Influence of ring- and side-chain substituents on the transamination of aromatic amino acids by two multispecific aspartate-aromatic aminotransferase isozymes purified from bushbean shoots

Abstract

The breadth of substrate specificity shown by the multispecific aspartate-aromatic aminotransferase of bushbean ( Phaseolus vulgaris) has been investigated by testing the ability of two cytosolic isozymes (I and II), purified from shoot tissue, to catalyse transamination reactions between a range of ring- and sidechain-substituted aromatic amino acids and 2-oxoglutarate. Ring-substituted phenylalanines were the most reactive substrates whereas ring-substitution in tyrosine or tryptophan resulted in transamination rates lower than those observed with the parent amino acids. All side chain-substituted analogues were found to be totally inactive. The highest activity shown by any ring-substituted phenylalanine was observed with the 4-amino- compound, followed closely by the 4-hydroxy- and 4-halogen-compounds. In contrast, 4-nitrophenylalanine was completely inactive. These trends were consistent for both isozymes I and II, but only isozyme II showed greatly enhanced activity over that found with the parent amino acid when certain ring-substituted analogues were tested. The varying capacity of the bushbean isozymes to utilize the present range of substituted amino acids is compared with previous reports on the substrate specificity shown by aspartate and aromatic aminotransferases isolated from mammalian and microbial systems. A model for the mechanism of activation observed with bushbean isozyme II in the presence of certain 4-substituted aromatic amino acids is proposed, based on current understanding of the nature of the active site of animal aspartate aminotransferases.