salicylates and alpha-aminobutyric-acid

The tryptophan (Trp) biosynthetic pathway leads to the production of many secondary metabolites with diverse functions, and its regulation is predicted to respond to the needs for both protein synthesis and secondary metabolism. We have tested the response of the Trp pathway enzymes and three other amino acid biosynthetic enzymes to starvation for aromatic amino acids, branched-chain amino acids, or methionine. The Trp pathway enzymes and cytosolic glutamine synthetase were induced under all of the amino acid starvation test conditions, whereas methionine synthase and acetolactate synthase were not. The mRNAs for two stress-inducible enzymes unrelated to amino acid biosynthesis and accumulation of the indolic phytoalexin camalexin were also induced by amino acid starvation. These results suggest that regulation of the Trp pathway enzymes under amino acid deprivation conditions is largely a stress response to allow for increased biosynthesis of secondary metabolites. Consistent with this hypothesis, treatments with the oxidative stress-inducing herbicide acifluorfen and the abiotic elicitor alpha-amino butyric acid induced responses similar to those induced by the amino acid starvation treatments. The role of salicylic acid in herbicide-mediated Trp and camalexin induction was investigated.

Topics: 5-Methyltetrahydrofolate-Homocysteine S-Methyltransferase; Acetolactate Synthase; Amino Acids; Aminobutyrates; Arabidopsis; Glutamate-Ammonia Ligase; Heat-Shock Response; Herbicides; Indoles; Nitrobenzoates; Oxidative Stress; RNA, Messenger; Salicylates; Salicylic Acid; Thiazoles; Tryptophan

Salmonella typhimurium strain DU501, which was found to be deficient in acetohydroxy acid synthase II (AHAS II) and to possess elevated levels of transaminase B and biosynthetic threonine deaminase, required isoleucine, methionine, or pantothenate for growth. This strain accumulated alpha-ketobutyrate and, to a lesser extent, alpha-aminobutyrate. We found that alpha-ketobutyrate was a competitive substrate for ketopantoate hydroxymethyltransferase, the first enzyme in pantothenate biosynthesis. This competition with the normal substrate, alpha-ketoisovalerate, limited the supply of pantothenate, which resulted in a requirement for methionine. Evidence is presented to support the conclusion that the ambivalent requirement for either pantothenate or methionine is related to a decrease in succinyl coenzyme A, which is produced from pantothenate and which is an obligatory precursor of methionine biosynthesis. The autointoxification by endogenously produced alpha-ketobutyrate could be mimicked in wild-type S. typhimurium by exogenously supplied alpha-ketobutyrate or salicylate, a known inhibitor of pantothenate biosynthesis. The accumulation of alpha-ketobutyrate was initiated by the inability of the residual AHAS activity provided by AHAS I to efficiently remove the alpha-ketobutyrate produced by biosynthetic threonine deaminase. The accumulation of alpha-ketobutyrate was amplified by the action of transaminase B, which decreased the isoleucine pool by catalyzing the formation of alpha-keto-beta-methylvalerate and aminobutyrate from isoleucine and alpha-ketobutyrate; this resulted in release of threonine deaminase from end product inhibition and unbridled production of alpha-ketobutyrate. Isoleucine satisfied the auxotrophic requirement of the AHAS II-deficient strain by curtailing the activity of threonine deaminase. Additional lines of evidence based on genetic and physiological experiments are presented to support the basis for the autointoxification of strain DU501 as well as other nonpolarigenic ilvG mutant strains.

Topics: Acetolactate Synthase; Aminobutyrates; Butyrates; Isoleucine; Methionine; Mutation; Pantothenic Acid; Salicylates; Salmonella typhimurium; Threonine Dehydratase; Transaminases