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Perennial crops and endogenous nutrient supplies

Published online by Cambridge University Press:  12 February 2007

T.E. Crews
T.E. Crews*
Affiliation:
Environmental Studies Program, Prescott College, 220 Grove Ave, Prescott, AZ 86301, USA.
*
*Corresponding author: [email protected]
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Abstract

Perennial cropping systems may achieve significant improvement over annual systems in the synchrony between crop nutrient demands and nutrient supplies. Improvements in nutrient synchrony would result in the reduction of nutrient losses and their associated environmental impacts. A perennial system with high levels of synchrony would also require fewer nutrient inputs, such that it may be possible to develop an agriculture that functions mostly, if not entirely, on nutrient inputs from endogenous sources (i.e., weathering of primary and secondary minerals and biological nitrogen fixation). In this paper I describe three realms of research that will inform the development of relatively high-yielding grain production systems grown on endogenous nutrient supplies: (1) improvement of nutrient synchrony through the development of perennial crops; (2) identification of soils that are in a high nutrient release phase of pedogenesis, which could balance the export of rock-derived nutrients in crop harvests; and (3) optimization of legume density, harvest index and percent nitrogen derived from the atmosphere (%Ndfa) to achieve adequate nitrogen inputs through biological fixation.

Keywords

legumelithophilic nutrientsnitrogennitrogen fixationpedogenesisphosphorussustainabilitysynchronyweathering
Type
Research Article
Information
Renewable Agriculture and Food Systems , Volume 20 , Issue 1 , March 2005 , pp. 25 - 37
Copyright
Copyright © Cambridge University Press 2005

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References

01Whittaker, R.H. 1975. Communities and Ecosystems. 2nd. USA Macmillan, New York,.Google Scholar
02Van Wambeke, A. 1992. Soils of the Tropics. McGraw-Hill, New York, USA.Google Scholar
03Herrera, R., Merida, T., Stark, N. and Jordan, C.F. 1978. Direct phosphorus transfer from leaf litter to roots. Naturwissenschaften 65: 208209.CrossRefGoogle Scholar
04Sanford, R.S. Jr. 1987. Apogeotropic roots in an Amazon rain forest. Science 235: 10621064.CrossRefGoogle Scholar
05Harlan, J.R. 1995. The Living Fields: Our Agricultural Heritage. Cambridge University Press, Cambridge, UK.Google Scholar
06Rowley-Conwy, P. 1981. Slash and burn in the temperate European neolithic. In Mercer, R. (ed.) Farming Practice in British Prehistory. Edinburgh University Press, Edinburgh, UK. p. 8596.Google Scholar
07Hurt, R.D. 1987. Indian Agriculture in America. USA University of Kansas Press, Lawrence, Kansas.Google Scholar
08Newman, E.I. 1997. Phosphorus balance of contrasting farming systems, past and present. Can food production be sustainable. Journal of Applied Ecology 34: 13341347.CrossRefGoogle Scholar
09Vitousek, P.M., Aber, J.D., Howarth, R.W., Likens, G.E., Matson, P.A., Schindler, D.W., Schlesinger, W.H. and Tilman, D.G. 1997. Human alteration of the global nitrogen cycle: sources and consequences. Ecological Applications 7: 737750.Google Scholar
10Turner, R.E. and Rabalais, N.N. 2003. Linking landscape and water quality in the Mississippi River basin for 200 years. Bioscience 53: 563572.CrossRefGoogle Scholar
11Townsend, A.R., Howarth, R.W., Bazzaz, F.A., Booth, M.S., Cleveland, C.C., Collinge, S.K., Dobson, A.P., Epstein, P.R., Holland, E.A., Keeney, D.R., Mallin, M.M., Rogers, C.A., Wayne, P. and Wolfe, A.H. 2003. Human health effects of a changing global nitrogen cycle. Frontiers in Ecology and the Environment 1: 240246.CrossRefGoogle Scholar
12Mudahar, M.S. and Hignett, T.P. 1987. Fertilizer and energy use. In Helsel, Z.R. (ed.) Energy in Plant Nutrition and Pest Control. The Netherlands Elsevier, Amsterdam, p. 2562.Google Scholar
13Jackson, W. and Jackson, L.L. 1999. Developing high seed yielding perennial polycultures as a mimic of mid-grass prairie. In Lefroy, E.C., Hobbs, R.J., O'Connor, M.H. and Pate, J.S. (eds) Agriculture as a Mimic of Natural Ecosystems. The Netherlands Kluwer Academic Publishers, Dordrecht, p. 137.Google Scholar
14Myers, R.J.K., van Noordwijk, M. and Vityakon, P. 1997. Synchrony of nutrient release and plant demand: Plant litter quality, soil environment and farmer management options. In Cadisch, G. and Giller, K.E. (eds) Driven by Nature. UK CAB International, Wallingford, p. 215229.Google Scholar
15Tilman, D., Cassman, K.G., Matson, P.A., Naylor, R. and Polasky, S. 2002. Agriculural sustainability and intensive production practices. Nature 418: 671677.CrossRefGoogle Scholar
16Robertson, G.P. 1997. Nitrogen use efficiency in row-crop agriculture: Crop nitrogen use and soil nitrogen loss. In Jackson, L. (ed.). Ecology in Agriculture. California, USA Academic Press, San Diego, p. 347365.CrossRefGoogle Scholar
17Crews, T.E. and Peoples, M.B. 2005. Can the synchrony of nitrogen supply and crop demand be improved in legume and fertilizer-based agroecosystems? A review Nutrient Cycling in Agroecosystems, in press.CrossRefGoogle Scholar
18Crews, T.E. and Peoples, M.B. 2004. Legume versus fertilizer sources of nitrogen: Ecological tradeoffs and human needs. Agriculture, Ecosystems and Environment 102: 279297.CrossRefGoogle Scholar
19Dinnes, D.L., Karlen, D.L., Jaynes, D.B., Kaspar, T.C., Hatfield, J.L., Colvin, T.S. and Cambardella, C.A. 2002. Nitrogen management strategies to reduce nitrate leaching in tile-drained Midwestern soils. Agronomy Journal 94: 153171.CrossRefGoogle Scholar
20Cassman, K.G., Dobermann, A. and Walters, D.T. 2002. Agroecosystems, nitrogen-use efficiency and nitrogen management. Ambio 31: 132140.CrossRefGoogle ScholarPubMed
21Likens, G.E., Bormann, F.H., Pierce, R.S., Eaton, J.S. and Johnson, N.M. 1977. Biogeochemistry of a Forested Ecosystem. Springer-Verlag, New York, USA.CrossRefGoogle Scholar
22Knapp, A.K., Briggs, J.M., Blair, J.M. and Turner, C.L. 1998. Patterns and controls of above ground net primary production in tallgrass prairie. In Knapp, A.K., Briggs, J.M., Hartnett, D.C. and Collins, S.L. (eds) Grassland Dynamics. USA Oxford University Press, New York. p. 193221.CrossRefGoogle Scholar
23Blair, J.M., Seastedt, T.R., Rice, C.W. and Ramundo, R.A. 1998. Terrestrial nutrient cycling in tallgrass prairie. In Knapp, A.K., Briggs, J.M., Hartnett, D.C. and Collins, S.L. (eds) Grassland Dynamics. USA Oxford University Press, New York, p. 222243.CrossRefGoogle Scholar
24Andrén, O., Lindberg, U., Boström, U., Clarholm, M., Hansson, A.C., Johansson, G., Lagerlöf, J., Paustian, K., Persson, J., Pettersson, R., Schnürer, J., Sohlenius, B. and Wivstad, M. 1990. Organic carbon and nitrogen flows. Ecological Bulletins 40: 85126.Google Scholar
25Paustian, K., Bergström, L., Jansson, P. and Johnsson, H. 1990. Ecosystem dynamics. Ecological Bulletins 40: 153180.Google Scholar
26Jaynes, D.B., Colvin, T.S., Karlen, D.L., Cambardella, C.A. and Meek, D.W. 2001. Nitrate loss in subsurface drainage as affected by nitrogen fertilizer rate. Journal of Environmental Quality 30: 13051314.CrossRefGoogle ScholarPubMed
27Randall, G.W., Huggins, D.R., Russelle, M.P., Fuchs, D.J., Nelson, W.W. and Anderson, J.L. 1997. Nitrate losses through subsurface tile drainage in conservation reserve program, alfalfa, and row crop systems. Journal of Environmental Quality 26: 12401247.CrossRefGoogle Scholar
28Wedin, D.A. and Tilman, D. 1990. Species effects on nitrogen cycling: a test with perennial grasses. Oecologia 84: 433441.CrossRefGoogle ScholarPubMed
29McKane, R.B., Grigal, D.F. and Russelle, M.P. 1990. Spatiotemporal differences in 15N uptake and the organization of an old-field plant community. Ecology 71: 11261132.CrossRefGoogle Scholar
30Van Der Krift, T.A.J., Berendse, F. 2001. The effect of plant species on soil nitrogen mineralisation. Journal of Ecology 89: 555561.CrossRefGoogle Scholar
31Mathers, A.C., Stewart, B.A. and Blair, B. 1975. Nitrate-nitrogen removal from soil profiles by alfalfa. Journal of Environmental Quality 4: 403405.CrossRefGoogle Scholar
32Bergström, L. 1987. Nitrate leaching and drainage from annual and perennial crops in tile-drained plots and lysimeters. Journal of Environmental Quality 16: 1118.CrossRefGoogle Scholar
33Huggins, D.R., Randall, G.W. and Russelle, M.P. 2001. Subsurface drain losses of water and nitrate following conversion of perennials to row crops. Agronomy Journal 93: 477486.CrossRefGoogle Scholar
34Marschner, H. 1995. Mineral Nutrition of Higher Plants. 2nd. Academic Press, New York, USA.Google Scholar
35Vitousek, P.M., Cassman, K., Cleveland, C., Crews, T., Field, C.B., Grimm, N., Howarth, R.W., Marino, R., Martinelli, L., Rastetter, E. and Sprent, J.I. 2002. Towards an ecological understanding of biological nitrogen fixation. Biogeochemistry 57/58145.CrossRefGoogle Scholar
36Vitousek, P.M. and Howarth, R.W. 1991. Nitrogen limitation on land and in the sea: How can it occur?. Biogeochemistry 13: 87115.CrossRefGoogle Scholar
37Walker, T.W. and Syers, J.K. 1976. The fate of phosphorus during pedogenesis. Geoderma 15: 119.CrossRefGoogle Scholar
38Vitousek, P.M. and Farrington, H. 1997. Nutrient limitation and soil development: experimental test of a biogeochemical theory. Biogeochemistry 37: 6375.CrossRefGoogle Scholar
39Hedin, L.O., Vitousek, P.M. and Matson, P.A. 2003. Nutrient losses over four million years of tropical forest development. Ecology 84: 22312255.CrossRefGoogle Scholar
40Crews, T.E. 1999. The presence of nitrogen fixing legumes in terrestrial communities: Evolutionary vs. ecological considerations. Biogeochemistry 46: 233246.CrossRefGoogle Scholar
41Bordeleau, L.M., Prévost, D. 1994. Nodulation and nitrogen fixation in extreme environments. Plant and Soil 161: 115125.CrossRefGoogle Scholar
42Robson, A.D. and Bottomley, P.J. 1991. Limitations in the use of legumes in agriculture and forestry. In Dilworth, M.J. and Glenn, A.R. (eds) Biology and Biochemistry of Nitrogen Fixation. The Netherlands Elsevier, Amsterdam, p. 320349.Google Scholar
43Cadisch, G., Sylvester-Bradley, R., Boller, B.C., Nösberger, J. 1993. Effects of phosphorus and potassium on N 2 fixation (15N-dilution) of field-grown Centrosema acutifolium and C. macrocarpum. Field Crops Research 31: 329340.CrossRefGoogle Scholar
44Crews, T.E., Kurina, L.M. and Vitousek, P.M. 2001. Organic matter and nitrogen accumulation and nitrogen fixation during early ecosystem development in Hawaii. Biogeochemistry 52: 259279.CrossRefGoogle Scholar
45Gates, C.T. 1974. Nodule and plant development in Stylosanthes hummilis H.B.K.: Symbiotic response to phosphorus and sulphur. Australian Journal of Botany 22: 4555.CrossRefGoogle Scholar
46Israel, D.W. 1987. Investigation of the role of phosphorus in symbiotic dinitrogen fixation. Plant Physiology 84: 835840.CrossRefGoogle ScholarPubMed
47Pereira, P.A.A. and Bliss, F.A. 1987. Nitrogen fixation and plant growth of common bean (Phaseolus vulgaris L.) at different levels of phosphorus availability. Plant and Soil 104: 7984.CrossRefGoogle Scholar
48Davis, M.R. 1991. The comparative phosphorus requirements of some temperate perennial legumes. Plant and Soil 133: 1730.CrossRefGoogle Scholar
49Peoples, M.B., Lilley, D.V., Burnett, V.F., Ridley, A.M. and Garden, D.L. 1995. Effects of surface application of lime and superphosphate to acid soils on growth and N2 fixation by subterranean clover in mixed pasture swards. Soil Biology and Biochemistry 27: 663671.CrossRefGoogle Scholar
50Crews, T.E., Farrington, H. and Vitousek, P.M. 2000. Changes in asymbiotic, heterotrophic nitrogen fixation on leaf litter of Metrosideros polymorpha with long-term ecosystem development in Hawaii. Ecosystems 3: 386395.CrossRefGoogle Scholar
51Eisele, K.A., Schimel, D.S., Kapustka, L.A. and Parton, W.J. 1989. Effects of available P and N:P ratios on non-symbiotic dinitrogen fixation in tallgrass prairie soils. Oecologia 79: 471474.CrossRefGoogle Scholar
52Crews, T.E. 1993. Phosphorus regulation of nitrogen fixation in a traditional Mexican agroecosystem. Biogeochemistry 21: 141166.CrossRefGoogle Scholar
53Harley, A.D. and Gilkes, R.J. 2000. Factors influencing the release of plant nutrient elements from silicate rock powders: a geochemical overview. Nutrient Cycling in Agroecosystems 56: 1136.CrossRefGoogle Scholar
54LeMaitre, R.W. 1976. The chemical variability of some common igneous rocks. Journal of Petrology 17: 589637.CrossRefGoogle Scholar
55Ritter, D.F., Kochel, R.C. and Miller, J.R. 2001. Process Geomorphology. McGraw-Hill, New York.Google Scholar
56Reiche, P. 1950. A survey of weathering processes and products Albuquerque, New Mexico University of New Mexico Publications in Geology, no. 3. The University of New Mexico Press.Google Scholar
57Carroll, D. 1970. Rock Weathering. USA Plenum Press, New York.CrossRefGoogle Scholar
58Vitousek, P.M., Chadwick, O.A., Crews, T.E., Fownes, J.H., Hendricks, D.M. and Herbert, D. 1997. Soil and ecosystem development across the Hawaiian islands. GSA Today 7: 18.Google Scholar
59Crews, T.E., Kitayama, K., Fownes, J.H., Riley, R.H., Herbert, D.A., Mueller-Dombois, D. and Vitousek, P.M. 1995. Changes in soil phosphorus fractions and ecosystem dynamics across a long chronosequence in Hawaii. Ecology 76: 14071424.CrossRefGoogle Scholar
60Vitousek, P.M., Turner, D.R. and Kitayama, K. 1995. Foliar nutrients during long-term soil development in Hawaiian montane rain forest. Ecology 76: 712720.CrossRefGoogle Scholar
61Crews, T.E. 1996. The supply of phosphorus from native, inorganic phosphorus pools in continuously cultivated Mexican agroecosystems. Agriculture, Ecosystems and Environment 57: 197208.CrossRefGoogle Scholar
62Haas, H.J., Grunes, D.L. and Reichman, G.A. 1961. Phosphorus changes in Great Plains soils as influenced by cropping and manure applications. Soil Science Society of America Proceedings 25: 214218.CrossRefGoogle Scholar
63Tiessen, H., Stewart, J.W.B. and Bettany, J.R. 1982. Cultivation effects on the amounts and concentration of carbon, nitrogen and phosphorus in grassland soils. Agronomy Journal 74: 831835.CrossRefGoogle Scholar
64Rosenweig, M.L. 1968. Net primary productivity of terrestrial communities: prediction from climatological data. The American Naturalist 102: 6774.CrossRefGoogle Scholar
65Gorham, E., Vitousek, P.M. and Reiners, W.A. 1979. The regulation of chemical budgets over the course of terrestrial ecosystem succession. Annual Review of Ecology and Systematics 10: 5384.CrossRefGoogle Scholar
66Stephenson, N.L. 1990. Climatic control of vegetation distribution: The role of the water balance. The American Naturalist 135: 649670.CrossRefGoogle Scholar
67Meetemeyer, V. 1978. Macroclimate and lignin control of litter decomposition rates. Ecology 59: 465472.CrossRefGoogle Scholar
68Bormann, B.T., Wang, D., Bormann, F.H., Benoit, G., April, R. and Synder, M.C. 1998. Rapid, plant-induced weathering in an aggrading experimental ecosystem. Biogeochemistry 43: 129155.CrossRefGoogle Scholar
69Moorhead, D.L., Currie, W.S., Rastetter, E.B., Parton, W.J. and Harmon, M.E. 1999. Climate and litter quality controls on decomposition: An analysis of modeling approaches. Global Biogeochemical Cycles 13: 575589.CrossRefGoogle Scholar
70Newman, E.I. 1995. Phosphorus inputs to terrestrial ecosystems. Journal of Ecology 83: 713726.CrossRefGoogle Scholar
71Crowley, D.E. and Rengel, Z. 1999. Biology and chemistry of nutrient availability in the rhizosphere. In Rengel, Z. (ed.) Mineral Nutrition of Crops. USA Food Products Press, New York. p. 140.Google Scholar
72Ryan, P.R., Delhaize, E. and Jones, D.L. 2001. Function and mechanism of organic anion exudation from plant roots. Annual Review of Plant Physiology and Plant Molecular Biology 52: 527560.CrossRefGoogle ScholarPubMed
73Peoples, M.B. and Craswell, E.T. 1992. Biological nitrogen fixation: Investments, expectations and actual contributions to agriculture. Plant and Soil 141: 1339.CrossRefGoogle Scholar
74McNeill, A.M., Zhu, C. and Fillery, I.R.P. 1997. Use of in situ 15N-labelling to estimate the total below-ground nitrogen of pasture legumes in intact soil-plant systems. Australian Journal of Agricultural Research 48: 295304.CrossRefGoogle Scholar
75Khan, D.F., Peoples, M.B., Chalk, P.M. and Herridge, D.F. 2002. Quantifying below-ground nitrogen of legumes. 2. A comparison of 15N and non isotopic methods. Plant and Soil 239: 277289.CrossRefGoogle Scholar
76Ledgard, S.F. 2001. Nitrogen cycling in low input legume-based agriculture, with emphasis on legume/grass pastures. Plant and Soil 228: 4359.CrossRefGoogle Scholar
77Peoples, M.B., Herridge, D.F. and Ladha, J.K. 1995. Biological nitrogen fixation: An efficient source of nitrogen for sustainable agricultural production? Plant and Soil 174: 328.CrossRefGoogle Scholar
78Harper, J.E. and Gibson, A.H. 1984. Differential nodulation tolerance to nitrate among legume species. Crop Science 24: 797801.CrossRefGoogle Scholar
79Gresshoff, P.M. 1990. The importance of biological nitrogen fixation to new crop development. In Janick, J. and Simon, J.E. (eds) Advances in New Crops. Oregon, USA Timber Press, Portland. p. 113119.Google Scholar
80Herridge, D.F. and Danso, S.K.A. 1995. Enhancing legume N2 fixation through selection and breeding. Plant and Soil 174: 5182.CrossRefGoogle Scholar
81Wheeler, C.T. and McLaughlin, M.E. 1978. Environmental regulation of nitrogen fixation in actinomycete nodulated plants. In Gordon, J.C., Wheeler, C.T. and Perry, D.A. (eds) Symbiotic Nitrogen Fixation in the Management of Temperate Forests. School of Forestry, Oregon State University, Corvallis, Oregon, USA, p. 124142.Google Scholar
82Waterer, J.G., Vessey, J.K. and Raper, D.C. 1992. Stimulation of nodulation in field peas (Pisum sativum) by low concentration of ammonium in hydroponic culture. Plant Physiology 86: 215220.CrossRefGoogle ScholarPubMed
83Goi, S.R., Sprent, J.I., Games, E.L., Jacob-Neto, J. 1992. Influence of nitrogen forms and concentration on the nitrogen fixation of Acacia auriculiformis. Symbiosis 14: 115122.Google Scholar
84Gutschick, V.P. 1981. Evolved strategies in nitrogen acquisition by plants. The American Naturalist 118: 607637.CrossRefGoogle Scholar
85Attiwill, P.M. and Adams, M.A. 1993. Nutrient cycling in forests. New Phytologist 124: 561582.CrossRefGoogle ScholarPubMed
86McNaughton, S.J. 1984. Grazing lawns: Animals in herds, plant form, and coevolution. The American Naturalist 124: 863886.CrossRefGoogle Scholar
87Dyer, M.I., Turner, C.L. and Seastedt, T.R. 1993. Herbivory and its consequences. Ecological Applications 3: 1016.CrossRefGoogle ScholarPubMed
88Smil, V. 2001. Enriching the Earth. MIT Press, Cambridge, Massachusetts, USAGoogle Scholar