high greenhouse gas (GHG) emissions and other adverse consequences for human and planetary health. Recently, commercial insect rearing has been claimed a more sustainable source of animal protein. However, this system also leaves residues called frass, which—depending on the insect diet—is rich in carbon (C) and nitrogen (N), and could thus be used as fertilizer in agriculture. The impact of this kind of fertilizer on soil GHG emissions is yet unknown. Therefore, we investigated the effect of black soldier fly (Hermetia illucens L.) frass derived from a carbohydrate (Carb-) or a protein (Prot-) based diet applied at two different application rates to an arable soil on C and N fluxes and microbial properties in a 40-day incubation experiment. CO2, N2O, NO, N2, CH4, water extractable organic C (WEOC), and inorganic N were continuously measured quantitatively. At the end of the incubation, microbial biomass (MB), stoichiometry, community composition, and abundance of functional genes were assessed. Along with a strong increase in WEOC and CO2, Carb-frass caused strong initial N2O emissions associated with high N and C availability. In contrast, Prot-frass showed lower CO2 emissions and N2O release, although soil nitrate levels were higher. At the end of incubation, MB was significantly increased, which was more pronounced following Carb-frass as compared to Prot-frass application, and at higher amendment rates. Fungal abundance increased most from both frass types with an even stronger response at higher application rates, whereas bacterial abundance rose following Carb-frass as compared to Prot-application. Abundance of functional genes related to ammonia-oxidizing bacteria and archaea were enhanced by high frass application but did not clearly differ between frass types. C use efficiency of microorganisms, as revealed by the metabolic quotient, was most strongly reduced in the high Prot-frass application rate. Overall, insect diet influenced available C and N in frass and thus affected mineralization dynamics, GHG emissions, and microbial growth. Overall, emissions were very high undermining the potential environmental benefit of insect based protein production and calling for more detailed analyses before frass is widely applied in agriculture.

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“…These inputs to an ~8% decrease in total soil carbon, a 13% increase in microbial biomass carbon, and a 16% increase in microbial biomass nitrogen (Gan et al, 2018). Moreover, deposition of insect frass, which is generally described as high in organic matter and nutrient content (Frost and Hunter, 2004;Watson et al, 2021), can create hot spots of high soil microbial activity with an increase in decomposition of soil organic matter (Kuzyakov et al, 2000;Filser et al, 2016;Gan et al, 2018;Watson et al, 2021), leading to subsequent increases in release of CO 2 , CH 4 , and N 2 O (Kammann et al, 2009;Fielding et al, 2013;Kammann et al, 2017;Grüning et al, 2018;Rummel et al, 2021;Watson et al, 2021). Larval movement in soil apparently represents another indirect effect.…”

Section: Jb Larvae Directly and Indirectly Increase Ghg Emissions Fro...mentioning

confidence: 99%

Larvae of an invasive scarab increase greenhouse gas emissions from soils and recruit gut mycobiota involved in C and N transformations

et al. 2023

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BackgroundSoil-derived prokaryotic gut communities of the Japanese beetle Popillia japonica Newman (JB) larval gut include heterotrophic, ammonia-oxidizing, and methanogenic microbes potentially capable of promoting greenhouse gas (GHG) emissions. However, no research has directly explored GHG emissions or the eukaryotic microbiota associated with the larval gut of this invasive species. In particular, fungi are frequently associated with the insect gut where they produce digestive enzymes and aid in nutrient acquisition. Using a series of laboratory and field experiments, this study aimed to (1) assess the impact of JB larvae on soil GHG emissions; (2) characterize gut mycobiota associated with these larvae; and (3) examine how soil biological and physicochemical characteristics influence variation in both GHG emissions and the composition of larval gut mycobiota.MethodsManipulative laboratory experiments consisted of microcosms containing increasing densities of JB larvae alone or in clean (uninfested) soil. Field experiments included 10 locations across Indiana and Wisconsin where gas samples from soils, as well as JB and their associated soil were collected to analyze soil GHG emissions, and mycobiota (ITS survey), respectively.ResultsIn laboratory trials, emission rates of CO2, CH4, and N2O from infested soil were ≥ 6.3× higher per larva than emissions from JB larvae alone whereas CO2 emission rates from soils previously infested by JB larvae were 1.3× higher than emissions from JB larvae alone. In the field, JB larval density was a significant predictor of CO2 emissions from infested soils, and both CO2 and CH4 emissions were higher in previously infested soils. We found that geographic location had the greatest influence on variation in larval gut mycobiota, although the effects of compartment (i.e., soil, midgut and hindgut) were also significant. There was substantial overlap in the composition and prevalence of the core fungal mycobiota across compartments with prominent fungal taxa being associated with cellulose degradation and prokaryotic methane production/consumption. Soil physicochemical characteristics such as organic matter, cation exchange capacity, sand, and water holding capacity, were also correlated with both soil GHG emission, and fungal a-diversity within the JB larval gut. Conclusions: Results indicate JB larvae promote GHG emissions from the soil directly through metabolic activities, and indirectly by creating soil conditions that favor GHG-associated microbial activity. Fungal communities associated with the JB larval gut are primarily influenced by adaptation to local soils, with many prominent members of that consortium potentially contributing to C and N transformations capable of influencing GHG emissions from infested soil.

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Increased Forest Soil CO2 and N2O Emissions During Insect Infestation

Cited by 8 publications

References 52 publications

Below‐ground responses to insect herbivory in ecosystems with woody plant canopies: A meta‐analysis

Below‐ground responses to insect herbivory in ecosystems with woody plant canopies: A meta‐analysis

Black Soldier Fly Diet Impacts Soil Greenhouse Gas Emissions From Frass Applied as Fertilizer

Larvae of an invasive scarab increase greenhouse gas emissions from soils and recruit gut mycobiota involved in C and N transformations

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