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Carbon dioxide enrichment and water stress interaction on growth of two tomato cultivars

Published online by Cambridge University Press:  27 March 2009

Alejandra Paez ,
H. Hellmers  and
B. R. Strain
Alejandra Paez
Affiliation:
Botany Department, Duke University, Durham, North Carolina 27706, U.S.A.
H. Hellmers
Affiliation:
Botany Department, Duke University, Durham, North Carolina 27706, U.S.A.
B. R. Strain
Affiliation:
Botany Department, Duke University, Durham, North Carolina 27706, U.S.A.
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Summary

If atmospheric carbon dioxide concentration continues to increase, plant growth and crop yield could be affected. New Yorker and Better Boy cultivars of tomato (Lycopersicon esculentum) were used to investigate possible intraspecific variation in the response of crop species to increased CO2. Because precipitation and temperature are predicted to change with the increasing atmospheric CO2 concentration, the response of the two cultivars to the interaction between CO2 and water stress was also examined. Seeds of the two cultivars were germinated and grown under controlled environmental conditions, in either 350 or 675 μ1 CO2/1.

The plant water status of the two cultivars was inherently different but was little affected by the CO2 concentration when the plants were well watered. When water was withheld for 5 days the total leaf water potential and osmotic potential decreased in both CO2 treatments but less rapidly in high CO2 than in low. Under low CO2 total leaf water potential decreased to a lower value than osmotic potential. The differences were due, at least in part, to the reduced stomatal conductance and transpiration rate under high CO2.

Increased CO2 ameliorated the detrimental effects of drought stress on plant growth. The results indicate that increased CO2 could differentially affect the relative drought resistance of species cultivars.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 102 , Issue 3 , June 1984 , pp. 687 - 693
Copyright
Copyright © Cambridge University Press 1984

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References

Baes, C. F., Goeller, H. E., Olson, J. S. & Rotty, R. M. (1977). Carbon dioxide and climate: the uncontrolled experiment. American Society of Agricultural Engineering 13, 264269.Google Scholar
Bauerle, W. L. & Dretchman, D. W. (1973). Further studies on the effect of carbon dioxide enrichment and temperature on the yield and quality of several new tobacco mosaic virus resistant lines and cultivars. Ohio Agricultural Research Development Center, Research Summary 66, 1719.Google Scholar
Boyer, J. S. (1971). Recovery of photosynthesis in sunflower after a period of low leaf water potential. Plant Physiology 47, 816820.CrossRefGoogle ScholarPubMed
Doss, B. D., Pearson, R. W. & Rogers, H. T. (1974). Effect of soil water stress at various growth stages on soybean yield. Agronomy Journal 66, 297299.CrossRefGoogle Scholar
Downs, R. J. & Hellmers, H. (1975). Environment and the Experimental Control of Plant Growth, 145 pp. London: Academic Press.Google Scholar
Gardner, R. (1966). Effects of carbon dioxide enrichment on crops of tomatoes, lettuce, and chrysanthemums as grown commercially on the N.A.A.S. Experimental Horticultural Stations in England and Wales. Proceedings, XVII International Horticultural Congress, p. 342.Google Scholar
Gifford, R. M. (1979). Growth and yield of carbon dioxide enriched wheat under water-limited conditions. Australian Journal of Plant Physiology 6, 367378.Google Scholar
Hartman, H. D. (1966). The effect of CO2 concentration on head lettuce with special regard to the response of varieties. Proceedings, XVII International Horticultural Congress, p. 461.Google Scholar
Hellmers, H. & Giles, L. J. (1979). Carbon dioxide: critique I. In Controlled Environmental Guidelines for Plant Research (ed. Tibbitts, T. W. and Kozlowski, T. T.), pp. 229234. New York: Academic Press.CrossRefGoogle Scholar
Hurd, R. G. (1968). Effects of CO2-enrichment on the growth of young tomato plants in low light. Annals of Botany 32, 531542.CrossRefGoogle Scholar
Imai, K. & Murata, T. (1977). Effect of carbon dioxide concentration on growth and dry matter production of crop plants. II. Specific and varietal differences in response of dry matter production. Japan Journal of Crop Science 46, 291297.Google Scholar
Ito, T. (1973). Plant growth and physiology of vegetable plants as influenced by carbon dioxide environment. Transactions of Faculty of Horticulture Chiba University 7, 134 pp.Google Scholar
Jaeger, C. H., Hellmers, H. & Teare, I. (1981). An improved medium for nutriculture incorporating arcillite. HortScience 16 (2), 176177.CrossRefGoogle Scholar
Jones, R. J. & Mansfield, T. A. (1970). Increases in the diffusion resistance of leaves in a carbon dioxide enriched atmosphere. Journal of Experimental Botany 21, 951958.CrossRefGoogle Scholar
Keeling, C. D., Bacastow, R. B., Ekdahl, C. A. Jr., Guenther, P. K., Waterman, L. S. & Chin, J. F. S. (1976). Atmospheric carbon dioxide variations at Mauna Loa observatory, Hawaii. Tellus 28, 538551.CrossRefGoogle Scholar
Knecht, G. N. & O'leary, J. W. (1974). Increased tomato fruit development by carbon dioxide. Journal of the American Society for Horticultural Science 99, 214216.CrossRefGoogle Scholar
Kramer, P. J., Hellmers, H. & Downs, R. J. (1970). SEPEL: new phytotrons for environmental research. BioScience 20, 12011208.CrossRefGoogle Scholar
Madsen, E. (1975). Effect of CO2-enrichment on growth, development, fruit production and fruit quality in tomato from a physiological point of view. In Phytotrons in Horticultural Research (ed. deBilderberg, N. and Chouard, P.), pp. 318330. Mount Vernon, VA, U.S.A.: American Society for Horticultural Science.Google Scholar
Madsen, E. (1976). Effect of CO2-concentration on morphological, histological, cytological and physiological processes in tomato plants. State seed testing station, Lyngby, Denmark. 264 pp. Dissertation.Google Scholar
Marshall, R. (1964). CO2 does not help tomato propagation. Grower 61, 812815.Google Scholar
Morgan, J. V. (1971). The influence of supplementary illumination and CO2 enrichment on the growth, flowering and fruiting of the tomato. Acta Horticulturae 22, 187198.CrossRefGoogle Scholar
Newton, P. (1966). The influence of increased CO2 concentration and supplementary illumination on growth of tomato seedlings during the winter months. Annals of Applied Biology 57, 345354.CrossRefGoogle Scholar
Pallas, J. E. Jr,. (1965). Transpiration and stomatal opening with changes in carbon dioxide content of the air. Science 147, 171173.CrossRefGoogle ScholarPubMed
Raschke, K. (1972). Saturation kinetics of the velocity of stomatal closing in response to CO2. Plant Physiology 49, 229234.CrossRefGoogle ScholarPubMed
Regehr, D. L., Bazzaz, F. A. & Boggess, W. R. (1975). Photosynthesis, transpiration and leaf conductance of Populus deltoides in relation to flooding and drought. Photosynthetica 9, 5261.Google Scholar
Sionit, N., Hellmers, H. & Strain, B. R. (1980). Growth and yield of wheat under CO2 enrichment and water stress. Crop Science 20, 687690.CrossRefGoogle Scholar
Sionit, N. & Kramer, P. J. (1976). Water potential and stomatal resistance of sunflower and soybean subjected to water stress during various growth stages. Plant Physiology 58, 537540.CrossRefGoogle ScholarPubMed
Sionit, N., Strain, B. R., Hellmers, H. & Kramer, P. J. (1981). Effects of atmospheric CO2 concentration and water stress on water relations of wheat. Botanical Gazette 142 (2), 191196.CrossRefGoogle Scholar
Sionit, N., Teare, I. D. & Kramer, P. J. (1980). Effects of repeated application of water stress on water status and growth of wheat. Physiologia Plantarum 50, 1115.CrossRefGoogle Scholar
Takami, S. & VanBavel, C. H. N. (1976). Numerical experiments on influence of CO2 release at ground level on crop assimilation and water use. Agricultural Meteorology 15, 193203.CrossRefGoogle Scholar
Tinus, R. W. (1974). Impact of the CO2 requirement on plant water use. Agricultural Meteorology 14, 99112.CrossRefGoogle Scholar
Wiebe, H. H., Campbell, G. S., Gardner, W. H., Rawlins, S. G., Cary, J. W. & Brown, R. W. (1971). Measurement of plant and soil water status. Utah Agricultural Experiment Station Bulletin 484.Google Scholar
Wittwer, S. H. & Robb, W. (1964). Carbon dioxide enrichment of greenhouse atmospheres for food crop production. Economic Botany 18, 3456.CrossRefGoogle Scholar
Woodwell, G. M., Whittaker, R. H., Reiners, W. A., Likens, G. E., Delwiche, C. C., & Botkin, D. B. (1978). The biota and the world carbon budget. Science 199, 141146.CrossRefGoogle ScholarPubMed