Caracterisation pharmacologique et moleculaire du site imidazolinique-guanidinique dans le tubule proximal de rein de lapin

SIGLECNRS T Bordereau / INIST-CNRS - Institut de l'Information Scientifique et TechniqueFRFranc

Whole-exome sequencing confirms implication of VPS13D as a potential cause of progressive spastic ataxia

International audienceBackground: VPS13D is a large ubiquitin-binding protein playing an essential role in mitophagy by regulating mitochondrial fission. Recently, VPS13D biallelic pathogenic variants have been reported in patients displaying variable neurological phenotypes, with an autosomic recessive inheritance. The objectives of the study were to determine the genetic etiology of a patient with early onset sporadic progressive spastic ataxia, and to investigate the pathogenicity of VPS13D variants through functional studies on patient's skin fibroblasts. Case presentation: We report the case of a 51-year-old patient with spastic ataxia, with an acute onset of the disease at age 7. Walking difficulties slowly worsened over time, with the use of a wheelchair since age 26. We have used trio-based whole-exome sequencing (WES) to identify genes associated with spastic ataxia. The impact of the identified variants on mitochondrial function was assessed in patient's fibroblasts by imaging mitochondrial network and measuring level of individual OXPHOS complex subunits. Compound heterozygous variants were identified in VPS13D: c.946C > T, p.Arg316* and c.12416C > T, p.(Ala4139Val). Primary fibroblasts obtained from this patient revealed an altered mitochondrial morphology, and a decrease in levels of proteins from complex I, III and IV. Conclusions: Our findings confirmed implication of VPS13D in spastic ataxia and provided further support for mitochondrial defects in patient's skin fibroblasts with VPS13D variants. This report of long-term follow up showed a slowly progressive course of the spastic paraplegia with cerebellar features. Furthermore, the performed functional studies could be used as biomarker helping diagnosis of VPS13D-related neurological disorders when molecular results are uneasy to interpret

Whole-exome sequencing confirms implication of VPS13D as a potential cause of progressive spastic ataxia

Abstract Background VPS13D is a large ubiquitin-binding protein playing an essential role in mitophagy by regulating mitochondrial fission. Recently, VPS13D biallelic pathogenic variants have been reported in patients displaying variable neurological phenotypes, with an autosomic recessive inheritance. The objectives of the study were to determine the genetic etiology of a patient with early onset sporadic progressive spastic ataxia, and to investigate the pathogenicity of VPS13D variants through functional studies on patient’s skin fibroblasts. Case presentation We report the case of a 51-year-old patient with spastic ataxia, with an acute onset of the disease at age 7. Walking difficulties slowly worsened over time, with the use of a wheelchair since age 26. We have used trio-based whole-exome sequencing (WES) to identify genes associated with spastic ataxia. The impact of the identified variants on mitochondrial function was assessed in patient’s fibroblasts by imaging mitochondrial network and measuring level of individual OXPHOS complex subunits. Compound heterozygous variants were identified in VPS13D: c.946C &gt; T, p.Arg316* and c.12416C &gt; T, p.(Ala4139Val). Primary fibroblasts obtained from this patient revealed an altered mitochondrial morphology, and a decrease in levels of proteins from complex I, III and IV. Conclusions Our findings confirmed implication of VPS13D in spastic ataxia and provided further support for mitochondrial defects in patient’s skin fibroblasts with VPS13D variants. This report of long-term follow up showed a slowly progressive course of the spastic paraplegia with cerebellar features. Furthermore, the performed functional studies could be used as biomarker helping diagnosis of VPS13D-related neurological disorders when molecular results are uneasy to interpret. </jats:sec

Detection of an Intragenic Deletion Expands the Spectrum of CTSC Mutations in Papillon–Lefèvre Syndrome

The Papillon–Lefèvre syndrome (PLS) is an autosomal recessive disorder. The gene responsible for the disease, cathepsin C (CTSC), is localized in 11q14.1–q14.21. We performed mutational and functional analyses of CTSC in two patients affected by this condition. Three previously unreported CTSC mutations were identified. The first patient had a compound heterozygous status with a p.G386R missense mutation and an intragenic deletion spanning exons 3–7. Second patient carried a homozygous splice site mutation, p.A253SfsX30. CTSC activity was undetectable in both patients, thus demonstrating the pathological effect of these mutations. We describe early evidence of an original intragenic deletion reported in PLS. Since this mutational mechanism could not be detected by direct sequencing, intragenic deletion has to be specifically investigated using gene dosage analysis techniques such as quantitative multiplex fluorescent polymerase chain reaction. We consider that this technique should be performed in patients with apparently homozygous CTSC mutations when one parent does not carry the expected mutation or is not available for analysis