Article: Synthesis of l-(+)-Tartaric Acid from l-Ascorbic Acid via 5-Keto-d-Gluconic Acid in Grapes

5-Keto-l-idionic acid ( identical with5-keto-d-gluconic acid, d-xylo-5-hexulosonic acid) was found as a metabolic product of l-ascorbic acid in slices of immature grapes, Vitis labrusca L. cv ;Delaware'. Specifically labeled compounds, recognized as metabolic products of l-ascorbic acid in grapes, were fed to young grape tissues to investigate the metabolic pathway from l-ascorbic acid to l-(+)-tartaric acid.Label from dehydro-l-[1-(14)C]ascorbic acid, 2-keto-l-[1-(14)C]idonic acid (l-xylo-2-hexulosonic acid), l-[1-(14)C]idonic acid, or 5-keto-l-[1-(14)C] idonic acid was incorporated into l-(+)-tartaric acid in high yields as it was in the l-[1-(14)C]ascorbic acid experiment. In a double label experiment involving a mixture of l-[1-(14)C]idonic acid and l-[2-(3)H]idonic acid, the (3)H/(14)C ratios of 5-keto-l-idonic acid and l-(+)-tartaric acid synthesized in young grape leaves were almost the same as the value of the l-idonic acid fed. Label from 5-keto-l-[6-(14)C]idonic acid was incorporated into sugars and insoluble residue in the same way as l-[6-(14)C]ascorbic acid was metabolized in grapes.These results provide strong evidence that in grapes l-(+)-tartaric acid is synthesized from the C(4) fragment that corresponds to the C1 to C4 group of the 5-keto-l-idonic acid derived from l-ascorbic acid via 2-keto-l-idonic acid and l-idonic acid.

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References

1.

Saito K . Conversion of labeled substrates to sugars, cell wall polysaccharides, and tartaric Acid in grape berries. Plant Physiol. 1978; 62(2):215-9. PMC: 1092092. DOI: 10.1104/pp.62.2.215. View

2.

Loewus F, Stafford H . Observations on the Incorporation of C into Tartaric Acid and the Labeling Pattern of D-Glucose from an Excised Grape Leaf Administered L-Ascorbic Acid-6-C. Plant Physiol. 1958; 33(2):155-6. PMC: 541046. DOI: 10.1104/pp.33.2.155. View

3.

Wagner G, Yang J, Loewus F . Stereoisomeric Characterization of Tartaric Acid Produced during l-Ascorbic Acid Metabolism in Plants. Plant Physiol. 1975; 55(6):1071-3. PMC: 541768. DOI: 10.1104/pp.55.6.1071. View

4.

Williams M, Loewus F . Biosynthesis of (+)-Tartaric Acid from l-[4-C]Ascorbic Acid in Grape and Geranium. Plant Physiol. 1978; 61(4):672-4. PMC: 1091942. DOI: 10.1104/pp.61.4.672. View

5.

Wagner G, Loewus F . l-Ascorbic Acid Metabolism in Vitaceae: Conversion to (+)-Tartaric Acid and Hexoses. Plant Physiol. 1974; 54(5):784-7. PMC: 366603. DOI: 10.1104/pp.54.5.784. View

Synthesis of L-(+)-Tartaric Acid from L-Ascorbic Acid Via 5-Keto-d-Gluconic Acid in Grapes