Journal of Experimental Botany

JXB Advance Access originally published online on May 28, 2003

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Journal of Experimental Botany, Vol. 54, No. 388, pp. 1761-1769, July 1, 2003
© 2003 Oxford University Press

¹²CO₂ emission from different metabolic pathways measured in illuminated and darkened C₃ and C₄ leaves at low, atmospheric and elevated CO₂ concentration

Received 14 November 2002; Accepted 7 April 2003

Paola Pinelli and Francesco Loreto^*,

CNR–Istituto di Biologia Agroambientale e Forestale, Via Salaria Km. 29,300, 00016 Monterotondo Scalo (Roma), Italy

* To whom correspondence should be addressed. Fax: +39 06 9064492. E-mail: francesco.loreto{at}ibaf.cnr.it
Abbreviations: *, , compensation points in the absence and in the presence of mitochondrial respiration, respectively; P_n, photosynthesis; R_d, ¹²CO₂ emission by mitochondrial respiration in the light; R_n, ¹²CO₂ emission by mitochondrial respiration in the dark.

The detection of ¹²CO₂ emission from leaves in air containing ¹³CO₂ allows simple and fast determination of the CO₂ emitted by different sources, which are separated on the basis of their labelling velocity. This technique was exploited to investigate the controversial effect of CO₂ concentration on mitochondrial respiration. The ¹²CO₂ emission was measured in illuminated and darkened leaves of one C₄ plant and three C₃ plants maintained at low (30–50 ppm), atmospheric (350–400 ppm) and elevated (700–800 ppm) CO₂ concentration. In C₃ leaves, the ¹²CO₂ emission in the light (R_d) was low at ambient CO₂ and was further quenched in elevated CO₂, when it was often only 20–30% of the ¹²CO₂ emission in the dark, interpreted as the mitochondrial respiration in the dark (R_n). R_n was also reduced in elevated CO₂. At low CO₂, R_d was often 70–80% of R_n, and a burst of ¹²CO₂ was observed on darkening leaves of Mentha sativa and Phragmites australis after exposure for 4 min to ¹³CO₂ in the light. The burst was partially removed at low oxygen and was never observed in C₄ leaves, suggesting that it may be caused by incomplete labelling of the photorespiratory pool at low CO₂. This pool may be low in sclerophyllous leaves, as in Quercus ilex where no burst was observed. R_d was inversely associated with photosynthesis, suggesting that the R_d/R_n ratio reflects the refixation of respiratory CO₂ by photosynthesizing leaves rather than the inhibition of mitochondrial respiration in the light, and that CO₂ produced by mitochondrial respiration in the light is mostly emitted at low CO₂, and mostly refixed at elevated CO₂._. In the leaves of the C₄ species Zea mays, the ¹²CO₂ emission in the light also remained low at low CO₂, suggesting efficient CO₂ refixation associated with sustained photosynthesis in non-photorespiratory conditions. However, R_n was inhibited in CO₂-free air, and the velocity of ¹²CO₂ emission after darkening was inversely associated with the CO₂ concentration. The emission may be modulated by the presence of post-illumination CO₂ uptake deriving from temporary imbalance between C₃ and C₄ metabolism. These experiments suggest that this uptake lasts longer at low CO₂ and that the imbalance is persistent once it has been generated by exposure to low CO₂.

Key words: ¹³C labelling, C₃ versus C₄ metabolism, mitochondrial respiration, photosynthesis, photorespiration.

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