Abstract
Mitochondrial isoleucine-valine biosynthesis in strain 330a, an iv-1 mutant of Neurospora, is blocked at the dihydroxy acid dehydration step owing to a mutation in the nuclear structural gene for the specific enzyme dihydroxy acid dehydratase. Dehydratase purified from either the soluble or the mitochondrial fraction of wild-type Neurospora, and incubated in vitro with 330a mitochondria, restores valine synthesis from pyruvate-C 14 to wild type levels. Up to 29% of the restored synthesis could be attributed to the penetration of enzyme into the mitochondria. However, the bulk of the restored synthesis was found to be mediated via the secretion of dihydroxyvaline (DHV) by the mitochondria into the assay milieu, with subsequent enzymatic catalysis of this metabolite to ketovaline occurring outside the organelle. The ketovaline apparently diffuses back into mitochondria for final transamination to valine. This shunting of valine precursors in and out of mitochondria has been demonstrated to be the mechanism whereby two different populations of mitochondria isolated from mutants 330a and 305A (an iv-2 mutant lacking a functional reductoisomerase) can complement each other for the biosynthesis of valine, even when each population is enclosed in a separate dialysis bag. This observation provides the basis for a biochemical understanding of the growth complementation at the organismic level when these two iv-requiring mutants are cultured together in minimal medium.
Published Version
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