Journal
FUNCTIONAL PLANT BIOLOGY
Volume 33, Issue 10, Pages 911-920Publisher
CSIRO PUBLISHING
DOI: 10.1071/FP06098
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Despite the intense effort developed over the past 10 years to determine the (12)C/(13)C isotope fractionation associated with photorespiration, much uncertainty remains about the amplitude, and even the sign, of the (12)C/(13)C isotope fractionation of glycine decarboxylase, the enzyme that produces CO(2) during the photorespiratory cycle. In fact, leaf gas-exchange data have repeatedly indicated that CO(2) evolved by photorespiration is depleted in (13)C compared with the source material, while glycine decarboxylase has mostly favoured (13)C in vitro. Here I give theoretical insights on the glycine decarboxylase reaction and show that (i), both photorespiration and glycine decarboxylation must favour the same carbon isotope - the in vitro measurements being probably adulterated by the high sensitivity of the enzyme to assay conditions and the possible reversibility of the reaction in these conditions, and (ii), simplified quantum chemistry considerations as well as comparisons with other pyridoxal 5 '-phosphate-dependent decarboxylases indicate that the carbon isotope fractionation favour the (12)C isotope by similar to 20%, a value that is consistent with the value of the photorespiratory fractionation (f) obtained by gas-exchange experiments.
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