Arabidopsis Mutants Define an in Vivo Role for Isoenzymes of Aspartate Aminotransferase in Plant Nitrogen Assimilation

Arabidopsis Mutants Define an in Vivo Role for Isoenzymes of Aspartate Aminotransferase in Plant Nitrogen Assimilation

Carolyn J. Schultz^a, Meier Hsu^a, Barbara Miesak^a, and Gloria M. Coruzzi^a
^a Biology Department, New York University, New York, New York, 10003

Corresponding author: Gloria M. Coruzzi, New York University, Biology Department, 100 Washington Square East, 1009 Main Bldg., New York, NY 10003, coruzg01{at}mcrcr6.med.nyu.edu (E-mail).

Communicating editor: E. MEYEROWITZ

Arabidopsis contains five isoenzymes of aspartate aminotransferase(AspAT) localized to the cytosol, chloroplast, mitochondria,or peroxisomes. To define the in vivo function of individualisoenzymes, we screened for Arabidopsis mutants deficient ineither of the two major isoenzymes, cytosolic AAT2 or chloroplasticAAT3, using a native gel activity assay. In a screen of 8,000M₂ seedlings, three independent mutants deficient in cytosolicAAT2 (aat2) and two independent mutants deficient in chloroplasticAAT3 (aat3) were isolated. Mapping of aat2 and aat3 mutationsand the five AspAT genes (ASP1–ASP5) established associationsas follows: the mutation affecting aat2 maps with and cosegregateswith ASP2, one of two expressed genes for cytosolic AspAT; themutation affecting aat3 maps to the same location as the ASP5gene encoding chloroplastic AspAT. Phenotypic analysis of theaat2 and aat3 mutants revealed a dramatic aspartate-relatedphenotype in one of the mutants deficient in cytosolic AAT2.The aat2-2 mutant displays an 80% reduction in levels of aspartatetransported in the phloem of light-grown plants, and a 50% reductionin levels of asparagine transported in dark-adapted plants.These results indicate that cytosolic AAT2 is the major isoenzymecontrolling aspartate synthesized for nitrogen transport inthe light, and that this aspartate pool is converted to asparaginewhen plants are dark adapted.

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