Abstract
Activity of soil decomposer microorganisms is generally limited by carbon availability, but factors controlling saprophagous soil animals remain largely unknown. In contrast to microorganisms, animals are unable to exploit mineral nutrient pools. Therefore, it has been suggested that soil animals, and earthworms in particular, are limited by the availability of nitrogen. In contrast to this view, a strong increase in density and biomass of endogeic earthworms in response to labile organic carbon addition has been documented in field experiments. The hypothesis that the growth of endogeic earthworms is primarily limited by carbon availability was tested in a laboratory experiment lasting for 10 weeks. In addition, it was investigated whether the effects of earthworms on microbial activity and nutrient mineralization depend on the availability of carbon resources. We manipulated food availability to the endogeic earthworm species Octolasion tyrtaeum by using two soils with different organic matter content, providing access to different amounts of soil, and adding labile organic carbon (glucose) enriched in 13C.
Glucose addition strongly increased the growth of O. tyrtaeum. From 8 to 17% of the total C in earthworm tissue was assimilated from the glucose added. Soil microbial biomass was not strongly affected by the addition of glucose, though basal respiration was significantly increased and up to 50% of the carbon added as glucose was incorporated into soil organic matter. The impact of earthworms on the mineralization and leaching of nitrogen depended on C availability. As expected, in C-limited soil, the presence of earthworms strongly increased nitrogen leaching. However, when C availability was increased by the addition of glucose, this pattern was reversed, i.e. the presence of O. tyrtaeum decreased nitrogen leaching and its availability to soil microflora. We conclude that irrespective of the total carbon content of soils, O. tyrtaeum was primarily limited by carbon, and that increased carbon availability allowed earthworms to be more effective in mobilizing N. The presence of earthworms increases C limitation of soil microorganisms, due to increased availability of N and P in earthworm casts or a direct depletion of easily available carbon resources by earthworms.
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References
Alphei J, Bonkowski M, Scheu S (1996) Protozoa, Nematoda and Lumbricidae in the rhizosphere of Hordelymus europaeus (Poaceae): faunal interactions, response of microorganisms and effects on plant growth. Oecologia 106:111–126
Anderson JPE, Domsch KH (1978) A physiological method for the quantitative measurement of microbial biomass in soil. Soil Biol Biochem 10:215–221
Beare MH, Coleman DC, Crossley DA Jr, Hendrix PF, Odum EP (1995) A hierarchical approach to evaluating the significance of soil biodiversity to biogeochemical cycling. Plant Soil 170:5–22
Beck T, Joergensen RG, Kandeler E, Makeschin F, Nuss E, Oberholzer HR, Scheu S (1997) An inter-laboratory comparison of ten different ways of measuring soil microbial biomass C. Soil Biol Biochem 29:1023–1032
Bolton PJ, Phillipson J (1976) Burrowing, feeding, egestion and energy budgets of Allolobophora rosea (Savigny). Oecologia 23:225–245
Cheng WX, Zhang QL, Coleman DC, Carroll CR, Hoffman CA (1996) Is available carbon limiting microbial respiration in the rhizosphere? Soil Biol Biochem 28:1283–1288
Clarholm M (1994) The microbial loop. In: Ritz K, Dighton J, Giller KE (eds) Beyond the biomass. Wiley, New York, pp 221–230
Daufresne T, Loreau M (2001) Ecological stoichiometry, primary producer-decomposer interactions, and ecosystem persistence. Ecology 82:3069–3082
Doube BM, Brown GG (1998) Life in a complex community: functional interactions between earthworms, organic matter, microorganisms, and plant growth. In: Edwards CA (ed) Earthworm ecology. St. Lucie, Boca Raton, pp 179–211
Gunnarsson T, Tunlid A (1986) Recycling of fecal pellets in isopodes: microorganisms and nitrogen compounds as potential food for Onicus asellus L. Soil Biol Biochem 18:595–600
Helal HM, Sauerbeck D (1986) Effect of plant roots on carbon metabolism of soil microbial biomass. Z Pflanzenernaehr Bodenkd 149:181–188
Joergensen RG, Scheu S (1999) Response of soil microorganisms to the addition of carbon, nitrogen and phosphorus in a forest rendzina. Soil Biol Biochem 31:859–866
Jonasson S, Vestergaard P, Jensen M, Michelsen A (1996) Effects of carbohydrate amendments on nutrient partitioning, plant and microbial performance of a grassland-shrub ecosystem. Oikos 75:220–226
Jonasson S, Michelsen A, Schmidt IK (1999) Coupling of nutrient cycling and carbon dynamics in the Arctic, integration of soil microbial and plant processes. Appl Soil Ecol 11:135–146
Kaye JP, Hart SC (1997) Competition for nitrogen between plants and soil microorganisms. Trends Ecol Evol 12:139–143
Keeney DR, Nelson DW (1982) Nitrogen—inorganic forms. In: Page AL, Miller RH, Keeney DR (eds) Methods of soil analysis, part 2. Chemical and microbiological properties. American Society of Agronomy, Madison, pp 643–698
Lee KE (1985) Earthworms; their ecology and relationships with soils and land use. Academic, Sydney
Lussenhop L (1992) Mechanisms of microarthropod-microbial interactions in soil. Adv Ecol Res 23:1–33
Magill AH, Aber JD (2000) Variation in soil net mineralization rates with dissolved organic carbon additions. Soil Biol Biochem 32:597–601
Mikola J, Setälä H (1998) Productivity and trophic-level biomasses in a microbial-based soil food web. Oikos 82:158–168
Olsen SR, Sommers LE (1982) Phosphorus. In: Page AL, Miller RH, Keeney DR (eds) Methods of soil analysis, part 2. Chemical and microbiological properties. American Society of Agronomy, Madison, pp 403–430
Parmelee RW, Bohlen PJ, Blair JM (1998) Earthworms and nutrient cycling processes: integrating across the ecological hierarchy. In: Edwards CA (ed) Earthworm ecology. St. Lucie, Boca Raton, pp 123–143
Petersen H, Luxton MA (1982) A comparative analysis of soil fauna populations and their role in decomposition process. Oikos 39:287–388
Phillips DL, Gregg JW (2002) Uncertainty in source partitioning using stable isotopes. Oecologia 127:171–179
Pokarzhevskii AD, Straalen NM van, Zaboev DP, Zaitsev AS (2003) Microbial links and element flows in nested detrital food-webs. Pedobiologia 47:213–224
Reineking A, Langel R, Schikowski J (1993) 15-N, 13-C-on-line measurements with an elemental analyser (Carlo Erba, NA 1500), a modified trapping box and a gas isotope mass spectrometer (Finnigan, MAT 251). Isotpenpraxis 29:169–174
Satchell JE (1983) Earthworm ecology in forest soils. In: Satchell JE (ed) Earthworm ecology from Darwin to vermiculture. Chapman & Hall, London, pp 161–170
Schaefer M (1991) Fauna of the European temperate deciduous forest. In: Röhrig E, Ulrich M (eds) Temperate deciduous forests. Elsevier, Amsterdam, pp 503–525
Scheu S (1987) The role of substrate feeding earthworms (Lumbricidae) for bioturbation in a beechwood soil. Oecologia 72:192–196
Scheu S (1990) Changes in microbial nutrient status during secondary succession and its modification by earthworms. Oecologia 84:351–358
Scheu S (1991) Mucus excretion and carbon turnover of endogeic earthworms. Biol Fertil Soils 12:217–220
Scheu S (1992) Automated measurement of the respiratory response of soil microcompartments—active microbial biomass in earthworm faeces. Soil Biol Biochem 24:1113–1118
Scheu S (1993) Analysis of the microbial nutrient status in soil microcompartments: earthworm faeces from a basalt-limestone gradient. Geoderma 56:575–586
Scheu S (2003) Effects of earthworms on plant growth: patterns and perspectives. Pedobiologia (in press)
Scheu S, Schaefer M (1998) Bottom-up control of the soil macrofauna community in a beechwood on limestone: manipulation of food resources. Ecology 79:1573–1585
Schönholzer F, Hahn D, Zeyer J (1999) Origins and fate of fungi and bacteria in the gut of Lumbricus terrestris L. studied by image analysis. FEMS Microbiol Ecol 28:235–248
Seastedt TR, James SW, Todd TC (1988) Interactions among soil invertebrates, microbes and plant growth in the tallgrass prairie. Agric Ecosyst Environ 24:219–228
Theenhaus A, Scheu S (1996) Successional changes in microbial biomass, activity and nutrient status in faecal material of the slug Arion rufus (Gastropoda) deposited after feeding on different plant materials. Soil Biol Biochem 28:569–577
Vance ED, Chapin III FS (2001) Substrate limitations to microbial activity in taiga forest floors. Soil Biol Biochem 33:173–188
White TRC (1993) The inadequate environment: nitrogen and the abundance of animals. Springer, Berlin
Willems JJGM, Marinissen JCY, Blair J (1996) Effects of earthworms on nitrogen mineralization. Biol Fertil Soils 23:57–63
Wolter C, Scheu S (1999) Changes in bacterial numbers and hyphal lengths during the gut passage through Lumbricus terrestris (Lumbricidae, Oligochaeta). Pedobiologia 43:891–900
Wolters V (1991) Soil invertebrates—effects on nutrient turnover and soil structure—a review. Z Pflanzenernaehr Bodenkd 154:389–402
Wolters V, Joergensen RG (1992) Microbial carbon turnover in beech forest soils worked by Aporrectodea caliginosa (Savigny) (Oligochaeta, Lumbricidae). Soil Biol Biochem 24:171–177
Acknowledgements
The preparation of the manuscript was supported through an Alexander von Humboldt fellowship awarded to A.V.T. The experiments were performed at the Institute of Zoology, University of Göttingen. Financial support by the Volkswagen-Stiftung is gratefully acknowledged.
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Tiunov, A.V., Scheu, S. Carbon availability controls the growth of detritivores (Lumbricidae) and their effect on nitrogen mineralization. Oecologia 138, 83–90 (2004). https://doi.org/10.1007/s00442-003-1391-4
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DOI: https://doi.org/10.1007/s00442-003-1391-4