AUTHOR=Ludwig Martha 

TITLE=The Roles of Organic Acids in C4 Photosynthesis

JOURNAL=Frontiers in Plant Science

VOLUME=7

YEAR=2016

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2016.00647

DOI=10.3389/fpls.2016.00647

ISSN=1664-462X

ABSTRACT=<p>Organic acids are involved in numerous metabolic pathways in all plants. The finding that some plants, known as C<sub>4</sub> plants, have four-carbon dicarboxylic acids as the first product of carbon fixation showed these organic acids play essential roles as photosynthetic intermediates. Oxaloacetate (OAA), malate, and aspartate (Asp) are substrates for the C<sub>4</sub> acid cycle that underpins the CO<sub>2</sub> concentrating mechanism of C<sub>4</sub> photosynthesis. In this cycle, OAA is the immediate, short-lived, product of the initial CO<sub>2</sub> fixation step in C<sub>4</sub> leaf mesophyll cells. The malate and Asp, resulting from the rapid conversion of OAA, are the organic acids delivered to the sites of carbon reduction in the bundle-sheath cells of the leaf, where they are decarboxylated, with the released CO<sub>2</sub> used to make carbohydrates. The three-carbon organic acids resulting from the decarboxylation reactions are returned to the mesophyll cells where they are used to regenerate the CO<sub>2</sub> acceptor pool. NADP-malic enzyme-type, NAD-malic enzyme-type, and phospho<italic>enol</italic>pyruvate carboxykinase-type C<sub>4</sub> plants were identified, based on the most abundant decarboxylating enzyme in the leaf tissue. The genes encoding these C<sub>4</sub> pathway-associated decarboxylases were co-opted from ancestral C<sub>3</sub> plant genes during the evolution of C<sub>4</sub> photosynthesis. Malate was recognized as the major organic acid transferred in NADP-malic enzyme-type C<sub>4</sub> species, while Asp fills this role in NAD-malic enzyme-type and phospho<italic>enol</italic>pyruvate carboxykinase-type plants. However, accumulating evidence indicates that many C<sub>4</sub> plants use a combination of organic acids and decarboxylases during CO<sub>2</sub> fixation, and the C<sub>4</sub>-type categories are not rigid. The ability to transfer multiple organic acid species and utilize different decarboxylases has been suggested to give C<sub>4</sub> plants advantages in changing and stressful environments, as well as during development, by facilitating the balance of energy between the two cell types involved in the C<sub>4</sub> pathway of CO<sub>2</sub> assimilation. The results of recent empirical and modeling studies support this suggestion and indicate that a combination of transferred organic acids and decarboxylases is beneficial to C<sub>4</sub> plants in different light environments.</p>