Stefanie Bulst scite author profile

Sodium valproate (VPA) is widely used throughout the world to treat epilepsy, migraine, chronic headache, bipolar disorder, and as adjuvant chemotherapy. VPA toxicity is an uncommon but potentially fatal cause of idiosyncratic liver injury. Rare mutations in POLG, which codes for the mitochondrial DNA polymerase γ (polγ), cause the Alpers-Huttenlocher syndrome (AHS). AHS is a neurometabolic disorder associated with an increased risk of developing fatal VPA-hepatotoxicity. We therefore set out to determine whether common genetic variants in POLG explain why some otherwise healthy individuals develop VPA-hepatotoxicity. We carried out a prospective study of subjects enrolled in the Drug Induced Liver Injury Network (DILIN) from 2004 to 2008 through five US centres. POLG was sequenced and the functional consequences of VPA and novel POLG variants were evaluated in primary human cell lines and the yeast model system Saccharomyces cerevisiae. Heterozygous genetic variation in POLG was strongly associated with VPA-induced liver toxicity (odds ratio = 23.6, 95% CI = 8.4 – 65.8, P = 5.1 × 10−7). This was principally due to the p.Q1236H substitution which compromised polγ function in yeast. Therapeutic doses of VPA inhibited human cellular proliferation, and high doses caused non-apoptotic cell death which was not mediated through mitochondrial DNA depletion, mutation, or a defect of fatty acid metabolism. These findings implicate impaired liver regeneration in VPA toxicity, and show that prospective genetic testing of POLG will identify individuals at high risk of this potentially fatal consequence of treatment.

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Scapuloperoneal syndrome type Kaeser and a wide phenotypic spectrum of adult-onset, dominant myopathies are associated with the desmin mutation R350P

Walter

Reilich

Huebner

et al. 2007

Brain

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In 1965, an adult-onset, autosomal dominant disorder with a peculiar scapuloperoneal distribution of weakness and atrophy was described in a large, multi-generation kindred and named 'scapuloperoneal syndrome type Kaeser' (OMIM #181400). By genetic analysis of the original kindred, we discovered a heterozygous missense mutation of the desmin gene (R350P) cosegregating with the disorder. Moreover, we detected DES R350P in four unrelated German families allowing for genotype-phenotype correlations in a total of 15 patients carrying the same mutation. Large clinical variability was recognized, even within the same family, ranging from scapuloperoneal (n = 2, 12%), limb girdle (n = 10, 60%) and distal phenotypes (n = 3, 18%) with variable cardiac (n = 7, 41%) or respiratory involvement (n = 7, 41%). Facial weakness, dysphagia and gynaecomastia were frequent additional symptoms. Overall and within each family, affected men seemingly bear a higher risk of sudden, cardiac death as compared to affected women. Moreover, histological and immunohistochemical examination of muscle biopsy specimens revealed a wide spectrum of findings ranging from near normal or unspecific pathology to typical, myofibrillar changes with accumulation of desmin. This study reveals that the clinical and pathological variability generally observed in desminopathies may not be attributed to the nature of the DES mutation alone, but may be influenced by additional genetic and epigenetic factors such as gender. In addition, mutations of the desmin gene should be considered early in the diagnostic work-up of any adult-onset, dominant myopathy, even if specific myofibrillar pathology is absent.

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In vitro supplementation with dAMP/dGMP leads to partial restoration of mtDNA levels in mitochondrial depletion syndromes

Bulst

Schöser

Holinski‐Feder

et al. 2009

Human Molecular Genetics

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Mitochondrial DNA depletion syndrome, a frequent cause of childhood (hepato)encephalomyopathies, is defined as a reduction of mitochondrial DNA copy number related to nuclear DNA. It was previously shown that mtDNA depletion can be prevented by dAMP/dGMP supplementation in deoxyguanosine kinase-deficient fibroblasts. We investigated myotubes of patients diagnosed with mtDNA depletion carrying pathogenic mutations in DGUOK, POLG1 (Alpers syndrome) and TYMP. Differentiating myotubes of all patients and controls were supplemented with different doses of dAMP/dGMP or dAMP/dGMP/dCMP in TYMP deficiency, and analysed for mtDNA/nDNA ratio and for cytochrome c oxidase (COX) activity. Serum deprivation and myotube formation triggered a decrease in mtDNA copy number in DGUOK or POLG1 deficient myotubes, but not in TYMP deficiency and healthy controls. Supplementation with dAMP/dGMP leads to a significant and reproducible rescue of mtDNA depletion in DGUOK deficiency. POLG1 deficient myotubes also showed a mild, not significant increase in mtDNA copy number. MtDNA depletion did not result in deficient COX staining in DGUOK and POLG1-deficient myotubes. Treatment with ethidium bromide resulted in very severe depletion and absence of COX staining in all cell types, and no recovery was observed after supplementation with dAMP/dGMP. We show that supplementation with dAMP/dGMP increases mtDNA copy number significantly in DGUOK deficient myotubes and, leads to a mild, non-significant improvement of mtDNA depletion in POLG1 deficiency. No adverse effect on mtDNA copy number was observed on high-dose supplementation in vitro. Further studies are needed to determine possible therapeutic implications of dAMP/dGMP supplementation for DGUOK deficiency in vivo.

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Late-onset ptosis and myopathy in a patient with a heterozygous insertion in POLG2

et al. 2010

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Polymerase gamma 1 (POLG) mutations are a frequent cause of both autosomal dominant and recessive complex neurological phenotypes. In contrast, only a single pathogenic mutation in one patient was reported in POLG2 so far. Here we describe a 62-year-old woman, carrying a novel heterozygous sequence variant in the POLG2 gene. She developed bilateral ptosis at 30 years of age, followed by exercise intolerance, muscle weakness and mild CK increase in her late forties. Muscle histology and respiratory chain activities were normal. Southern blot and long range PCR detected multiple mtDNA deletions, but no depletion in muscle DNA. Sequencing of POLG, PEO1, ANT1, OPA1 and RRM2B showed normal results. A novel heteroallelic 24 bp insertion (c.1207_1208ins24) was detected in POLG2. This 24 bp insertion into exon 7 causes missplicing and loss of exon 7 in myoblast cDNA. We did not detect POLG2 mutations in 62 patients with multiple mtDNA deletions in muscle DNA, suggesting that POLG2 mutations may represent a rare cause of autosomal dominant PEO.

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In vitro supplementation with deoxynucleoside monophosphates rescues mitochondrial DNA depletion

Bulst

Holinski‐Feder

Payne

et al. 2012

Molecular Genetics and Metabolism

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Mitochondrial DNA depletion syndromes are a genetically heterogeneous group of often severe diseases, characterized by reduced cellular mitochondrial DNA content. Investigation of potential therapeutic strategies for mitochondrial DNA depletion syndromes will be dependent on good model systems. We have previously suggested that myotubes may be the optimal model system for such studies. Here we firstly validate this technique in a diverse range of cells of patients with mitochondrial DNA depletion syndromes, showing contrasting effects in cell lines from genetically and phenotypically differing patients.Secondly, we developed a putative therapeutic approach using variable combinations of deoxynucleoside monophosphates in different types of mitochondrial DNA depletion syndromes, showing near normalization of mitochondrial DNA content in many cases. Furthermore, we used nucleoside reverse transcriptase inhibitors to precisely titrate mtDNA depletion in vitro. In this manner we can unmask a physiological defect in mitochondrial depletion syndrome cell lines which is also ameliorated by deoxynucleoside monophosphate supplementation. Finally, we have extended this model to study fibroblasts after myogenic transdifferentiation by MyoD transfection, which similar to primary myotubes also showed deoxynucleoside monophosphate responsive mitochondrial DNA depletion in vitro, thus providing a more convenient method for deriving future models of mitochondrial DNA depletion.Our results suggest that using different combinations of deoxynucleoside monophosphates depending on the primary gene defect and molecular mechanism may be a possible therapeutic approach for many patients with mitochondrial DNA depletion syndromes and is worthy of further clinical investigation.

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Stefanie Bulst

Polymerase γ Gene POLG Determines the Risk of Sodium Valproate-Induced Liver Toxicity

Scapuloperoneal syndrome type Kaeser and a wide phenotypic spectrum of adult-onset, dominant myopathies are associated with the desmin mutation R350P

In vitro supplementation with dAMP/dGMP leads to partial restoration of mtDNA levels in mitochondrial depletion syndromes

Late-onset ptosis and myopathy in a patient with a heterozygous insertion in POLG2

In vitro supplementation with deoxynucleoside monophosphates rescues mitochondrial DNA depletion

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