Net transfer of carbon between ectomycorrhizal tree species in the field (original) (raw)

References

  1. Molina, R., Massicotte, H. & Trappe, J. M. in Mycorrhizal Functioning: An Integrative Plant–Fungal Progess(ed. Allen, M. F.) 357–423 (Chapman and Hall, New York, (1992)).
    Google Scholar
  2. Massicotte, H. G., Molina, R., Luoma, D. L. & Smith, J. E. Biology of the ectomycorrhizal genus, Rhizopogon. II. Patterns of host-fungus specificity following spore inoculation of diverse hosts grown in monoculture and dual culture. New Phytol. 126, 677–690 (1994).
    Article Google Scholar
  3. Francis, R. & Read, D. J. Direct transfer of carbon between plants connected by vesicular–arbuscular mycorrhizal mycelium. Nature 307, 53–56 (1984).
    Article ADS CAS Google Scholar
  4. Brownlee, C., Duddridge, J. A., Malibari, A. & Read, D. J. The structure and function of ectomycorrhizal roots with special reference to their role in forming interplant connections and providing pathways for assimulate and water transport. Plant Soil 71, 433–443 (1983).
    Article Google Scholar
  5. Finlay, R. & Read, D. J. The structure and function of the vegetative mycelium of ectomycorrhizal plants. I. Translocation of 14C-labeled carbon between plants interconnected by a common mycelium. New Phytol. 103, 143–156 (1986).
    Article Google Scholar
  6. Arnebrant, K., Ek, H., Finlay, R. D. & Soderstrom, B. Nitrogen translocation between Alnus glutinosa (L.) Gaertn. seedlings inoculated with Frankia sp. and Pinus contorta Doug. ex Loud seedlings connected by a common ectomycorrhizal mycelium. New Phytol. 130, 231–242 (1993).
    Article Google Scholar
  7. Bethlenfalvay, G. J., Reyes-Solis, M. G., Camel, S. B. & Ferrera-Cerrato, R. Nutrient transfer between the root zones of soybean and maize plants connected by a common mycorrhizal mycelium. Physiologia Plantarum 82, 423–432 (1991).
    Article CAS Google Scholar
  8. Newman, E. I. & Eason, W. R. Rates of phosphorus transfer within and between ryegrass (Lolium perenne) plants. Funct. Ecol. 7, 242–248 (1993).
    Article Google Scholar
  9. Wittingham, J. & Read, D. J. Vesicular-arbascular mycorrhiza in natural vegetation systems III. Nutrient transfer between plants with mycorrhizal connections. New Phytol. 90, 277–284 (1982).
    Article Google Scholar
  10. Newman, E. I. Mycorrhizal links between plants: their functioning and ecological significance. Adv. Ecol. Res. 18, 243–270 (1988).
    Article Google Scholar
  11. Miller, S. L. & Allen, E. B. in Mycorrhizal Functioning: An Integrative Plant–Fungal Process(ed. Allen, M. F.) 301–332 (Chapman and Hall, New York, (1992)).
    Google Scholar
  12. Ritz, K. & Newman, E. I. Nutrient transport between ryegrass plants differing in nutrient status. Oecologia 70, 128–131 (1986).
    Article ADS CAS PubMed Google Scholar
  13. Frey, B. & Schüepp. H. Transfer of symbiotically fixed nitrogen from berseem (Trifolium alexandrium L.) to maize via vesicular arbuscular mycorrhizal hyphae. New Phytol. 125, 447–454 (1992).
    Article Google Scholar
  14. Ekblad, A. & Huss-Danell, K. Nitrogen fixation by Alnus incana and nitrogen transfer from A. incana to Pinus sylvestris influenced by macronutrients and ectomycorrhiza. New Phytol. 131, 453–459 (1995).
    Article PubMed Google Scholar
  15. Perry, D. A., Bell, T. & Amaranthus, M. P. in The Ecology of Mixed-Species Stands of Trees(eds Cannell, M. G. R., Malcom, D. C. & Robertson, P. A.) 151–179 (Cambridge Univ. Press, (1992)).
    Google Scholar
  16. Perry, D. A., Amaranthus, M. P., Borchers, J. G., Borchers, S. L. & Brainerd, R. E. Bootstrapping in ecosystems. Bioscience 39, 230–237.
  17. Read, D. J. in Biodiversity and Ecosystem Function(eds Schulze, E.-D. & Mooney, H. A.) 181–209 (Springer, Berlin, (1994)).
    Book Google Scholar
  18. Tilman, D. Dynamics and Structure of Plant Communities(Princeton Univ. Press, NJ, (1988)).
    Google Scholar
  19. Shulze, E.-D. & Mooney, H. A. in Biodiversity and Ecosystem Function(eds Schulze, E.-D. & Mooney, H. A.) 497–510 (Springer, Berlin, (1994)).
    Book Google Scholar
  20. Simard, S. W. thesis, Oregon State Univ.((1995)).
    Google Scholar
  21. Pearcy, R. W.et al. Carbon gain by plants in natural environments. Bioscience 37, 21–28 (1987).
    Article Google Scholar
  22. Smith, S. E. & Smith, F. A. Structure and function of the interfaces in biotrophic symbioses as they relate to nutrient transport. New Phytol. 114, 1–38 (1990).
    Article CAS PubMed Google Scholar
  23. Abuzinadah, R. A. & Read, D. J. Carbon transfer associated with assimilation of organic nitrogen sources by silver birch (Betula pendula Roth.). Trees 3, 17–23 (1989).
    Article Google Scholar
  24. Alpert, P., Warembourg, F. R. & Roy, J. Transport of carbon among connected ramets of Eichhornia crassipes (Pontederiaceae) at normal and high levels of CO2. Am. J. Bot. 78, 1459–1466 (1991).
    Article CAS Google Scholar
  25. Watkins, N. K., Fitter, A. H., Graves, J. D. & Robinson, D. Carbon transfer between C3 and C4 plants linked by a common mycorrhizal network, quantified using stable carbon isotopes. Soil Biol. Biochem. 28, 471–477 (1996).
    Article CAS Google Scholar
  26. Waters, J. R. & Borowicz, V. A. Effect of clipping, benomyl, and genet on 14C transfer between mycorrhizal plants. Oikos 71, 246–252 (1994).
    Article ADS CAS Google Scholar
  27. Tilman, D., Wedin, D. & Knops, J. Productivity and sustainability influence biodiversity in grassland ecosystems. Nature 379, 718–720 (1996).
    Article ADS CAS Google Scholar
  28. Perry, D. A., Margolis, H., Choquette, C., Molina, R. & Trappe, J. M. Ectomycorrhizal mediation of competition between coniferous tree species. New Phytol. 112, 501–511 (1989).
    Article CAS PubMed Google Scholar
  29. Boutton, T. W. in Carbon Isotope Techniques(eds Coleman, D. C. & Fry, B.) 155–170 (Academic, San Diego, (1991)).
    Book Google Scholar
  30. Warembourg, F. R. & Kummerow, J. in Carbon Isotope Techniques(eds Coleman, D. C. & Fry, B.) 11–37 (Academic, San Diego, (1991)).
    Book Google Scholar

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