Nitrogen addition changes grassland soil organic matter decomposition

Riggs, Charlotte E.; Hobbie, Sarah E.; Bach, Elizabeth M.; Hofmockel, Kirsten; Kazanski, Clare E.

doi:10.1007/s10533-015-0123-2

Cited by 168 publications

(136 citation statements)

References 81 publications

Supporting

Mentioning

114

Contrasting

Order By: Relevance

“…This also agrees with the findings from a long-term N fertilization experiment in meadow communities of alpine tundra, which suggest that under chronic N addition detritus plant material can move directly into stabilized mineral-associated organic matter pools (Neff et al 2002). Finally, our finding agrees with the observation that N fertilization can contribute to C accumulation and stabilization in small mineral-associated soil aggregates (Riggs et al 2015).…”

Section: Discussionsupporting

confidence: 91%

Chronic nitrogen fertilization and carbon sequestration in grassland soils: evidence of a microbial enzyme link

et al. 2015

View full text Add to dashboard Cite

Chronic nitrogen (N) fertilization can greatly affect soil carbon (C) sequestration by altering biochemical interactions between plant detritus and soil microbes. In lignin-rich forest soils, chronic N additions tend to increase soil C content partly by decreasing the activity of lignin-degrading enzymes. In cellulose-rich grassland soils it is not clear whether cellulose-degrading enzymes are also inhibited by N additions and what consequences this might have on changes in soil C content. Here we address whether chronic N fertilization has affected (1) the C content of light versus heavier soil fractions, and (2) the activity of four extracellular enzymes including the C-acquiring enzyme b-1,4-glucosidase (BG; necessary for cellulose hydrolysis). We found that 19 years of chronic N-only addition to permanent grassland have significantly increased soil C sequestration in heavy but not in light soil density fractions, and this C accrual was associated with a significant increase (and not decrease) of BG activity. Chronic N fertilization may increase BG activity because greater N availability reduces root C:N ratios thus increasing microbial demand for C, which is met by C inputs from enhanced root C pools in N-only fertilized soils. However, BG activity and total root mass strongly decreased in high pH soils under the application of lime (i.e. CaCO 3 ), which reduced the ability of these organo-mineral soils to gain more C per units of N added. Our study is the first to show a potential 'enzyme link' between (1) long-term additions of inorganic N to grassland soils, and (2) the greater C content of organo-mineral soil fractions. Our new hypothesis is that the 'enzyme link' occurs because (a) BG activity is stimulated by increased microbial C demand relative to N under chronic fertilization, and (b) increased BG activity causes more C from roots and from microbial Responsible Editor: Sharon A. Billings. Electronic supplementary materialThe online version of this article

show abstract

Section: Discussionsupporting

confidence: 91%

Chronic nitrogen fertilization and carbon sequestration in grassland soils: evidence of a microbial enzyme link

et al. 2015

View full text Add to dashboard Cite

show abstract

“…Therefore, we interpret CO 2 production at the end of the incubation to be from a recalcitrant pool. It is possible to use microbial respiration data to model the size and decay rates of soil carbon pools (see Riggs et al 2015), but our analysis focuses on differences in soil respiration rates and the decay of these rates during the incubation period. We used Akaike's information criterion to identify the best (lowest AICc) and other plausible models (DAICc \ 2) for each sample.…”

Section: Soil Carbon Quality Across Landscape Age and Climate Gradientsmentioning

confidence: 99%

Soil carbon storage, respiration potential, and organic matter quality across an age and climate gradient in southwestern Greenland

Bradley-Cook

Virginia

2015

Polar Biol

View full text Add to dashboard Cite

Geological factors influence biological cycling of organic carbon in soils but are not well represented in our understanding of Arctic carbon dynamics. Landscape age, for instance, directly affects quantity and quality of soil carbon, which are two strong controls of the temperature sensitivity of soil organic matter. We investigated soil carbon storage, respiration potential, and organic matter quality for microbial decomposition across a climate and landscape age gradient in southwest Greenland that deglaciated during the Holocene. We measured soil respiration during a 370-day laboratory incubations of active layer soils collected from four study areas across this gradient (ages 1.8 9 10 2 , 6.8 9 10 3 , and 1.0 9 10 4 , coinciding with a climate gradient from drier inland to wetter coastal terrain) and used a soil respiration model comparison approach to assess the substrate quality of stored organic matter for microbial decomposers. Soils store more than three times greater organic carbon at the 10,000-year-old, maritime climate study areas than the 180-year-old, continental climate study areas. Respiration rates were highest in the surface soils of the coastal areas. Model comparisons reveal important heterogeneity in the quality of organic matter for microbial decomposition between areas: coastal soils were best modeled by both one-and two-pooled models, and inland soils were best represented by one-pooled respiration models. Together, the measures of carbon quality (C:N, CO 2 production, and model parameters estimating initial CO 2 production rates from different organic matter pools) show that shallow soils at the southern coastal area, Kobbefjord, had the highest respiration rates from the recalcitrant carbon pool. This study reveals differences in carbon storage and turnover associated with landscape age and climate factors in western Greenland. When applied to thermodynamic theory, which predicts that temperature sensitivity increases with carbon recalcitrance, our findings suggest that carbon stored in coastal soils may be more sensitive to climate warming than inland soils.

show abstract

“…Soil organic carbon (SOC), which is the largest carbon reservoir in the terrestrial biosphere, contains two to four times the amount of carbon in the atmosphere. Consequently, either positive or negative changes of soil carbon storage, in response to N deposition, could lead to significant alteration in the carbon dioxide (CO 2 ) concentration of atmosphere (Riggs et al, 2015;Zak et al, 2017), and thus have implications for future global climate change.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies revealed that soil N input has the potential to decrease microbial decomposition of SOC and thereby increase soil carbon storage (Ramirez et al, 2012;Zhou et al, 2014;Riggs et al, 2015). Although this negative effect of N input on microbial decomposition of SOC seems paradoxical since the increased input of plant litter and root exudates induced by N enrichment may increase carbon availability to microbes (Liu and Greaver, 2010), a number of microbial mechanisms have been proposed to explain why microbial decomposition of SOC decreases with N addition (Riggs and Hobbie, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Thus, responses of SOC decomposition to N addition may be more strongly associated with the level of physicochemical protection (aggregate occlusion and mineral association) than with the biochemical composition of organic substrates. Although previous studies have documented the effects of N additions on the distribution of SOC in different functional fractions (Cusack et al, 2011;Riggs et al, 2015;Xu et al, 2016;Zak et al, 2017), very few studies examined the heterogeneous responses of SOC decomposition rates in different physical and chemical fractions to N enrichments (but see Neff et al, 2002;Cusack et al, 2010). Clearly, the mechanisms regarding these heterogeneous responses warrant investigation given their expected importance to understand soil carbon emissions in the context of increasing N deposition.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Physico-chemical protection, rather than biochemical composition, governs the responses of soil organic carbon decomposition to nitrogen addition in a temperate agroecosystem

Tan¹,

Wang

Huang

et al. 2017

Science of The Total Environment

View full text Add to dashboard Cite

Nitrogen addition changes grassland soil organic matter decomposition

Cited by 168 publications

References 81 publications

Chronic nitrogen fertilization and carbon sequestration in grassland soils: evidence of a microbial enzyme link

Chronic nitrogen fertilization and carbon sequestration in grassland soils: evidence of a microbial enzyme link

Soil carbon storage, respiration potential, and organic matter quality across an age and climate gradient in southwestern Greenland

Physico-chemical protection, rather than biochemical composition, governs the responses of soil organic carbon decomposition to nitrogen addition in a temperate agroecosystem

Contact Info

Product

Resources

About