Two human patient mitochondrial pyruvate carrier mutations reveal distinct molecular mechanisms of dysfunction
Lalita Oonthonpan, … , Audrey C. Boutron, Eric B. Taylor
Lalita Oonthonpan, … , Audrey C. Boutron, Eric B. Taylor
Published May 30, 2019
Citation Information: JCI Insight. 2019;4(13):e126132. https://doi.org/10.1172/jci.insight.126132.
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Research Article Cell biology Metabolism

Two human patient mitochondrial pyruvate carrier mutations reveal distinct molecular mechanisms of dysfunction

Abstract

The mitochondrial pyruvate carrier (MPC) occupies a central metabolic node by transporting cytosolic pyruvate into the mitochondrial matrix and linking glycolysis with mitochondrial metabolism. Two reported human MPC1 mutations cause developmental abnormalities, neurological problems, metabolic deficits, and for one patient, early death. We aimed to understand biochemical mechanisms by which the human patient C289T and T236A MPC1 alleles disrupt MPC function. MPC1 C289T encodes 2 protein variants, a misspliced, truncation mutant (A58G) and a full-length point mutant (R97W). MPC1 T236A encodes a full-length point mutant (L79H). Using human patient fibroblasts and complementation of CRISPR-deleted, MPC1-null mouse C2C12 cells, we investigated how MPC1 mutations cause MPC deficiency. Truncated MPC1 A58G protein was intrinsically unstable and failed to form MPC complexes. The MPC1 R97W protein was less stable but, when overexpressed, formed complexes with MPC2 that retained pyruvate transport activity. Conversely, MPC1 L79H protein formed stable complexes with MPC2, but these complexes failed to transport pyruvate. These findings inform MPC structure-function relationships and delineate 3 distinct biochemical pathologies resulting from 2 human patient MPC1 mutations. They also illustrate an efficient gene pass-through system for mechanistically investigating human inborn errors in pyruvate metabolism.

Authors

Lalita Oonthonpan, Adam J. Rauckhorst, Lawrence R. Gray, Audrey C. Boutron, Eric B. Taylor

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Figure 1

Patient fibroblasts contain MPC1 mutations on highly conserved residues and express aberrant MPC1 and MPC2 levels.

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Patient fibroblasts contain MPC1 mutations on highly conserved residues ...
(A) Schematic of MPC1 transcript indicating location of patient mutations. The c.C289T mutation produces 2 mRNAs shown as red arrows: a full-length transcript (R97W), and a truncated transcript (A58GfsX2). The c.T236A mutation coding for L79H is shown as a blue arrow. Sequence alignments show evolutionary conservation across multiple species. Two transmembrane regions were predicted using transmembrane helix prediction (TMHMM). MPC1 point mutations are marked by *, and truncated MPC1 mutant is indicated with #. (B) Representative MPC1, MPC2, and VDAC levels visualized by immunoblot of immortalized patient fibroblasts from Control, c.C289T, or c.T236A mutants (n = 3). (C and D) Quantification of relative MPC1 (C) and MPC2 (D) protein levels relative to VDAC in patient fibroblasts c.C289T and c.T236A as compared with WT (n = 3). (E and F) Relative MPC1 (E) and MPC2 (F) mRNA levels in patient fibroblasts c.C289T and c.T236A as compared with WT (n = 3). Data are presented as mean ± SEM. One-way ANOVA was performed for CF (##P ≤ 0.01, ###P ≤ 0.001, ns = not significant; see also Supplemental Figure 1).