Soil under dead or live organic matter systems: Effect of European shag (<i>Phalacrocorax aristotelis</i> L.) nesting on soil nematodes and nutrient mineralization

Manuel Aira; Jorge Domínguez

doi:10.1007/s42832-020-0023-9

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Soil Ecology Letters ›› 2020, Vol. 2 ›› Issue (1) : 40-46. DOI: 10.1007/s42832-020-0023-9

RESEARCH ARTICLE

Soil under dead or live organic matter systems: Effect of European shag (Phalacrocorax aristotelis L.) nesting on soil nematodes and nutrient mineralization

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Abstract

Here we studied whether soil systems differ if they are under the influence of live (plants) or dead organic matter systems (nest) in terms of C and N mineralization, microbiological characteristics and nematode trophic group structure. We analyzed physicochemical and microbiological properties of soils inside and outside nests of the European shag (Phalacrocorax aristotelis, L.) on the Cíes Islands (NW Spain). We sampled fresh soil below dead (nests) and live organic matter (plants) (paired samples, n=7). Soil of nests had lower organic matter and higher electric conductivity and dissolved organic C and extractable N contents than the soil of plants. Microbial biomass and activity were greater in soil of nests than in soil of plants. The abundance of nematode trophic groups (bacterivores, fungivores, omnivores and herbivores) differred between soils of nests and plants, and the soil of plants supported a more abundant and diverse nematode community. The present results points to that source of organic matter promote differences in the decomposer community, being more efficient in soil of nests because C mineralization is greater. Further, this occurred independently of the complexity of the systems, higher in the soil of plants with more groups of nematodes.

Keywords

C and N mineralization / Decomposer food web / Nematode trophic structure / Microbial biomass

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Manuel Aira, Jorge Domínguez. Soil under dead or live organic matter systems: Effect of European shag (Phalacrocorax aristotelis L.) nesting on soil nematodes and nutrient mineralization. Soil Ecology Letters, 2020, 2(1): 40‒46 https://doi.org/10.1007/s42832-020-0023-9

References

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

[1]	Anderson, J.P.E., 1982. Soil respiration, in: Page, A.L., Miller, R.H., (Eds.), Methods of Soil Analysis, Part 2, Chemical and Microbiological Properties 2nd edition. Agronomy mono graph No. 9, ASA-SSSA, Madison, WI, pp 831–871.

[2]	Adu, J.K., Oades, J.M., 1978. Utilization of organic materials in soil aggregates by bacteria and fungi. Soil Biology and Biochemistry 10, 117–122.

[3]

Balloni, W., Favilli, F., 1987. Effects of agricultural practices on the physical, chemical and biochemical properties of soils. Part I. Effect of some agricultural practices on the biological soil fertility, in: Barth, H., and Hermite, P.L., (Eds.), Scientific Basis for Soil Protection in the European Community, Elsevier, London, pp 161–175.

[4]	Bancroft, W.J., Garkaklisb, M.J., Roberts, J.D., 2005. Burrow building in seabird colonies: a soil-forming process in island ecosystems. Pedobiologia 49, 149–165.

[5]	Bardgett, R.D., Wardle, D.A., 2010. Aboveground-belowground linkages. Biotic interactions, ecosystem processes, and global change. Oxford University Press

[6]	Beare, M.H., Parmelee, R.W., Hendrix, P.F., Cheng, W., 1992. Microbial and faunal interactions and effects on litter nitrogen and decomposition in agroecosystems. Ecological Monographs 62, 569–591.

[7]	Brockway, D.G., Outcalt, K.W., Wilkins, R.N., 1998. Restoring longleaf pine wiregrass ecosystems: plant cover, diversity and biomass following long-rate hexazinone application on Florida sandhills. Forest Ecology and Management 103, 159–175.

[8]	Cabrera, M.L., Beare, M.H., 1993. Alkaline persulfate oxidation for determining total nitrogen in microbial biomass extracts. Soil Science Society of America Journal 57, 1007–1012.

[9]	Coûteaux, M.M., Darbyshire, J.F., 1998. Functional diversity amongst soil protozoa. Applied Soil Ecology 10, 229–237.

[10]	Denslow, J., 2001. The ecology of insular biotas. Trends in Ecology and Evolution 16, 423–424.

[11]	Foth, H.D., Turk, L.M., 1981. Fundamentos de la ciencia del suelo. Compañía Editorial Continental, México

[12]	Fukami, T., Wardle, D.A., Bellingham, P.J., Mulder, C.P.H.,Towns, D.R., Yeates, G.W., Bonner, K.Y., Durrett, M.S., Grant-Hoffman, M.N., Williamson, W.M., 2006. Above- and below-ground impacts of introduced predators in seabird-dominated island ecosystems. Ecology Letters 9, 1299–1307.

[13]	Harrow, G., Hawke, D.J., Holdaway, R.N., 2006. Surface soil chemistry at an alpine procellariid breeding colony in New Zealand, and comparison with a lowland site. New Zealand Journal of Zoology 33, 165–174. CrossRef Google scholar

[14]	Herrera, C.M., 2000. Flower-to-seedling consequences of different pollination regimes in an insect-pollinated shrub. Ecology 81, 15–29.

[15]	Hobara, S., Koba, K., Osono, T., Tokuchi, N., Ishida, A., Kameda, K., 2005. Nitrogen and phosphorus enrichment and balance in forests colonized by cormorants: Implications of the influence of soil adsorption. Plant and Soil 268, 89–101.

[16]	Ingham, R.E., Trofymow, J.A., Ingham, E.R., 1985. Interactions of bacteria, fungi, and their nematode grazers: effects on nutrient cycling and plant growth. Ecological Monographs 55, 119–140.

[17]	Joergensen, R.G., Scheu, S., 1999. Response of soil microorganisms to the addition of carbon, nitrogen and phosphorus in a forest rendzina. Soil Biology and Biochemistry 31, 859–866.

[18]

Kiers, E.T., Duhamel, M., Beesetty, Y., Mensah, J.A., Franken, O., Verbruggen, E., Fellbaum, C.R., Kowalchuk, G.A., Hart, M.M., Bago, A., Palmer, T.M., West, S.A., Vandenkoornhuyse, P., Jansa, J., Bückin, H., 2011. Reciprocal rewards stabilize cooperation in the mycorrhizal symbiosis. Science 333, 880–882.

CrossRef Google scholar

[19]	Klironomos, J.N., 2002. Feedback with soil biota contributes to plant rarity and invasiveness in communities. Nature 417, 67–70.

[20]	Ligeza, S., Smal, H., 2003. Accumulation of nutrients in soils affected by perennial colonies of piscivorous birds with reference to biogeochemical cycles of elements. Chemosphere 52, 595–602.

[21]	McCullagh, P., Nelder, J.A., 1989. Generalized linear models. Chapman and Hall, London

[22]	Mikola, J., Setälä, H., 1998. Productivity and trophic-level biomasses in a microbial-based soil food web. Oikos 82, 158–168. CrossRef Google scholar

[23]	Moore, J.C., 1994. Impact of agricultural practices on soil food web structure: theory and application. Agriculture Ecosystems and Environment 51, 239–247.

[24]	Mulder, C.P.H., Keall, S.N., 2001. Burrowing seabirds and reptiles: impacts on seeds, seedlings and soils in an island forest in New Zealand. Oecologia 127, 350–360.

[25]	Neher, D.A., 2001. Role of nematodes in soil health and their use as indicators. Journal of Nematology 33, 161–168. Pubmed

[26]	Parmelee, R.W., Alston, D.G., 1986. Nematode trophic structure in conventional and no-tillage agroecosystems. Journal of Nematology 18, 403–407.

[27]	Reynolds, H.L., Packer, A.L., Bever, J.D., Clay, K., 2003. Grassroots ecology: plant-microbe-soil interactions as drivers of plant community structure and dynamics. Ecology 84, 2281–2291.

[28]	Ruess, L., Schmidt, I.K., Michelsen, A., Jonasson, S., 2001. Manipulations of a microbial based soil food web at two arctic sites: evidence of species redundancy among the nematode fauna. Applied Soil Ecology 17, 19–30.

[29]	Schmidt, I.K., Ruess, L., Baath, E., Michelsen, A., Ekelund, F.,Jonasson, S., 2000. Long-term manipulation of the microbes and microfauna of two subarctic heaths by addition of fungicide bactericide carbon and fertilizer. Soil Biology and Biochemistry 32, 707–720.

[30]	Sims, G.K., Ellsworth, T.R., Mulvaney, R.L., 1995. Microscale determination of inorganic nitrogen in water and soil extracts. Communications in Soil Science and Plant Analysis 26, 303–316.

[31]	Vance, E.D., Brookes, P.C., Jenkinson, D.S., 1987. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry 19, 703–707.

[32]	Velando, A., 1997. Ecología y comportamiento del cormorán moñudo (Phalacrocórax aristotelis L.) en las Islas Cíes y Ons. Doctoral Thesis, Universidad de Vigo

[33]	Velando, A., Freire, J., 2001. Can the central-periphery distribution become general in seabird colonies? Nest spatial pattern in the European Shag. Condor 103, 544–554.

[34]	Velando, A., Freire, J., 2003. Nest-site characteristics, occupation and breeding success in the European shag. Waterbirds 26, 473–483.

[35]	Velando, A., Munilla, I., Leyenda, P.M., 2005. Short-term indirect effects of the ‘Prestige’ oil spill on European shags: changes in availability of prey. Marine Ecology Progress Series 302, 263–274. CrossRef Google scholar

[36]	Venette, R.C., Ferris, H., 1998. Influence of bacterial type and density on population growth of bacterial-feeding nematodes. Soil Biology and Biochemistry 30, 949–960.

[37]	Wait, D.T., Aubrey, D.P., Anderson, W.P., 2005. Seabird guano influences on desert islands: soil chemistry and herbaceous species richness and productivity. Journal of Arid Environments 60, 681–695.

[38]	Zelenev, V.V., Berkelmans, R., van Bruggen, A.H.C., Bongers, T., Semenov, A.M., 2004. Daily changes in bacterial-feeding nematode populations oscillate with similar periods as bacterial populations after a nutrient impulse in soil. Applied Soil Ecology 26, 93–106.