Chorismate ion

Claisen rearrangement plays an important part in the biosynthesis of several natural products. For example, the chorismate ion is rearranged to the prephenate ion by the Claisen rearrangement, which is catalysed by the enzyme chorismate mutase. This prephenate ion is a key intermediate in the shikimic acid pathway for the biosynthesis of phenylalanine, tyrosine and many other biologically important natural products. 

Chemical properties appropriate to a compound found at a branch point of metabolism are displayed by chorismic acid. Simply warming the compound in acidic aqueous solution yields a mixture of prephen-ate and para-hydroxybenzoate (corresponding to reactions h and l of Fig. 25-1). Note that the latter reaction is a simple elimination of the enolate anion of pyruvate. As indicated in Fig. 25-1, these reactions correspond to only two of several metabolic reactions of the chorismate ion. In E. coli the formation of phe-nylpyruvate (steps h and i, Fig. 25-1) is catalyzed by a single protein molecule with two distinctly different enzymatic activities chorismate mutase and prephenate dehydratase.34-36 However, in some organisms the enzymes are separate.37 Both of the reactions catalyzed by these enzymes also occur spontaneously upon warming chorismic acid in acidic solution. The chorismate mutase reaction, which is unique in its mechanism,373 is discussed in Box 9-E. Stereochemical studies indicate that the formation of phenylpyruvate in Fig. 25-1, step z, occurs via a... 

Schultz and coworkers (Jackson et a ., 1988) have generated an antibody which exhibits behaviour similar to the enzyme chorismate mutase. The enzyme catalyses the conversion of chorismate [49] to prephenate [50] as part of the shikimate pathway for the biosynthesis of aromatic amino acids in plants and micro-organisms (Haslam, 1974 Dixon and Webb, 1979). It is unusual for an enzyme in that it does not seem to employ acid-base chemistry, nucleophilic or electrophilic catalysis, metal ions, or redox chemistry. Rather, it binds the substrate and forces it into the appropriate conformation for reaction and stabilizes the transition state, without using distinct catalytic groups. 

The shikimic acid pathway leading to the production of chorismic acid is regulated in the cytosol of the fungal cells. Cytosol or intracellular fluid (cytoplasmic matrix) is a complex mixture of substances dissolved in water. These include ions (such as calcium, sodium, and potassium), macromolecules, and large complexes of enzymes that act together to carry out metabolic pathways. Production of chorismic acid in the cytosol is ultimately utilized in the synthesis of folate, ubiquinone, and amino acids, the most important of which is tryptophan which plays a major role in the biosynthesis of psilocybin. 

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