Abstract
High transpiration rates were found to affect the photosynthetic capacity of Xanthium strumarium L. leaves in a manner analagous to that of low soil water potential. The effect was also looked for and found in Gossypium hirsutum L., Agathis robusta (C. Moore ex Muell.) Bailey, Eucalyptus microcarpa Maiden, Larrea divaricata Cav., the wilty flacca tomato mutant (Lycopersicon esculentum (L.) Mill.) and Scrophularia desertorum (Munz) Shaw. Two methods were used to distinguish between effects on stomatal conductance, which can lower assimilation by reducing CO2 availability, and effects on the photosynthetic capacity of the mesophyll. First, the response of assimilation to intercellular CO2 pressure (C i) was compared under conditions of high and low transpiration. Second, in addition to estimating C i using the usual Ohm's law analogy, C i was measured directly using the closed-loop technique of T.D. Sharkey, K. Imai, G.D. Farquhar and I.R. Cowan (1982, Plant Physiol, 60, 657–659). Transpiration stress responses of Xanthium strumarium were compared with soil drought effects. Both stresses reduced photosynthesis at high C i but not at low C i; transpiration stress increased the quantum requirement of photosynthesis. Transpiration stress could be induced in small sections of leaves. Total transpiration from the plant did not influence the photosynthetic capacity of a leaf kept under constant conditions, indicating that water deficits develop over small areas within the leaf. The effect of high transpiration on photosynthesis was reversed approximately half-way by returning the plants to low-transpiration conditions. This reversal occurred as fast as measurements could be made (5 min), but little further recovery was observed in subsequent hours.
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Abbreviations
- A :
-
photosynthetic CO2 assimilation rate
- C a :
-
ambient CO2 partial pressure
- C i :
-
partial pressure of CO2 inside the leaf
- VPD:
-
leaf-to-air water-vapor pressure difference
References
Badger, M.R, Sharkey, T.D., von Caemmerer, S. (1984) The relationship between steady-state gas exchange of bean leaves and the levels of carbon reduction cycle intermediates. Planta, in press
Ball, M.C. (1981) Physiology of photosynthesis in two mangrove species: responses to salinity and other environmental factors. Ph.D. thesis, Australian National University, Canberra
Bradford, K.J., Sharkey, T.D., Farquhar, G.D. (1983) Gas exchange, stomatal behavior and δ13C values of the flacca tomato mutant in relation to abscisic acid. Plant Physiol. 72, 245–250
Cowan, I.R. (1977) Stomatal behaviour and environment. Adv. Bot. Res. 4, 117–228
Cowan, I.R., Farquhar, G.D. (1977) Stomatal function in relation to leaf metabolism and environment. Symp. Soc. Exp. Bot. 31, 471–505
Farquhar, G.D., Schulze, E.-D., Küppers M. (1980) Responses to humidity by stomata of Nicotiana glauca L. and Corylus avellana L. are consistent with the optimization of carbon dioxide uptake with respect to water loss. Aust. J. Plant Physiol. 7, 315–327
Farquhar, G.D., von Caemmerer, S. (1982) Modelling of photosynthetic response, to environmental conditions. In: Encyclopedia of plant physiology, N.S., vol. 12B: Physiological plant ecology II: Water relations and carbon assimilation, pp. 549–587, Lange, O.L., Nobel, P.S., Osmond, C.B., Ziegler, H., eds. Springer, Berlin Heidelberg New York
Farquhar, G.D., Sharkey, T.D. (1982) Stomatal conductance and photosynthesis. Annu. Rev. Plant Physiol. 33, 317–345
Field, C., Berry, J.A., Mooney, H.A. (1982) A portable system for measuring carbon dioxide and water vapour exchange of leaves. Plant Cell Environ. 5, 179–186
Forseth, I.N., Ehleringer, J.R. (1983) Ecophysiology of two solar tracking desert winter annuals. III. Gas exchange responses to light, CO2 and VPD in relation to long-term drought. Oecologia 57, 344–351
Hall, A.E., Schulze, E.-D., (1980) Stomatal response to environment and a possible interrelation between stomatal effects on transpiration and CO2 assimilation. Plant Cell Environ. 3, 467–474
Jarman, P.D. (1974) The diffusion of carbon dioxide and water vapour through stomata. J. Exp. Bot. 25, 927–936
Jones, H.G. (1973) Estimation of plant water status with the beta gauge. Agric. Meteorol. 11, 345–355
Langenheim, J.H., Osmond, C.B., Brooks, A., Ferrar, P.J. (1983) Photosynthetic responses to light in seedlings of selected Amazonian and Australian rainforest tree species. Oecologia, in press
Leuning, R. (1983) Transport of gases into leaves. Plant Cell Environ. 6, 181–194
Meidner, H. (1975) Water supply, evaporation, and vapour diffusion in leaves. J. Exp. Bot. 26, 666–673
Mohanty, P., Boyer, J.S. (1976) Chloroplast response to low leaf water potentials. IV. Quantum yield is reduced. Plant Physiol. 57, 704–709
Molz, F.J., Boyer, J.S. (1978) Growth-induced water potentials in plant cells and tissues. Plant Physiol. 62, 423–429
Passioura, J.B. (1982) Water in the soil-plant-atmosphere continuum. In: Encyclopedia of plant physiology, N.S., vol. 12B: Physiological plant ecology II: Water relations and carbon assimilation, pp. 5–34, Lange, O.L., Nobel, P.S., Osmond, C.B., Ziegler, H., eds. Springer, Berlin Heidelberg New York
Schulze, E.-D., Küppers, M. (1979) Short-term and long-term effects of plant water deficits on stomatal response to humidity in Corylus avellana L. Planta 146, 319–326
Schulze, E.-D., Lange, O.L., Buschbom, U., Kappen, L., Evenari, M. (1972) Stomatal responses to changes in humidity in plants growing in the desert. Planta 108, 259–270
Sharkey, T.D., Badger, M.R. (1982) Effects of water stress on photosynthetic electron transport, photophosphorylation and metabolite levels of Xanthium strumarium mesophyll cells. Planta 156, 199–206
Sharkey, T.D., Badger, M.R. (1984) Factors limiting photosynthesis as determined from gas exchange characteristics and metabolite pool sizes. Proc. VIth Int. Congr. Photosyn., Brussels 1983. Nijhoff/Dr. Junk, The Hague
Sharkey, T.D., Imai, K., Farquhar, G.D., Cowan, I.R. (1982) A direct confirmation of the standard method of estimating intercellular partial pressure of CO2. Plant Physiol. 69, 657–659
Sheriff, D.W. (1982) The hydraulic pathways in Nicotania glauca (Grah.) and Tradescantia virginiana (L.) leaves. and water potentials in leaf epidermes. Ann. Bot (London) 50, 535–548
Tyree, M.T., Yianoulis, P. (1980) The site of water evaporation from sub-stomatal cavities, liquid path resistances and hydroactive stomatal closure. Ann. Bot. (London) 46, 175–193
von Caemmerer, S. (1981) On the relationship between chloroplast biochemistry and gas exchange of leaves. Ph.D. thesis, Australian National University, Canberra
von Caemmerer, S., Farquhar, G.D. (1981) Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta 153, 376–387
Wylie, R.B. (1943) The role of the epidermis in foliar organization and its relations to the minor venation. Am. J. Bot. 30, 273–280
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This research was begun while the author was a Postdoctoral Research Fellow at the Australian National University, Canberra
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Sharkey, T.D. Transpiration-induced changes in the photosynthetic capacity of leaves. Planta 160, 143–150 (1984). https://doi.org/10.1007/BF00392862
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DOI: https://doi.org/10.1007/BF00392862