Decomposition of labile and recalcitrant coniferous litter fractions affected by temperature during the growing season

Veronika Jílková; Kristýna Dufková; Tomáš Cajthaml

doi:10.1007/s11676-018-00877-7

Journal of Forestry Research ›› 2019, Vol. 31 ›› Issue (4) : 1115 -1121. DOI: 10.1007/s11676-018-00877-7

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Decomposition of labile and recalcitrant coniferous litter fractions affected by temperature during the growing season

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Abstract

Temperate coniferous forest soils are considered important sinks of soil organic carbon (C). Fresh C inputs may, however, affect soil microbial activity, leading to increased organic matter decomposition and carbon dioxide production. Litter consists of labile and recalcitrant fractions which are thought to be utilized by distinct microbial communities and at different rates during the growing season. In this study, we incubated the whole litter (LC + RC), the labile (LC) and the recalcitrant (RC) fractions with the coniferous soil at two temperatures representing spring/autumn (10 °C) and summer (20 °C) for one month. Soil respiration and microbial community composition were regularly determined using phospholipid fatty acids as biomarkers. The LC fraction greatly increased soil respiration at the beginning of the incubation period but this effect was rather short-term. The effect of the RC fraction persisted longer and, together with the LC + RC fraction, respiration increased during the whole incubation period. Decomposition of the RC fraction was more strongly affected by higher temperatures than decomposition of the more labile fractions (LC and LC + RC). However, when we consider the relative increase in soil respiration compared to the dH₂O treatment, respiration increased more at a lower temperature, suggesting that available C is more important for microbial metabolism at lower temperatures. Although C was added only once in our study, no changes in microbial community composition were detected, possibly because the microbial community is adapted to relatively low amounts of additional C such as the amounts naturally found in litter.

Keywords

Temperate forest / Picea abies / Soil respiration / Hot water-extractable carbon / PLFA (phospholipid fatty acids)

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Veronika Jílková, Kristýna Dufková, Tomáš Cajthaml. Decomposition of labile and recalcitrant coniferous litter fractions affected by temperature during the growing season. Journal of Forestry Research, 2019, 31(4): 1115-1121 DOI:10.1007/s11676-018-00877-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Berg B, McClaugherty C. Plant litter. Decomposition, humus formation, carbon sequestration, 2008, Berlin: Springer.

[2]	Brady NC, Weil RR. The nature and properties of soils, 2002, Upper Saddle River: Prentice-Hall.

[3]	Cepáková Š, Tošner Z, Frouz J. The effect of tree species on seasonal fluctuations in water-soluble and hot water-extractable organic matter at post-mining sites. Geoderma, 2016, 275: 19-27.

[4]	Crow SE, Lajtha K, Bowden RD, Yano Y, Brant JB, Caldwell BA, Sulzman EW. Increased coniferous needle inputs accelerate decomposition of soil carbon in an old-growth forest. Forest Ecol Manag, 2009, 258: 2224-2232.

[5]	Don A, Kalbitz K. Amounts and degradability of dissolved organic carbon from foliar litter at different decomposition stages. Soil Biol Biochem, 2005, 37: 2171-2179.

[6]	Ekschmitt K, Liu M, Vetter S, Fox O, Wolters V. Strategies used by soil biota to overcome soil organic matter stability - why is dead organic matter left over in the soil?. Geoderma, 2005, 128: 167-176.

[7]	Frankland JC. Fungal succession—unravelling the unpredictable. Mycol Res, 1998, 102: 1-15.

[8]	Ghani A, Dexter M, Perrott KW. Hot-water extractable carbon in soils: a sensitive measurement for determining impacts of fertilisation, grazing and cultivation. Soil Biol Biochem, 2003, 35: 1231-1243.

[9]	Jílková V, Cajthaml T, Frouz J. Respiration in wood ant (Formica aquilonia) nests as affected by altitudinal and seasonal changes in temperature. Soil Biol Biochem, 2015, 86: 50-57.

[10]	Jílková V, Cajthaml T, Frouz J. Relative importance of honeydew and resin for the microbial activity in wood ant nest and forest floor substrate—a laboratory study. Soil Biol Biochem, 2018, 117: 1-4.

[11]	Joly F-X, Fromin N, Kiikkilä O, Hättenschwiler S. Diversity of leaf litter leachates from temperate forest trees and its consequences for soil microbial activity. Biogeochemistry, 2016, 129: 373-388.

[12]	Kalbitz K, Meyer A, Yang R, Gerstberger P. Response of dissolved organic matter in the forest floor to long-term manipulation of litter and throughfall inputs. Biogeochemistry, 2007, 86: 301-318.

[13]	Kammer A, Schmidt MWI, Hagedorn F. Decomposition pathways of ¹³C-depleted leaf litter in forest soils of the Swiss Jura. Biogeochemistry, 2012, 108: 395-411.

[14]	Karhu K, Fritze H, Tuomi M, Vanhala P, Spetz P, Kitunen V, Liski J. Temperature sensitivity of organic matter decomposition in two boreal forest soil profiles. Soil Biol Biochem, 2010, 42: 72-82.

[15]	Koranda M, Kaiser C, Fuchslueger L, Kitzler B, Sessitsch A, Zechmeister-Boltenstern S, Richter A. Fungal and bacterial utilization of organic substrates depends on substrate complexity and N availability. FEMS Microbiol Ecol, 2014, 87: 142-152.

[16]	Kuzyakov Y, Friedel JK, Stahr K. Review of mechanisms and quantification of priming effects. Soil Biol Biochem, 2000, 32: 1485-1498.

[17]	Lal R. Soil carbon stocks under present and future climate with specific reference to European ecoregions. Nutr Cycl Agroecosyst, 2008, 81: 113-127.

[18]	Manzoni S, Taylor P, Richter A, Taylor P, Richter A, Porporato A, Agren GI. Environmental and stoichiometric controls on microbial carbon-use efficiency in soils. New Phytol, 2012, 196: 79-91.

[19]	Marschner B, Kalbitz K. Controls of bioavailability and biodegradability of dissolved organic matter in soils. Geoderma, 2003, 113: 211-235.

[20]	Paterson E, Osler G, Dawson LA, Gebbing T, Sim A, Ord B. Labile and recalcitrant plant fractions are utilised by distinct microbial communities in soil: independent of the presence of roots and mycorrhizal fungi. Soil Biol Biochem, 2008, 40: 1103-1113.

[21]	Paterson E, Sim A, Osborne SM, Murray PJ. Long-term exclusion of plant inputs to soil reduces the functional capacity of microbial communities to mineralise recalcitrant root-derived carbon sources. Soil Biol Biochem, 2011, 43: 1873-1880.

[22]	Paul EA, Clark FE. Soil microbiology and biochemistry, 1996, San Diego: Academic Press.

[23]	Persson T, Bååth E, Clarholm M, Lundkvist H, Söderström B, Sohlenius B. Trophic structure, biomass dynamics and carbon metabolism of soil organisms in a Scots pine forest. Ecol Bull (Stockholm), 1980, 32: 419-462.

[24]	Qualls RG, Haines BL. Geochemistry of dissolved organic nutrients in water percolating through a forest ecosystem. Soil Sci Soc Am J, 1991, 55: 1112-1123.

[25]	Raich JW, Russell AE, Kitayama K, Parton WJ, Vitousek PM. Temperature influences carbon accumulation in moist tropical forests. Ecology, 2006, 87: 76-87.

[26]	Schlesinger WH, Andrews JA. Soil respiration and the global carbon cycle. Biogeochemistry, 2000, 48: 7-20.

[27]	Šnajdr J, Valášková V, Merhautová V, Cajthaml T, Baldrian P. Activity and spatial distribution of lignocellulose-degrading enzymes during forest soil colonization by saprotrophic basidiomycetes. Enzyme Microbiol Technol, 2008, 43: 186-192.

[28]	Sparling G, Vojvodic-Vukovic M, Schipper LA. Hot-water-soluble C as a simple measure of labile soil organic matter: the relationship with microbial biomass C. Soil Biol Biochem, 1998, 30: 1469-1472.

[29]	Swift MJ, Heal OW, Anderson JM. Decomposition in terrestrial ecosystems, 1979, Oxford: Blackwell.

[30]	Tyrrell ML, Ross J, Kelty M. Ashton MS, Tyrrell ML, Spalding D, Gentry B. Carbon dynamics in the temperate forest. Managing forest carbon in a changing climate, 2012, New York: Springer 77 107

[31]	Valášková V, Šnajdr J, Bittner B, Cajthaml T, Merhautová V, Hofrichter M, Baldrian P. Production of lignocellulose-degrading enzymes and degradation of leaf litter by saprotrophic basidiomycetes isolated from a Quercus petraea forest. Soil Biol Biochem, 2007, 39: 2651-2660.

[32]	von Lützow M, Kögel-Knabner I. Temperature sensitivity of soil organic matter decomposition—what do we know?. Biol Fertil Soils, 2009, 46: 1-15.

[33]	Wang Q, Suping L, Silong W. Debris manipulation alters soil CO₂ efflux in a subtropical plantation forest. Geoderma, 2013, 192: 316-322.

[34]	Wardle DA. A comparative assessment of factors which influence microbial biomass carbon and nitrogen levels in soil. Biol Rev, 1992, 67: 321-358.

[35]	Wardle D, Bardgett R, Klironomos J. Ecological linkages between aboveground and belowground biota. Science, 2004, 304: 1629-1633.

[36]	White RE. Principles and practice of soil science, 1997, Oxford: Blackwell Science.

[37]	Xu W, Li W, Jiang P, Wang H, Bai E. Distinct temperature sensitivity of soil carbon decomposition in forest organic layer and mineral soil. Sci Rep, 2014, 4: 6512.

[38]	Zsolnay A, Steindl H. Geovariability and biodegradability of the water-extractable organic material in an agricultural soil. Soil Biol Biochem, 1991, 23: 1077-1082.