Abstract
Fungi are capable of both nitrification and denitrification and dominate the microbial biomass in many soils. Recent work suggests that fungal rather than bacterial pathways dominate N transformation in desert soils. We evaluated this hypothesis by comparing the contributions of bacteria and fungi to N2O production at control and N fertilized sites within a semiarid grassland in central New Mexico (USA). Soil samples were taken from the rhizosphere of blue grama (B. gracilus) and the microbiotic crusts that grow in open areas between the bunch grasses. Soils incubated at 30% or 70% water holding capacity, were exposed to one of three biocide treatments (control, cycloheximide or streptomycin). After 48 h, N2O and CO2 production were quantified along with the activities of several extracellular enzymes. N2O production from N fertilized soils was higher than that of control soils (165 vs. 41 pmol h−1 g−1), was higher for crust soil than for rhizosphere soil (108 vs. 97 pmol h−1 g−1), and increased with soil water content (146 vs. 60 pmol h−1 g−1). On average, fungicide (cycloheximide) addition reduced N2O production by 85% while increasing CO2 production by 69%; bactericide (streptomycin) reduced N2O by 53% with mixed effects on CO2 production. N2O production was significantly correlated with C and N mineralization potential as measured by assays for glycosidic and proteolytic enzymes, and with extractable nitrate and ammonium. Our data indicate that fungal nitrifier denitrification and bacterial autotrophic nitrification dominate N transformation in this ecosystem and that N2O production is highly sensitive to soil cover, N deposition and moisture.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Asner GP, Seastedt TR, Townsend AR (1997) The decoupling of terrestrial carbon and nitrogen cycles. BioScience 47:226–234
Austin AT, Yahdjian L, Stark JM, Belnap J, Porportato A, Norton U, Ravetta DA, Schaeffer SM (2004) Water pulses and biogeochemical cycles in arid and semiarid ecosystems. Oecologia 141:221–235
Báez, S, Fargione J, Moore DI, Collins SL, Gosz JR (2007) Atmospheric nitrogen deposition in the northern Chihuahuan desert: temporal trends and potential consequences. J Arid Environ 68:640–651
Belnap J (2002) Nitrogen fixation in biological soil crusts from southeast Utah, USA. Biol Fert Soils 35:128–135
Belnap J, Phillips SL, Miller ME (2004) Response of desert biological soil crusts to alterations in precipitation frequency. Oecologia 141:306–316
Bowler MA, Reed SC, Belnap J, Phillips SL (2002) Temporal variation in community composition, pigmentation, and Fv/Fm of desert cyanobacterial soil crusts. Microb Ecol 43:13–25
Castaldi S, Smith KL (1998) Effect of cycloheximide on N2O and NO3 − production in a forest and an agricultural soil. Biol and Fert Soil 27:27–34
Davidson EA, Matson PA, Vitousek PM, Riley R, Dunkin K, Garcia-Mendez G, Maass JM (1993) Processes regulating soil emissions of NO and N2O in a seasonally dry tropical forest. Ecology 74:130–139
Fenn ME, Baron JS, Allen EB, Rueth HM, Nydick KR, Geiser L, Bowman WD, Sickman JO, Meixner T, Johnson DW, Neitlich P (2003) Ecological effects of nitrogen deposition in the Western United States. BioScience 53:404–420
Fierer N, Jackson RB (2006) The diversity and biogeography of soil bacterial communities. Proc Natl Acad Sci 103:626–631
Huxman TE, Cable JM, Ignance DD, Eilts JA, English NB, Weltzin J, Williams DG (2004) Response of net ecosystem gas exchange to a simulated precipitation pulse in a semi-arid grassland: the role of native versus non-native grasses and soil texture. Oecologia 141:295–305
Johnson NC, Rowland DL, Corkidi L, Egerton-Warburton LM, Allen EB (2003) Nitrogen enrichment alters mycorrhizal allocation at five mesic to semi-arid grasslands. Ecology 84:1895–1908
Kinney CA, Moiser AR, Ferrrer I, Furlong ET, Mandernack KW (2004) The effects of the fungicides mancozeb and chlorothalonil on fluxes of CO2, N2O, and CH4 in a fertilized Colorado grassland soil. J Geophl Res-Atm 109:D05303
Laughlin RJ, Stevens RJ (2002) Evidence for fungal dominance of denitrification and codenitrification in a grassland soil. Soil Sci Soc Am J 66:1540–1548
Loik ME, Breshears DD, Lauenroth WK, Belnap J (2004) A multi-scale perspective of water pulses in dryland ecosystems: climatology and ecohydrology of the western USA. Oecologia 141:269–281
Martens DA, Loeffelmann KL (2003) Soil amino acid composition quantified by acid hydrolysis and anion chromatography-pulsed amperometry. J Agric Food Chem 51:6521–6529
McLain JET, Martens DA (2005) Nitrous oxide flux from amino acid mineralization. Soil Biol Biochem 37:289–299
McLain JET, Martens DA (2006) N2O production by heterotrophic N transformations in a semiarid soil. Appl Soil Ecol 32:253–263
Mulvaney RL (1996) Methods of soil analysis. Part 3. Chemical methods. Soil Sci Soc Am J 5:1123–1184
Mummey DL, Smith JL, Bolton H (1994) Nitrous oxide flux from a shrub-steppe ecosystem: sources and regulation. Soil Bio Biochem 26:279–286
Peterjohn WT, Schlesinger WH (1991) Factors controlling denitrification in a Chihuahuan desert ecosystem. Soil Sci Soc Am J 55:1694–1701
Phillips RL, Whalen SC, Schlesinger WH (2001) Influence of atmospheric CO2 enrichment on nitrous oxide flux in a temperate forest ecosystem. Global Biogeochem Cycles 15:741–752
Porras-Alfaro A, Herrara J, Natvig DO, Sinsabaugh RL (2007) Long-term nitrogen fertilization affects dominant mycorrhizal fungi in a semiarid grassland. Plant Soil 296:65–75
Shoun H, Kim D, Uchiyama H, Sugiyama J (1992) Denitrification by fungi. FEMS Microbiol Lett 94:277–282
Stursova M, Crenshaw CL, Sinsabaugh RL (2006) Microbial responses to long term N deposition in a semi-arid grassland. Microbial Ecol 51:90–98
Stursova M, Sinsabaugh RL (2007) Stabilization of oxidative enzymes in desert soil may limit organic matter accumulation. Soil Biol Biochem (in press). doi:10.1016/j.soilbio.2007.09.002
Virginia RA, Jarrell WM, Franco-Vizcaino E (1982) Direct measurement of denitrification in a Prosopis (mesquite) dominated Sonoran Desert ecosystem. Oecologia 53:120–122
Walvoord MA, Phillips FM, Stonestrom DA, Evans RD, Hartsough PC, Newman BD, Striegl RG (2003) A reservoir of nitrate beneath desert soils. Science 302:1021–1024
Welter JR, Fisher SG, Grimm NB (2005) Nitrogen transport and retention in an arid land watershed: influence of storm characteristics on terrestrial-aquatic linkages. Biogeochemitry 75:421–440
White CS, Pendleton RL, Pendleton BK (2006) Response of two semiarid grasslands to a second fire application. Rangeland Ecol Manage 59:98–106
Wrage N, Veithof GL, van Beusichem ML, Oenema O (2001) Role of nitrifier denitrification in the production of nitrous oxide. Soil Biol Biochem 33:1723–1732
Zak DR, Tilman D, Parmenter RR, Rice CW, Fisher FM, Vose J, Milchunas D, Martin CW (1994) Plant production and soil microorganisms in late-successional ecosystems: a continental-scale study. Ecology 75:2333–2347
Zhou A, Takaya N, Sakairi MAC, Shoun H (2001) Oxygen requirement for denitrification by the fungus Fusarium oxysporum. Arch Microbiol 175:19–25
Acknowledgements
This work was supported by a grant from the National Science Foundation, Ecosystem Science Program (DEB 0516113) and the Sevilleta LTER program.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Crenshaw, C.L., Lauber, C., Sinsabaugh, R.L. et al. Fungal control of nitrous oxide production in semiarid grassland. Biogeochemistry 87, 17–27 (2008). https://doi.org/10.1007/s10533-007-9165-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10533-007-9165-4