Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-28T05:21:40.155Z Has data issue: false hasContentIssue false

Effects of Carbon Dioxide Enrichment on the Expansion and Size of Kudzu (Pueraria lobata) Leaves

Published online by Cambridge University Press:  12 June 2017

Thomas W. Sasek
Affiliation:
Duke Phytotron, Dep. Bot., Duke Univ., Durham, NC 27706
Boyd R. Strain
Affiliation:
Duke Phytotron, Dep. Bot., Duke Univ., Durham, NC 27706 Reprint requests to T. Sasek, School of For. and Environ. Studies, Duke Univ., Durham, NC 27706

Abstract

Seedlings of kudzu were grown at 350, 675, or 1000 μl/L CO2 in controlled-environment chambers. At elevated CO2 concentrations, maximum leaf expansion rates were approximately 40% greater, leaves were fully expanded several days sooner, fully expanded leaves were larger at each leaf position, and leaf production rates were increased 12%. Peak starch accumulation was much greater in plants grown at elevated CO2 concentrations. Total xylem water potentials were higher (less negative) at full hydration, and osmotic potentials were decreased (more negative) by CO2 enrichment. At 1000 μl/L CO2, leaf turgor pressure was twice that at 350 μl/L CO2. Results suggest that leaf expansion rates and leaf expansivity may have been increased due to higher turgor pressure at the higher CO2 concentrations. The potential for successful seedling establishment may be enhanced as the atmospheric CO2 concentration continues to rise, increasing kudzu invasiveness.

Type
Physiology, Chemistry, and Biochemistry
Copyright
Copyright © 1989 by the Weed Science Society of America 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

1. Bradford, K. J. and Hsiao, T. C. 1982. Physiological responses to moderate water stress. Pages 88105 in Lange, O. L., Nobel, P. S., Osmond, C. B., and Ziegler, H., eds. Encyclopedia of Plant Physiology, New Series, Vol. 12 B. Springer-Verlag, Berlin.Google Scholar
2. Clark, W. C., ed. 1982. Carbon Dioxide Review. Oxford Univ. Press, New York.Google Scholar
3. Downs, R. J. and Hellmers, H. 1978. Controlled climate and plant research. World Meterological Organization, Technical Note #148. Geneva.Google Scholar
4. Edmonds, J. A., Reilly, J., Trabalka, J. R., and Reichle, D. E. 1984. An analysis of possible future retention of fossil fuel CO2. DOE OR/21400-1. US Dep. Energy, Washington, DC.Google Scholar
5. Ebell, L. F. 1979. Specific total starch determinations in conifer tissues with glucose oxidase. Phytochemistry 8:2536.Google Scholar
6. Ford, M. A. and Thorne, G. N. 1967. Effect of CO2 concentration on growth of sugarbeet, barley, kale, and maize. Ann. Bot. 31:629644.Google Scholar
7. Friend, D.J.C., Helston, U. A., and Fisher, J. E. 1962. The rate of dry weight accumulation in Marquis wheat as affected by temperature and light intensity. Can. J. Bot. 40:939955.Google Scholar
8. Hardy, R.W.F. and Havelka, U. D. 1977. Possible routes to increase the conversion of solar energy to food and feed by grain legumes and cereal grains (drop production): CO2 and N2 fixation, foliar fertilization, and assimilate partitioning. Pages 299322 in Mitsui, A., Miyachi, S., San Pietro, A., Tamura, S., eds. Biological Solar Energy Conversion. Academic Press, New York.Google Scholar
9. Hellmers, H. and Giles, L. J. 1979. Carbon dioxide: critic I. Pages 229234 in Tibbitts, T. W. and Kozlowski, T. T., eds. Controlled Environment Guidelines for Plant Research. Academic Press, New York.Google Scholar
10. Ho, L. C. 1977. Effects of CO2 enrichment on the rates of photosynthesis and translocation of tomato leaves. Ann. Appl. Biol. 87:191200.Google Scholar
11. Knecht, G. N. and O'Leary, J. W. 1972. Components of increased leaf growth resulting from carbon dioxide enrichment. J. Colo. Wyo. Acad. Sci. 7:23.Google Scholar
12. Kramer, P. J., Hellmers, H., and Downs, R. J. 1970. SEPEL: new phytotrons for environmental research. Bioscience 20:12011208.Google Scholar
13. Morison, J.I.L. and Gifford, R. M. 1984. Ethylene contamination of CO2 cylinders. Plant Physiol. 75:275277.Google Scholar
14. Newton, P. 1965. Growth of Cucumis sativus, variety Butcher's Disease Resistor, with two concentrations of carbon dioxide. Ann. Appl. Biol. 56:5564.CrossRefGoogle Scholar
15. Pearcy, R. W. and Bjorkman, O. 1983. Physiological effects. Pages 65105 in Lemon, E. R., ed. CO2 and Plants: The Response of Plants to Rising Levels of Atmospheric Carbon Dioxide. Westview Press, Inc., Boulder, CO.Google Scholar
16. Pharr, D. M., Huber, S. C., and Sox, H. N. 1985. Leaf carbohydrate status and enzymes of translocate synthesis in fruiting and vegetative plants of Cucumis sativus L. Plant Physiol. 77:104108.Google Scholar
17. Sasek, T. W. and Strain, B. R. 1988. Effects of carbon dioxide enrichment on the growth and morphology of kudzu (Pueraria lobata). Weed Sci. 36:2836.Google Scholar
18. Scholander, P. F., Hammel, H. T., Broadstreet, E. D., and Hemmingsen, E. A. 1965. Sap pressure in vascular plants. Science 148:339346.Google Scholar
19. Stevens, L. 1976. King Kong kudzu, menace to the South. Smithsonian 7:9399.Google Scholar
20. Stuiver, M. 1982. Atmospheric carbon dioxide in the 19th century. Science 202:1109.Google Scholar
21. Thomas, J. F. and Harvey, C. N. 1983. Leaf anatomy of four species grown under continuous CO2 enrichment. Bot. Gaz. 144:303309.CrossRefGoogle Scholar
22. Tsugawa, H. and Tange, M. 1981. Prediction equation for estimating leaflet area of kudzu vines (Pueraria lobata Ohwi). Sci. Rep. Fac. Agric. Kobe Univ. 14:249252.Google Scholar
23. Tsugawa, H., Tange, M., and Masui, K. 1979. Top and root growth of seedlings of kudzu vines (Pueraria lobata Ohwi). Sci. Rep. Fac. Agric. Kobe Univ. 13:203208.Google Scholar
24. Tsugawa, H., Tange, M., and Mizuta, Y. 1985. Influence of shade treatment on leaf and branch emergence, and dry matter production of kudzu vine seedlings (Pueraria lobata Ohwi). Sci. Rep. Fac. Agric. Kobe Univ. 16:359367.Google Scholar
25. Wardlaw, C. W. 1952. Experimental and analytical studies of Pteridophytes. XVIII. The nutritonal status of the apex and morphogenesis. Ann. Bot. 16:207218.Google Scholar
26. 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 44:6874.Google Scholar