Summary
Microbial biomass, nutrient (N and P) status, and carbon and nutrient limitation of the microflora were investigated in soils from five different sites (field, 5-, 12-, and about 50-year-old fallow, beechwood), which represent different stages of a secondary succession from a wheat field to the climax ecosystem of a beechwood on limestone. In addition, the effect of faeces production by the substrate feeding earthworm species Octolasion lacteum (Örley) on the nutrient status of the soil microflora of these sites was studied. Humus had accumulated in the soil of the third fallow site, with an enhanced biomass of microflora. However, in the beechwood soil, which had the highest humus content, microbial biomass was lower than in the soil of the third fallow site and similar to that of the field and the two younger fallow sites. In general, soil microbial biomass was little affected by the passage of soil through the gut of O. lacteum. The soil microflora of the field, the 5-, 12-, and about 50-year-old fallow was limited by carbon, whereas in the beechwood soil phosphorus limited microbial growth. NItrogen availability to the soil microflora was low in the two younger fallow sites and high in the field and the third fallow. In the beechwood soil nitrogen supply did not affect microbial carbon utilization. Application of phosphorus stimulated glucose mineralization in the soil of the field, the third fallow, and the beechwood, but not in the two younger fallow sites. Therefor, the nutrient status of the soil microflora seems to have changed during secondary succession: presumably, during the first phase the availability of nitrogen decreased, whereas during the second phase microbial phosphorus supply became more important, which resulted in phosphorus limitation of the soil microflora in the climax ecosystem. The passage of soil through the gut of O. lacteum caused an alteration in the microbial nutrient status. Generally, microbial growth in earthworm casts was limited by carbon. The relative effect of the gut passage of the soils on microbial carbon utilization seems to increase during succession. Therefore, the effect of decomposer invertebrates on microbial nutrient supply seems to increase during secondary succession. In general, nitrogen did not limit microbial carbon utilization in earthworm casts. Phosphorus requirements of the soil microflora were lowered by the gut passage of the soil of the third fallow site and the beechwood, which indicates an increased phosphorus supply in earthworm casts. Howerver, this additional supply was not sufficient to enable optimal carbon utilization by the soil microflora. The results indicate that the effect of decomposer invertebrates on the soil microflora depends on the nutrient status of the ecosystem.
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References
Aldag R, Graff O (1975) N-Fraktionen in Regenwurmlosung und deren Ursprungsboden. Pedobiologia 15:151–153
Anderson JM (1987) Interactions between invertebrates and microorganisms: noise or necessity for soil processes. In. Ecology of microbial communities. Cambridge University Press, Cambridge, pp 125–145
Anderson JM (1988) Spatiotemporal effects of invertebrates on soil processes. Biol Fertil Soils 7:216–227
Anderson JM, Ineson P (1984) Interactions between microorganisms and soil invertebrates in nutrient flux pathways of forest ecosystems. In: Anderson JM, Rayner ADM, Walton DWH (eds) Invertebrate-microbial interactions Cambridge University Press, Cambridge, pp 59–88
Anderson JPE, Domsch KH (1978) A physiological method for the quantitative measurement of microbial biomass in soils. Soil Biol Biochem 10:215–221
Anderson JPE, Domsch K (1980) Quantities of plant nutrients in the microbial biomass of selected soils. Soil Science 130:211–216
Coleman DC, Reid CPP, Cole CV (1983) Biological strategies of nutrient cycling in soil systems. In: Macfadyen A, Ford ED (eds) Advances in ecological research 13, New York, pp 1–13
Czerwinski Z, Jakubczyk H, Nowak E (1974) Analyses of sheep pasture ecosystem in the Pieniny Mountainns (The Carpathians). XII. The effect of earthworms on the pasture soil. Ekol Pol 22:635–650
Diaz-Ravina M, Carballas T, Acea MJ (1988) Microbial biomass and metabolic activity in four acid soils. Soil Biol Biochem 20:817–824
Domsch KH (1982) Produktion und Umsetzung mikrobieller Biomasse im Boden. Arbeitsber SFB 135 (1):175–208
Evans AC (1947) A method for studying the burrowing activities of earthworms. Ann Mag Nat Hist 14:643
Golley FB, Gentry JB (1965) A comparison of variety and standing crop of vegetation on a one-year and a twelve-year abandoned field. Oikos 15:185–199
Graff O (1971) Stickstoff, Phosphor und Kalium in der Regenwurmlosung auf der Wiesenversuchsfläche des Sollingprojektes. Ann Zool Ecol Anim, Special Publ 4, 503–512
Hahn W, Wolf A, Schmidt W (1979) Untersuchungen zum Stickstoff-Umatz von Tussilago farfara- und Agropyron repens-Beständen. Verh Ges Ökologie 7:369–380
Insam H, Domsch KH (1988) Relationship between soil organic carbon and microbial biomass on chronosequences of reclaimed sites. Microb Ecol 15:177–188
Lee KE (1985) Earthworms. Sydney, Academic Press, pp 411
Loquet M, Bhatnagar T, Bouché MB, Rouelle J (1977) Essai d'estimation de l'influence écologique des lombricienes sur le microorganismes. Pedobiologia 17:400–417
Mansell GP, Syers JK, Gregg PEH (1981) Plant availability of phosphorus in dead herbage ingested by surface casting earthworms. Soil Biol Biochem 13:163–167
Odum EP (1960) Organic production and turnover in old field succession. Ecology 41:34–49
Ottow JCG, Fabig W (1984) Einfluß der Sauerstoffbegasung auf die Denitrifikationsintensität (aerobe Denitrifikation) und das Redoxniveau unterschiedlicher Bakterien. Landwirtsch Forsch 37:453–470 (Kongreßband 1984)
Reiners WA (1981) Nitrogen cycling in relation to ecosystem succession. In: Clark EF, Rosswall T (eds) Terrestrial nitrogen cycles. Ecol Bull 33, Stockholm, pp 507–528
Schaefer M (1990) The soil fauna of a beech forest on limestone: trophic structure and energy budget. Oecologia 82:128–136
Scheu S (1987a) The role of substrate feeding earthworms (Lumbricidae) for bioturbation in a beechwood soil. Oecologia 72:192–196
Scheu S (1987b) Microbial activity and nutrient dynamics in earthworm casts (Lumbricidae). Biol Fertil Soils 5:230–234
Scheu S (1987c) The influence of earthworms (Lumbricidae) on the nitrogen dynamics in the soil litter system of a deciduous forest. Oecologia 72:197–201
Scheu S (1990) Die saprophage Makrofauna (Diplopoda, Isopoda und Lumbricidae) in Lebensräumen auf Kalkgestein: Sukzession und Stoffumsatz. Berichte des Forschungszentrums Waldökosysteme, Reihe A, Band 57:1–302
Scheu S, Sprengel T (1989) Die Rolle der endogäischen Regenwürmer im Ökosystem Kalkbuchenwald und ihre Wechselwirkung mit saprophagen Makroarthropoden. Verh Ges Ökologie 17:237–243
Schnürer J, Clarholm M, Rosswall T (1985) MIcrobial biomass and activity in an agricultural soil with different organic matter content. Soil Biol Biochem 17:611–618
Sharpley AN, Syers JK (1977) Seasonal variation in casting activity and in the amounts and release to solution of phosphorus forms in earthworm casts. Soil Biol Biochem 9:227–231
Sokal RR, Rohlf FJ (1981) Biometry. The principals and practice of statistics in biological sciences, 2nd ed. Freeman and Company, New York
Vitousek PM (1981) Clear-cutting and the nitrogen cycle. In: Clark FE, Rosswall T (eds) Terrestrial nitrogen cycles. Ecol Bull 33, Stockholm, pp 631–642
Wiegert RG, McGinnis JT (1975) Annual production and disappearance of detritus on three South Carolina old fields. Ecology 56:129–140
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Scheu, S. Changes in microbial nutrient status during secondary succession and its modification by earthworms. Oecologia 84, 351–358 (1990). https://doi.org/10.1007/BF00329758
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DOI: https://doi.org/10.1007/BF00329758