Tryptophan substrates, feedback inhibition

Studies with isolated enzymes in vitro reveal feedback inhibition of chorismate mutase by phenylalanine and tyrosine. Tryptophan apparently controls its own synthesis by feedback inhibition of anthranilate synthase and furthermore exerts control in the partitioning of chorismate between the two competing routes of chorismate metabolism by its ability to both activate chorismate mutase and relieve the inhibition imposed on this step by phenylalanine and tyrosine. In addition, carbon flux throuch chorismate to prephenate is also sensitive to fluctuations in chorismate concentration due to the allosteric substrate activation of chorismate mutase by chorismate. 

It is a monomeric protein of M.W. about 70,000, shows Kj, values for L-tryptophan and dimethylallyl pyrophosphate of 0.067 and 0.2 mM, respectively, and seems to have a relatively low turnover number, about 7 sec . During studies on this enzyme it was observed (13) that agroclavlne and elymoclavine, the terminal alkaloids in the strain used for the isolation of the enzyme, inhibited purified DMAT synthetase. At concentrations of 3 mM ( v<750 mg/1) agroclavlne and elymoclavine inhibited the enzyme 90% and 70%, respectively. The inhibition is of a mixed or uncompetitive type as shown by kinetic analysis with either tryptophan or dimethylallyl pyrophosphate as the variable substrate (Fig. 6). Subsequently, feedback Inhibition by elymoclavine was also demonstrated by GrSger s group (3) for chanoclavlne cyclase and by us for anthranllate synthetase from... 

B. Feedback Inhibition Controlling Synthesis of the Substrates for the First Reaction in Tryptophan Synthesis... 

The synthesis of tryptophan in microorganisms is affected at several levels by end-product inhibition. Thus, end-product feedback inhibition partly regulates the synthesis of chorismic acid which is the final product of the common aromatic pathway and serves as a substrate for the first reaction in the tryptophan-synthesizing branch pathway (see Fig. 2). Regulation of the common aromatic pathway was recently reviewed by Doy [72]. The first enzyme of the common aromatic pathway, 3-deoxy-D-flrah/>jo-heptulosonate 7-phosphate synthetase (DAHPS), has been reported to exist as at least three isoenzymes, each specifically susceptible to inhibition by one of the aromatic amino acid end products (tyrosine, phenylalanine, and tryptophan), in E. coli (see reference [3]). It should be noted that many reports have indicated that in E. coli the DAHPS (trp), the isoenzyme whose synthesis is repressed specifically by tryptophan, was not sensitive to end-product inhibition by tryptophan. Recently, however, tryptophan inhibition of DAHPS (trp) activity has been demonstrated in E. coli [3,73,74]. The E. coli pattern, therefore, represents an example of enzyme multiplicity inhibition based on the inhibition specificity of isoenzymes. It is interesting to note the report by Wallace and Pittard [75] that even in the presence of an excess of all three aromatic amino acids enough chorismate is synthesized to provide for the synthesis of the aromatic vitamins whose individual pathways branch from this last common aromatic intermediate. In S. typhimurium, thus far, only two DAHPS isoenzymes, DAHPS (tyr) and DAHPS (phe) have been identified as sensitive to tyrosine and phenylalanine, respectively [76]. 

The feedback inhibition control described above provides one form of regulation of the synthesis of chorismic acid which serves as a substrate in the first reaction specific to the tryptophan branch pathway. In the same reaction glutamine serves as the amino donor [80,81] in the... 

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