The role of carbonic anhydrase in photosynthesis and the activity of the carbon-concentrating-mechanism in bryophytes of the class Anthocerotae

ELIZABETH C. SMITH; HOWARD GRIFFITHS

doi:10.1046/j.1469-8137.2000.00559.x

Abstract

The role of carbonic anhydrase in the carbon-concentrating-mechanism of bryophytes of the class Anthocerotae was investigated by comparing the gas-exchange characteristics of material which had been incubated in the membrane-permeable Carbonic Anhydrase inhibitor ethoxyzolamide, with those of untreated material and material which had been incubated in buffer solution. In Phaeoceros laevis (Anthocerotae), incubation in ethoxyzolamide caused a depression in the rate of gross assimilation and a decrease in CO2 affinity beyond that which could be attributed to increased diffusion limitation. A range of liverworts and mosses, in which a carbon-concentrating-mechanism is absent, were also investigated. These showed no depression of rates of gross assimilation after incubation in ethoxyzolamide relative to those of untreated material. The CO2 compensation point and CO2 uptake characteristics of Phaeoceros laevis were significantly affected by incubation in ethoxyzolamide. Values of CO2 compensation point for Phaeoceros laevis rose from 2.5 Pa, after incubation in buffer, to 20 Pa after incubation in ethoxyzolamide. The CO2 compensation point for the liverworts Pellia epiphylla and Marchantia polymorpha was not significantly affected by incubation in ethoxyzolamide. Measurements of the release of CO2 at the end of a short (15 min) period of illumination revealed that, after suppression of carbonic anhydrase activity, the rapid release of a CO2 pool occurred in Phaeoceros laevis but not in the liverworts. There were also significant differences between values for fractionation measured in units per mil (‰), measured instantaneously, for Phaeoceros laevis incubated in ethoxyzolamide, compared with fractionation values for this species after incubation in buffer. Incubation in ethoxyzolamide caused fractionation values to rise from 12.4–22.7‰, indicating that the carbon-concentrating-mechanism of this species had been inactivated. Incubation in ethoxyzolamide had no effect on fractionation values for the liverworts. The convexity of the light saturation curves of liverworts and Phaeoceros laevis was also investigated, but there were no differences between groups before or after the two treatments. The data indicate an important role for carbonic anhydrase in the functioning of the carbon-concentrating-mechanism in the Anthocerotae.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Mitchell, P.L. and Sheehy, J.E. 2000. Redesigning Rice Photosynthesis to Increase Yield, Proceedings of the Workshop on the Quest to Reduce Hunger: Redesigning Rice Photosynthesis. Vol. 7, Issue. , p. 269.

Pursell, Ronald A. Thiers, Barbara M. Allen, Bruce and Buck, William R. 2000. Recent Literature on Bryophytes—103(3). The Bryologist, Vol. 103, Issue. 3, p. 610.

Leegood, Richard C. 2002. C4 photosynthesis: principles of CO2 concentration and prospects for its introduction into C3 plants. Journal of Experimental Botany, Vol. 53, Issue. 369, p. 581.

Raven, John A and Edwards, Dianne 2004. The Evolution of Plant Physiology. p. 17.

FLETCHER, BENJAMIN J. BEERLING, DAVID J. and CHALONER, WILLIAM. G. 2004. Stable carbon isotopes and the metabolism of the terrestrial Devonian organism Spongiophyton. Geobiology, Vol. 2, Issue. 2, p. 107.

Griffiths, Howard Maxwell, Kate Richardson, David and Robe, Wendy 2004. The Evolution of Plant Physiology. p. 3.

Shaw, Jonathan and Renzaglia, Karen 2004. Phylogeny and diversification of bryophytes . American Journal of Botany, Vol. 91, Issue. 10, p. 1557.

Fletcher, Benjamin J. Beerling, David J. Brentnall, Stuart J. and Royer, Dana L. 2005. Fossil bryophytes as recorders of ancient CO2 levels: Experimental evidence and a Cretaceous case study. Global Biogeochemical Cycles, Vol. 19, Issue. 3,

Sas, Klára Nárcisz Kovács, László Zsίros, Ottó Gombos, Zoltán Garab, Győző Hemmingsen, Lars and Danielsen, Eva 2006. Fast cadmium inhibition of photosynthesis in cyanobacteria in vivo and in vitro studies using perturbed angular correlation of γ-rays. JBIC Journal of Biological Inorganic Chemistry, Vol. 11, Issue. 6, p. 725.

NISBET, E. G. GRASSINEAU, N. V. HOWE, C. J. ABELL, P. I. REGELOUS, M. and NISBET, R. E. R. 2007. The age of Rubisco: the evolution of oxygenic photosynthesis. Geobiology, Vol. 5, Issue. 4, p. 311.

Bartlett, Sue G. Mitra, Mautusi and Moroney, James V. 2007. The Structure and Function of Plastids. Vol. 23, Issue. , p. 253.

Meyer, Moritz Seibt, Ulli and Griffiths, Howard 2008. To concentrate or ventilate? Carbon acquisition, isotope discrimination and physiological ecology of early land plant life forms. Philosophical Transactions of the Royal Society B: Biological Sciences, Vol. 363, Issue. 1504, p. 2767.

Liu, Yan Liu, Zaihua Zhang, Jinliu He, Yuanyuan and Sun, Hailong 2010. Experimental study on the utilization of DIC by Oocystis solitaria Wittr and its influence on the precipitation of calcium carbonate in karst and non-karst waters. Carbonates and Evaporites, Vol. 25, Issue. 1, p. 21.

Villarreal, Juan Carlos and Renner, Susanne S. 2012. Hornwort pyrenoids, carbon-concentrating structures, evolved and were lost at least five times during the last 100 million years. Proceedings of the National Academy of Sciences, Vol. 109, Issue. 46, p. 18873.

Sage, R. F. and Weber, A. 2013. Photorespiratory compensation: a driver for biological diversity. Plant Biology, Vol. 15, Issue. 4, p. 624.

Raven, John A. and Edwards, Dianne 2014. Photosynthesis in Bryophytes and Early Land Plants. Vol. 37, Issue. , p. 29.

Hanson, David T. Renzaglia, Karen and Villarreal, Juan Carlos 2014. Photosynthesis in Bryophytes and Early Land Plants. Vol. 37, Issue. , p. 95.

Rae, Benjamin D Long, Benedict M Förster, Britta Nguyen, Nghiem D Velanis, Christos N Atkinson, Nicky Hee, Wei Yih Mukherjee, Bratati Price, G. Dean and McCormick, Alistair J 2017. Progress and challenges of engineering a biophysical CO2-concentrating mechanism into higher plants. Journal of Experimental Botany, Vol. 68, Issue. 14, p. 3717.

Gimeno, Teresa E. Ogée, Jérôme Royles, Jessica Gibon, Yves West, Jason B. Burlett, Régis Jones, Sam P. Sauze, Joana Wohl, Steven Benard, Camille Genty, Bernard and Wingate, Lisa 2017. Bryophyte gas‐exchange dynamics along varying hydration status reveal a significant carbonyl sulphide (COS) sink in the dark and COS source in the light. New Phytologist, Vol. 215, Issue. 3, p. 965.

Wang, Pengyuan Wang, Shaoqiang Chen, Bin Amir, Muhammad Wang, Lei Chen, Jinghua Ma, Li Wang, Xiaobo Liu, Yuanyuan and Zhu, Kai 2022. Light and Water Conditions Co-Regulated Stomata and Leaf Relative Uptake Rate (LRU) during Photosynthesis and COS Assimilation: A Meta-Analysis. Sustainability, Vol. 14, Issue. 5, p. 2840.

Download full list

Article contents

The role of carbonic anhydrase in photosynthesis and the activity of the carbon-concentrating-mechanism in bryophytes of the class Anthocerotae

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The role of carbonic anhydrase in photosynthesis and the activity of the carbon-concentrating-mechanism in bryophytes of the class Anthocerotae

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests