RRM1 variants cause a mitochondrial DNA maintenance disorder via impaired de novo nucleotide synthesis
Jonathan Shintaku, … , Robert W. Taylor, Michio Hirano
Jonathan Shintaku, … , Robert W. Taylor, Michio Hirano
Published May 26, 2022
Citation Information: J Clin Invest. 2022;132(13):e145660. https://doi.org/10.1172/JCI145660.
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Research Article Genetics

RRM1 variants cause a mitochondrial DNA maintenance disorder via impaired de novo nucleotide synthesis

Abstract

Mitochondrial DNA (mtDNA) depletion/deletions syndromes (MDDS) encompass a clinically and etiologically heterogenous group of mitochondrial disorders caused by impaired mtDNA maintenance. Among the most frequent causes of MDDS are defects in nucleoside/nucleotide metabolism, which is critical for synthesis and homeostasis of the deoxynucleoside triphosphate (dNTP) substrates of mtDNA replication. A central enzyme for generating dNTPs is ribonucleotide reductase, a critical mediator of de novo nucleotide synthesis composed of catalytic RRM1 subunits in complex with RRM2 or p53R2. Here, we report 5 probands from 4 families who presented with ptosis and ophthalmoplegia as well as other clinical manifestations and multiple mtDNA deletions in muscle. We identified 3 RRM1 loss-of-function variants, including a dominant catalytic site variant (NP_001024.1: p.N427K) and 2 homozygous recessive variants at p.R381, which has evolutionarily conserved interactions with the specificity site. Atomistic molecular dynamics simulations indicate mechanisms by which RRM1 variants affect protein structure. Cultured primary skin fibroblasts of probands manifested mtDNA depletion under cycling conditions, indicating impaired de novo nucleotide synthesis. Fibroblasts also exhibited aberrant nucleoside diphosphate and dNTP pools and mtDNA ribonucleotide incorporation. Our data reveal that primary RRM1 deficiency and, by extension, impaired de novo nucleotide synthesis are causes of MDDS.

Authors

Jonathan Shintaku, Wolfgang M. Pernice, Wafaa Eyaid, Jeevan B. GC, Zuben P. Brown, Marti Juanola-Falgarona, Javier Torres-Torronteras, Ewen W. Sommerville, Debby M.E.I. Hellebrekers, Emma L. Blakely, Alan Donaldson, Ingrid van de Laar, Cheng-Shiun Leu, Ramon Marti, Joachim Frank, Kurenai Tanji, David A. Koolen, Richard J. Rodenburg, Patrick F. Chinnery, H.J.M. Smeets, Gráinne S. Gorman, Penelope E. Bonnen, Robert W. Taylor, Michio Hirano

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Figure 2

Structural analysis and MD simulations of RRM1 variants.

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Structural analysis and MD simulations of RRM1 variants. (A) Surface ren...
(A) Surface rendering of RRM1 dimer with highlighted catalytic site (blue), specificity site composed of loop 1 (green) and loop 2 (yellow), and loci of RRM1 variants (pink). (B) Hydrogen bonds between p.R381 and the specificity site via p.E355 and p.S260. (C) RRM1 protomers (yellow and green), ligands TTP and GDP, and allosteric communication bridging the mutation, specificity site, and catalytic site. (D) Interprotomer BSA of WT, p.R381C, and p.R381H, with median values of 1830.6 Å2, 1734.8 Å2, and 1764.2 Å2, respectively. (E) Snapshots of the p.R381H MD simulation capture the reorientation of p.R293 and p.Q288. (F) Conformational distance between the p.R293 side chain guanidinium group and GDP. (G) Buried surface area of TTP.