Your search keyword '"Nicolas Auger"' showing total 11 results

1. Transcriptomic analysis reinforces the implication of spatacsin in neuroinflammation and neurodevelopment

Author

Liriopé Toupenet Marchesi, Daniel Stockholm, Typhaine Esteves, Marion Leblanc, Nicolas Auger, Julien Branchu, Khalid Hamid El Hachimi, and Giovanni Stevanin

Subjects

Spastic paraplegia, Transcriptomic analysis, Mouse model, SPG11, DEG, GSEA, Medicine, Science

Abstract

Abstract Hereditary spastic paraplegia (HSP) encompasses a group of rare genetic diseases primarily affecting motor neurons. Among these, spastic paraplegia type 11 (SPG11) represents a complex form of HSP caused by deleterious variants in the SPG11 gene, which encodes the spatacsin protein. Previous studies have described several potential roles for spatacsin, including its involvement in lysosome and autophagy mechanisms, neuronal and neurites development or mitochondria function. Despite these findings, the precise function of the spatacsin protein remains elusive. To elucidate its function, we conducted an extensive RNA sequencing (RNAseq) experiment and transcriptomic analysis in three distinct neural structures (cerebellum, cortex and hippocampus) and at three different ages (6 weeks, 4 months and 8 months) in both wild type and Spg11 −/− mice. Our functional analysis of differentially expressed genes (DEGs) and Gene Set Enrichment Analysis (GSEA) revealed dysregulation in pathways related to inflammation, RNA metabolism and neuronal and neurite development, factors frequently implicated in neurodegenerative disorders. Notably, we also observed early deregulation in cellular pathways related to cell proliferation. Our results represent a significant step towards a better understanding of the functions of spatacsin in the cell and the underlying cellular mechanisms disrupted by its absence.

Published

2025

2. Pathogenic Variants in ABHD16A Cause a Novel Psychomotor Developmental Disorder With Spastic Paraplegia

Author

Ashraf Yahia, Liena E. O. Elsayed, Remi Valter, Ahlam A. A. Hamed, Inaam N. Mohammed, Maha A. Elseed, Mustafa A. Salih, Typhaine Esteves, Nicolas Auger, Rayan Abubaker, Mahmoud Koko, Fatima Abozar, Hiba Malik, Rawaa Adil, Sara Emad, Mhammed Alhassan Musallam, Razaz Idris, Isra Z. M. Eltazi, Arwa Babai, Elhami A. A. Ahmed, Amal S. I. Abd Allah, Mathilde Mairey, Ahmed K. M. A. Ahmed, Mustafa I. Elbashir, Alexis Brice, Muntaser E. Ibrahim, Ammar E. Ahmed, Foudil Lamari, and Giovanni Stevanin

Subjects

ABHD16A, hereditary spastic paraplegia, next-generation sequencing, targeted-metabolomics, lipid metabolism, phosphatidylserine, Neurology. Diseases of the nervous system, RC346-429

Abstract

Introduction: Hereditary spastic paraplegia is a clinically and genetically heterogeneous neurological entity that includes more than 80 disorders which share lower limb spasticity as a common feature. Abnormalities in multiple cellular processes are implicated in their pathogenesis, including lipid metabolism; but still 40% of the patients are undiagnosed. Our goal was to identify the disease-causing variants in Sudanese families excluded for known genetic causes and describe a novel clinico-genetic entity.Methods: We studied four patients from two unrelated consanguineous Sudanese families who manifested a neurological phenotype characterized by spasticity, psychomotor developmental delay and/or regression, and intellectual impairment. We applied next-generation sequencing, bioinformatics analysis, and Sanger sequencing to identify the genetic culprit. We then explored the consequences of the identified variants in patients-derived fibroblasts using targeted-lipidomics strategies.Results and Discussion: Two homozygous variants in ABHD16A segregated with the disease in the two studied families. ABHD16A encodes the main brain phosphatidylserine hydrolase. In vitro, we confirmed that ABHD16A loss of function reduces the levels of certain long-chain lysophosphatidylserine species while increases the levels of multiple phosphatidylserine species in patient's fibroblasts.Conclusion:ABHD16A loss of function is implicated in the pathogenesis of a novel form of complex hereditary spastic paraplegia.

Published

2021

3. Derivation of keratinocytes from chicken embryonic stem cells: Establishment and characterization of differentiated proliferative cell populations

Author

Mathilde Couteaudier, Laëtitia Trapp-Fragnet, Nicolas Auger, Katia Courvoisier, Bertrand Pain, Caroline Denesvre, and Jean-François Vautherot

Subjects

Biology (General), QH301-705.5

Abstract

A common challenge in avian cell biology is the generation of differentiated cell-lines, especially in the keratinocyte lineage. Only a few avian cell-lines are available and very few of them show an interesting differentiation profile. During the last decade, mammalian embryonic stem cell-lines were shown to differentiate into almost all lineages, including keratinocytes. Although chicken embryonic stem cells had been obtained in the 1990s, few differentiation studies toward the ectodermal lineage were reported. Consequently, we explored the differentiation of chicken embryonic stem cells toward the keratinocyte lineage by using a combination of stromal induction, ascorbic acid, BMP4 and chicken serum. During the induction period, we observed a downregulation of pluripotency markers and an upregulation of epidermal markers. Three homogenous cell populations were derived, which were morphologically similar to chicken primary keratinocytes, displaying intracellular lipid droplets in almost every pavimentous cell. These cells could be serially passaged without alteration of their morphology and showed gene and protein expression profiles of epidermal markers similar to chicken primary keratinocytes. These cells represent an alternative to the isolation of chicken primary keratinocytes, being less cumbersome to handle and reducing the number of experimental animals used for the preparation of primary cells.

Published

2015

4. On the Worst-Case Complexity of TimSort.

Author

Nicolas Auger, Vincent Jugé, Cyril Nicaud, and Carine Pivoteau

Published

2018

5. Good Predictions Are Worth a Few Comparisons.

Author

Nicolas Auger, Cyril Nicaud, and Carine Pivoteau

Published

2016

6. Analysis of Algorithms for Permutations Biased by Their Number of Records.

Author

Nicolas Auger, Mathilde Bouvel, Cyril Nicaud, and Carine Pivoteau

Published

2016

7. Heterozygous PNPT1 variants cause spinocerebellar ataxia type 25

Author

Mathieu Barbier, Melanie Bahlo, Alessandra Pennisi, Maxime Jacoupy, Rick M. Tankard, Claire Ewenczyk, Kayli C. Davies, Patricia Lino‐Coulon, Claire Colace, Haloom Rafehi, Nicolas Auger, Brendan R. E. Ansell, Ivo van der Stelt, Katherine B. Howell, Marie Coutelier, David J. Amor, Emeline Mundwiller, Lena Guillot‐Noël, Elsdon Storey, R. J. McKinlay Gardner, Mathew J. Wallis, Alfredo Brusco, Olga Corti, Agnès Rötig, Richard J. Leventer, Alexis Brice, Martin B. Delatycki, Giovanni Stevanin, Paul J. Lockhart, and Alexandra Durr

Subjects

spinocerebellar ataxias, PNPT1, SCA25, cerebellum, Cerebellar Ataxia, Australia, Neurology, Exoribonucleases, Interferon Type I, Humans, Ataxia, Neurology (clinical), France

Abstract

Dominant spinocerebellar ataxias (SCA) are characterized by genetic heterogeneity. Some mapped and named loci remain without a causal gene identified. Here we applied next generation sequencing (NGS) to uncover the genetic etiology of the SCA25 locus.Whole-exome and whole-genome sequencing were performed in families linked to SCA25, including the French family in which the SCA25 locus was originally mapped. Whole exome sequence data were interrogated in a cohort of 796 ataxia patients of unknown etiology.The SCA25 phenotype spans a slowly evolving sensory and cerebellar ataxia, in most cases attributed to ganglionopathy. A pathogenic variant causing exon skipping was identified in the gene encoding Polyribonucleotide Nucleotidyltransferase PNPase 1 (PNPT1) located in the SCA25 linkage interval. A second splice variant in PNPT1 was detected in a large Australian family with a dominant ataxia also mapping to SCA25. An additional nonsense variant was detected in an unrelated individual with ataxia. Both nonsense and splice heterozygous variants result in premature stop codons, all located in the S1-domain of PNPase. In addition, an elevated type I interferon response was observed in blood from all affected heterozygous carriers tested. PNPase notably prevents the abnormal accumulation of double-stranded mtRNAs in the mitochondria and leakage into the cytoplasm, associated with triggering a type I interferon response.This study identifies PNPT1 as a new SCA gene, responsible for SCA25, and highlights biological links between alterations of mtRNA trafficking, interferonopathies and ataxia. ANN NEUROL 2022;92:122-137.

Published

2022

8. NPTX1 mutations trigger endoplasmic reticulum stress and cause autosomal dominant cerebellar ataxia

Author

François Ancien, Nicolas Sgarioto, Roxanne Larivière, Bernard Brais, Martje G Pauly, David-Alexandre Trégouët, Eric A. Shoubridge, Ganapathi Varma Saripella, Natalie Deininger, Marie Coutelier, Dimitri Gilis, Maxime Jacoupy, Léna Guillot-Noel, Khalid H El Hachimi, Alexandra Durr, Alexis Brice, Flore Renaud, Sabrina Sayah, G. Stevanin, Alexandre Janer, Perrine Charles, Marianne Rooman, Nicolas Auger, C. Helmchen, Isabelle Le Ber, Tobias B. Haack, Fabrizio Pucci, Rémi Valter, and Astrid Nümann

Subjects

Genetics, Arthrogryposis, Cerebellar ataxia, Cerebellar Ataxia, Genetic heterogeneity, ATF6, Endoplasmic reticulum, Nerve Tissue Proteins, Biology, medicine.disease, Endoplasmic Reticulum Stress, Phenotype, Pedigree, C-Reactive Protein, Autosomal dominant cerebellar ataxia, Mutation, Exome Sequencing, medicine, Missense mutation, Humans, Neurology (clinical), medicine.symptom, Exome sequencing

Abstract

With more than 40 causative genes identified so far, autosomal dominant cerebellar ataxias exhibit a remarkable genetic heterogeneity. Yet, half the patients are lacking a molecular diagnosis. In a large family with nine sampled affected members, we performed exome sequencing combined with whole-genome linkage analysis. We identified a missense variant in NPTX1, NM_002522.3:c.1165G>A: p.G389R, segregating with the phenotype. Further investigations with whole-exome sequencing and an amplicon-based panel identified four additional unrelated families segregating the same variant, for whom a common founder effect could be excluded. A second missense variant, NM_002522.3:c.980A>G: p.E327G, was identified in a fifth familial case. The NPTX1-associated phenotype consists of a late-onset, slowly progressive, cerebellar ataxia, with downbeat nystagmus, cognitive impairment reminiscent of cerebellar cognitive affective syndrome, myoclonic tremor and mild cerebellar vermian atrophy on brain imaging. NPTX1 encodes the neuronal pentraxin 1, a secreted protein with various cellular and synaptic functions. Both variants affect conserved amino acid residues and are extremely rare or absent from public databases. In COS7 cells, overexpression of both neuronal pentraxin 1 variants altered endoplasmic reticulum morphology and induced ATF6-mediated endoplasmic reticulum stress, associated with cytotoxicity. In addition, the p.E327G variant abolished neuronal pentraxin 1 secretion, as well as its capacity to form a high molecular weight complex with the wild-type protein. Co-immunoprecipitation experiments coupled with mass spectrometry analysis demonstrated abnormal interactions of this variant with the cytoskeleton. In agreement with these observations, in silico modelling of the neuronal pentraxin 1 complex evidenced a destabilizing effect for the p.E327G substitution, located at the interface between monomers. On the contrary, the p.G389 residue, located at the protein surface, had no predictable effect on the complex stability. Our results establish NPTX1 as a new causative gene in autosomal dominant cerebellar ataxias. We suggest that variants in NPTX1 can lead to cerebellar ataxia due to endoplasmic reticulum stress, mediated by ATF6, and associated to a destabilization of NP1 polymers in a dominant-negative manner for one of the variants.

Published

2021

9. Arbres et arbustes fruitiers pour le Québec

Author

Marianne Baril, Nicolas Auger, Marianne Baril, and Nicolas Auger

Abstract

Qui n'a jamais rêvé de cultiver chez soi ses propres fruits: pommes, poires, prunes, bleuets, framboises, fraises, kiwis rustiques, etc., et d'avoir ainsi à portée de main des fruits frais tout l'été? Pour le débutant ou pour l'amateur passionné, sur un petit ou un grand terrain, Arbres et arbustes fruitiers pour le Québec se veut un livre de référence unique, riche en trucs nouveaux, en conseils simples et pratiques: • Les meilleurs choix de fruitiers pour votre projet • Les cultivars les plus résistants aux maladies • La plantation, l'entretien, la taille, la pollinisation • Des conseils et trucs écologiques contre les maladies et ravageurs, etc. Pourquoi mon pommier ne produit pas de fruits? Comment obtenir une récolte plus abondante? Et bien d'autres questions trouveront réponses grâce aux explications et conseils adaptés à notre climat québécois.

Published

2020

10. On the Worst-Case Complexity of TimSort

Author

Nicolas Auger and Vincent Jugé and Cyril Nicaud and Carine Pivoteau, Auger, Nicolas, Jugé, Vincent, Nicaud, Cyril, Pivoteau, Carine, Nicolas Auger and Vincent Jugé and Cyril Nicaud and Carine Pivoteau, Auger, Nicolas, Jugé, Vincent, Nicaud, Cyril, and Pivoteau, Carine

Abstract

TimSort is an intriguing sorting algorithm designed in 2002 for Python, whose worst-case complexity was announced, but not proved until our recent preprint. In fact, there are two slightly different versions of TimSort that are currently implemented in Python and in Java respectively. We propose a pedagogical and insightful proof that the Python version runs in O(n log n). The approach we use in the analysis also applies to the Java version, although not without very involved technical details. As a byproduct of our study, we uncover a bug in the Java implementation that can cause the sorting method to fail during the execution. We also give a proof that Python's TimSort running time is in O(n + n log rho), where rho is the number of runs (i.e. maximal monotonic sequences), which is quite a natural parameter here and part of the explanation for the good behavior of TimSort on partially sorted inputs.

Published

2018

11. Good Predictions Are Worth a Few Comparisons

Author

Nicolas Auger and Cyril Nicaud and Carine Pivoteau, Auger, Nicolas, Nicaud, Cyril, Pivoteau, Carine, Nicolas Auger and Cyril Nicaud and Carine Pivoteau, Auger, Nicolas, Nicaud, Cyril, and Pivoteau, Carine

Abstract

Most modern processors are heavily parallelized and use predictors to guess the outcome of conditional branches, in order to avoid costly stalls in their pipelines. We propose predictor-friendly versions of two classical algorithms: exponentiation by squaring and binary search in a sorted array. These variants result in less mispredictions on average, at the cost of an increased number of operations. These theoretical results are supported by experimentations that show that our algorithms perform significantly better than the standard ones, for primitive data types.

Published

2016