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. 1974 Aug;54(2):271–277. doi: 10.1172/JCI107762

Utilization of α-Keto and α-Hydroxy Analogues of Valine by the Growing Rat

Rajender K Chawla 1,2,3, Daniel Rudman 1,2,3
PMCID: PMC301554  PMID: 4367888

Abstract

When 70-80-g male albino rats eat a diet furnishing daily requirement of valine for optimal growth (70 μmol/g) and all other nutrients (“complete diet”), they gain weight at an average rate of 3.0 g/100 g body wt/day. When valine is removed, they lose weight at an average 2.1 g/100 g body wt/day. The growth retardation is improved or corrected by adding valine to the diet, daily weight gain being proportional to dietary valine content over a range of 0-70 μmol/g.

Addition of α-ketoisovaleric acid instead of valine to the valine-free diet also improves or corrects the growth failure. Percent efficiency of α-ketoisovaleric acid as a substitute for valine was calculated as: 100 × (micromole valine per gram diet required to produce specified growth response)/(micromole α-ketoisovaleric acid per gram diet required to produce the same response). Efficiency of the substitution is inversely related to dietary content of the keto analogue, being 80% when diet contains 17.5 μmol/g (molar equivalent of ¼ the daily requirement of valine), and 37% when diet provides 140 μmol/g (molar equivalent of twice the daily requirement of valine).

α-Hydroxyisovaleric acid also substitutes for valine. Efficiency of the substitution at the single ration tested, 70 μmol/g diet, is 45%, similar to that for the keto analogue under the same conditions.

When [1-14C]α-ketoisovaleric acid is injected intravenously, 30-80% of the administered radioactivity is exhaled as 14CO2 within 24 h. This finding suggests that inefficiency of α-ketoisovaleric acid as a substitute for valine results in part from degradation of the keto acid to isobutyric acid by branched chain dehydrogenase-decarboxylase.

Oral administration of neomycin, polymyxin, and bacitracin reduces efficiency of α-ketoisovaleric acid as a substitute for valine by ¼-½. This effect suggests that transamination of the keto acid may be performed in part by gastrointestinal microbes.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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