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The growth and development of cowpeas (Vigna unguiculata) under tropical field conditions

Published online by Cambridge University Press:  27 March 2009

E. J. Littleton ,
M. D. Dennett ,
J. Elston  and
J. L. Monteith
E. J. Littleton
Affiliation:
International Institute for Tropical Agriculture, P.M.B. 5320, Ibadan, Nigeria
M. D. Dennett
Affiliation:
Department of Agricultural Botany, University of Reading, Whiteknights, Reading
J. Elston
Affiliation:
Department of Plant Science, University of Leeds
J. L. Monteith
Affiliation:
Department of Physiology and Environmental Studies, University of Nottingham School of Agriculture, Loughborough
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Summary

The CO2 exchange of leaves, pods and peduncles was measured in cowpea crops grown at Ibadan, Nigeria, using a portable infra-red gas analysis system. Most leaves had maximum rates of photosynthesis (Pm) of about 1·4 mg CO2/m2/sec and maintained this value for 20 days from full expansion. Early leaves had slightly slower rates. Pm decreased when leaf temperature exceeded 35 °C. The maximum efficiency of photosynthesis, ɛm, was about 2 g CO2/E (0·045 mol CO2/E). ɛmdecreased with temperature for leaves, but increased for pods. The latter response probably results from the effect of the high CO2 concentrations within the pod on the ribulose disphosphate carboxylation reaction. Water shortage reduced Pm but not ɛm. Pods and peduncles had a slightly negative CO2 exchange rate at light saturation but this was considerably less than the rate of CO2 evolution in the dark.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 97 , Issue 3 , December 1981 , pp. 539 - 550
Copyright
Copyright © Cambridge University Press 1981

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References

REFERENCES

Atkins, C.A. & Pate, J. S. (1977). An IRGA technique to measure CO2 content of small volumes of gas from the internal atmospheres of plant organs. Photosynthetica 11, 214216.Google Scholar
Beuerlein, J. E. & Pendleton, J. W. (1971). Photosynthetic rates and light saturation curves of individual soybean leaves under field conditions. Crop Science 11, 217219.CrossRefGoogle Scholar
Biscoe, P. V., Gallagher, J. N., Littleton, E. J., Monteith, J. L. & Scott, R. K. (1975). Barley and its environment. IV. Sources of assimilate for the grain. Journal of Applied Ecology 12, 295318.CrossRefGoogle Scholar
Bonhomme, R., Varlet Grancher, C., Chartier, M. & Artis, P. (1977). Utilisation de l'energie solaire par une culture de Vigna sinensis. IV. Influence de l'âge des ´clairements pass´s sur le potential photosynth´tique des feuilles cotylédonaires. Annales Agronomiquea 28, 159169.Google Scholar
Charles-Edwards, D. A. (1978). An analysis of the photosynthesis and productivity of vegetable crops in the United Kingdom. Annals of Botany 421, 717731.Google Scholar
Dornoff, G. N. & Shibles, R. N. (1970). Varietal differences in net photosynthesis of soybean leaves. Crop Science 10, 4245.Google Scholar
Ehleringer, J. & Bjorkman, O. (1977). Quantum yields for CO2 uptake in C2 and C4 plants. Plant Physiology 59, 8690.CrossRefGoogle Scholar
El-Sharkawy, M. A. & Hesketh, J. D. (1964). Effects of temperature and water deficit on leaf photosynthetic rates of different species. Crop Science 4, 514518.Google Scholar
Flinn, A. M., Atkins, C. A. & Pate, J. S. (1977). Significance of photosynthetic and respiratory exchanges in the carbon economy of the developing pea fruit. Plant Physiology 60, 412418.CrossRefGoogle ScholarPubMed
Gifford, R. M. (1974). A comparison of potential photosynthesis, productivity and yield of plant species with differing photosynthetic metabolism. Australian Journal of Plant Physiology 1, 107117.Google Scholar
Harvey, D. M., Hedley, C. L. & Keely, R. (1976). Photosynthetic and respiratory studies during pod and seed development in Pisum sativum L. Annals of Botany 40, 9931001.Google Scholar
Imbamba, S. K. & Tieszen, L. L. (1977). Influence of light and temperature on photosynthesis and transpiration in some C3 and C4 vegetable plants from Kenya. Physiologia Plantarum 39, 311316.CrossRefGoogle Scholar
Korner, C. H., Scheel, O. A. & Bauer, H. (1979). Maximum leaf diffusive conductance in vascular plants. Photosynthetica 13, 4582.Google Scholar
Kumar, D. & Tieszen, L. L. (1980). Photosynthesis in Coffea arabica. I. Effects of light and temperature. Experimental Agriculture 16, 1319.CrossRefGoogle Scholar
Kumura, A. & Naniwa, I. (1965). Studies on dry matter production of soybean plant. I. Ontogenic changes in photosynthetic and respiratory capacity of soybean plant and its parts. Proceedings Crop Science Society of Japan 33, 467472.CrossRefGoogle Scholar
Littleton, E. J. (1971). The gas exchange of barley leaves and ears. Ph.D. thesis, University of Nottingham.Google Scholar
Littleton, E. J., Dennett, M. D., Elston, J. & Monteith, J. L. (1979). The growth and development of cowpeas under tropical field conditions. 1. Leaf area. Journal of Agricultural Science, Cambridge 93, 291307.Google Scholar
Littleton, E. J., Dennett, M. D., Monteith, J. L. & Elston, J. (1979). The growth and development of cowpeas under tropical field conditions. 2. Dry matter accumulation and partitioning. Journal of Agricultural Science, Cambridge 93, 309320.CrossRefGoogle Scholar
Littleton, E. J. & Knight, J. R. (1980). Nottingham/Reading/IITA Productivity Project System Reference Manual. O.D.A. Tropical Microclimatology Project, University of Nottingham School of Agriculture.Google Scholar
Ludlow, M. M. & Wilson, G. L. (1971). Photosynthesis of tropical pasture plants. I. Illuminance, carbon dioxide concentration, leaf temperature and leaf-air vapour pressure difference. Australian Journal of Biological Sciences 24, 449470.CrossRefGoogle Scholar
Lush, W. M. & Rawson, H. M. (1979). Effects of domestication and region of origin on leaf gas exchange in cowpea (Vigna unguiculata (L.) Walp.). Photosynthetica 13, 417427.Google Scholar
Marshall, B. & Biscoe, P. V. (1977). A mobile apparatus for measuring photosynthesis in the field. Journal of Experimental Botany 28, 10081017.CrossRefGoogle Scholar
Peat, W. E. (1970). Relationships between photosynthesis and light in the tomato. Annals of Botany 34, 319328.Google Scholar
Rawson, H. M. & Hackett, C. (1974). An exploration of the carbon economy of the tobacco plant. III. Gas exchange of leaves in relation to position on stem, ontogeny and nitrogen content. Australian Journal of Plant Physiology 11, 551560.Google Scholar
Sinclair, T. R., Lugg, D. G. & Spaeth, S. C. (1980). Comparative fixation and utilisation of carbon and nitrogen among soybean genotypes. In Advances in Legume Science (ed. Summerfield, R. J. and Bunting, A. H.), pp. 313322. Royal Botanic Garden, Kew.Google Scholar
Summerfield, R. J. (1977). Vegetative growth, reproductive ontogeny and seed yield of selected tropical grain legumes. In Crop Protection Agents, Their Biological Evaluation (ed. McFarlane, N. A.), pp. 251271. London: Academic Press.Google Scholar
Thornley, J. H. M. (1976). Mathematical Models in Plant Physiology. London: Academic Press, 318 pp.Google Scholar
Varlet Grancher, C., Bonhomme, R. & Chartier, P. (1978). Efficiency of Sugar Cane and Cowpea as Solar Energy Converters. Proceedings International Solar Energy Congress, New Delhi, India, 16–21 01 1978, pp. 797803.Google Scholar
Woodward, R. G. & Rawson, H. M. (1976). Photosynthesis and transpiration in dicotyledonous plants. II. Expanding and senescing leaves of soybean. Australian Journal of Plant Physiology 3, 257267.Google Scholar
Woolhouse, H. W. (1978). Light-gathering and carbon assimilation processes in photosynthesis; their adaptive modifications and significance for agriculture. Endeavour 2, 3546.CrossRefGoogle Scholar