Your search keyword '"Luppe J"' showing total 5 results

1. Heterozygous and homozygous variants in STX1A cause a neurodevelopmental disorder with or without epilepsy.

Author

Luppe, J., Sticht, H., Lecoquierre, F., Goldenberg, A., Gorman, K.M., Molloy, B., Agolini, E., Novelli, A., Briuglia, S., Kuismin, O., Marcelis, C.L.M., Vitobello, A., Denommé-Pichon, A.S., Julia, S., Lemke, J.R., Abou Jamra, R., Platzer, K., Luppe, J., Sticht, H., Lecoquierre, F., Goldenberg, A., Gorman, K.M., Molloy, B., Agolini, E., Novelli, A., Briuglia, S., Kuismin, O., Marcelis, C.L.M., Vitobello, A., Denommé-Pichon, A.S., Julia, S., Lemke, J.R., Abou Jamra, R., and Platzer, K.

Abstract

Item does not contain fulltext, The neuronal SNARE complex drives synaptic vesicle exocytosis. Therefore, one of its core proteins syntaxin 1A (STX1A) has long been suspected to play a role in neurodevelopmental disorders. We assembled eight individuals harboring ultra rare variants in STX1A who present with a spectrum of intellectual disability, autism and epilepsy. Causative variants comprise a homozygous splice variant, three de novo missense variants and two inframe deletions of a single amino acid. We observed a phenotype mainly driven by epilepsy in the individuals with missense variants in contrast to intellectual disability and autistic behavior in individuals with single amino acid deletions and the splicing variant. In silico modeling of missense variants and single amino acid deletions show different impaired protein-protein interactions. We hypothesize the two phenotypic courses of affected individuals to be dependent on two different pathogenic mechanisms: (1) a weakened inhibitory STX1A-STXBP1 interaction due to missense variants results in an STX1A-related developmental epileptic encephalopathy and (2) a hampered SNARE complex formation due to inframe deletions causes an STX1A-related intellectual disability and autism phenotype. Our description of a STX1A-related neurodevelopmental disorder with or without epilepsy thus expands the group of rare diseases called SNAREopathies.

Published

2023

2. Heterozygous and homozygous variants in STX1A cause a neurodevelopmental disorder with or without epilepsy.

Author

Luppe J, Sticht H, Lecoquierre F, Goldenberg A, Gorman KM, Molloy B, Agolini E, Novelli A, Briuglia S, Kuismin O, Marcelis C, Vitobello A, Denommé-Pichon AS, Julia S, Lemke JR, Abou Jamra R, and Platzer K

Subjects

Humans, Phenotype, Syntaxin 1 genetics, Heterozygote, Autistic Disorder genetics, Epilepsy genetics, Intellectual Disability pathology, Neurodevelopmental Disorders genetics

Abstract

The neuronal SNARE complex drives synaptic vesicle exocytosis. Therefore, one of its core proteins syntaxin 1A (STX1A) has long been suspected to play a role in neurodevelopmental disorders. We assembled eight individuals harboring ultra rare variants in STX1A who present with a spectrum of intellectual disability, autism and epilepsy. Causative variants comprise a homozygous splice variant, three de novo missense variants and two inframe deletions of a single amino acid. We observed a phenotype mainly driven by epilepsy in the individuals with missense variants in contrast to intellectual disability and autistic behavior in individuals with single amino acid deletions and the splicing variant. In silico modeling of missense variants and single amino acid deletions show different impaired protein-protein interactions. We hypothesize the two phenotypic courses of affected individuals to be dependent on two different pathogenic mechanisms: (1) a weakened inhibitory STX1A-STXBP1 interaction due to missense variants results in an STX1A-related developmental epileptic encephalopathy and (2) a hampered SNARE complex formation due to inframe deletions causes an STX1A-related intellectual disability and autism phenotype. Our description of a STX1A-related neurodevelopmental disorder with or without epilepsy thus expands the group of rare diseases called SNAREopathies., (© 2022. The Author(s).)

Published

2023

3. WARS1 and SARS1: Two tRNA synthetases implicated in autosomal recessive microcephaly.

Author

Bögershausen N, Krawczyk HE, Jamra RA, Lin SJ, Yigit G, Hüning I, Polo AM, Vona B, Huang K, Schmidt J, Altmüller J, Luppe J, Platzer K, Dörgeloh BB, Busche A, Biskup S, Mendes MI, Smith DEC, Salomons GS, Zibat A, Bültmann E, Nürnberg P, Spielmann M, Lemke JR, Li Y, Zenker M, Varshney GK, Hillen HS, Kratz CP, and Wollnik B

Subjects

Animals, Humans, Ligases, RNA, Transfer, Zebrafish genetics, Amino Acyl-tRNA Synthetases genetics, Charcot-Marie-Tooth Disease genetics, Microcephaly genetics, Microcephaly pathology, Tryptophan-tRNA Ligase genetics

Abstract

Aminoacylation of transfer RNA (tRNA) is a key step in protein biosynthesis, carried out by highly specific aminoacyl-tRNA synthetases (ARSs). ARSs have been implicated in autosomal dominant and autosomal recessive human disorders. Autosomal dominant variants in tryptophanyl-tRNA synthetase 1 (WARS1) are known to cause distal hereditary motor neuropathy and Charcot-Marie-Tooth disease, but a recessively inherited phenotype is yet to be clearly defined. Seryl-tRNA synthetase 1 (SARS1) has rarely been implicated in an autosomal recessive developmental disorder. Here, we report five individuals with biallelic missense variants in WARS1 or SARS1, who presented with an overlapping phenotype of microcephaly, developmental delay, intellectual disability, and brain anomalies. Structural mapping showed that the SARS1 variant is located directly within the enzyme's active site, most likely diminishing activity, while the WARS1 variant is located in the N-terminal domain. We further characterize the identified WARS1 variant by showing that it negatively impacts protein abundance and is unable to rescue the phenotype of a CRISPR/Cas9 wars1 knockout zebrafish model. In summary, we describe two overlapping autosomal recessive syndromes caused by variants in WARS1 and SARS1, present functional insights into the pathogenesis of the WARS1-related syndrome and define an emerging disease spectrum: ARS-related developmental disorders with or without microcephaly., (© 2022 The Authors. Human Mutation published by Wiley Periodicals LLC.)

Published

2022

4. Unique variants in CLCN3, encoding an endosomal anion/proton exchanger, underlie a spectrum of neurodevelopmental disorders.

Author

Duncan AR, Polovitskaya MM, Gaitán-Peñas H, Bertelli S, VanNoy GE, Grant PE, O'Donnell-Luria A, Valivullah Z, Lovgren AK, England EM, Agolini E, Madden JA, Schmitz-Abe K, Kritzer A, Hawley P, Novelli A, Alfieri P, Colafati GS, Wieczorek D, Platzer K, Luppe J, Koch-Hogrebe M, Abou Jamra R, Neira-Fresneda J, Lehman A, Boerkoel CF, Seath K, Clarke L, van Ierland Y, Argilli E, Sherr EH, Maiorana A, Diel T, Hempel M, Bierhals T, Estévez R, Jentsch TJ, Pusch M, and Agrawal PB

Subjects

Adolescent, Animals, Child, Child, Preschool, Female, Homozygote, Humans, Infant, Infant, Newborn, Male, Mice, Mice, Knockout, Neurodevelopmental Disorders etiology, Neurodevelopmental Disorders metabolism, Chloride Channels genetics, Disease Models, Animal, Ion Channels physiology, Mutation, Neurodevelopmental Disorders pathology, Phenotype

Abstract

The genetic causes of global developmental delay (GDD) and intellectual disability (ID) are diverse and include variants in numerous ion channels and transporters. Loss-of-function variants in all five endosomal/lysosomal members of the CLC family of Cl - channels and Cl - /H + exchangers lead to pathology in mice, humans, or both. We have identified nine variants in CLCN3, the gene encoding CIC-3, in 11 individuals with GDD/ID and neurodevelopmental disorders of varying severity. In addition to a homozygous frameshift variant in two siblings, we identified eight different heterozygous de novo missense variants. All have GDD/ID, mood or behavioral disorders, and dysmorphic features; 9/11 have structural brain abnormalities; and 6/11 have seizures. The homozygous variants are predicted to cause loss of ClC-3 function, resulting in severe neurological disease similar to the phenotype observed in Clcn3 -/- mice. Their MRIs show possible neurodegeneration with thin corpora callosa and decreased white matter volumes. Individuals with heterozygous variants had a range of neurodevelopmental anomalies including agenesis of the corpus callosum, pons hypoplasia, and increased gyral folding. To characterize the altered function of the exchanger, electrophysiological analyses were performed in Xenopus oocytes and mammalian cells. Two variants, p.Ile607Thr and p.Thr570Ile, had increased currents at negative cytoplasmic voltages and loss of inhibition by luminal acidic pH. In contrast, two other variants showed no significant difference in the current properties. Overall, our work establishes a role for CLCN3 in human neurodevelopment and shows that both homozygous loss of ClC-3 and heterozygous variants can lead to GDD/ID and neuroanatomical abnormalities., (Copyright © 2021 American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2021

5. CDK19-related disorder results from both loss-of-function and gain-of-function de novo missense variants.

Author

Zarate YA, Uehara T, Abe K, Oginuma M, Harako S, Ishitani S, Lehesjoki AE, Bierhals T, Kloth K, Ehmke N, Horn D, Holtgrewe M, Anderson K, Viskochil D, Edgar-Zarate CL, Sacoto MJG, Schnur RE, Morrow MM, Sanchez-Valle A, Pappas J, Rabin R, Muona M, Anttonen AK, Platzer K, Luppe J, Gburek-Augustat J, Kaname T, Okamoto N, Mizuno S, Kaido Y, Ohkuma Y, Hirose Y, Ishitani T, and Kosaki K

Subjects

Animals, Cyclin-Dependent Kinases genetics, Gain of Function Mutation, Humans, Infant, Mutation, Missense, Zebrafish genetics, Intellectual Disability, Neurodevelopmental Disorders

Abstract

Purpose: To expand the recent description of a new neurodevelopmental syndrome related to alterations in CDK19., Methods: Individuals were identified through international collaboration. Functional studies included autophosphorylation assays for CDK19 Gly28Arg and Tyr32His variants and in vivo zebrafish assays of the CDK19 G28R and CDK19 Y32H ., Results: We describe 11 unrelated individuals (age range: 9 months to 14 years) with de novo missense variants mapped to the kinase domain of CDK19, including two recurrent changes at residues Tyr32 and Gly28. In vitro autophosphorylation and substrate phosphorylation assays revealed that kinase activity of protein was lower for p.Gly28Arg and higher for p.Tyr32His substitutions compared with that of the wild-type protein. Injection of CDK19 messenger RNA (mRNA) with either the Tyr32His or the Gly28Arg variants using in vivo zebrafish model significantly increased fraction of embryos with morphological abnormalities. Overall, the phenotype of the now 14 individuals with CDK19-related disorder includes universal developmental delay and facial dysmorphism, hypotonia (79%), seizures (64%), ophthalmologic anomalies (64%), and autism/autistic traits (56%)., Conclusion: CDK19 de novo missense variants are responsible for a novel neurodevelopmental disorder. Both kinase assay and zebrafish experiments showed that the pathogenetic mechanism may be more diverse than previously thought.

Published

2021