Root growth and functioning under atmospheric CO2 enrichment (original) (raw)
References
Acock, B. & Pasternak, D. 1986. Effects of CO2 concentration on composition, anatomy, and morphology of plants. In: Enoch, H. Z. & Kimball, B. A. (eds), Carbon Dioxide Enrichment of Greenhouse Crops. II. Physiology, yield and economics. pp. 41–53. CRC Press, Inc., Boca Raton. Google Scholar
AllenJr, L. H., Vu, J. C. V., Valle, R. R., Boote, K. J. & Jones, P. H. 1988. Nonstructural carbohydrates and nitrogen of soybean grown under carbon dioxide enrichment. Crop. Sci. 28: 84–94. Google Scholar
Bazzaz, F. A. 1990. The response of natural ecosystems to the rising global CO2 levels. Annu. Rev. Ecol. Syst. 21: 167–196. Google Scholar
Bhattacharya, N. C., Biswas, P. K., Bhattacharya, S., Sionit, N. & Strain, B. R. 1985. Growth and yield response of sweet potato to atmospheric CO2 enrichment. Crop Science 25: 975–981. Google Scholar
Billings, W. D., Luken, J. O., Mortenson, D. A. & Peterson, K. M. 1982. Arctic tundra: a source or sink for atmospheric carbon dioxide in a changing environment? Oecologia 53: 7–11. Google Scholar
Billings, W. D., Luken, J. O., Mortenson, D. A. & Peterson, K. M. 1983. Increasing atmospheric carbon dioxide: possible effects on arctic tundra. Oecologia 58: 286–289. Google Scholar
Billings, W. D., Peterson, K. M., Luken, J. O. & Mortenson, D. A. 1984. Interaction of increasing atmospheric carbon dioxide and soil nitrogen on the carbon balance of tundra microcosms. Oecologia 65: 26–29. Google Scholar
Boot, R. G. A. 1989. The significance of size and morphology of root systems. In: Lambers, H, Cambridge, M. L., Konings, H. & Pons, T. L. (eds), Causes and Consequences of Variation in Growth rate and Productivity. pp 299–311. SPB Academic Publishing, The Hague. Google Scholar
Brouwer, R. 1962. Distribution of dry matter in the plant. Neth. J. Agric. Sci. 10: 361–376. Google Scholar
Brouwer, R. 1983. Functional equilibrium: sense or nonsense? Neth. J. Agric. Sci. 31: 335–348. Google Scholar
Bunce, J. A. 1990. Short- and long-term inhibition of respiratory carbon dioxide efflux by elevated carbon dioxide. Ann. Bot. 65: 637–642. Google Scholar
Campagna, M. A. & Margolis, H. A. 1989. Influence of short-term atmospheric CO2 enrichment on growth, allocation patterns, and biochemistry of black spruce seedlings at different stages of development. Can. J. For. Res. 19: 773–782. Google Scholar
Chapin, F. S.III 1980. The mineral nutrition of wild plants. Annu. Rev. Ecol. Syst. 11: 1007–1010. Google Scholar
Clough, J. M., Peet, M. M. & Kramer, P. J. 1981. Effects of high atmospheric CO2 and sink size on rates of photosynthesis of a soybean cultivar. Plant Physiol. 67: 1007–1010. Google Scholar
Cure, J. D. & Acock, B. 1986. Crop responses to carbon dioxide doubling: a literature survey. Agric. For. Meteorol. 38: 127–145. Google Scholar
Cure, J. D., Israel, D. W. & RuftyJr, T. W. 1988. Nitrogen stress effects on growth and seed yield of nonnodulated soybean exposed to elevated carbon dioxide. Crop Sci. 28: 671–677. Google Scholar
Del, Castillo, D., Acock, B., Reddy, V. R. & Acock, M. C. 1989. Elongation and branching of roots of soybean plants in a carbon dioxide-enriched aerial environment. Agron. J. 81: 692–695. Google Scholar
Den, Hertog, J. & Stulen, I. 1990. The effects of an elevated atmospheric CO2 concentration on dry matter and nitrogen allocation. In: Goudriaan, J., Van, Keulen, H. & Van, Laar, H. H. (eds). The Greenhouse Effect and Primary Productivity in European Agro-ecosystems. pp. 27–30. Pudoc, Wageningen. Google Scholar
Den, Hertog, J., Stulen, I. & Lambers, H. 1993. Assimilation and allocation of carbon in Plantago major as affected by atmospheric CO2 levels: a case study. Vegetatio: 104/105: 369–378. Google Scholar
De Visser, R. 1984. Interactions between energy and nitrogen metabolism in_Pisum sativum_. Thesis, Groningen.
De Willigen, P. & Van Noordwijk, M. 1987. Roots, plant production and nutrient use efficiency. Thesis, Wageningen.
Enoch, H. Z. 1990. Crop responses to aerial carbon dioxide. Acta horticulturae 268: 17–33. Google Scholar
Finn, G. A. & Brun, W. A. 1982. Effect of atmospheric CO2 enrichment on growth, nonstructural carbohydrate content, and root nodule activity in soybean. Plant Physiol. 69: 327–331. Google Scholar
Ford, M. A. & Thorne, G. N. 1967. Effect of CO2 concentration on growth of sugar-beet, barley, kale and maize. Ann. Bot. 31: 629–694. Google Scholar
Gastal, F. & Saugier, B. 1989. Relationships between nitrogen uptake and carbon assimilation in. Plant Cell Environm. 12: 407–418. Google Scholar
Gifford, R. M. 1979. Growth and yield of CO2-enriched wheat under water-limited conditions. Aust. J. Plant Physiol. 6: 367–378. Google Scholar
Gifford, R. M., Lambers, H & Morison, J. I. L. 1985. Respiration of crop species under CO2 enrichment. Physiol. Plant 63: 351–356. Google Scholar
Hardy, R. W. F. & Havelka, U. D. 1975. Photosynthate as a major factor limiting nitrogen fixation by field grown legumes with emphasis on soybeans. In: Nutman, P. S. (ed.), Symbiotic Nitrogen Fixation in Plants. pp 421–439. International Biology Program Series, Vol. 7. Cambridge University Press, London. Google Scholar
Hocking, P. J. & Meyer, C. P. 1985. Responses of Noogoora burr (Xanthium occidentale Bertol.) to nitrogen supply and carbon dioxide enrichment. Ann. Bot. 55: 835–844. Google Scholar
Hughes, A. P. & Cockshull, K. E. 1969. Effects of carbon dioxide concentration on the growth of_Callistephus chinensis_ cultivar Johannistag. 33: 351–365. Google Scholar
Hurd, R. G. 1968. Effects of CO2-enrichment on the growth of young tomato plants in low light. Ann. Bot. 32: 531–542. Google Scholar
Jolliffe, P. A. & Ehret, D. L. 1985. Growth of bean plants at elevated carbon dioxide concentrations. Can. J. Bot. 63: 2121–2125. Google Scholar
Kaushal, P., Guehl, J. M. & Aussenac, G. 1989. Differential growth response to atmospheric carbon dioxide enrichment in seedlings of_Cedrus atlantica_ and_Pinus nigra_ ssp.Laricio var.Corsicana. Can. J. For. Res. 19: 1351–1358. Google Scholar
Kimball, B. A. 1983. Carbon dioxide and agricultural yield: an assemblage and analysis of 430 prior observations. Agron. J. 75: 779–789. Google Scholar
Kimball, B. A. 1986. CO2 stimulation of growth and yield under environmental restraints. In: Enoch, H. Z. & Kimball, B. A. (eds), Carbon Dioxide Enrichment of Greenhouse Crops. Vol II. Physiology, yield, and economics. pp. 53–67. CRC Press, Inc., Boca Raton. Google Scholar
Konings, H. 1989. Physiological and morphological differences between plants with a high NAR or a high LAR as related to environmental conditions. In: Lambers, H, Cambridge, M. L., Konings, H. & Pons, T. L. (eds.), Causes and Consequences of Variation in Growth Rate and Productivity. pp 101–123. SPB Academic Publishing, The Hague. Google Scholar
Lambers, H. 1987. Growth, respiration, exudation and symbiotic associations: the fate of carbon translocated to the roots. In: Gregory, P. J., Lake, J. V. Rose, D. A. (eds), Root Development and Functions. pp. 124–146. Cambridge University Press, Cambridge. Google Scholar
Lambers, H. & Posthumus, F. 1980. The effect of light intensity and relative humidity on growth rate and root respiration of_Plantago lanceolata_ and_Zea mays_. J. Exp. Bot. 31: 1621–1630. Google Scholar
Larigauderie, L., Hilbert, D. W. & Oechel, W. C. 1988. Effect of CO2 enrichment and nitrogen availability on resource acquisition and resource allocation in a grass,Bromus mollis. Oecologia 77: 544–549. Google Scholar
Luxmoore, R. J., O'Neill, E. G., Ells, J. M. & Rogers, J. M. 1986. Nutrient uptake and growth responses of Virginia pine to elevated atmospheric CO2. J. Environ. Qual. 15: 244–251. Google Scholar
Masterson, C. L. & Sherwood, M. T. 1978. Some effects of increased atmospheric carbon dioxide on white clover (Trifolium repens) and pea (Pisum sativum). Plant and Soil 49: 421–426. Google Scholar
Morison, J. I. L. & Gifford, R. M. 1984. Plant growth and water use with a limited water supply in high CO2 concentrations. II. Plant dry weight, partitioning and water use efficiency. Aust. J. Plant Physiol. 11: 361–374. Google Scholar
Mousseau, M. & Enoch, H. Z. 1989. Carbon dioxide enrichment reduces shoot growth in sweet chestnut seedlings (Castanea sativa Mill.). Plant Cell Environm. 12: 927–934. Google Scholar
Nijs, I., Impens, I. & Behaeghe, T. 1989. Leaf and canopy responses of_Lolium perenne_ to long-term elevated atmospheric carbon-dioxide concentration. Planta 177: 312–320. Google Scholar
Norby, R. J. 1987. Nodulation and nitrogenase activity in nitrogen-fixing woody plants stimulated by CO2 enrichment in the atmosphere. Physiol. Plant. 71: 77–82. Google Scholar
Norby, R. J., Luxmoore, R. J., O'Neill, E. G. & Weller, D. G. 1984. Plant responses to elevated atmospheric CO2 with emphasis on belowground processes. ORNL/TM-9426. Oak Ridge National Laboratory, Oak Ridge, Tennessee. Google Scholar
Norby, R. J., O'Neill, E. G., Hood, W. G. & Luxmoore, R. J. 1987. Carbon allocation, root exudation and mycorrhizal colonization. Tree Physiol. 3: 203–210. Google Scholar
Norby, R. J., O'Neill, E. G. & Luxmoore, R. J. 1986a. Effects of atmospheric CO2 enrichment on the growth and mineral nutrition of_Quercus alba_ seedlings in nutrient-poor soil. Plant Physiol. 82: 83–89. Google Scholar
Norby, R. J., Pastor, J. & Melillo, J. M. 1986b. Carbon-nitrogen interactions in CO2-enriched white oak: physiological and long-term perspectives. Tree Physiol. 2: 233–241. Google Scholar
Oberbauer, S. F., Sionit, N., Hastings, S. J. & Oechel, W. C. 1986. Effects of CO2 enrichment on growth, photosynthesis, and nutrient concentration of Alaskan tundra plant species. Can. J. Bot. 64: 2993–2998. Google Scholar
Overdieck, O., Reid, C. H. & Strain, B. R. 1988. The effects of preindustrial and future CO2 concentrations on growth, dry matter production and the C/N relationship in plants at low nutrient supply:Vigna unguiculata (cowpea),Abelmoschus esculentus (okra) and_Raphanus sativus_ (radish). Angew. Botanik 62: 119–134. Google Scholar
Paez, A., Hellmers, H. & Strain, B. R. 1980. CO2 effects on apical dominance in_Pisum sativum_. Physiol. Plant. 50: 43–46. Google Scholar
Patterson, D. T. & Flint, E. P. 1982. Interacting effects of CO2 and nutrient concentrations. Weed Science 30: 389–394. Google Scholar
Phillips, D. A., Newell, K. D., Hassell, S. A. & Felling, C. E. 1976. The effect of CO2 enrichment on root nodule development and symbiotic N2 reduction in_Pisum sativum_ L. Amer. J. Bot. 63: 356–362. Google Scholar
Poorter, H., Pot, S. & Lambers, H. 1988. The effect of an elevated atmospheric CO2 concentration on growth, photosynthesis and respiration of_Plantago major_. Physiol. Plant. 73: 553–559. Google Scholar
Reddy, V. R., Acock, B. & Acock, M. C. 1989. Seasonal carbon and nitrogen accumulation in relation to net carbon dioxide exchange in a carbon dioxide-enriched soybean canopy. Agron. J. 81: 78–83. Google Scholar
Reynolds, J. F. & Thornley, J. H. M. 1982. A shoot:root partitioning model. Ann. Bot. 49: 585–597. Google Scholar
Richardson, S. D. 1953. Studies on root growth in_Acer saccharinum_ L. I. The relation between root growth and photosynthesis. Proc. K. Ned. Acad. Wet. C56: 185–193. Google Scholar
Rogers, H. H., Cure, J. D., Thomas, J. F. & Smith, J. M. 1984. Influence of elevated CO2 on growth of soybean plants. Crop Sci. 24: 361–367. Google Scholar
Rowland-Bamford, A. J., Allen, L. H.Jr., Baker, J. T. & Boote, K. J. 1990. Carbon dioxide effects on carbohydrate status and partitioning in rice. J. exp. Bot. 41: 1601–1608. Google Scholar
Sasek, T. W. & Strain, B. R. 1988. Effects of carbon dioxide enrichment on the growth and morphology of Kudzu (Pueraria lobata). Weed Science 36: 28–36. Google Scholar
Shivashankar, K. & Vlassak, K. 1978. Influence of straw and CO2 on N2-fixation and yield of field-grown soybeans. Plant and Soil 49: 259–266. Google Scholar
Sionit, N. 1983. Response of soybean to two levels of mineral nutrition in CO2-enriched atmosphere. Crop Sci. 23: 329–334. Google Scholar
Sionit, N., Strain, B. R. & Hellmers, H. 1981a. Effects of different concentrations of atmospheric CO2 on growth and yield components of wheat. J. Agric. Sci. 79: 335–339. Google Scholar
Sionit, N., Hellmers, H. & Strain, B. R. 1980. Growth and yield of wheat under CO2 enrichment and water stress. Crop Sci. 20: 687–690. Google Scholar
Sionit, N., Hellmers, H. & Strain, B. R. 1982. Interaction of atmospheric CO2 enrichment and irradiance on plant growth. Agron. J. 74: 721–725. Google Scholar
Sionit, N., Mortensen, D. A., Strain, B. R. & Hellmers, H. 1981b. Growth response of wheat to CO2 enrichment and different levels of mineral nutrition. Agron. J. 73: 1023–1027. Google Scholar
Sionit, N., Strain, B. R., Hellmers, H., Riechers, G. H. & Jaeger, C. H. 1985. Long-term atmospheric CO2 enrichment affects the growth and development of_Liquidambar styraciflua_ and_Pinus taeda_ seedlings. Can. J. For. Res. 15: 468–471. Google Scholar
Sritharan, R. & Lenz, F. 1990. The effect of CO2 concentration and water supply on photosynthesis, dry matter production and nitrate concentrations of kohlrabi (Brassica oleracea var.gongylodes L.). Acta Horticulturae 286: 43–55. Google Scholar
Stulen, I., Den, Hertog, J. & Jansen, C. M. 1992. The influence of atmospheric CO2 enrichment on allocation patterns of carbon and nitrogen in plants from natural vegetations. In: Govindjee, Abrol, Y. P. & Mohanty, P. (ed), Photosynthesis and Plant Productivity.in press Oxford QIBP Publishing Co. PVT. LTD, New Delhi. Google Scholar
Thornley, J. H. M. 1972. A balanced quantitative model for root:shoot ratios in vegetative plants. Ann. Bot. 36: 431–441. Google Scholar
Tinus, R. W. 1972. CO2 enriched atmosphere speeds growth of Ponderosa pine and blue spruce seedlings. Tree Plant. Notes 23: 12–15. Google Scholar
Tognoni, F., Halevy, A. H. & Wittwer, S. H. 1967. Growth of bean and tomato plants as affected by root absorbed growth substances and atmospheric carbon dioxide. Planta 72: 43–52. Google Scholar
Tolley, L. C. & Strain, B. R. 1984. Effects of CO2 enrichment and water stress on growth of_Liquidambar styraciflua_ and_Pinus taeda_ seedlings. Can. J. Bot. 62: 2135–2139. Google Scholar
Tolley, L. C. & Strain, B. R. 1985. Effects of CO2 enrichment and water stress on gas exchange of_Liquidambar styraciflua_ and_Pinus taeda_ seedlings grown under different irradiance levels. Oecologia 65: 166–172. Google Scholar
Van der, Werf, A., Kooijman, A, Welschen, R & Lambers, H. 1988. Respiratory energy costs for the maintenance of biomass, for growth and for ion uptake in roots of_Carex diandra_ and_Carex acutiformis_. Physiol. Plant. 72: 483–491. Google Scholar
Vessey, J. K., Henry, L. T. & RaperJr, C. D. 1990. Nitrogen nutrition and temporal effects of enhanced carbon dioxide on soybean growth. Crop Sci. 30: 287–294. Google Scholar
Whipps, J. M. 1985. Effect of CO2 concentration on growth, carbon distribution and loss of carbon from the roots of maize. J. Exp. Bot. 36: 644–651. Google Scholar
Whipps, J. M. 1987. Carbon loss from the roots of tomato and pea seedlings grown in soil. Plant and Soil 103: 95–100. Google Scholar
Wilson, J. B. 1988. A review of evidence on the control of shoot: root ratio, in relation to models. Ann. Bot. 61: 433–449. Google Scholar
Wittwer, S. H. 1986. Worldwide status and history of CO2 enrichment — an overview. In: Enoch, H. Z. & Kimball, B. A. (eds), Carbon Dioxide Enrichment of Greenhouse Crops. Vol I. Status and CO2 source. pp. 3–16. CRC Press, Inc., Boca Raton. Google Scholar
Wong, S. C. 1979. Elevated atmospheric partial pressure of CO2 and plant growth. I. Interactions of nitrogen nutrition and photosynthetic capacity in C3 and C4 plants. Oecologia 44: 68–74. Google Scholar
Wong, S. C. 1990. Elevated atmospheric partial pressure of CO2 and plant growth. II Non-structural carbohydrate content in cotton plants and its effect on growth. Photosynthesis Research 23: 171–180. Google Scholar
Yelle, S., Gosselin, A. & Trudel, M. J. 1987. Effect of atmospheric CO2 concentration and root-zone temperature on growth, mineral nutrition, and nitrate reductase activity of greenhouse tomato. J. Amer. Soc. Hort. Sci. 112: 1036–1040. Google Scholar