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The occurrence, and influence on photolithotrophs, of high oxygen concentrations
Published online by Cambridge University Press: 05 December 2011
Synopsis
Hyperoxia (O2 in solution in excess of air-equilibrium values) occurs in certain photosynthesising cells which use inorganic C concentrating mechanisms, and as a result of abiological mechanisms. Geochemical evidence suggests that the atmosphere may have had significantly higher O2 partial pressures in the past (e.g. the Upper Carboniferous) than occurs today. Biochemical effects of high O2 concentrations in solution include inhibition of RUBISCO (competitive with CO2) and nitrogenase, as well as damage caused by higher levels of toxic O species (H2O2, O2 and, especially, 1O2 and OH). The influence of high (twice the extant level) atmospheric O2 on growth of non-N2-fixers is as predicted from the properties of RUBISCO and the occurrence of inorganic C concentrating mechanisms. Acclimation of N2-fixers to twice the extant O2 level involves increased restriction on O2 diffusion to nitrogenase so that growth is not inhibited (unless the high O2 has access to the C3 photosynthesis apparatus). Evidence as to the effect of hyperoxia on quenchers and scavengers of toxic O species is equivocal. Cells exposed to high O2 probably have higher mutation rates as a result of higher levels of toxic O species, although the production and maintenance of ‘stem’ cells may occur in parts of the plants with relatively low O2 levels.
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- Copyright © Royal Society of Edinburgh 1994
References
Berner, R. A. 1990. Atmospheric carbon dioxide levels over Phanerozoic time. Science 249, 1382–6.CrossRefGoogle Scholar
Berner, R. A. & Canfield, D. E. 1989. A new model for atmospheric oxygen over Phanerozoic time. American Journal of Science 289, 333–61.CrossRefGoogle ScholarPubMed
Berry, J., Boynton, J., Kaplan, A. & Badger, M. 1976. Growth and photosynthesis of Chlamydomonas reinhardtii as a function of CO2 concentration. Yearbook of the Carnegie Institution of Washington 75, 423–32.Google Scholar
Dakora, F. D. & Atkins, C. A. 1990. Effects of pO2 during growth on the gaseous diffusion properties of nodules of cowpea (Vigna unguiculata L. Walp.). Plant Physiology 93, 956–61.CrossRefGoogle Scholar
Dakora, F. D. & Atkins, C. A. 1991. Adaptation of nodulated soybean (Glycine max. (L.) Merr.) to growth in rhizospheres containing nonambient pO2. Plant Physiology 96, 728–36.Google Scholar
Edwards, G. & Walker, D. A. 1983. C3, C4: mechanisms, and cellular and environmental regulation, of photosynthesis. Oxford: Blackwell.Google Scholar
Foster, J. G. & Hess, J. L. 1980. Responses of superoxide dismutase and glutathione reductase activities in cotton leaf tissue exposed to an atmosphere enriched in oxygen. Plant Physiology 66, 482–7.Google Scholar
Gupta, A. S., Heiner, J. C., Holaday, A-S., Burke, J. J. & Allen, R. D. 1993. Increased resistance to oxidative stress in transgenic plants that overexpress chloroplastic Cu/Zn superoxide dismutase. Proceedings of the National Academy of Sciences U.S.A. 90, 1629–33.Google Scholar
Halliwell, B. & Gutteridge, J. M. C. 1989. Free radicals in biology and medicine. Oxford: Clarendon.Google Scholar
Imlay, J. A. & Linn, S. 1988. DNA damage and oxygen radical toxicity. Science 240, 1302–9.Google Scholar
Kaiser, S. D., Mascio, P., Murray, M. E. & Sies, H. 1990. Physical and chemical scavenging of singlet oxygen by tocopherols. Archives of Biochemistry and Biophysics 211, 101–8.CrossRefGoogle Scholar
Martin, A. P. & Palumbi, S. R. 1993. Body size, metabolic rate, generation time, and the molecular clock. Proceedings of the National Academy of Sciences U.S.A. 90, 4087–91.CrossRefGoogle ScholarPubMed
Matsue, T., Koike, S., Abe, T., Itaboski, T. & Uchida, I. 1992. An ultramicroelectrode for determination of intracellular oxygen. Light-irradiation-induced change in oxygen concentration in algal protoplast. Biochimica et Biophysica Acta 1101, 69–72.Google Scholar
Matta, J. C. & Trench, R. K. 1991. The enzymatic response of the symbiotic dinoflagellate Symbiodinium microadriaticum (Freudenthal) to growth in vitro under varied oxygen tensions. Symbiosis 11, 31–45.Google Scholar
Parsons, R. & Day, D. A. 1990. Mechanism of soybean nodule adaptation to different oxygen pressures. Plant, Cell and Environment 13, 501–12.Google Scholar
Pirt, M. W. & Pirt, S. J. 1980. The influence of carbon dioxide and oxygen partial pressure on Chlorella growth in photosynthetic steady-state cultures. Journal of General Microbiology 119, 321–6.Google Scholar
Pruder, G. D. & Bolton, J. E. 1980. Differences between cell division and carbon dioxide fixation rates associated with light intensity and oxygen concentration: implications in the cultivation of a marine diatom. Marine Biology 59, 1–6.CrossRefGoogle Scholar
Pulich, W. M. Jr 1974. Resistance to high oxygen tension, streptonigrin and U.V. irradiation in the green alga Chlorella sorokiniana strain ORS. Journal of Cell Biology 62, 904–7.CrossRefGoogle Scholar
Quebedaux, B. & Chollet, R. 1977. Comparative growth analyses of Panicum species with different rates of photorespiration. Plant Physiology 59, 42–4.Google Scholar
Quebedaux, B. & Hardy, R. W. F. 1975. Reproductive growth and dry matter production of Glycine max. (L.) Merr. in response to oxygen concentration. Plant Physiology 55, 102–7.Google Scholar
Raven, J. A. 1991a. Plant responses to high O2 episodes: relevance to a previous high O2 episodes. Palaeogeography, Palaeophysiology, Palaeoecology (Global and Planetary Change Section) 97, 19–38.CrossRefGoogle Scholar
Raven, J. A. 1991b. Implications of inorganic carbon utilization: ecology, evolution and geochemistry. Canadian Journal of Botany 69, 908–24.Google Scholar
Raven, J. A. 1991c. Long-term functioning of enucleate sieve elements: possible mechanisms of damage avoidance and damage repair. Plant, Cell and Environment 14, 139–46.Google Scholar
Raven, J. A. & Spicer, R. A. 1994. The evolution of CAM. In Winter, K., Smith, A. R. & Smith, J. A. C. (Eds) Proceedings of the International Conference on Crassulacean Acid Metabolism, Panama City, Panama, 1993. Heidelberg: Springer-Verlag (in press).Google Scholar
Raven, J. A., Johnston, A. M., Parsons, R. P. & Ktlbler, J. 1994. The influence of natural and experimental high O2 concentrations on O2-evolving photolithotrophs. Biological Reviews 69, 61–94.Google Scholar
Rawsthorne, S., von Caemmerer, S., Brooks, A. & Leegood, R. C. 1992. Metabolic interactions in leaves of C3-C4 intermediate plants. In Tobin, A. K. (Ed.) Plant organelles: compartmentation of metabolism in photosynthetic tissue, pp. 113–39. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Richardson, B., Wagner, F. W. & Welch, B. E. 1969. Growth of Chlorella sorokiniana at hyperbaric oxygen pressures. Applied Microbiology 17, 135–8.Google Scholar
Samish, Y. B. 1975. Oxygen build-up in photosynthesising leaves and canopies is small. Photosynthetica 9, 372–5.Google Scholar
Shick, J. M. & Dykens, J. A. 1985. Oxygen detoxification in alga-invertebrate symbioses from the Great Barrier Reef. Oecologia 66, 33–41.Google Scholar
Silvester, W. B., Whitbeck, J., Silvester, J. K. & Torrey, J. G. 1988. Growth, nodule morphology and nitrogenase activity of Myrica gale with roots grown at various oxygen levels. Canadian Journal of Botany 66, 1772–9.Google Scholar
Tepperman, J. M. & Dunsmuir, P. 1990. Transferred plants with elevated levels of chloroplastic superoxide dismutase are not more resistant to superoxide toxicity. Plant Molecular Biology 14, 165–77.Google Scholar
Zelitch, I. 1990. Physiological investigations of a tobacco mutant with O2-resistant photosynthesis and enhanced catalase activity. Plant Physiology 93, 1521–4.Google Scholar