Abstract
Previously, the role of residues in the ADP/ATP carrier (AAC) from Saccharomyces cerevisiae has been studied by mutagenesis, but the dependence of mitochondrial biogenesis on functional AAC impedes segregation of the mutational effects on transport and biogenesis. Unlike other mitochondrial carriers, expression of the AAC from yeast or mammalians in Escherichia coli encountered difficulties because of disparate codon usage. Here we introduce the AAC from Neurospora crassa in E. coli, where it is accumulated in inclusion bodies and establish the reconstitution conditions. AAC expressed with heat shock vector gave higher activity than with pET-3a. Transport activity was absolutely dependent on cardiolipin. The 10 single mutations of intrahelical positive residues and of the matrix repeat (+X+) motif resulted in lower activity, except of R245A. R143A had decreased sensitivity toward carboxyatractylate. The ATP-linked exchange is generally more affected than ADP exchange. This reflects a charge network that propagates positive charge defects to ATP(4-) more strongly than to ADP(3-) transport. Comparison to the homologous mutants of yeast AAC2 permits attribution of the roles of these residues more to ADP/ATP transport or to AAC import into mitochondria.
Highlights
The role of residues in the ADP/ATP carrier (AAC) from Saccharomyces cerevisiae has been studied by mutagenesis, but the dependence of mitochondrial biogenesis on functional AAC impedes segregation of the mutational effects on transport and biogenesis
AAC2 (S. cerevisiae) Versus AAC (N. crassa) Expression in E. coli—To compare AAC mutations expressed in E. coli with those previously obtained in mitochondria, we first attempted to express the AAC2 from S. cerevisiae in E. coli
The cDNAs for yeast AAC2 and human AAC1 were incorporated into the heat shock vector pJLA503 and into the T7 RNA polymerase pET-3a vector
Summary
The role of residues in the ADP/ATP carrier (AAC) from Saccharomyces cerevisiae has been studied by mutagenesis, but the dependence of mitochondrial biogenesis on functional AAC impedes segregation of the mutational effects on transport and biogenesis. In several mutants that lacked AAC protein, the functional effect could not be accurately determined It could not be clearly deduced whether the mutated residue was involved primarily in the incorporation or in the transport function of AAC. It seemed that functional impairment decreased the level of AAC expression. Single mutational neutralizations of 10 positive charges are introduced in the AAC from N. crassa, and the effects on the transport properties and the interaction with inhibitors were measured
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