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1.
Ann Neurol ; 2024 Sep 04.
Article in English | MEDLINE | ID: mdl-39230499

ABSTRACT

OBJECTIVE: Mitochondrial DNA (mtDNA) depletion/deletions syndrome (MDDS) comprises a group of diseases caused by primary autosomal defects of mtDNA maintenance. Our objective was to study the etiology of MDDS in 4 patients who lack pathogenic variants in known genetic causes. METHODS: Whole exome sequencing of the probands was performed to identify pathogenic variants. We validated the mitochondrial defect by analyzing mtDNA, mitochondrial dNTP pools, respiratory chain activities, and GUK1 activity. To confirm pathogenicity of GUK1 deficiency, we expressed 2 GUK1 isoforms in patient cells. RESULTS: We identified biallelic GUK1 pathogenic variants in all 4 probands who presented with ptosis, ophthalmoparesis, and myopathic proximal limb weakness, as well as variable hepatopathy and altered T-lymphocyte profiles. Muscle biopsies from all probands showed mtDNA depletion, deletions, or both, as well as reduced activities of mitochondrial respiratory chain enzymes. GUK1 encodes guanylate kinase, originally identified as a cytosolic enzyme. Long and short isoforms of GUK1 exist. We observed that the long isoform is intramitochondrial and the short is cytosolic. In probands' fibroblasts, we noted decreased GUK1 activity causing unbalanced mitochondrial dNTP pools and mtDNA depletion in both replicating and quiescent fibroblasts indicating that GUK1 deficiency impairs de novo and salvage nucleotide pathways. Proband fibroblasts treated with deoxyguanosine and/or forodesine, a purine phosphatase inhibitor, ameliorated mtDNA depletion, indicating potential pharmacological therapies. INTERPRETATION: Primary GUK1 deficiency is a new and potentially treatable cause of MDDS. The cytosolic isoform of GUK1 may contribute to the T-lymphocyte abnormality, which has not been observed in other MDDS disorders. ANN NEUROL 2024.

2.
Neurol Genet ; 9(2): e200058, 2023 Apr.
Article in English | MEDLINE | ID: mdl-37090936

ABSTRACT

Background and Objectives: Coenzyme Q10 (CoQ10)-deficient cerebellar ataxia can be due to pathogenic variants in genes encoding for CoQ10 biosynthetic proteins or associated with defects in protein unrelated to its biosynthesis. Diagnosis is crucial because patients may respond favorably to CoQ10 supplementation. The aim of this study was to identify through whole-exome sequencing (WES) the pathogenic variants, and assess CoQ10 levels, in fibroblasts from patients with undiagnosed cerebellar ataxia referred to investigate CoQ10 deficiency. Methods: WES was performed on genomic DNA extracted from 16 patients. Sequencing data were filtered using a virtual panel of genes associated with CoQ10 deficiency and/or cerebellar ataxia. CoQ10 levels were measured by high-performance liquid chromatography in 14 patient-derived fibroblasts. Results: A definite genetic etiology was identified in 8 samples of 16 (diagnostic yield = 50%). The identified genetic causes were pathogenic variants of the genes COQ8A (ADCK3) (n = 3 samples), ATP1A3 (n = 2), PLA2G6 (n = 1), SPG7 (n = 1), and MFSD8 (n = 1). Five novel mutations were found (COQ8A n = 3, PLA2G6 n = 1, and MFSD8 n = 1). CoQ10 levels were significantly decreased in 3/14 fibroblast samples (21.4%), 1 carrying compound heterozygous COQ8A pathogenic variants, 1 harboring a homozygous pathogenic SPG7 variant, and 1 with an unknown molecular defect. Discussion: This work confirms the importance of COQ8A gene mutations as a frequent genetic cause of cerebellar ataxia and CoQ10 deficiency and suggests SPG7 mutations as a novel cause of secondary CoQ10 deficiency.

3.
Antioxidants (Basel) ; 11(4)2022 Mar 30.
Article in English | MEDLINE | ID: mdl-35453349

ABSTRACT

Coenzyme Q (CoQ) is a conserved polyprenylated lipid composed of a redox-active benzoquinone ring and a long polyisoprenyl tail that serves as a membrane anchor. CoQ biosynthesis involves multiple steps, including multiple modifications of the precursor ring 4-hydroxybenzoic acid. Mutations in the enzymes involved in CoQ biosynthesis pathway result in primary coenzyme Q deficiencies, mitochondrial disorders whose clinical heterogenicity reflects the multiple biological function of CoQ. Patients with these disorders do not always respond to CoQ supplementation, and CoQ analogs have not been successful as alternative approaches. Progress made in understanding the CoQ biosynthesis pathway and studies of supplementation with 4-hydroxybenzoic acid ring analogs have opened a new area in the field of primary CoQ deficiencies treatment. Here, we will review these studies, focusing on efficacy of the different 4-hydroxybenzoic acid ring analogs, models in which they have been tested, and their mechanisms of action. Understanding how these compounds ameliorate biochemical, molecular, and/or clinical phenotypes of CoQ deficiencies is important to develop the most rational treatment for CoQ deficient patients, depending on their molecular defects.

4.
Cell Rep ; 38(10): 110475, 2022 03 08.
Article in English | MEDLINE | ID: mdl-35263592

ABSTRACT

Mitochondrial cardiomyopathies are fatal diseases, with no effective treatment. Alterations of heart mitochondrial function activate the mitochondrial integrated stress response (ISRmt), a transcriptional program affecting cell metabolism, mitochondrial biogenesis, and proteostasis. In humans, mutations in CHCHD10, a mitochondrial protein with unknown function, were recently associated with dominant multi-system mitochondrial diseases, whose pathogenic mechanisms remain to be elucidated. Here, in CHCHD10 knockin mutant mice, we identify an extensive cardiac metabolic rewiring triggered by proteotoxic ISRmt. The stress response arises early on, before the onset of bioenergetic impairments, triggering a switch from oxidative to glycolytic metabolism, enhancement of transsulfuration and one carbon (1C) metabolism, and widespread metabolic imbalance. In parallel, increased NADPH oxidases elicit antioxidant responses, leading to heme depletion. As the disease progresses, the adaptive metabolic stress response fails, resulting in fatal cardiomyopathy. Our findings suggest that early interventions to counteract metabolic imbalance could ameliorate mitochondrial cardiomyopathy associated with proteotoxic ISRmt.


Subject(s)
Cardiomyopathies , Mitochondrial Diseases , Animals , Cardiomyopathies/pathology , Disease Models, Animal , Mice , Mitochondria/metabolism , Mitochondrial Diseases/metabolism , Mitochondrial Proteins/genetics , Mitochondrial Proteins/metabolism
5.
Aging (Albany NY) ; 11(19): 8433-8462, 2019 09 27.
Article in English | MEDLINE | ID: mdl-31560653

ABSTRACT

Many patients suffering late-onset Alzheimer disease show a deficit in respiratory complex IV activity. The de novo pyrimidine biosynthesis pathway connects with the mitochondrial respiratory chain upstream from respiratory complex IV. We hypothesized that these patients would have decreased pyrimidine nucleotide levels. Then, different cell processes for which these compounds are essential, such as neuronal membrane generation and maintenance and synapses production, would be compromised. Using a cell model, we show that inhibiting oxidative phosphorylation function reduces neuronal differentiation. Linking these processes to pyrimidine nucleotides, uridine treatment recovers neuronal differentiation. To unmask the importance of these pathways in Alzheimer disease, we firstly confirm the existence of the de novo pyrimidine biosynthesis pathway in adult human brain. Then, we report altered mRNA levels for genes from both de novo pyrimidine biosynthesis and pyrimidine salvage pathways in brain from patients with Alzheimer disease. Thus, uridine supplementation might be used as a therapy for those Alzheimer disease patients with low respiratory complex IV activity.


Subject(s)
Alzheimer Disease , Electron Transport Complex IV/physiology , Neurons/physiology , Oxidative Phosphorylation/drug effects , Pyrimidines/biosynthesis , Uridine , Alzheimer Disease/drug therapy , Alzheimer Disease/metabolism , Brain/metabolism , Cell Differentiation/drug effects , Drug Design , Humans , Mitochondria/metabolism , Neuroprotective Agents/pharmacology , Signal Transduction/drug effects , Uridine/metabolism , Uridine/pharmacology
6.
Cells ; 8(11)2019 11 08.
Article in English | MEDLINE | ID: mdl-31717322

ABSTRACT

Neuronal differentiation appears to be dependent on oxidative phosphorylation capacity. Several drugs inhibit oxidative phosphorylation and might be detrimental for neuronal differentiation. Some pregnant women take these medications during their first weeks of gestation when fetal nervous system is being developed. These treatments might have later negative consequences on the offspring's health. To analyze a potential negative effect of three widely used medications, we studied in vitro dopaminergic neuronal differentiation of cells exposed to pharmacologic concentrations of azidothymidine for acquired immune deficiency syndrome; linezolid for multidrug-resistant tuberculosis; and atovaquone for malaria. We also analyzed the dopaminergic neuronal differentiation in brains of fetuses from pregnant mice exposed to linezolid. The drugs reduced the in vitro oxidative phosphorylation capacity and dopaminergic neuronal differentiation. This differentiation process does not appear to be affected in the prenatally exposed fetus brain. Nevertheless, the global DNA methylation in fetal brain was significantly altered, perhaps linking an early exposure to a negative effect in older life. Uridine was able to prevent the negative effects on in vitro dopaminergic neuronal differentiation and on in vivo global DNA methylation. Uridine could be used as a protective agent against oxidative phosphorylation-inhibiting pharmaceuticals provided during pregnancy when dopaminergic neuronal differentiation is taking place.


Subject(s)
Dopaminergic Neurons/cytology , Dopaminergic Neurons/drug effects , Dopaminergic Neurons/metabolism , Neuroprotective Agents/pharmacology , Oxidative Phosphorylation/drug effects , Uridine/pharmacology , Xenobiotics/pharmacology , Animals , Biomarkers , Cell Differentiation/drug effects , Cell Differentiation/genetics , Cell Line , Cells, Cultured , DNA Methylation , Glucose/pharmacology , Humans , Immunohistochemistry , Mice , Mitochondria/genetics , Mitochondria/immunology
7.
Ageing Res Rev ; 45: 24-32, 2018 Aug.
Article in English | MEDLINE | ID: mdl-29689408

ABSTRACT

Late-onset Parkinson disease is a multifactorial and multietiological disorder, age being one of the factors implicated. Genetic and/or environmental factors, such as pesticides, can also be involved. Up to 80% of dopaminergic neurons of the substantia nigra are lost before motor features of the disorder begin to appear. In humans, these neurons are only formed a few weeks after fertilization. Therefore, prenatal exposure to pesticides or industrial chemicals during crucial steps of brain development might also alter their proliferation and differentiation. Oxidative phosphorylation is one of the metabolic pathways sensitive to environmental toxicants and it is crucial for neuronal differentiation. Many inhibitors of this biochemical pathway, frequently found as persistent organic pollutants, affect dopaminergic neurogenesis, promote the degeneration of these neurons and increase the risk of suffering late-onset Parkinson disease. Here, we discuss how an early, prenatal, exposure to these oxidative phosphorylation xenobiotics might trigger a late-onset, old age, Parkinson disease.


Subject(s)
Oxidative Phosphorylation/drug effects , Parkinson Disease, Secondary/metabolism , Prenatal Exposure Delayed Effects/chemically induced , Prenatal Exposure Delayed Effects/metabolism , Xenobiotics/adverse effects , Age of Onset , Dopamine/metabolism , Dopaminergic Neurons/drug effects , Dopaminergic Neurons/metabolism , Dopaminergic Neurons/pathology , Female , Humans , Neurogenesis/drug effects , Neurogenesis/physiology , Parkinson Disease, Secondary/epidemiology , Pregnancy , Prenatal Exposure Delayed Effects/epidemiology , Substantia Nigra/drug effects , Substantia Nigra/metabolism , Substantia Nigra/pathology
8.
J Alzheimers Dis ; 42(1): 87-96, 2014.
Article in English | MEDLINE | ID: mdl-25024340

ABSTRACT

We present a new hypothesis on the contribution of a dysfunction of the oxidative phosphorylation system, through a decrease in the de novo synthesis of pyrimidine nucleotides, to the pathogenesis of late onset Alzheimer's disease (AD). In the light of this proposition, different treatments for AD patients, such as enhancing the electron flow downstream the coenzyme Q10 of the mitochondrial respiratory chain or increasing mitochondrial biogenesis or directly providing pyrimidines, would be possible. AD is a multifactorial disorder and not all patients would benefit from these treatments. Those healthy individuals harboring mtDNA haplotypes related to a coupled OXPHOS function would probably be the better candidates for these preventive therapies.


Subject(s)
Alzheimer Disease/drug therapy , Alzheimer Disease/genetics , Oxidative Phosphorylation/drug effects , Pyrimidine Nucleotides , Alzheimer Disease/metabolism , Animals , DNA, Mitochondrial/metabolism , Humans , Neurons/drug effects , Neurons/metabolism , Nootropic Agents/pharmacology , Nootropic Agents/therapeutic use , Pharmacogenetics/methods , Pyrimidine Nucleotides/biosynthesis
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