Abstract
Intact mesophyll cells can be rapidly isolated from the cladophylls ofAsparagus officinalis by gentle scraping with a plastic card, the yield being higher than 80% on a chlorophyll basis. The cells can be stored for at least 24h without loss of photosynthetic capacity and were found to be stable under a variety of conditions. In contrast to cell preparations from other plant species, photosynthetic activity was little affected by the presence of sorbitol as an osmoticum up to a concentration of 1.5 M. Similarly, the pH value of the medium influenced photosynthesis to only a small extent at a constant [CO2] of 200 μM. The response of the cells' photosynthetic capacity to light, temperature and CO2 concentration was similar to those reported for isolated cells from other plant species. Isolated cells ofA. officinalis can be used under a large range of conditions which gives them a measure of flexibility not possible with most plant cells which have sharply defined optimal conditions for photosynthesis. The isolated cells have a photosynthetic capacity of 40–60% of that of the intact cladophyll. The loss of photosynthetic activity observed upon isolation could not be accounted for by breakage of the cells. Virtually all of the cells were shown to be intact on the basis of Evans Blue exclusion and more than 80% of the cells contained intact chloroplasts and vacuoles. The entire loss of photosynthetic activity could be accounted for by a decrease in sucrose synthesis rather than by an equal decrease in the synthesis in all products. A six- to seven fold increase in the level of14C in hexose phosphates in the isolated cells supports the notion of inhibition of the sucrose-synthesis pathway.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aono, R., Kano, H., Hirata, H. (1974) Photosynthetic activity of isolated spinach mesophyll cells. Plant Cell Physiol.15, 567–570
Arnon, D.I. (1949) Copper enzymes in isolated chloroplasts. Plant Physiol24, 1–12
Bown, A.W. (1982) An investigation into the roles of photosynthesis and respiration in H+ efflux from aerated suspensions ofAsparagus mesophyll cells. Plant Physiol.70, 803–814
Bjorkman, O. (1981) Responses to different quantum flux densities. In: Encyclopaedia of plant physiology N.S., vol. 12a: Response to physical environment, pp 57–107, Lange, O.L., Nobel, P.S., Osmond, C.B., Ziegler, H., eds. Springer, Berlin Heidelberg New York
Cataldo, D.A., Berlyn, G.P. (1974) An evaluation of selected physical characteristics of enzymatically separated mesophyll cells and minor veins of tobacco. Plant Physiol.61, 957–963
Cheruel, J., Jullien, M. (1979) Amino acid uptake into cultivated mesophyll cells fromAsparagus officinalis. Plant Physiol.63, 621–626
Colman, B., Mawson, B.T. (1978) The role of plasmolysis in the isolation of photosynthetically active leaf mesophyll cells. Z. Pflazenphysiol.86, 331–338
Colman, B., Mawson, B.T., Espie, G.S. (1979) The rapid isolation of photosynthetcally active mesophyll cells fromAsparagus cladophylls. Can. J. Bot.57, 1505–1510
Delieu, T., Walker, D.A. (1972) An improved cathode for the measurement of photosynthetic oxygen evolution by isolated chloroplasts. New Phytol.71, 201–225
Delieu, T., Walker, D.A. (1981) Polarographic measurement of photosynthetic oxygen evolution by leaf discs. New Phytol89, 165–178
Edwards, G.E., Robinson, S.P., Tyler, N.J.C., Walker, D.A. (1978) Photosynthesis by isolated protoplasts, protoplast extracts and chloroplasts of wheat. Plant Physiol.62, 313–319
Enser, U., Heber, U. (1980) Metabolic regulation by pH gradients. Inhibition of photosynthesis by indirect proton transfer across the chloroplast envelope. Biochim. Biophys. Acta.592, 577–591
Fraser, A.R., Ridley, S.M. (1984) Direct measurement of enzyme activities and inhibition kinetics within isolated asparagus cells using a freeze-thaw technique. In: Advances in photosynthesis research, vol. III, pp. 589–592, Sybesma, C. ed. Nijhoff/Tunk, The Hague
Flügge, U.I., Freisch, M., Heldt, H.W. (1980) The mechanism of the control of carbon fixation by the pH in the chloroplast stroma. Planta149, 48–51
Foyer, C., Walker, D.A., Spencer, C., Mann, B. (1982) Observations on the phosphate status and intracellular pH of intact cells, protoplasts and chloroplasts from photosynthetic tissue using phosphorus 31 nuclear magnetic resonance. Biochem. J.202, 429–434
Gaff, D.F., Okong'O-Ogola, O. (1971) The use of non-permeating pigments for testing the survival of cells. J. Exp. Bot.22, 756–758
Herold, A. (1980) Regulation of photosynthesis by sink activity — the missing link. New Phytol.86, 131–144
Hills, M.J. (1984) Photosynthetic characteristics of isolated mesophyll cells ofAsparagus officinalis. Ph. D. thesis, Sheffield University, UK
Hills, M.J., Walker, D.A. (1984) Sucrose efflux fromAsparagus officinalis cells. In: Advances in photosynthesis research, vol. III, pp. 677–680, Sybesma, C. ed. Nijhoff/Junk, The Hague
Jensen, R.G., Francki, R.I.B., Zaitlin, M. (1971) Metabolism of separated leaf cells. Plant Physiol.48, 9–13
Kaiser, G., Heber, U. (1983) Photosynthesis of leaf cell protoplasts and permeability of the plasmalemma. Planta157, 462–470
Karpen, L. (1981) Ecological significance of resistance to higher temperature. In: Encyclopaedia of plant physiology, N.S. vol. 12a: Response to physical environment, pp. 439–474, Lange, O.L., Nobel, P.S., Osmond, C.B., Ziegler, H., eds. Springer, Berlin Heidelberg New York
Oliver, D.J., Thorne, J.H., Poincelot, R.P. (1979) Rapid isolation of mesophyll cells from soybean leaves. Plant Sci. Letts.16, 149–155
Outlaw, W.H., Jnr. Schmuck, C.L., Tolbert, N.E. (1976) Photosynthetic carbon metabolism in the palisade parenchyma and spongy parenchyma ofVicia faba L. Plant Physiol.58, 186–189
Paul, J.S., Bassham, J.A. (1977) Maintenance of high photosynthetic rates in mesophyll cells isolated fromPapaver somniferum. Plant Physiol.60, 775–778
Peel, E. (1982) Photoautotrophic growth of suspension cultures ofAsparagus officinalis cells in turbidostats. Plant Sci. Letts.24, 147–155
Purczeld, P., Chon, C.J., Portis, A.R., Heldt, H.W., Heber, U. (1978) The mechanism of the control of carbon fixation by the chloroplast stroma. Biochim. Biophys. Acta.501, 488–498
Servites, J.C., Ogren, W.L. (1977) Rapid isolation of mesophyll cells from leaves of soybean for photosynthetic studies. Plant Physiol.59, 587–590
Sharkey, T.D., Badger M.R. (1982) Effects of water stress on photosynthetic electron transport, photophosphorylation and metabolite levels ofXanthium strumarium mesophyll cells. Planta156, 199–206
Sharkey, T.D., Raschke, K. (1980) Effects of phaseic acid and dihydrophaseic acid on stomata and the photosynthetic apparatus. Plant Physiol.65, 291–297
Stitt, M., Wirtz, W., Heldt, H.W. (1983) Regulation of sucrose synthesis by cytoplasmic fructose bisphosphatase and sucrose phosphate synthase during photosynthesis in varying light and carbon dioxide. Plant Physiol.72, 767–774
Walton, N.J., Woolhouse, H.W., Peterkin, J.H., Stewart, G.R. (1984) Ammonia assimilation in relation to photosynthesis in isolated cells ofAsparagus cladophylls. In: Advances in photosynthesis research, vol. III, pp. 891–895, Sybesma, C. ed. Nijhoff/Junk, The Hague
Werdan, K., Heldt, H.W., Milovancev, M. (1975) The role of pH in the regulation of carbon fixation in the chloroplast stroma. Biochem. Biophys. Acta.396, 276–292
Woodrow, I.E., Ellis, J.R., Jellings, A., Foyer, C.H. (1984) Compartmentation and fluxes of inorganic phosphate in photosynthetic cells. Planta161, 525–530
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hills, M.J. Photosynthetic characteristics of mesophyll cells isolated from cladophylls ofAsparagus officinalis L.. Planta 169, 38–45 (1986). https://doi.org/10.1007/BF01369773
Issue Date:
DOI: https://doi.org/10.1007/BF01369773