Hostname: page-component-78c5997874-xbtfd Total loading time: 0 Render date: 2024-11-19T22:08:05.920Z Has data issue: false hasContentIssue false
  • English
  • Français

Biochemical Basis for Plant Competition

Published online by Cambridge University Press:  12 June 2017

C. C. Black ,
T. M. Chen  and
R. H. Brown
C. C. Black
Affiliation:
Department of Biochemistry, University of Georgia, Athens, Georgia
T. M. Chen
Affiliation:
Department of Agronomy, University of Georgia, Athens, Georgia
R. H. Brown
Affiliation:
Department of Agronomy, University of Georgia, Athens, Georgia
Get access Rights & Permissions [Opens in a new window]

Abstract

A survey has been made of the literature on biochemical characteristics of plants with particular emphasis on factors affecting photosynthesis. From these characteristics, plants have been divided into two groups, efficient and non-efficient. This division is justified on the basis of data published by numerous workers. A hypothesis has been developed that efficient plants often have been used in agriculture because of their high production, but efficient plants also are very competitive and the observation has been made that almost all weeds which have been tested are members of the efficient groups of plants. This hypothesis is discussed and some general conclusions have been advanced related to plant breeding, development of herbicides to inhibit specific biochemical reactions, ecology, and increasing food production.

Type
Research Article
Information
Weed Science , Volume 17 , Issue 3 , July 1969 , pp. 338 - 344
Copyright
Copyright © 1969 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. Alex, J. F. 1964. Weeds of tomato and corn fields in two regions of Ontario. Weeds 12:308318.Google Scholar
2. Bassham, J. A. and Calvin, M. 1957. The path of carbon in photosynthesis. Prentice-Hall, Englewood Cliffs, N. J. 104 p.Google Scholar
3. Björkman, O. 1966. The effect of oxygen concentration on photosynthesis in higher plants. Physiol. Plant. 19:618633.Google Scholar
4. Björkman, O., Hiesey, W. M., Nobs, M., Nicholson, F. and Hart, R. W. 1968. Effect of oxygen concentration on dry matter production in higher plants. p. 228245. Carnegie Inst. Year Book. Carnegie Inst. of Washington, Wash. D. C. Google Scholar
5. Brown, R. H., Blaser, R. E. and Dunton, H. L. 1966. Leaf area index and apparent photosynthesis under various microclimates for different pasture species. Proc. Intl. Grassland Congr. 10:108113.Google Scholar
6. Burnside, C. A. and Bohning, R. H. 1957. The effect of prolonged shading on the light saturation curves of apparent photosynthesis in sun plants. Plant Physiol. 32:6163.CrossRefGoogle ScholarPubMed
7. Burnside, O. C. and Colville, W. L. 1964. Soybean and weed yields as affected by irrigation, row spacing, tillage and amiben. Weeds 12:109112.Google Scholar
8. Burnside, O. C. and Wicks, G. A. 1967. The effect of weed removal treatments on sorghum growth. Weeds 15:204207.Google Scholar
9. Cooper, J. P. and Tainton, N. M. 1968. Light and temperature requirements for the growth of tropical and temperate grasses. Herbage Abstr. 38:167176.Google Scholar
10. Decker, J. P. 1955. A rapid, post-illumination deceleration of respiration in green leaves. Plant Physiol. 30:8284.CrossRefGoogle Scholar
11. Decker, J. P. 1959. Comparative responses of carbon dioxide outburst and uptake in tobacco. Plant Physiol. 34:100102.Google Scholar
12. Downes, R. W. and Hesketh, J. D. 1968. Enhanced photosynthesis at low oxygen concentrations: Differential response of temperate and tropical grasses. Planta 78:7984.Google Scholar
13. Downton, J., Berry, J. and Tregunna, E. B. 1969. Photosynthesis: Temperate and tropical characteristics within a single grass genus. Science 163:7879.CrossRefGoogle ScholarPubMed
14. Downton, W. J. S. and Tregunna, E. B. 1968. Carbon dioxide compensation—its relation to photosynthetic carboxylation reactions, systematics of the Gramineae, and leaf anatomy. Can. J. Bot. 46:207215.Google Scholar
15. El-Sharkawy, M. A. and Hesketh, J. 1964. Effects of temperature and water deficit on leaf photosynthetic rates of different species. Crop Sci. 4:514518.CrossRefGoogle Scholar
16. El-Sharkawy, M. A. and Hesketh, J. D. 1965. Photosynthesis among species in relation to characteristics of leaf anatomy and CO2 diffusion resistances. Crop Sci. 5:517521.Google Scholar
17. El-Sharkawy, M. A., Loomis, R. S. and Williams, W. A. 1967. Apparent reassimilation of respiratory carbon dioxide by different plant species. Physiol. Plant. 20:171186.CrossRefGoogle Scholar
18. El-Sharkawy, M. A., Loomis, R. S., and Williams, W. A. 1968. Photosynthesis and respiratory exchanges of carbon dioxide by leaves of the grain amaranth. J. Appl. Ecol. 5:243251.Google Scholar
19. Everson, R. G. and Slack, C. R. 1968. Distribution of carbonic anhydrase in relation to the C4 pathway of photosynthesis. Phytochemistry 7:581584.Google Scholar
20. Forrester, M. L., Krotkov, G., and Nelson, C. D. 1966. Effect of oxygen on photosynthesis, photorespiration and respiration in detached leaves. I. Soybean, II. Corn and other monocotyledons. Plant Physiol. 41:422427; 428-431.Google Scholar
21. Hartt, C. E. 1965. Light and translocation of 14C in detached blades of sugarcane. Plant Physiol. 40:718724.CrossRefGoogle Scholar
22. Hatch, M. D. and Slack, C. R. 1966. Photosynthesis by sugar cane leaves. A new carboxylation reaction and the pathway of sugar formation. Biochem. J. 101:103111.Google Scholar
23. Hatch, M. D., Slack, C. R., and Johnson, H. S. 1967. Further studies on a new pathway of photosynthetic carbon dioxide fixation in sugar cane and its occurrence in other plant species. Biochem. J. 102:417422.Google Scholar
24. Hauser, E. W., Shaw, W. C., Harrison, H. F. and Parham, S. A. 1962. Herbicides and herbicide mixtures for weed control in peanuts. Weeds 10:139144.Google Scholar
25. Hesketh, J. D. and Moss, D. N. 1963. Variation in the response of photosynthesis to light. Crop Sci. 3:107110.Google Scholar
26. Hesketh, J. D. 1963. Limitations to photosynthesis responsible for differences among species. Crop Sci. 3:493496.Google Scholar
27. Hesketh, J. D. 1967. Enhancement of photosynthetic CO2 assimilation in the absence of oxygen, as dependent upon species and temperature. Planta 76:371374.CrossRefGoogle ScholarPubMed
28. Holm, L. 1969. Weed problems in developing countries. Weed Sci. 17:113118.Google Scholar
29. Holstun, J. T. Jr. 1963. Cultivation techniques in combination with chemical weed control in cotton. Weeds 11:190194.Google Scholar
30. Jones, S. B. Jr. and Davis, D. E. 1963. Weeds of the lower Coastal Plain in Alabama. Weeds 11:322323.CrossRefGoogle Scholar
31. Johnson, H. S. and Hatch, M. D. 1968. Distribution of the C4 dicarboxylic acid pathway of photosynthesis and its occurrence in dicotyledonous plants. Phytochemistry 7:375380.Google Scholar
32. Kacperska-Palacz, A. E., Putala, E. C. and Vengris, J. 1963. Developmental anatomy of barnyardgrass seedlings. Weeds 11:311316.CrossRefGoogle Scholar
33. King, R. W. and Evans, L. T. 1966. Photosynthesis in artificial communities of wheat, lucerne and subterranean clover plants. Aust. J. Biol. Sci. 20:623635. 1967.Google Scholar
34. Kortschak, H. P., Hartt, C. E., and Burr, G. O. 1965. Carbon dioxide fixation in sugar cane leaves. Plant Physiol. 40:209213.Google Scholar
35. Laetsch, W. M. 1968. Chloroplast specialization in dicotyledons possessing the C4 dicarboxylic acid pathway of photosynthetic CO2 fixation. Am. J. Bot. 55:875883.CrossRefGoogle Scholar
36. McAlister, E. D. and Myers, J. 1940. The time course of photosynthesis and fluorescence observed simultaneously. Smithson Misc. Coll. 99:626.Google Scholar
37. Miller, V. J. 1960. Temperature effect on the rate of the apparent photosynthesis of seaside bent and bermudagrass. Am. Soc. Hort. Sci. 75:700703.Google Scholar
38. Moss, D. N. 1962. The limiting carbon dioxide concentration for photosynthesis. Nature 193:587.Google Scholar
39. Murata, Y. and Iyama, J. 1963. Studies on the photosynthesis of forage crops. II. Influence of air temperature upon the photosynthesis of some forage and grain crops. Proc. Crop Sci. Soc. Japan. 31:315322.Google Scholar
40. Murata, Y., Iyama, J., and Honma, T. 1965. Studies on the photosynthesis of forage crops. IV. Influence of air temperature upon photosynthesis and respiration of alfalfa and several southern type forage crops. Proc. Crop Sci. Soc. Japan. 34:154158.Google Scholar
41. Osmond, C. B. 1967. β-Carboxylation during photosynthesis in Atriplex . Biochim. Biophys. Acta 141:197199.Google Scholar
42. Phillips, W. M. 1964. A new technique of controlling weeds in sorghum in a wheat-sorghum-fallow rotation in the Great Plains. Weeds 12:4244.Google Scholar
43. Racker, E. 1957. The reductive pentose phosphate cycle. I. Phosphoribulokinase and ribulose diphosphate carboxylase. Arch. Biochem. Biophys. 69:300310.Google Scholar
44. Robinson, R. G., Nelson, W. W., Thompson, R. L. and Thompson, J. R. 1964. Herbicides and mixtures for annual weed control in grain sorghum. Weeds 12:7779.Google Scholar
45. Rosado-Alberio, J., Weier, T. E., and Stocking, C. R. 1968. Continuity of the chloroplast membrane systems in Zea mays L. Plant Physiol. 43:13251331.Google Scholar
46. Shantz, H. L. and Piemeisel, L. N. 1927. The water requirements of plants at Akron, Colorado. J. Agr. Res. 34:10931189.Google Scholar
47. Slack, C. R. and Hatch, M. D. 1967. Comparative studies on the activity of carboxylases and other enzymes in relation to the new pathway of photosynthetic carbon dioxide fixation in tropical grasses. Biochem. J. 103:660665.CrossRefGoogle Scholar
48. Tregunna, E. B., Krotkov, G., and Nelson, C. D. 1961. Evolution of carbon dioxide by tobacco leaves during the dark period following illumination with different light intensities. Can. J. Bot. 39:10451056.Google Scholar
49. Tregunna, E. B., Krotkov, G. and Nelson, C. D. 1964. Further evidence on the effects of light on respiration during photosynthesis. Can. J. Bot. 42:989997.Google Scholar
50. Tregunna, E. B. and Downton, J. 1967. Carbon dioxide compensation in members of the amaranthaceae and some related families. Can. J. Bot. 45:23852387.Google Scholar
51. Tregunna, B. 1966. Flavin mononucleotide control of glycolic acid oxidase and photorespiration in corn leaves. Science 151:12391241.Google Scholar
52. Vengris, J. 1952. Weed populations as related to certain cultivated crops in the Connecticut River Valley, Mass. Weeds 2:125134.CrossRefGoogle Scholar
53. Warburg, O. 1920. Über die Geschwindigkeit der photochemischen Kohlensäurezersetzung in lebender Zellen. II. Biochem. Z. 103:188217.Google Scholar
54. Wax, L. W. and Pendleton, J. W. 1968. Effect of row spacing on weed control in soybeans. Weeds 16:462464.Google Scholar
55. Wiese, A. F., Collier, J. W., Clark, L. E., and Havelka, U. D. 1964. Effects of weeds and cultural practices on sorghum yields. Weeds 12:209211.Google Scholar
56. Zelitch, I. 1967. Water and CO2 transport in the photosynthetic process, p. 231248. In San Pietro, A., Greer, F. A., and Army, T. J. (eds.) Harvesting the Sun. Acad. Press, New York.Google Scholar
57. Zelitch, I. 1968. Investigations on photorespiration with a sensitive 14C-assay. Plant Physiol. 43:18291837.Google Scholar
58. Zelitch, I. and Day, P. R. 1968. Variation in photorespiration. The effect of genetic differences in photorespiration on net photosynthesis in tobacco. Plant Physiol. 43:18381844.Google Scholar