Positive effects of alternative cropping systems on terrestrial Oligochaeta (Clitellata, Annelida)

Authors

  • Francesca Ricci INRA, AgroParisTech
  • Laure Bentze INRA, AgroParisTech
  • David Montagne INRA
  • Sabine Houot INRA, AgroParisTech
  • Celine Pelosi INRA, AgroParisTech

Keywords:

Enchytraeids, Potworms, Earthworms, Organic matter, Agricultural practices

Abstract

Agricultural intensification has reduced soil biodiversity in cultivated fields. Alternative cropping systems have been implemented to limit the harmful environmental effects of intensive conventional systems. This study aims at (i) assessing the impact of alternative systems on abundance and biomass of earthworms and enchytraeids, which are involved in key agro-ecological functions, and (ii) investigating the relationship between these soil organisms, under field conditions. Field data were collected in spring 2014 in two long-term agricultural sites near Paris, France. In Site 1, two types of organic amendments i.e. animal manure (MAN) and composted sludge (SLU) were compared to a control system (CONT) without organic fertilization. In Site 2, four different cropping systems were compared: a conventional (CONV), an integrated (INT), an organic (ORG) and a living mulch-based cropping system (LIV). They differed mainly in soil tillage, pesticide and fertilizer use, crop rotation and  crop biomass production. In both sites, higher earthworm abundance was found in the alternative systems except in the INT system i.e. SLU, MAN vs CONT and LIV, ORG vs CONV, even if differences were not always significant. For enchytraeids, we found no significant effect of organic amendments but a higher abundance in LIV and ORG systems than in CONV and INT systems in Site 2. Positive effects of alternative systems on earthworm and enchytraeid communities could be explained by the organic amendments in Site 1 and the permanent plant cover, the absence of pesticide use and tillage and the crop rotations in Site 2. Finally, no significant correlation was found between enchytraeid and earthworm abundance or biomass. We concluded that under environmental favorable conditions, earthworms and enchytraeids could coexist without competitive exclusion.

References

Altieri, M. A. (1999): The ecological role of biodiversity in agroecosystems. – Agriculture, Ecosystems & Environment 74: 19–31.

Andrén, O. & J. Lagerlöf (1983): Soil fauna (microarthropods, enchytraeids, nematodes) in Swedish agricultural cropping systems. – Acta Agriculturae Scandinavica 33: 33–52.

Annabi, M., Y. Le Bissonnais, M. Le Villio-Poitrenaud & S. Houot (2011): Improvement of soil aggregate stability by repeated applications of organic amendments to a cultivated silty loam soil. – Agriculture, Ecosystems & Environment 144: 382–389.

Beylich, A., & R.K. Achazi (1999): Influence of low soil moisture on enchytraeids. – Newsletter on Enchytraeidae 6, 49–58.

Beylich, A. & U. Graefe (2009): Investigations of annelids at soil monitoring sites in Northern Germany: reference ranges and time-series data. – Soil Organisms 81: 175–196.

Blanchart, E., C. Villenave, A. Viallatoux, B. Barthès, C. Girardin, A. Azontonde & C. Feller (2006): Long-term effect of a legume cover crop (Mucuna pruriens var. utilis) on the communities of soil macrofauna and nematofauna, under maize cultivation, in southern Benin. – European Journal of Soil Biology 42, Supplement 1: 136–144.

Blouin, M., M. E. Hodson, E. A. Delgado, G. Baker, L. Brussaard, K. R. Butt, J. Dai, L. Dendooven, G. Pérès, J. E. Tondoh, D. Cluzeau & J. J. Brun (2013): A review of earthworm impact on soil function and ecosystem services. – European Journal of Soil Science 64: 161–182.

Cambier, P., V. Pot, V. Mercier, A. Michaud, P. Benoit, A. Revallier & S. Houot (2014): Impact of long-term organic residue recycling in agriculture on soil solution composition and trace metal leaching in soils. – Science of the Total Environment 499: 560–573.

Chan, K. Y. (2001): An overview of some tillage impacts on earthworm population abundance and diversity - implications for functioning in soils. – Soil and Tillage Research 57: 179–191.

Daugbjerg, P., J. Hinge, J. P. Jensen & H. Sigurdardottir (1988): Earthworms as bioindicators of cultivated soils? – Ecological Bulletin 39: 45–47.

Debaeke, P., N. Munier-Jolain, M. Bertrand, L. Guichard, J.-M. Nolot, V. Faloya & P. Saulas (2009): Iterative design and evaluation of rule-based cropping systems: methodology and case studies. A review. – Agronomy for Sustainable Development 29: 73–86.

Didden, W. A. M. (1990): Involvement of Enchytraeidae (Oligochaeta) in soil structure evolution in agricultural fields. – Biology and Fertility of Soils 9: 152–158.

Didden, W. A. M. (1991): Population ecology and functioning of Enchytraeidae in some arable farming systems. – PhD Dissertation, Agricultural University Wageningen, The Netherlands.

Didden, W. & J. Römbke (2001): Enchytraeids as indicator organisms for chemical stress in terrestrial ecosystems. – Ecotoxicology and Environmental Safety 50: 25–43.

Didden, W. A. M., J. C. Y. Marinissen, M. J. Vreeken-Buijs, S. L. G. E. Burgers, R. de Fluiter, M. Geurs & L. Brussaard (1994): Soil meso- and macrofauna in two agricultural systems: factors affecting population dynamics and evaluation of their role in carbon and nitrogen dynamics. – Agriculture, Ecosystems & Environment 51: 171–186.

Edwards, C. A. & P. J. Bohlen (1996): Biology and Ecology of Earthworms - Third Edition – Chapman & Hall, London.

Golebiowska, J. & L. Ryszkowski (1977): Energy and carbon fluxes in soil compartments of agroecosystems. – Ecological Bulletin 25: 274–283.

Graefe, U. & A. Beylich (2002): The German long-term soil monitoring program and its implications for the knowledge of Enchytraeidae. – Newsletter on Enchytraeidae 7: 91–93.

Haukka, J. K. (1987): Growth and survival of Eisenia fetida (Sav.) (Oligochaeta: Lumbricidae) in relation to temperature, moisture and presence of Enchytraeus albidus (Henle) (Enchytraeidae). – Biology and Fertility of Soils 3: 99–102.

Hendrix, P. F., R. W. Parmelee, D. A. Crossley, D. C. Coleman, E. P. Odum & P. M. Groffman (1986): Detritus food webs in conventional and no-tillage agroecosystems. – Bioscience 36: 374–380.

Henneron, L., L. Bernard, M. Hedde, C. Pelosi, C. Villenave, C. Chenu, M. Bertrand, C. Girardin & E. Blanchart (2015): Fourteen years of evidence for positive effects of conservation agriculture and organic farming on soil life. – Agronomy for Sustainable Development 35: 169–181.

Holland, J. M. (2004): The environmental consequences of adopting conservation tillage in Europe: reviewing the evidence. – Agriculture, Ecosystems & Environment 103: 1–25.

Holt, E. A. & S. W. Miller (2011): Bioindicators: Using organisms to measure environmental impacts. – In: Nature Education Knowledge, 01-08-2011 [http://www.nature.com/scitable/knowledge/library/bioindicators-usingorganisms-to-measure-environmental-impacts-16821310].

House, G. J. & R. W. Parmelee (1985): Comparison of soil arthropods and earthworms from conventional and no-tillage agroecosystems. – Soil and Tillage Research 5: 351–360.

Huhta, V. & K. Viberg (1999): Competitive interactions between the earthworm Dendrobaena octaedra and the enchytraeid Cognitta sphagnetorum. – Pedobiologia 43: 886–890.

ISO 23611-3 (2007): Soil quality - sampling of soil invertebrates - Part 3: Sampling and soil extraction of enchytraeids. – (International Organization for Standardization), Geneva, Switzerland.

Jänsch, S., J. Römbke & W. Didden (2005): The use of enchytraeids in ecological soil classification and assessment concepts. – Ecotoxicology and Environmental Safety 62: 266–277.

Juarez, S., N. Nunan, A.-C. Duday, V. Pouteau & C. Chenu (2013): Soil carbon mineralisation responses to alterations of microbial diversity and soil structure. – Biology and Fertility of Soils 49: 939–948.

Karaban, K. & A. V. Uvarov (2014): Non-trophic effects of earthworms on enchytraeids: An experimental investigation. – Soil Biology and Biochemistry 73: 84–92.

Karnatak, A. K., D. C. Karnataka, S. S. Thakur & S. Awdhesh (2007): Impact of commonly used pesticides on the population of beneficial soil inhabitants (enchytraeids) and yield in rice crop ecosystem. – Pantnagar Journal of Research 5: 27–29.

Langmaack, M., S. Schrader & K. Helming (2001): Effect of mesofaunal activity on the rehabilitation of sealed soil surfaces. – Applied Soil Ecology 16: 121–130.

Lavelle, P., T. Decaëns, M. Aubert, S. Barot, M. Blouin, F. Bureau, P. Margerie, P. Mora & J.P. Rossi (2006): Soil invertebrates and ecosystem services. – European Journal of Soil Biology 42: 3–15.

Lee, K. E. (1985): Earthworms: their ecology and relationship with soils and land use. – Academic Press, Sidney, Australia.

Linden, D. R., P. F. Hendrix, D. C. Coleman & P. C. J. Van Vliet (1994): Faunal indicators of soil quality. – In: Doran, J. W., D. C. Coleman, D. F. Bezdicek & B. A. Stewart (eds): Defining soil quality for a sustainable environment. – SSSA Special Publication 35: 91–106.

Makulec, G. & I. Pilipiuk (2000): Influence of plant diversity and earthworm casts on the abundance and species composition of the enchytraeids (Oligochaeta: Enchytraeidae) in a lysimetric experiment. – Polish Journal of Ecology 48: 185–193.

Metzke, M., M. Potthoff, M. Quintern, J. Hess & R. G. Joergensen (2007): Effect of reduced tillage systems on earthworm communities in a 6-year organic rotation. – European Journal of Soil Biology 43 Supplement: 209–215.

Mitchell, M. J., R. Hartenstein, B. L. Swift, E. F. Neuhauser, B. I. Abrams, R. M. Mulligan, B.A. Brown, D. Craig & D. Kaplan (1978): Effects of different sewage sludges on some chemical and biological characteristics of soil. – Journal of Environmental Quality 7: 551–559.

Neuhauser, E. F., R. Hartenstein & D. L. Kaplan (1980): Growth of earthworm Eisenia foetida in relation to population density and food rationing. – Oikos 35: 93–98.

Nowak, E. (2004): Enchytraeids (Oligochaeta) in the agricultural landscape. – POLISH Journal of Ecology 52: 115–122.

O’Connor, F. B. (1957): An ecological study of the enchytraeid worm population of a coniferous forest soil. – Oikos 8: 162–198.

O’Connor, F. B. (1962): The extraction of Enchytraeidae from soil. – In: Murphy, P. W. (eds): Progress in Soil Zoology. – Butterworths, London, UK: 279–285.

O’Connor, F. B. (1967): The Enchytraeidae. – In: Burges, A. & F. Raw (eds): Soil Biology. – Academic Press, London, UK: 212–257.

Parmelee, R. W., M. H. Beare, W. Cheng, P. F. Hendrix, S.J. Rider, D. A. Crossley & D. C. Coleman (1990): Earthworms and enchytraeids in conventional and no-tillage agroecosystems: a biocide approach to assess their role in organic matter breakdown. – Biology and Fertility of Soils 10: 1–10.

Paoletti, M. G. (1999): The role of earthworms for assessment of sustainability and as bioindicators. – Agriculture, Ecosystems and Environment 74: 137–155.

Pelosi, C., M. Bertrand, Y. Capowiez, H. Boizard & J. Roger-Estrade (2009a): Earthworm collection from agricultural fields: Comparisons of selected expellants in presence/absence of hand-sorting. – European Journal of Soil Biology 45: 176–183.

Pelosi, C., M. Bertrand & J. Roger-Estrade (2009b): Earthworm community in conventional, organic and direct seeding with living mulch cropping systems. – Agronomy for Sustainable Development 29: 287–295.

Pelosi, C., L. Toutous, F. Chiron, F. Dubs, M. Hedde, A. Muratet, J.-F. Ponge, S. Salmon & D. Makowski (2013): Reduction of pesticide use can increase earthworm populations in wheat crops in a European temperate region. – Agriculture, Ecosystems and Environment 181: 223–230.

Pelosi, C., M. Bertrand, J. Thénard & C. Mougin (2015): Earthworms in a 15 years agricultural trial. – Applied Soil Ecology 88: 1–8.

Pérès, G., A. Bellido, P. Curmi, P. Marmonier & D. Cluzeau (2010): Relationships between earthworm communities and burrow numbers under different land use systems. – Pedobiologia 54: 37–44.

Ponge, J.-F., G. Pérès, M. Guernion, N. Ruiz-Camacho, J. Cortet, C. Pernin, C. Villenave, R. Chaussod, F. Martin-Laurent, A. Bispo & D. Cluzeau (2013): The impact of agricultural practices on soil biota: A regional study. – Soil Biology and Biochemistry 67: 271–284.

Postma-Blaauw, M. B., R. G. M. de Goede, J. Bloem, J. H. Faber & L. Brussaard (2012): Agricultural intensification and de-intensification differentially affect taxonomic diversity of predatory mites, earthworms, enchytraeids, nematodes and bacteria. – Applied Soil Ecology 57: 39–49.

Phillipson, J., R. Abel, J. Steel & S. R. J. Woodell (1979): Enchytraeid numbers, biomass and respiratory metabolism in a beech woodland - Wytham Woods, Oxford. – Oecologia 43: 173–193.

R Development Core Team (2011): R: A language and environment for statistical computing. – R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0 [URL http://www.R-project.org/].

Räty, M. (2004): Growth of Lumbricus terrestris and Aporrectodea caliginosa in an acid forest soil, and their effects on enchytraeid populations and soil properties. – Pedobiologia 48: 321–328.

Räty, M. & V. Huhta (2003): Earthworms and pH affect communities of nematodes and enchytraeids in forest soil. – Biology and Fertility of Soils 38: 52–58.

Röhrig, R., M. Langmaack, S. Schrader & O. Larink (1998): Tillage systems and soil compaction - their impact on abundance and vertical distribution of Enchytraeidae. – Soil and Tillage Research 46: 117–127.

Sandor, M. & S. Schrader (2012): Interaction of earthworms and enchytraeids in organically amended soil. – North-Western Journal of Zoology 8: 46–56.

Schlaghamerský, J., N. Eisenhauer & L. E. Frelich (2014): Earthworm invasion alters enchytraeid community composition and individual biomass in northern hardwood forests of North America. – Applied Soil Ecology 83: 159–169.

Schneider, C. A., W. S. Rasband & K. W. Eliceiri (2012): NIH Image to ImageJ: 25 years of image analysis. – Nature Methods 9: 671–675.

Schrader, S. & C. Seibel (2001): Impact of cultivation management in an agroecosystem on hot spot effects of earthworm middens. – European Journal of Soil Biology 37: 309–313.

Severon, T., M. Joschko, D. Barkusky & U. Graefe (2012): The impact of conventional and reduced tillage on the Enchytraeidae population in sandy soil and their correlation with plant residue and earthworms. – Landbauforschung Special Issue 357: 45–52.

Sims, R. W. & B. M. Gerard (1999): Earthworms. – FSC Publications, Shrewsbury, UK.

Stoate, C., N. D. Boatman, R. J. Borralho, C. R. Carvalho, G. R. d. Snoo & P. Eden (2001): Ecological impacts of arable intensification in Europe. – Journal of Environmental Management 63: 337–365.

Syers, J. K. & J. A. Springett (1983): Earthworm ecology in grassland soils. – In: Satchell, J. E. (eds): Earthworm Ecology: From Darwin to Vermiculture. – Chapman and Hall, London, UK: 67–83.

Tao, J., Y. Xu, B. S. Griffiths, F. Hu, X. Chen, J. Jiao & H. Li (2011): Earthworms reduce the abundance of nematodes and enchytraeids in a soil mesocosm experiment despite abundant food resources. – Soil Science Society of America Journal 75: 1774–1778.

Topoliantz, S., J.-F. Ponge & P. Viaux (2000): Earthworm and enchytraeid activity under different arable farming systems, as exemplified by biogenic structures. – Plant and Soil 225: 39–51.

Van Capelle, C., S. Schrader & J. Brunotte (2012): Tillage-induced changes in the functional diversity of soil biota – A review with a focus on German data. – European Journal of Soil Biology 50: 165–181.

Van Gestel, C. A. M. (1992): Validation of earthworm toxicity tests by comparison with field studies: A review of benomyl, carbendazim, carbofuran, and carbaryl. – Ecotoxicology and Environmental Safety 23: 221–236.

Van Vliet, P. C. J., L. T. West, P. F. Hendrix & D. C. Coleman (1993): The influence of Enchytraeidae (Oligochaeta) on the soil porosity of small microcosms. – Geoderma 56: 287–299.

Van Vliet, P. C. J., M. H. Beare & D. C. Coleman (1995): Population dynamics and functional roles of Enchytraeidae (Oligochaeta) in hardwood forest and agricultural ecosystems. – Plant and Soil 170: 199–207.

Wardle, D. A., G. W. Yeates, K. I. Bonner, K. S. Nicholson & R. N. Watson (2001): Impacts of ground vegetation management strategies in a kiwifruit orchard on the composition and functioning of the soil biota. – Soil Biology and Biochemistry 33: 893–905.

Willard, J. R. (1974): Soil invertebrates: VIII. A summary of populations and biomass. – Matador Project. Technical Report 56: 1–110.

Zhang, H. & S. Schrader (1993): Earthworm effects on selected physical and chemical properties of soil aggregates. – Biology and Fertility of Soils 15: 229–234.

Zaborski, E. R. (2003): Allyl isothiocyanate: an alternative chemical expellant for sampling earthworms. – Applied Soil Ecology 22: 87–95.

Downloads

Published

2015-08-01

How to Cite

Ricci, F., Bentze, L., Montagne, D., Houot, S., & Pelosi, C. (2015). Positive effects of alternative cropping systems on terrestrial Oligochaeta (Clitellata, Annelida). SOIL ORGANISMS, 87(2), 71–83. Retrieved from https://soil-organisms.org/index.php/SO/article/view/320

Issue

Vol. 87 No. 2 (2015)

Section

ARTICLES

License

Copyright (c) 2015 SOIL ORGANISMS

All articles from Senckenberg’s SOIL ORGANISMS Open Access scientific journal that are made available on the Senckenberg website (www.senckenberg.de) and also www.soil-organisms.org may be read, copied, distributed, and (in limited quantity) printed for non-commercial, private, scientific purposes.

In accordance with the German Science Foundation’s „Rules for the Safeguarding of Good Scientific Practice“, references to cited articles are to be complete and correct and furnished with a link to the website of the Senckenberg journal in question.

The Senckenberg Society for Nature Research (Senckenberg Gesellschaft für Naturforschung, SGN) is a member of the Leibniz Association (Leibniz-Gemeinschaft) and is therefore committed to the idea of Open Access as explained in the Berlin Declaration (Berlin Declaration on Open Access to Scientific Knowledge, Berliner Erklärung über den offenen Zugang zu wissenschaftlichem Wissen).

Open Access is understood to mean the charge-exempt public access to scientific results via the internet. The users should be able to read, copy, print, search within, and reference the full text without limitation and to use it in any conceivable lawful manner without financial, legal or technical hindrance.

This applies also to the SGN, which publishes various scientific series. Some scientific journals are made available to the public via Open Acess in addition to printed copies.