Your search keyword '"Barcia, G"' showing total 11 results

1. Polyradiculoneuritis on MRI: An Overlooked Feature of Biallelic POLG Gene Mutations in Infancy.

Author

Roux CJ, Dufeu-Berat CM, Hully M, Rotig A, Schiff M, De Lonlay P, Aubart M, Alison M, Jaroussie M, Levy R, Dangouloff-Ros V, Barcia G, Desguerre I, Munnich A, Gitiaux C, and Boddaert N

Subjects

Humans, Infant, Male, Female, DNA Polymerase gamma genetics, Magnetic Resonance Imaging, Mutation

Published

2024

2. A KCNC1 mutation in epilepsy of infancy with focal migrating seizures produces functional channels that fail to be regulated by PKC phosphorylation.

Author

Zhang Y, Ali SR, Nabbout R, Barcia G, and Kaczmarek LK

Subjects

Animals, CHO Cells, Cricetinae, Cricetulus, Epilepsy metabolism, Phosphorylation, Protein Kinase C metabolism, Shaw Potassium Channels chemistry, Shaw Potassium Channels genetics, Sialyltransferases genetics, Sialyltransferases metabolism, Epilepsy genetics, Mutation, Shaw Potassium Channels metabolism, Sialyltransferases deficiency

Abstract

Channelopathies caused by mutations in genes encoding ion channels generally produce a clear change in channel function. Accordingly, mutations in KCNC1 , which encodes the voltage-dependent Kv3.1 potassium channel, result in progressive myoclonus epilepsy as well as other developmental and epileptic encephalopathies, and these have been shown to reduce or fully abolish current amplitude. One exception to this is the mutation A513V Kv3.1b, located in the cytoplasmic C-terminal domain of the channel protein. This de novo variant was detected in a patient with epilepsy of infancy with focal migrating seizures (EIFMS), but no difference could be detected between A513V Kv3.1 current and that of wild-type Kv3.1. Using both biochemical and electrophysiological approaches, we have now confirmed that this variant produces functional channels but find that the A513V mutation renders the channel completely insensitive to regulation by phosphorylation at S503, a nearby regulatory site in the C-terminus. In this respect, the mutation resembles those in another channel, KCNT1, which are the major cause of EIFMS. Because the amplitude of Kv3.1 current is constantly adjusted by phosphorylation in vivo, our findings suggest that loss of such regulation contributes to EIFMS phenotype and emphasize the role of channel modulation for normal neuronal function. NEW & NOTEWORTHY Ion channel mutations that cause serious human diseases generally alter the biophysical properties or expression of the channel. We describe a de novo mutation in the Kv3.1 potassium channel that causes severe intellectual disability with early-onset epilepsy. The properties of this channel appear identical to those of wild-type channels, but the mutation prevents phosphorylation of the channel by protein kinase C. Our findings emphasize the role of channel modulation in normal brain function.

Published

2021

3. Improving post-natal detection of mitochondrial DNA mutations.

Author

Barcia G, Assouline Z, Magen M, Pennisi A, Rötig A, Munnich A, Bonnefont JP, and Steffann J

Subjects

DNA Mutational Analysis methods, High-Throughput Nucleotide Sequencing methods, Humans, Molecular Diagnostic Techniques, Postnatal Care methods, Sensitivity and Specificity, DNA, Mitochondrial, Genetic Predisposition to Disease, Genetic Testing methods, Genetic Testing standards, Mitochondrial Diseases diagnosis, Mitochondrial Diseases genetics, Mutation

Abstract

Introduction: Currently, genetic testing of mitochondrial DNA mutations includes screening for single-nucleotide variants, several base pair insertions or deletions, large-scale deletions, or relative depletion of total mitochondrial DNA content. Within the last decade, next-generation sequencing (NGS) has resulted in remarkable advances in the field of mitochondrial diseases (MD) and has become a routine step of the diagnostic workup., Areas Covered: We aimed to present an overview of current technologies employed in molecular diagnosis of mitochondrial DNA diseases. We report on the recent contributions of NGS testing to the diagnosis and understanding of MD., Expert Opinion: The progress of NGS technologies allows the simultaneous detection of mutations and quantification of the heteroplasmy level, ensuring sensitivity and specificity requested for the detection of mitochondrial DNA point mutations. NGS protocols enabling the simultaneous analysis of mitochondrial and nuclear DNA are now efficient and cost-saving approaches, and have become the gold-standard technique in diagnostic laboratories.

Published

2020

4. Clinical, neuroimaging and biochemical findings in patients and patient fibroblasts expressing ten novel GFM1 mutations.

Author

Barcia G, Rio M, Assouline Z, Zangarelli C, Gueguen N, Dumas VD, Marcorelles P, Schiff M, Slama A, Barth M, Hully M, de Lonlay P, Munnich A, Desguerre I, Bonnefont JP, Steffann J, Procaccio V, Boddaert N, Rötig A, Metodiev MD, and Ruzzenente B

Subjects

Alleles, Brain diagnostic imaging, Brain pathology, Databases, Genetic, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Mitochondria genetics, Pedigree, Fibroblasts metabolism, Gene Expression Regulation, Genetic Association Studies methods, Genetic Predisposition to Disease, Mitochondrial Proteins genetics, Mutation, Neuroimaging methods, Peptide Elongation Factor G genetics

Abstract

Pathogenic GFM1 variants have been linked to neurological phenotypes with or without liver involvement, but only a few cases have been reported in the literature. Here, we report clinical, biochemical, and neuroimaging findings from nine unrelated children carrying GFM1 variants, 10 of which were not previously reported. All patients presented with neurological involvement-mainly axial hypotonia and dystonia during the neonatal period-with five diagnosed with West syndrome; two children had liver involvement with cytolysis episodes or hepatic failure. While two patients died in infancy, six exhibited a stable clinical course. Brain magnetic resonance imaging showed the involvement of basal ganglia, brainstem, and periventricular white matter. Mutant EFG1 and OXPHOS proteins were decreased in patient's fibroblasts consistent with impaired mitochondrial translation. Thus, we expand the genetic spectrum of GFM1-linked disease and provide detailed clinical profiles of the patients that will improve the diagnostic success for other patients carrying GFM1 mutations., (© 2019 Wiley Periodicals, Inc.)

Published

2020

5. KCNT1 epilepsy with migrating focal seizures shows a temporal sequence with poor outcome, high mortality and SUDEP.

Author

Kuchenbuch M, Barcia G, Chemaly N, Carme E, Roubertie A, Gibaud M, Van Bogaert P, de Saint Martin A, Hirsch E, Dubois F, Sarret C, Nguyen The Tich S, Laroche C, des Portes V, Billette de Villemeur T, Barthez MA, Auvin S, Bahi-Buisson N, Desguerre I, Kaminska A, Benquet P, and Nabbout R

Subjects

Adolescent, Brain Mapping methods, Child, Child, Preschool, Electroencephalography methods, Epilepsies, Partial metabolism, Female, Humans, Longitudinal Studies, Male, Nerve Tissue Proteins metabolism, Phenotype, Potassium Channels genetics, Potassium Channels metabolism, Potassium Channels, Sodium-Activated metabolism, Epilepsies, Partial genetics, Mutation, Nerve Tissue Proteins genetics, Potassium Channels, Sodium-Activated genetics, Sudden Unexpected Death in Epilepsy

Abstract

Epilepsy of infancy with migrating focal seizures was first described in 1995. Fifteen years later, KCNT1 gene mutations were identified as the major disease-causing gene of this disease. Currently, the data on epilepsy of infancy with migrating focal seizures associated with KCNT1 mutations are heterogeneous and many questions remain unanswered including the prognosis and the long-term outcome especially regarding epilepsy, neurological and developmental status and the presence of microcephaly. The aim of this study was to assess data from patients with epilepsy in infancy with migrating focal seizures with KCNT1 mutations to refine the phenotype spectrum and the outcome. We used mind maps based on medical reports of children followed in the network of the French reference centre for rare epilepsies and we developed family surveys to assess the long-term outcome. Seventeen patients were included [age: median (25th-75th percentile): 4 (2-15) years, sex ratio: 1.4, length of follow-up: 4 (2-15) years]. Seventy-one per cent started at 6 (1-52) days with sporadic motor seizures (n = 12), increasing up to a stormy phase with long lasting migrating seizures at 57 (30-89) days. The others entered this stormy phase directly at 1 (1-23) day. Ten patients entered a consecutive phase at 1.3 (1-2.8) years where seizures persisted at least daily (n = 8), but presented different semiology: brief and hypertonic with a nocturnal (n = 6) and clustered (n = 6) aspects. Suppression interictal patterns were identified on the EEG in 71% of patients (n = 12) sometimes from the first EEG (n = 6). Three patients received quinidine without reported efficacy. Long-term outcome was poor with neurological sequelae and active epilepsy except for one patient who had an early and long-lasting seizure-free period. Extracerebral symptoms probably linked with KCNT1 mutation were present, including arteriovenous fistula, dilated cardiomyopathy and precocious puberty. Eight patients (47%) had died at 3 (1.5-15.4) years including three from suspected sudden unexpected death in epilepsy. Refining the electro-clinical characteristics and the temporal sequence of epilepsy in infancy with migrating focal seizures should help diagnosis of this epilepsy. A better knowledge of the outcome allows one to advise families and to define the appropriate follow-up and therapies. Extracerebral involvement should be investigated, in particular the cardiac system, as it may be involved in the high prevalence of sudden unexpected death in epilepsy in these cases., (© The Author(s) (2019). Published by Oxford University Press on behalf of the Guarantors of Brain. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2019

6. Inhibition of mitochondrial translation in fibroblasts from a patient expressing the KARS p.(Pro228Leu) variant and presenting with sensorineural deafness, developmental delay, and lactic acidosis.

Author

Ruzzenente B, Assouline Z, Barcia G, Rio M, Boddaert N, Munnich A, Rötig A, and Metodiev MD

Subjects

Acidosis, Lactic metabolism, Developmental Disabilities metabolism, Female, Fibroblasts cytology, HEK293 Cells, Hearing Loss, Sensorineural metabolism, Humans, Infant, Mitochondria metabolism, Oxidative Phosphorylation, Pedigree, Protein Biosynthesis, Proto-Oncogene Proteins p21(ras) chemistry, Proto-Oncogene Proteins p21(ras) metabolism, RNA Stability, Exome Sequencing methods, Acidosis, Lactic genetics, Developmental Disabilities genetics, Fibroblasts metabolism, Hearing Loss, Sensorineural genetics, Mutation, Proto-Oncogene Proteins p21(ras) genetics

Abstract

Aminoacyl-tRNA synthetases are ubiquitous enzymes, which universally charge tRNAs with their cognate amino acids for use in cytosolic or organellar translation. In humans, mutations in mitochondrial tRNA synthetases have been linked to different tissue-specific pathologies. Mutations in the KARS gene, which encodes both the cytosolic and mitochondrial isoform of lysyl-tRNA synthetase, cause predominantly neurological diseases that often involve deafness, but have also been linked to cardiomyopathy, developmental delay, and lactic acidosis. Using whole exome sequencing, we identified two compound heterozygous mutations, NM_001130089.1:c.683C>T p.(Pro228Leu) and NM_001130089.1:c.1438del p.(Leu480TrpfsX3), in a patient presenting with sensorineural deafness, developmental delay, hypotonia, and lactic acidosis. Nonsense-mediated mRNA decay eliminated the truncated mRNA transcript, rendering the patient hemizygous for the missense mutation. The c.683C>T mutation was previously described, but its pathogenicity remained unexamined. Molecular characterization of patient fibroblasts revealed a multiple oxidative phosphorylation deficiency due to impaired mitochondrial translation, but no evidence of inhibition of cytosolic translation. Reintroduction of wild-type mitochondrial KARS, but not the cytosolic isoform, rescued this phenotype confirming the disease-causing nature of p.(Pro228Leu) exchange and demonstrating the mitochondrial etiology of the disease. We propose that mitochondrial translation deficiency is the probable disease culprit in this and possibly other patients with mutations in KARS., (© 2018 Wiley Periodicals, Inc.)

Published

2018

7. NDUFB8 Mutations Cause Mitochondrial Complex I Deficiency in Individuals with Leigh-like Encephalomyopathy.

Author

Piekutowska-Abramczuk D, Assouline Z, Mataković L, Feichtinger RG, Koňařiková E, Jurkiewicz E, Stawiński P, Gusic M, Koller A, Pollak A, Gasperowicz P, Trubicka J, Ciara E, Iwanicka-Pronicka K, Rokicki D, Hanein S, Wortmann SB, Sperl W, Rötig A, Prokisch H, Pronicka E, Płoski R, Barcia G, and Mayr JA

Subjects

Amino Acid Sequence, Brain diagnostic imaging, Brain pathology, Electron Transport Complex I chemistry, Electron Transport Complex I genetics, Female, Fibroblasts enzymology, Fibroblasts pathology, Humans, Magnetic Resonance Imaging, Male, Oxidative Phosphorylation, Pedigree, Porins metabolism, Brain Diseases genetics, Electron Transport Complex I deficiency, Leigh Disease genetics, Mitochondrial Diseases genetics, Mutation genetics

Abstract

Respiratory chain complex I deficiency is the most frequently identified biochemical defect in childhood mitochondrial diseases. Clinical symptoms range from fatal infantile lactic acidosis to Leigh syndrome and other encephalomyopathies or cardiomyopathies. To date, disease-causing variants in genes coding for 27 complex I subunits, including 7 mitochondrial DNA genes, and in 11 genes encoding complex I assembly factors have been reported. Here, we describe rare biallelic variants in NDUFB8 encoding a complex I accessory subunit revealed by whole-exome sequencing in two individuals from two families. Both presented with a progressive course of disease with encephalo(cardio)myopathic features including muscular hypotonia, cardiac hypertrophy, respiratory failure, failure to thrive, and developmental delay. Blood lactate was elevated. Neuroimaging disclosed progressive changes in the basal ganglia and either brain stem or internal capsule. Biochemical analyses showed an isolated decrease in complex I enzymatic activity in muscle and fibroblasts. Complementation studies by expression of wild-type NDUFB8 in cells from affected individuals restored mitochondrial function, confirming NDUFB8 variants as the cause of complex I deficiency. Hereby we establish NDUFB8 as a relevant gene in childhood-onset mitochondrial disease., (Copyright © 2018 American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2018

8. Mutations in Complex I Assembly Factor TMEM126B Result in Muscle Weakness and Isolated Complex I Deficiency.

Author

Sánchez-Caballero L, Ruzzenente B, Bianchi L, Assouline Z, Barcia G, Metodiev MD, Rio M, Funalot B, van den Brand MA, Guerrero-Castillo S, Molenaar JP, Koolen D, Brandt U, Rodenburg RJ, Nijtmans LG, and Rötig A

Subjects

Adolescent, Adult, Child, Electron Transport Complex I genetics, Exercise, Exome genetics, Genetic Complementation Test, Heterozygote, Humans, Infant, Male, Young Adult, Electron Transport Complex I deficiency, Membrane Proteins genetics, Mitochondrial Diseases genetics, Muscle Weakness genetics, Mutation

Abstract

Mitochondrial complex I deficiency results in a plethora of often severe clinical phenotypes manifesting in early childhood. Here, we report on three complex-I-deficient adult subjects with relatively mild clinical symptoms, including isolated, progressive exercise-induced myalgia and exercise intolerance but with normal later development. Exome sequencing and targeted exome sequencing revealed compound-heterozygous mutations in TMEM126B, encoding a complex I assembly factor. Further biochemical analysis of subject fibroblasts revealed a severe complex I deficiency caused by defective assembly. Lentiviral complementation with the wild-type cDNA restored the complex I deficiency, demonstrating the pathogenic nature of these mutations. Further complexome analysis of one subject indicated that the complex I assembly defect occurred during assembly of its membrane module. Our results show that TMEM126B defects can lead to complex I deficiencies and, interestingly, that symptoms can occur only after exercise., (Copyright © 2016 American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2016

9. Utility of whole exome sequencing for the early diagnosis of pediatric-onset cerebellar atrophy associated with developmental delay in an inbred population.

Author

Megahed H, Nicouleau M, Barcia G, Medina-Cano D, Siquier-Pernet K, Bole-Feysot C, Parisot M, Masson C, Nitschké P, Rio M, Bahi-Buisson N, Desguerre I, Munnich A, Boddaert N, Colleaux L, and Cantagrel V

Subjects

Brain metabolism, Brain pathology, Cerebellar Ataxia diagnosis, Cerebellar Ataxia genetics, Child, Preschool, Early Diagnosis, Female, Humans, Magnetic Resonance Imaging, Male, Phenotype, Atrophy diagnosis, Atrophy genetics, Developmental Disabilities diagnosis, Developmental Disabilities genetics, Exome genetics, Mutation genetics, Sequence Analysis, DNA methods

Abstract

Background: Cerebellar atrophy and developmental delay are commonly associated features in large numbers of genetic diseases that frequently also include epilepsy. These defects are highly heterogeneous on both the genetic and clinical levels. Patients with these signs also typically present with non-specific neuroimaging results that can help prioritize further investigation but don't suggest a specific molecular diagnosis., Methods: To genetically explore a cohort of 18 Egyptian families with undiagnosed cerebellar atrophy identified on MRI, we sequenced probands and some non-affected family members via high-coverage whole exome sequencing (WES; >97 % of the exome covered at least by 30x). Patients were mostly from consanguineous families, either sporadic or multiplex. We analyzed WES data and filtered variants according to dominant and recessive inheritance models., Results: We successfully identified disease-causing mutations in half of the families screened (9/18). These mutations are located in seven different genes, PLA2G6 being the gene most frequently mutated (n = 3). We also identified a recurrent de novo mutation in the KIF1A gene and a molybdenum cofactor deficiency caused by the loss of the start codon in the MOCS2A open-reading frame in a mildly affected subject., Conclusions: This study illustrates the necessity of screening for dominant mutations in WES data from consanguineous families. Our identification of a patient with a mild and improving phenotype carrying a previously characterized severe loss of function mutation also broadens the clinical spectrum associated with molybdenum cofactor deficiency.

Published

2016

10. Mutations in QARS, encoding glutaminyl-tRNA synthetase, cause progressive microcephaly, cerebral-cerebellar atrophy, and intractable seizures.

Author

Zhang X, Ling J, Barcia G, Jing L, Wu J, Barry BJ, Mochida GH, Hill RS, Weimer JM, Stein Q, Poduri A, Partlow JN, Ville D, Dulac O, Yu TW, Lam AT, Servattalab S, Rodriguez J, Boddaert N, Munnich A, Colleaux L, Zon LI, Söll D, Walsh CA, and Nabbout R

Subjects

Aminoacylation, Animals, Child, Preschool, Female, Humans, Magnetic Resonance Imaging, Male, Microcephaly pathology, Pedigree, Zebrafish, Amino Acyl-tRNA Synthetases genetics, Brain Diseases genetics, Genetic Predisposition to Disease, Microcephaly genetics, Mutation, Seizures genetics

Abstract

Progressive microcephaly is a heterogeneous condition with causes including mutations in genes encoding regulators of neuronal survival. Here, we report the identification of mutations in QARS (encoding glutaminyl-tRNA synthetase [QARS]) as the causative variants in two unrelated families affected by progressive microcephaly, severe seizures in infancy, atrophy of the cerebral cortex and cerebellar vermis, and mild atrophy of the cerebellar hemispheres. Whole-exome sequencing of individuals from each family independently identified compound-heterozygous mutations in QARS as the only candidate causative variants. QARS was highly expressed in the developing fetal human cerebral cortex in many cell types. The four QARS mutations altered highly conserved amino acids, and the aminoacylation activity of QARS was significantly impaired in mutant cell lines. Variants p.Gly45Val and p.Tyr57His were located in the N-terminal domain required for QARS interaction with proteins in the multisynthetase complex and potentially with glutamine tRNA, and recombinant QARS proteins bearing either substitution showed an over 10-fold reduction in aminoacylation activity. Conversely, variants p.Arg403Trp and p.Arg515Trp, each occurring in a different family, were located in the catalytic core and completely disrupted QARS aminoacylation activity in vitro. Furthermore, p.Arg403Trp and p.Arg515Trp rendered QARS less soluble, and p.Arg403Trp disrupted QARS-RARS (arginyl-tRNA synthetase 1) interaction. In zebrafish, homozygous qars loss of function caused decreased brain and eye size and extensive cell death in the brain. Our results highlight the importance of QARS during brain development and that epilepsy due to impairment of QARS activity is unusually severe in comparison to other aminoacyl-tRNA synthetase disorders., (Copyright © 2014 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2014

11. Clinical whole-genome sequencing in severe early-onset epilepsy reveals new genes and improves molecular diagnosis

Author

Martin, H, Kim, G, Pagnamenta, A, Murakami, Y, Carvill, G, Meyer, E, Copley, R, Rimmer, A, Barcia, G, Fleming, MR, Kronengold, J, Brown, MR, Hudspith, K, Broxholme, J, Kanapin, A, Cazier, J, Kinoshita, T, Nabbout, R, Bentley, D, McVean, G, Heavin, S, Zaiwalla, Z, McShane, T, Mefford, H, Shears, D, Stewart, H, Kurian, M, Scheffer, I, Blair, E, Donnelly, P, Kaczmarek, L, and Taylor, J

Subjects

Male, Epilepsy, NAV1.2 Voltage-Gated Sodium Channel, Potassium Channels, High-Throughput Nucleotide Sequencing, Membrane Proteins, Nerve Tissue Proteins, Articles, Potassium Channels, Sodium-Activated, Uniparental Disomy, Young Adult, Child, Preschool, Mutation, Humans, KCNQ2 Potassium Channel, Genetic Predisposition to Disease, Proto-Oncogene Proteins c-cbl, Pathology, Molecular, Child, Chromosomes, Human, Pair 9, Genome-Wide Association Study

Abstract

In severe early-onset epilepsy, precise clinical and molecular genetic diagnosis is complex, as many metabolic and electro-physiological processes have been implicated in disease causation. The clinical phenotypes share many features such as complex seizure types and developmental delay. Molecular diagnosis has historically been confined to sequential testing of candidate genes known to be associated with specific sub-phenotypes, but the diagnostic yield of this approach can be low. We conducted whole-genome sequencing (WGS) on six patients with severe early-onset epilepsy who had previously been refractory to molecular diagnosis, and their parents. Four of these patients had a clinical diagnosis of Ohtahara Syndrome (OS) and two patients had severe non-syndromic early-onset epilepsy (NSEOE). In two OS cases, we found de novo non-synonymous mutations in the genes KCNQ2 and SCN2A. In a third OS case, WGS revealed paternal isodisomy for chromosome 9, leading to identification of the causal homozygous missense variant in KCNT1, which produced a substantial increase in potassium channel current. The fourth OS patient had a recessive mutation in PIGQ that led to exon skipping and defective glycophosphatidyl inositol biosynthesis. The two patients with NSEOE had likely pathogenic de novo mutations in CBL and CSNK1G1, respectively. Mutations in these genes were not found among 500 additional individuals with epilepsy. This work reveals two novel genes for OS, KCNT1 and PIGQ. It also uncovers unexpected genetic mechanisms and emphasizes the power of WGS as a clinical tool for making molecular diagnoses, particularly for highly heterogeneous disorders.

Published

2014