Fatal neonatal lactic acidosis caused by a novel de novo mitochondrial G7453A tRNA-Serine ((UCN)) mutation.

INTRODUCTION: Heteroplasmic mitochondrial DNA (mtDNA) mutations are an important cause of childhood disorders, but the role of homoplasmic mtDNA mutations in severe neonatal manifestations is not well understood. METHODS: The following were performed: full mtDNA sequencing for mutation detection, blue-native protein analysis of autopsy-derived tissues to detect respiratory chain (RC) deficiency, light and electron microscopy for morphologic analysis, and northern blot and computational modeling to study the effect of mtDNA mutations on transfer RNA (tRNA) stability. RESULTS: We describe data from a patient with fatal neonatal lactic acidosis caused by a novel homoplasmic mutation at a highly conserved nucleotide G7453A within the tRNA(Ser (UCN)) in mtDNA. The patient's heart, skeletal muscle, brain, and liver showed severe combined complex I and IV (CI and CIV) deficiencies, accompanied by severe depletion of mature tRNA(Ser (UCN)). The mutation was absent in the patient's mother and in a placental sample from a subsequent pregnancy of the mother, suggesting a de novo mutation. DISCUSSION: We conclude that the G7453A mutation of mtDNA manifests with exceptional severity as compared with other tRNA(Ser (UCN)) mutations, typically associated with sensorineural deafness. De novo homoplasmic mtDNA tRNA-mutations should be considered as a cause of fatal neonatal lactic acidosis.

Cosegregation of MIDD and MODY in a pedigree: functional and clinical consequences.

The aim of this study was characterization of a family carrying two mutations known to cause monogenic forms of diabetes, the M626K mutation in the HNF1alpha gene (MODY3) and the A3243G in mtDNA. Beta-cell function and insulin sensitivity were assessed with the Botnia clamp. Heteroplasmy of the A3243G mutation and variants in type 2 diabetes susceptibility genes were determined, and transcriptional activity, DNA binding, and subcellular localization of mutated HNF1alpha were studied. Thirteen family members carried the mutation in mtDNA; 6 of them also had the M626K mutation, whereas none had only the M626K mutation. The protective Ala12 allele in peroxisome proliferator-activated receptor (PPAR)gamma was present in two nondiabetic individuals. Carriers of both mtDNA and HNF1alpha mutations showed an earlier age at onset of diabetes than carriers of only the mtDNA mutation (median 22 vs. 45 years) but no clear difference in beta-cell function or insulin sensitivity. In vitro, the M626K mutation caused a 53% decrease in transcriptional activity in HeLa cells. The mutated protein showed normal nuclear targeting but increased DNA binding. These data demonstrate that several genetic factors might contribute to diabetes risk, even in families with mtDNA and HNF1alpha mutations.