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2. OC 17.3 Prothrombotic Polymorphisms FV Leiden and Prothrombin G20210A in 699 Unrelated Patients with Congenital Antithrombin Deficiency: More than a Prognostic Value

Author

Bravo Perez, C., primary, Orlando, C., additional, Gindele, R., additional, Cifuentes, R., additional, Stouffs, K., additional, Ilonczai, P., additional, de la Morena-Barrio, M., additional, Schlammadinger, Á., additional, Pfliegler, G., additional, Corral, J., additional, Jochmans, K., additional, and Bereczky, Z., additional

Published
2023
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5. Maternally inherited differences in mitochondrial DNA genotype between ART and spontaneously conceived individuals associate with low birthweight

Author

Mertens, J., Belva, F., Van Montfoort, A., Zambelli, F., Seneca, S., de Deckersberg, E. Couvreu, Bonduelle, M., Tournaye, H., Stouffs, K., Barbe, K., Smeets, H., Van De Velde, H., Sermon, K., Blockeel, C., Spits, C., Basic (bio-) Medical Sciences, Faculty of Medicine and Pharmacy, Clinical sciences, Medical Genetics, Reproduction and Genetics, Vriendenkring VUB, Surgical clinical sciences, Biology of the Testis, Centre for Reproductive Medicine - Gynaecology, Radiation Therapy, Artificial Intelligence supported Modelling in clinical Sciences, Biostatistics and medical informatics, Digital Mathematics, Public Health Sciences, and Applied Physics and Photonics

Published
2021

6. O-184 Maternally inherited differences in mitochondrial DNA genotype between ART and spontaneously conceived individuals associate with low birthweight

Author

Mertens, J, primary, Belva, F, additional, Van Montfoort, A, additional, Zambelli, F, additional, Seneca, S, additional, Couvreu de Deckersberg, E, additional, Bonduelle, M, additional, Tournaye, H, additional, Stouffs, K, additional, Barbé, K, additional, Smeets, H, additional, Van de Velde, H, additional, Sermon, K, additional, Blockeel, C, additional, and Spits, C, additional

Published
2021
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7. Genetic heterogeneity of polymicrogyria: study of 123 patients using deep sequencing

Author

Stutterd, CA, Brock, S, Stouffs, K, Fanjul-Fernandez, M, Lockhart, PJ, McGillivray, G, Mandelstam, S, Pope, K, Delatycki, MB, Jansen, A, Leventer, RJ, Stutterd, CA, Brock, S, Stouffs, K, Fanjul-Fernandez, M, Lockhart, PJ, McGillivray, G, Mandelstam, S, Pope, K, Delatycki, MB, Jansen, A, and Leventer, RJ

Abstract

Polymicrogyria is a malformation of cortical development characterized by overfolding and abnormal lamination of the cerebral cortex. Manifestations include epilepsy, speech disturbance and motor and cognitive disability. Causes include acquired prenatal insults and inherited and de novo genetic variants. The proportion of patients with polymicrogyria and a causative germline or mosaic variant is not known. The aim of this study was to identify the monogenic causes of polymicrogyria in a heterogeneous cohort of patients reflective of specialized referral services. Patients with polymicrogyria were recruited from two clinical centres in Australia and Belgium. Patients with evidence of congenital cytomegalovirus infection or causative chromosomal copy number variants were excluded. One hundred and twenty-three patients were tested using deep sequencing gene panels including known and candidate genes for malformations of cortical development. Causative and potentially causative variants were identified and correlated with phenotypic features. Pathogenic or likely pathogenic variants were identified in 25/123 (20.3%) patients. A candidate variant was identified for an additional patient but could not be confirmed as de novo, and therefore it was classified as being of uncertain significance with high clinical relevance. Of the 22 dominant variants identified, 5 were mosaic with allele fractions less than 0.33 and the lowest allele fraction 0.09. The most common causative genes were TUBA1A and PIK3R2. The other eleven causative genes were PIK3CA, NEDD4L, COL4A1, COL4A2, GPSM2, GRIN2B, WDR62, TUBB3, TUBB2B, ACTG1 and FH. A genetic cause was more likely to be identified in the presence of an abnormal head size or additional brain malformations suggestive of a tubulinopathy, such as dysmorphic basal ganglia. A gene panel test provides greater sequencing depth and sensitivity for mosaic variants than whole exome or genome sequencing but is limited to the genes included, pote

Published
2021

8. Defining the phenotypical spectrum associated with variants in TUBB2A

Author

Brock, S, Vanderhasselt, T, Vermaning, S, Keymolen, K, Regal, L, Romaniello, R, Wieczorek, D, Storm, TM, Schaeferhoff, K, Hehr, U, Kuechler, A, Kraegeloh-Mann, I, Haack, TB, Kasteleijn, E, Schot, R, Mancini, GMS, Webster, R, Mohammad, S, Leventer, RJ, Mirzaa, G, Dobyns, WB, Bahi-Buisson, N, Meuwissen, M, Jansen, AC, Stouffs, K, Brock, S, Vanderhasselt, T, Vermaning, S, Keymolen, K, Regal, L, Romaniello, R, Wieczorek, D, Storm, TM, Schaeferhoff, K, Hehr, U, Kuechler, A, Kraegeloh-Mann, I, Haack, TB, Kasteleijn, E, Schot, R, Mancini, GMS, Webster, R, Mohammad, S, Leventer, RJ, Mirzaa, G, Dobyns, WB, Bahi-Buisson, N, Meuwissen, M, Jansen, AC, and Stouffs, K

Abstract

BACKGROUND: Variants in genes belonging to the tubulin superfamily account for a heterogeneous spectrum of brain malformations referred to as tubulinopathies. Variants in TUBB2A have been reported in 10 patients with a broad spectrum of brain imaging features, ranging from a normal cortex to polymicrogyria, while one patient has been reported with progressive atrophy of the cerebellar vermis. METHODS: In order to further refine the phenotypical spectrum associated with TUBB2A, clinical and imaging features of 12 patients with pathogenic TUBB2A variants, recruited via the international network of the authors, were reviewed. RESULTS: We report 12 patients with eight novel and one recurrent variants spread throughout the TUBB2A gene but encoding for amino acids clustering at the protein surface. Eleven patients (91.7%) developed seizures in early life. All patients suffered from intellectual disability, and 11 patients had severe motor developmental delay, with 4 patients (36.4 %) being non-ambulatory. The cerebral cortex was normal in five individuals and showed dysgyria of variable severity in seven patients. Associated brain malformations were less frequent in TUBB2A patients compared with other tubulinopathies. None of the patients had progressive cerebellar atrophy. CONCLUSION: The imaging phenotype associated with pathogenic variants in TUBB2A is highly variable, ranging from a normal cortex to extensive dysgyria with associated brain malformations. For recurrent variants, no clear genotype-phenotype correlations could be established, suggesting the role of additional modifiers.

Published
2021

10. International consensus recommendations on the diagnostic work-up for malformations of cortical development

Author

Oegema, R. (Renske), Barakat, T.S. (Tahsin Stefan), Wilke, M. (Martina), Stouffs, K. (Katrien), Amrom, D. (Dina), Aronica, E.M.A. (Eleonora), Bahi-Buisson, N. (Nadia), Conti, V. (Valerio), Fry, A.E. (Andrew E.), Geis, T. (Tobias), Andres, D.G. (David Gomez), Parrini, E. (Elena), Pogledic, I. (Ivana), Said, E. (Edith), Soler, D. (Doriette), Valor, L.M. (Luis M.), Zaki, M.S. (Maha), Mirzaa, G.M. (Ghayda), Dobyns, W.B. (William), Reiner, O. (Orly), Guerrini, R. (Renzo), Pilz, D.T. (Daniela), Hehr, U. (Ute), Leventer, R.J. (Richard), Jansen, A.C. (Anna C.), Mancini, G.M.S. (Grazia), Di Donato, N. (Nataliya), Oegema, R. (Renske), Barakat, T.S. (Tahsin Stefan), Wilke, M. (Martina), Stouffs, K. (Katrien), Amrom, D. (Dina), Aronica, E.M.A. (Eleonora), Bahi-Buisson, N. (Nadia), Conti, V. (Valerio), Fry, A.E. (Andrew E.), Geis, T. (Tobias), Andres, D.G. (David Gomez), Parrini, E. (Elena), Pogledic, I. (Ivana), Said, E. (Edith), Soler, D. (Doriette), Valor, L.M. (Luis M.), Zaki, M.S. (Maha), Mirzaa, G.M. (Ghayda), Dobyns, W.B. (William), Reiner, O. (Orly), Guerrini, R. (Renzo), Pilz, D.T. (Daniela), Hehr, U. (Ute), Leventer, R.J. (Richard), Jansen, A.C. (Anna C.), Mancini, G.M.S. (Grazia), and Di Donato, N. (Nataliya)

Abstract

Malformations of cortical development (MCDs) are neurodevelopmental disorders that result from abnormal development of the cerebral cortex in utero. MCDs place a substantial burden on affected individuals, their families and societies worldwide, as these individuals can experience lifelong drug-resistant epilepsy, cerebral palsy, feeding difficulties, intellectual disability and other neurological and behavioural anomalies. The diagnostic pathway for MCDs is complex owing to wide variations in presentation and aetiology, thereby hampering timely and adequate management. In this article, the international MCD network Neuro-MIG provides consensus recommendations to aid both expert and non-expert clinicians in the diagnostic work-up of MCDs with the aim of improving patient management worldwide. We reviewed the literature on clinical presentation, aetiology and diagnostic approaches for the main MCD subtypes and collected data on current practices and recommendations from clinicians and diagnostic laboratories within Neuro-MIG. We reached consensus by 42 professionals from 20 countries, using expert discussions and a Delphi consensus process. We present a diagnostic workflow that can be applied to any individual with MCD and a comprehensive list of MCD-related genes with their associated phenotypes. The workflow is designed to maximize the diagnostic yield and increase the number of patients receiving personalized care and counselling on prognosis and recurrence risk.

Published
2020
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11. Defining the phenotypical spectrum associated with variants in TUBB2A

Author

Brock, S. (Stefanie), Vanderhasselt, T. (Tim), Vermaning, S. (Sietske), Keymolen, K. (Kathelijn), Régal, L. (Luc), Romaniello, R. (Romina), Wieczorek, D. (Dagmar), Storm, T.M. (Tim Matthias), Schaeferhoff, K. (Karin), Hehr, U. (Ute), Kuechler, A. (Alma), Krägeloh-Mann, I. (Ingeborg), Haack, T.B. (Tobias B.), Kasteleijn, E. (Esmee), Schot, R. (Rachel), Mancini, G.M.S. (Grazia), Webster, R. (Richard), Mohammad, S. (Shekeeb), Leventer, R.J. (Richard), Mirzaa, G.M. (Ghayda), Dobyns, W.B. (William), Bahi-Buisson, N. (Nadia), Meuwissen, M.E.C. (Marije), Jansen, A.C. (Anna C.), Stouffs, K. (Katrien), Brock, S. (Stefanie), Vanderhasselt, T. (Tim), Vermaning, S. (Sietske), Keymolen, K. (Kathelijn), Régal, L. (Luc), Romaniello, R. (Romina), Wieczorek, D. (Dagmar), Storm, T.M. (Tim Matthias), Schaeferhoff, K. (Karin), Hehr, U. (Ute), Kuechler, A. (Alma), Krägeloh-Mann, I. (Ingeborg), Haack, T.B. (Tobias B.), Kasteleijn, E. (Esmee), Schot, R. (Rachel), Mancini, G.M.S. (Grazia), Webster, R. (Richard), Mohammad, S. (Shekeeb), Leventer, R.J. (Richard), Mirzaa, G.M. (Ghayda), Dobyns, W.B. (William), Bahi-Buisson, N. (Nadia), Meuwissen, M.E.C. (Marije), Jansen, A.C. (Anna C.), and Stouffs, K. (Katrien)

Abstract

BACKGROUND: Variants in genes belonging to the tubulin superfamily account for a heterogeneous spectrum of brain malformations referred to as tubulinopathies. Variants in TUBB2A have been reported in 10 patients with a broad spectrum of brain imaging features, ranging from a normal cortex to polymicrogyria, while one patient has been reported with progressive atrophy of the cerebellar vermis. METHODS: In order to further refine the phenotypical spectrum associated with TUBB2A, clinical and imaging features of 12 patients with pathogenic TUBB2A variants, recruited via the international network of the authors, were reviewed. RESULTS: We report 12 patients with eight novel and one recurrent variants spread throughout the TUBB2A gene but encoding for amino acids clustering at the protein surface. Eleven patients (91.7%) developed seizures in early life. All patients suffered from intellectual disability, and 11 patients had severe motor developmental delay, with 4 patients (36.4 %) being non-ambulatory. The cerebral cortex was normal in five individuals and showed dysgyria of variable severity in seven patients. Associated brain malformations were less frequent in TUBB2A patients compared with other tubulinopathies. None of the patients had progressive cerebellar atrophy. CONCLUSION: The imaging phenotype associated with pathogenic v

Published
2020
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12. International consensus recommendations on the diagnostic work-up for malformations of cortical development

Author

Oegema, R, Barakat, TS, Wilke, M, Stouffs, K, Amrom, D, Aronica, E, Bahi-Buisson, N, Conti, V, Fry, AE, Geis, T, Gomez Andres, D, Parrini, E, Pogledic, I, Said, E, Soler, D, Valor, LM, Zaki, MS, Mirzaa, G, Dobyns, WB, Reiner, O, Guerrini, R, Pilz, DT, Hehr, U, Leventer, RJ, Jansen, AC, Mancini, GMS, Di Donato, N, Oegema, R, Barakat, TS, Wilke, M, Stouffs, K, Amrom, D, Aronica, E, Bahi-Buisson, N, Conti, V, Fry, AE, Geis, T, Gomez Andres, D, Parrini, E, Pogledic, I, Said, E, Soler, D, Valor, LM, Zaki, MS, Mirzaa, G, Dobyns, WB, Reiner, O, Guerrini, R, Pilz, DT, Hehr, U, Leventer, RJ, Jansen, AC, Mancini, GMS, and Di Donato, N

Abstract

Malformations of cortical development (MCDs) are neurodevelopmental disorders that result from abnormal development of the cerebral cortex in utero. MCDs place a substantial burden on affected individuals, their families and societies worldwide, as these individuals can experience lifelong drug-resistant epilepsy, cerebral palsy, feeding difficulties, intellectual disability and other neurological and behavioural anomalies. The diagnostic pathway for MCDs is complex owing to wide variations in presentation and aetiology, thereby hampering timely and adequate management. In this article, the international MCD network Neuro-MIG provides consensus recommendations to aid both expert and non-expert clinicians in the diagnostic work-up of MCDs with the aim of improving patient management worldwide. We reviewed the literature on clinical presentation, aetiology and diagnostic approaches for the main MCD subtypes and collected data on current practices and recommendations from clinicians and diagnostic laboratories within Neuro-MIG. We reached consensus by 42 professionals from 20 countries, using expert discussions and a Delphi consensus process. We present a diagnostic workflow that can be applied to any individual with MCD and a comprehensive list of MCD-related genes with their associated phenotypes. The workflow is designed to maximize the diagnostic yield and increase the number of patients receiving personalized care and counselling on prognosis and recurrence risk.

Published
2020

14. The landscape of epilepsy-related GATOR1 variants (vol 21, pg 398, 2019)

Author

Baldassari, S., Picard, F., Verbeek, N.E., Kempen, M. van, Brilstra, E.H., Lesca, G., Conti, V., Guerrini, R., Bisulli, F., Licchetta, L., Pippucci, T., Tinuper, P., Hirsch, E., Saint Martin, A. de, Chelly, J., Rudolf, G., Chipaux, M., Ferrand-Sorbets, S., Dorfmuller, G., Sisodiya, S., Balestrini, S., Schoeler, N., Hernandez-Hernandez, L., Krithika, S., Oegema, R., Hagebeuk, E., Gunning, B., Deckers, C., Berghuis, B., Wegner, I., Niks, E.H., Jansen, F.E., Braun, K., Jong, D. de, Rubboli, G., Talvik, I., Sander, V., Uldall, P., Jacquemont, M.L., Nava, C., Leguern, E., Julia, S., Gambardella, A., d'Orsi, G., Crichiutti, G., Faivre, L., Darmency, V., Benova, B., Krsek, P., Biraben, A., Lebre, A.S., Jennesson, M., Sattar, S., Marchal, C., Nordli, D.R., Lindstrom, K., Striano, P., Lomax, L.B., Kiss, C., Bartolomei, F., Lepine, A.F., Schoonjans, A.S., Stouffs, K., Jansen, A., Panagiotakaki, E., Ricard-Mousnier, B., Thevenon, J., Bellescize, J. de, Catenoix, H., Dorn, T., Zenker, M., Muller-Schluter, K., Brandt, C., Krey, I., Polster, T., Wolff, M., Balci, M., Rostasy, K., Achaz, G., Zacher, P., Becher, T., Cloppenborg, T., Yuskaitis, C.J., Weckhuysen, S., Poduri, A., Lemke, J.R., Moller, R.S., and Baulac, S.

Published
2019

15. Germ line gene panel analysis in a HBOC population

Author

Seneca, S., De Grève, J., Bonduelle, M., Joris, S., Keymolen, K., De Rademaeker, M., Stouffs, K., Gheldof, A., Clinical sciences, Medical Genetics, Reproduction and Genetics, Laboratory of Molecular and Medical Oncology, Vriendenkring VUB, and Medical Oncology

Published
2019

17. Heterogeneous clinical phenotypes and cerebral malformations reflected by rotatin cellular dynamics

Author

Vandervore, L.V., Schot, R. (Rachel), Kasteleijn, E., Oegema, R., Stouffs, K., Gheldof, A, Grochowska, M.M. (Martyna), Sterre, M.L.T. (Marianne) van der, van Unen, L.M.A., Wilke, M. (Martina), Elfferich, P.C., Spek, P.J. (Peter) van der, Heijsman, D. (Daphne), Grandone, A., Demmers, J.A.A. (Jeroen), Dekkers, D.H. (Dick), Slotman, J.A., Kremers, G.J. (Gert-Jan), Schaaf, G.J., Masius, R.G., Essen, J.A. (Anthonie) van, Rump, P, Haeringen, A. (Arie) van, Peeters, E. (Ellen), Altunoglu, U. (Umut), Kalayci, T., Poot, R.A. (Raymond), Dobyns, W.B. (William), Bahi-Buisson, N. (Nadia), Verheijen, F.W. (Frans), Jansen, AC, Mancini, G.M.S. (Grazia), Vandervore, L.V., Schot, R. (Rachel), Kasteleijn, E., Oegema, R., Stouffs, K., Gheldof, A, Grochowska, M.M. (Martyna), Sterre, M.L.T. (Marianne) van der, van Unen, L.M.A., Wilke, M. (Martina), Elfferich, P.C., Spek, P.J. (Peter) van der, Heijsman, D. (Daphne), Grandone, A., Demmers, J.A.A. (Jeroen), Dekkers, D.H. (Dick), Slotman, J.A., Kremers, G.J. (Gert-Jan), Schaaf, G.J., Masius, R.G., Essen, J.A. (Anthonie) van, Rump, P, Haeringen, A. (Arie) van, Peeters, E. (Ellen), Altunoglu, U. (Umut), Kalayci, T., Poot, R.A. (Raymond), Dobyns, W.B. (William), Bahi-Buisson, N. (Nadia), Verheijen, F.W. (Frans), Jansen, AC, and Mancini, G.M.S. (Grazia)

Published
2019
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18. Heterogeneous clinical phenotypes and cerebral malformations reflected by rotatin cellular dynamics

Author

Vandervore, Laura, Schot, Rachel, Kasteleijn, Esmee, Oegema, Renske, Stouffs, K, Gheldof, A, Grochowska, Martyna, Sterre, Marianne, Unen, Leontine, Wilke, Martina, Elfferich, Peter, van der Spek, Peter, Heijsman, Daphne, Grandone, A, Demmers, Jeroen, Dekkers, Dick, Slotman, Johan, Kremers, Gert-Jan, Schaaf, Gerben, Masius, Roy, van Essen, AJ, Rump, P, van Haeringen, A, Peeters, E, Altunoglu, U, Kalayci, T, Poot, Raymond, Dobyns, WB, Bahi-Buisson, N, Verheijen, Frans, Jansen, AC (An), Verheijen - Mancini, Grazia, Vandervore, Laura, Schot, Rachel, Kasteleijn, Esmee, Oegema, Renske, Stouffs, K, Gheldof, A, Grochowska, Martyna, Sterre, Marianne, Unen, Leontine, Wilke, Martina, Elfferich, Peter, van der Spek, Peter, Heijsman, Daphne, Grandone, A, Demmers, Jeroen, Dekkers, Dick, Slotman, Johan, Kremers, Gert-Jan, Schaaf, Gerben, Masius, Roy, van Essen, AJ, Rump, P, van Haeringen, A, Peeters, E, Altunoglu, U, Kalayci, T, Poot, Raymond, Dobyns, WB, Bahi-Buisson, N, Verheijen, Frans, Jansen, AC (An), and Verheijen - Mancini, Grazia

Published
2019

21. A new mutation in the calcium-sensing receptor gene causing hypocalcaemia: case report of a father and two sons

Author

Schoutteten, M K, Bravenboer, B, Seneca, S, Stouffs, K, Velkeniers, B, MUMC+: MA Med Staf Artsass Interne Geneeskunde (9), RS: FHML non-thematic output, Clinical sciences, Reproduction and Genetics, and Faculty of Medicine and Pharmacy

Subjects
CA2+-SENSING RECEPTOR, calcium-sensing receptor, Internal Medicine, GAIN, Autosomal dominant hypocalcemia, hypocalcemia, AUTOSOMAL-DOMINANT HYPOCALCEMIA, FAMILY
Abstract

Background: Regulation of calcium is mediated by parathyroid hormone (PTH) and 1.25-dihydroxyvitamine D3. The calcium-sensing receptor (CaSR) regulates PTH release by a negative feedback system. Gain-of-function mutations in the CaSR gene reset the calcium-PTH axis, leading to hypocalcaemia. Patients and methods: We analysed a family with hypocalcaemia. The proband was a 47-year-old man (index, patient I-1), who presented with paraesthesias in both limbs. He has two sons (patient II1 and II2). The probands' lab results showed: serum calcium of 1.95 mmol/l, albumin 41 g/l, phosphate 0.81 mmol/l and PTH 6.6 ng/l (normal 15-65 ng/l). Based on this analysis, we suspected a hereditary form of hypocalcaemia and performed genetic testing by polymerase chain reaction and Sanger sequencing of the coding regions and intron boundaries of the CaSR gene. Genetic analysis revealed a new heterozygous mutation: c. 2195A> G, p.(Asn732Ser) in exon 7. The lab results of patient II1 showed: serum calcium of 1.93 mmol/l, phosphate 1.31 mmol/l, albumin 41 g/l, and PTH 24.3 ng/l. His genotype revealed the same activating mutation and, like his father, he also lost his scalp hair at an early adolescent age. Patient II2 is asymptomatic, and has neither biochemical abnormalities, nor the familial CaSR gene mutation. He still has all his scalp hair. Conclusions: 1) The c. 2195A> G, p.(Asn732Ser) mutation in exon 7 of the CaSR gene leads to hypocalcaemia, and has not been reported before in the medical literature. 2) Possibly, this mutation is linked to premature baldness.

Published
2017

22. Expanding the clinical spectrum of biallelic ZNF335 variants

Author

Stouffs, K., primary, Stergachis, A.B., additional, Vanderhasselt, T., additional, Dica, A., additional, Janssens, S., additional, Vandervore, L., additional, Gheldof, A., additional, Bodamer, O., additional, Keymolen, K., additional, Seneca, S., additional, Liebaers, I., additional, Jayaraman, D., additional, Hill, H.E., additional, Partlow, J.N., additional, Walsh, C.A., additional, and Jansen, A.C., additional

Published
2018
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23. Early Onset Epileptic Encephalopathy: Genetic Analysis and Further Delineation of Genotype-phenotype Correlation

Author

Scalais, E, de Meurichy, A, Amrom, A, De Meirleir, L, Lederer, D, May, Patrick, Jansens, A, Stouffs, K, Caberg, J, Löfgren, A, Van Houwe, J, Stambacher H, Van Rijckevorsel, K, Scalais, E, de Meurichy, A, Amrom, A, De Meirleir, L, Lederer, D, May, Patrick, Jansens, A, Stouffs, K, Caberg, J, Löfgren, A, Van Houwe, J, Stambacher H, and Van Rijckevorsel, K

Abstract

Objective: Early onset epileptic encephalopathy (EOEE)remains an important diagnostic and therapeutic challenge.The objective was to perform genetic analysis in patientswith EOEE and to further delineate the genotype-phenotype correlation in patients with EOEE. Methods: We recruited 15 refractory epileptic patientswith epileptic onset before age 12 months. All patients had metabolic screening, electroencephalogram, magnetic reso-nance imaging and molecular analysis (comparative genomic hybridization, gene sequencing, next generation sequencing and or whole exome sequencing. Results: Dravet syndrome (DS) with SCN1A mutations was found in six patients with refractory epilepsy (RE) andmoderate to severe developmental delay (DD). Two patients diagnosed (KCNT1, SCN) with malignant migrating partialseizure (MMPS) had RE, severe DD, autistic behavior. The latter had movement disorders (video) (choreoathetosis, ballis-mus) with a worse outcome than the patients with DS phe-notype with SCN1A mutations. Severe DD and RE wasfound in patients with SCN8A, SLC13A5, SMC1A, orHCFC1 and ATRX mutations. Patient with SCN2A mutation had severe DD. A better outcome was observed in the patient with CDKL5 mutations in the catalytic domain in compari-son with the patient with a deletion in Xp22.13 including CDKL5. The patient with SMC1A mutations disclosed the Cornelia de Lange syndrome phenotype (Table 1). TRXmutations and deletions in 2q24.3 and Xp22.13. In SLC13A5 and SCN2A mutations, epileptic onset occurred atthe earliest age.

Published
2017

26. Detailed molecular characterization of a novel IDS exonic mutation associated with multiple pseudoexon activation

Author

Grodecká, L., primary, Kováčová, T., additional, Kramárek, M., additional, Seneca, S., additional, Stouffs, K., additional, De Laet, C., additional, Majer, F., additional, Kršjaková, T., additional, Hujová, P., additional, Hrnčířová, K., additional, Souček, P., additional, Lissens, W., additional, Buratti, E., additional, and Freiberger, Tomas, additional

Published
2016
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36. Heterogeneous clinical phenotypes and cerebral malformations reflected by rotatin cellular dynamics

Author

Marianne L. T. van der Sterre, Rachel Schot, Peter J. van der Spek, Daphne Heijsman, Leontine van Unen, Gert-Jan Kremers, Martyna M. Grochowska, Grazia M.S. Mancini, Laura Vandervore, Roy Masius, Gerben J. Schaaf, Martina Wilke, Nadia Bahi-Buisson, Anna Grandone, Renske Oegema, Anna Jansen, Patrick Rump, Arie van Haeringen, Tugba Kalayci, Frans W. Verheijen, Katrien Stouffs, Peter Elfferich, Els A. J. Peeters, Esmee Kasteleijn, Anton J. van Essen, Umut Altunoglu, Alexander Gheldof, Dick H. W. Dekkers, Johan A. Slotman, Jeroen Demmers, Raymond A. Poot, WB Dobyns, Vandervore, L. V., Schot, R., Kasteleijn, E., Oegema, R., Stouffs, K., Gheldof, A., Grochowska, M. M., Van Der Sterre, M. L. T., Van Unen, L. M. A., Wilke, M., Elfferich, P., Van Der Spek, P. J., Heijsman, D., Grandone, A., Demmers, J. A. A., Dekkers, D. H. W., Slotman, J. A., Kremers, G. -J., Schaaf, G. J., Masius, R. G., Van Essen, A. J., Rump, P., Van Haeringen, A., Peeters, E., Altunoglu, U., Kalayci, T., Poot, R. A., Dobyns, W. B., Bahi-Buisson, N., Verheijen, F. W., Jansen, A. C., Mancini, G. M. S., Clinical Genetics, Pathology, Molecular Genetics, Cell biology, Clinical sciences, Faculty of Medicine and Pharmacy, Medical Genetics, Reproduction and Genetics, Faculty of Psychology and Educational Sciences, Public Health Sciences, Mental Health and Wellbeing research group, Neurogenetics, and Pediatrics

Subjects
0301 basic medicine, Microcephaly, MIGRATION, MYH10, Clinical Neurology, Lissencephaly, PRIMARY CILIA, Cell Cycle Proteins, Biology, medicine.disease_cause, NONMUSCLE MYOSIN-II, 03 medical and health sciences, 0302 clinical medicine, Ciliogenesis, medicine, Polymicrogyria, Basal body, Humans, mitosis, Mutation, mitosi, DEFECTS, Original Articles, medicine.disease, POINT MUTATION, Cell biology, 030104 developmental biology, Phenotype, Centrosome, Neurology (clinical), centrosome amplification, Carrier Proteins, Multipolar spindles, RTTN, 030217 neurology & neurosurgery
Abstract

See Uzquiano and Francis (doi:10.1093/brain/awz048) for a scientific commentary on this article. Mutations in RTTN, which encodes Rotatin, give rise to various brain malformations. Vandervore et al. reveal mitotic failure, aneuploidy, apoptosis and defective ciliogenesis in patient cells. Rotatin binds to myosin subunits in the leading edge of human neurons, which may explain the proliferation and migration defects observed., Recessive mutations in RTTN, encoding the protein rotatin, were originally identified as cause of polymicrogyria, a cortical malformation. With time, a wide variety of other brain malformations has been ascribed to RTTN mutations, including primary microcephaly. Rotatin is a centrosomal protein possibly involved in centriolar elongation and ciliogenesis. However, the function of rotatin in brain development is largely unknown and the molecular disease mechanism underlying cortical malformations has not yet been elucidated. We performed both clinical and cell biological studies, aimed at clarifying rotatin function and pathogenesis. Review of the 23 published and five unpublished clinical cases and genomic mutations, including the effect of novel deep intronic pathogenic mutations on RTTN transcripts, allowed us to extrapolate the core phenotype, consisting of intellectual disability, short stature, microcephaly, lissencephaly, periventricular heterotopia, polymicrogyria and other malformations. We show that the severity of the phenotype is related to residual function of the protein, not only the level of mRNA expression. Skin fibroblasts from eight affected individuals were studied by high resolution immunomicroscopy and flow cytometry, in parallel with in vitro expression of RTTN in HEK293T cells. We demonstrate that rotatin regulates different phases of the cell cycle and is mislocalized in affected individuals. Mutant cells showed consistent and severe mitotic failure with centrosome amplification and multipolar spindle formation, leading to aneuploidy and apoptosis, which could relate to depletion of neuronal progenitors often observed in microcephaly. We confirmed the role of rotatin in functional and structural maintenance of primary cilia and determined that the protein localized not only to the basal body, but also to the axoneme, proving the functional interconnectivity between ciliogenesis and cell cycle progression. Proteomics analysis of both native and exogenous rotatin uncovered that rotatin interacts with the neuronal (non-muscle) myosin heavy chain subunits, motors of nucleokinesis during neuronal migration, and in human induced pluripotent stem cell-derived bipolar mature neurons rotatin localizes at the centrosome in the leading edge. This illustrates the role of rotatin in neuronal migration. These different functions of rotatin explain why RTTN mutations can lead to heterogeneous cerebral malformations, both related to proliferation and migration defects.

Published
2019

37. De novo missense variants in LMBRD2 are associated with developmental and motor delays, brain structure abnormalities and dysmorphic features

Author

Benjamin Navet, Renee Perrier, Kiyotaka Tomiwa, Alexander Pepler, Hui Xi, Adele Schneider, Xiao Mao, Ryan J. Taft, Paul Rollier, Alban Ziegler, Roberto Colombo, Noriko Miyake, Emmanuel Scalais, Katrien Stouffs, Estelle Colin, Denise L. Perry, Adeline Vanderver, Nobuhiko Okamoto, Magalie Barth, Li Shu, Elizabeth Wohler, Louise Amlie-Wolf, Hainan Zhang, Alessandro Serretti, Naomichi Matsumoto, Dominique Bonneau, Hua Wang, Omar Sherbini, Alka Malhotra, Nara Sobreira, Alessandra Ferrarini, Malhotra A., Ziegler A., Shu L., Perrier R., Amlie-Wolf L., Wohler E., Lygia De MacEna Sobreira N., Colin E., Vanderver A., Sherbini O., Stouffs K., Scalais E., Serretti A., Barth M., Navet B., Rollier P., Xi H., Wang H., Zhang H., Perry D.L., Ferrarini A., Colombo R., Pepler A., Schneider A., Tomiwa K., Okamoto N., Matsumoto N., Miyake N., Taft R., Mao X., Bonneau D., Service de génétique [Angers], Université d'Angers (UA)-Centre Hospitalier Universitaire d'Angers (CHU Angers), PRES Université Nantes Angers Le Mans (UNAM)-PRES Université Nantes Angers Le Mans (UNAM), Physiopathologie Cardiovasculaire et Mitochondriale (MITOVASC), Université d'Angers (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Hunan Agricultural University [Changsha], Department of Neurology, Children's National Medical Center, Universitair Ziekenhuis Brussel, Centre Hospitalier de Luxembourg [Luxembourg] (CHL), Institute of Psychiatry, Alma Mater Studiorum Università di Bologna [Bologna] (UNIBO), Réseau Maladies Métaboliques, Hôpitaux Universitaires du Grand Ouest, Immunobiology of Human αβ and γδ T Cells and Immunotherapeutic Applications (CRCINA-ÉQUIPE 1), Centre de Recherche en Cancérologie et Immunologie Nantes-Angers (CRCINA), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Nantes - UFR de Médecine et des Techniques Médicales (UFR MEDECINE), Université de Nantes (UN)-Université de Nantes (UN)-Centre hospitalier universitaire de Nantes (CHU Nantes)-Centre National de la Recherche Scientifique (CNRS)-Université d'Angers (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Nantes - UFR de Médecine et des Techniques Médicales (UFR MEDECINE), Université de Nantes (UN)-Université de Nantes (UN)-Centre hospitalier universitaire de Nantes (CHU Nantes)-Centre National de la Recherche Scientifique (CNRS)-Université d'Angers (UA), CHU Pontchaillou [Rennes], Shandong University, Nanjing University of Science and Technology (NJUST), Service de génétique médicale, Centre Hospitalier Universitaire Vaudois [Lausanne] (CHUV), Università degli Studi di Brescia [Brescia], Genetics Division, Einstein Medical Center, Gifu University Graduate School of Medicine, Yokohama City University School of Medecine (YCUSM), Yokohama University School of Medecine, Institute for Molecular Bioscience, University of Queensland [Brisbane], Clinical sciences, Medical Genetics, Reproduction and Genetics, and Faculty of Law and Criminology

Subjects
0301 basic medicine, gain of function mutation, Microcephaly, [SDV]Life Sciences [q-bio], Population, Biology, DNA sequencing, 03 medical and health sciences, 0302 clinical medicine, Neurodevelopmental disorder, Genetics, medicine, Missense mutation, education, Exome, Allele frequency, Genetics (clinical), Exome sequencing, ComputingMilieux_MISCELLANEOUS, education.field_of_study, mutation, missense, medicine.disease, 030104 developmental biology, genetics, medical, 030217 neurology & neurosurgery
Abstract

ObjectiveTo determine the potential disease association between variants in LMBRD2 and complex multisystem neurological and developmental delay phenotypes.MethodsHere we describe a series of de novo missense variants in LMBRD2 in 10 unrelated individuals with overlapping features. Exome sequencing or genome sequencing was performed on all individuals, and the cohort was assembled through GeneMatcher.ResultsLMBRD2 encodes an evolutionary ancient and widely expressed transmembrane protein with no known disease association, although two paralogues are involved in developmental and metabolic disorders. Exome or genome sequencing revealed rare de novo LMBRD2 missense variants in 10 individuals with developmental delay, intellectual disability, thin corpus callosum, microcephaly and seizures. We identified five unique variants and two recurrent variants, c.1448G>A (p.Arg483His) in three cases and c.367T>C (p.Trp123Arg) in two cases. All variants are absent from population allele frequency databases, and most are predicted to be deleterious by multiple in silico damage-prediction algorithms.ConclusionThese findings indicate that rare de novo variants in LMBRD2 can lead to a previously unrecognised early-onset neurodevelopmental disorder. Further investigation of individuals harbouring LMBRD2 variants may lead to a better understanding of the function of this ubiquitously expressed gene.

Published
2021

38. The landscape of epilepsy-related GATOR1 variants

Author

Johannes R. Lemke, Pia Zacher, Thomas Dorn, Laura Hernandez-Hernandez, Natasha E. Schoeler, Stéphanie Baulac, Sara Baldassari, Anne de Saint Martin, Eleni Panagiotakaki, Anne Fabienne Lepine, Markus Wolff, Arnaud Biraben, Renske Oegema, Edouard Hirsch, Anna Jansen, Charles Deckers, Nienke E. Verbeek, Fabienne Picard, Georg Dorfmüller, Sarah Ferrand-Sorbets, Barbora Benova, Francesca Bisulli, Inga Talvik, Kristin Lindstrom, Tilman Polster, Douglas R. Nordli, Tommaso Pippucci, Eva H. Brilstra, Shifteh Sattar, Erik H. Niks, Marie Line Jacquemont, Kees P.J. Braun, Karen Müller-Schlüter, Sanjay M. Sisodiya, Sarah Weckhuysen, Lysa Boissé Lomax, Sophie Julia, Brigitte Ricard-Mousnier, Mathilde Chipaux, Laura Licchetta, Gaetan Lesca, Bianca Berghuis, S. Krithika, Jamel Chelly, Renzo Guerrini, Hélène Catenoix, Annapurna Poduri, Melanie Jennesson, Pasquale Striano, Rikke S. Møller, Antonio Gambardella, Guillaume Achaz, Peter Uldall, Fabrice Bartolomei, Giuseppe d'Orsi, Laurence Faivre, Floor E. Jansen, An Sofie Schoonjans, Kevin Rostasy, Thomas Becher, Pavel Krsek, Julien Thevenon, Marjan J. A. van Kempen, Guido Rubboli, Cécile Marchal, Meral Balci, Boudewijn Gunning, Ilona Krey, Julitta de Bellescize, Veronique Darmency, Christopher J. Yuskaitis, Daniëlle de Jong, Giovanni Crichiutti, Paolo Tinuper, Katrien Stouffs, Valentin Sander, Anne-Sophie Lebre, Thomas Cloppenborg, Valerio Conti, Gabrielle Rudolf, Courtney Kiss, Eveline Hagebeuk, Caroline Nava, Eric LeGuern, Ilse Wegner, Christian Brandt, Martin Zenker, Simona Balestrini, Picard, Fabienne, Baldassari S., Picard F., Verbeek N.E., van Kempen M., Brilstra E.H., Lesca G., Conti V., Guerrini R., Bisulli F., Licchetta L., Pippucci T., Tinuper P., Hirsch E., de Saint Martin A., Chelly J., Rudolf G., Chipaux M., Ferrand-Sorbets S., Dorfmuller G., Sisodiya S., Balestrini S., Schoeler N., Hernandez-Hernandez L., Krithika S., Oegema R., Hagebeuk E., Gunning B., Deckers C., Berghuis B., Wegner I., Niks E., Jansen F.E., Braun K., de Jong D., Rubboli G., Talvik I., Sander V., Uldall P., Jacquemont M.-L., Nava C., Leguern E., Julia S., Gambardella A., d'Orsi G., Crichiutti G., Faivre L., Darmency V., Benova B., Krsek P., Biraben A., Lebre A.-S., Jennesson M., Sattar S., Marchal C., Nordli D.R., Lindstrom K., Striano P., Lomax L.B., Kiss C., Bartolomei F., Lepine A.F., Schoonjans A.-S., Stouffs K., Jansen A., Panagiotakaki E., Ricard-Mousnier B., Thevenon J., de Bellescize J., Catenoix H., Dorn T., Zenker M., Muller-Schluter K., Brandt C., Krey I., Polster T., Wolff M., Balci M., Rostasy K., Achaz G., Zacher P., Becher T., Cloppenborg T., Yuskaitis C.J., Weckhuysen S., Poduri A., Lemke J.R., Moller R.S., Baulac S., Institut du Cerveau et de la Moëlle Epinière = Brain and Spine Institute (ICM), Institut National de la Santé et de la Recherche Médicale (INSERM)-CHU Pitié-Salpêtrière [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), CHU Pitié-Salpêtrière [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP), Department of Genetics [Utrecht, the Netherlands], University Medical Center [Utrecht], Service de Génétique [HCL Groupement Hospitalier Est], Groupement Hospitalier Lyon-Est (GHE), Hospices Civils de Lyon (HCL)-Hospices Civils de Lyon (HCL), Centre de recherche en neurosciences de Lyon - Lyon Neuroscience Research Center (CRNL), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet [Saint-Étienne] (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Children's Hospital A. Meyer, Service de Neurologie [Strasbourg], CHU Strasbourg-Hopital Civil, Institut de Génétique et de Biologie Moléculaire et Cellulaire (IGBMC), Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Department of Clinical and Experimental Epilepsy, University College of London [London] (UCL), Academic Center for Epileptology Kempenhaeghe & Maastricht UMC+ [Heeze], Danish Epilepsy Centre, Denmark and Aarhus University, Aarhus, Centre Hospitalier Universitaire de La Réunion (CHU La Réunion), Service de Génétique Cytogénétique et Embryologie [CHU Pitié-Salpêtrière], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP), Service de génétique médicale [Toulouse], CHU Toulouse [Toulouse], Centre de génétique - Centre de référence des maladies rares, anomalies du développement et syndromes malformatifs (CHU de Dijon), Centre Hospitalier Universitaire de Dijon - Hôpital François Mitterrand (CHU Dijon), FHU TRANSLAD (CHU de Dijon), Université de Bourgogne (UB), Service de Neurophysiologie Clinique (CHU Dijon), CHU Pontchaillou [Rennes], Service de pédiatrie spécialisée et médecine infantile (neurologie, pneumologie, maladies héréditaires du métabolisme) [Hôpital de la Timone - APHM], Hôpital de la Timone [CHU - APHM] (TIMONE), Epilepsie, sommeil et explorations fonctionnelles neuropédiatriques, Hospices Civils de Lyon (HCL)-Hôpital Femme Mère Enfant, Equipe GAD (LNC - U1231), Lipides - Nutrition - Cancer [Dijon - U1231] (LNC), Université de Bourgogne (UB)-Institut National de la Santé et de la Recherche Médicale (INSERM)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement-Université de Bourgogne (UB)-Institut National de la Santé et de la Recherche Médicale (INSERM)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement, Université Bourgogne Franche-Comté [COMUE] (UBFC), Département d'Epilepsie, Sommeil et Neurophysiologie Pédiatrique [HCL, Lyon], Hospices Civils de Lyon (HCL), Institute of Human Genetics, University Hospital Magdeburg, Institut de Systématique, Evolution, Biodiversité (ISYEB ), Muséum national d'Histoire naturelle (MNHN)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université des Antilles (UA), Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU), Groupement hospitalier Lyon-Est, Centre de recherche en neurosciences de Lyon (CRNL), Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU), and CHU Toulouse [Toulouse]-Hôpital Purpan [Toulouse]

Subjects
Male, 0301 basic medicine, Proband, DEPDC5, SUDEP, 030105 genetics & heredity, Bioinformatics, Loss of Function Mutation/genetics, Epilepsy, INDEL Mutation, Loss of Function Mutation, mTORC1 pathway, Genetics(clinical), Child, Genetics (clinical), Multiprotein Complexes/genetics, Brugada Syndrome, DNA Copy Number Variation, Brugada syndrome, INDEL Mutation/genetics, GTPase-Activating Proteins, NPRL3, Seizure, Phenotype, Pedigree, 3. Good health, Brugada Syndrome/genetics, Child, Preschool, Female, Human, Signal Transduction, DNA Copy Number Variations, Adolescent, Seizures/complications, Mechanistic Target of Rapamycin Complex 1/genetics, DNA Copy Number Variations/genetics, Mechanistic Target of Rapamycin Complex 1, Tumor Suppressor Proteins/genetics, Article, Focal cortical dysplasia, 03 medical and health sciences, Seizures, GTPase-Activating Proteins/genetics, medicine, Humans, Genetic Predisposition to Disease, Genetic focal epilepsy, Epilepsy/complications, Repressor Proteins/genetics, business.industry, GTPase-Activating Protein, Tumor Suppressor Proteins, Infant, Newborn, Correction, Infant, Repressor Protein, Cortical dysplasia, medicine.disease, ddc:616.8, Repressor Proteins, 030104 developmental biology, Frontal lobe seizures, [SDV.GEN.GH]Life Sciences [q-bio]/Genetics/Human genetics, Multiprotein Complexes, Multiprotein Complexe, Signal Transduction/genetics, Human medicine, business
Abstract

Purpose:\ud \ud To define the phenotypic and mutational spectrum of epilepsies related to DEPDC5, NPRL2 and NPRL3 genes encoding the GATOR1 complex, a negative regulator of the mTORC1 pathway.\ud \ud Methods:\ud \ud We analyzed clinical and genetic data of 73 novel probands (familial and sporadic) with epilepsy-related variants in GATOR1-encoding genes and proposed new guidelines for clinical interpretation of GATOR1 variants.\ud \ud Results:\ud \ud The GATOR1 seizure phenotype consisted mostly in focal seizures (e.g., hypermotor or frontal lobe seizures in 50%), with a mean age at onset of 4.4 years, often sleep-related and drug-resistant (54%), and associated with focal cortical dysplasia (20%). Infantile spasms were reported in 10% of the probands. Sudden unexpected death in epilepsy (SUDEP) occurred in 10% of the families. Novel classification framework of all 140 epilepsy-related GATOR1 variants (including the variants of this study) revealed that 68% are loss-of-function pathogenic, 14% are likely pathogenic, 15% are variants of uncertain significance and 3% are likely benign.\ud \ud Conclusion:\ud \ud Our data emphasize the increasingly important role of GATOR1 genes in the pathogenesis of focal epilepsies (>180 probands to date). The GATOR1 phenotypic spectrum ranges from sporadic early-onset epilepsies with cognitive impairment comorbidities to familial focal epilepsies, and SUDEP.

Published
2018

39. Diagnostic work-up in malformations of cortical development.

Author

Rijckmans E, Stouffs K, and Jansen AC

Subjects
Humans, Cerebral Cortex diagnostic imaging, Cerebral Cortex pathology, Cerebral Cortex abnormalities, Lissencephaly genetics, Lissencephaly diagnosis, Malformations of Cortical Development diagnosis, Malformations of Cortical Development diagnostic imaging, Malformations of Cortical Development genetics
Abstract

Malformations of cortical development (MCDs) represent a heterogeneous spectrum of disorders characterized by atypical development of the cerebral cortex. MCDs are most often diagnosed on the basis of imaging, although subtle lesions, such as focal cortical dysplasia, may only be revealed on neuropathology. Different subtypes have been defined, including lissencephaly, heterotopia, cobblestone malformation, polymicrogyria, and dysgyria. Many MCDs are of genetic origin, although acquired factors, such as congenital cytomegalovirus infections and twinning sequence, can lead to similar phenotypes. In this narrative review, we provide an overview of the diagnostic approach to MCDs, which is illustrated with clinical vignettes, on diagnostic pitfalls such as somatic mosaicism and consanguinity, and recognizable phenotypes on imaging, such as tubulinopathies, the lissencephaly spectrum, tuberous sclerosis complex, and FLNA-related periventricular nodular heterotopia., (© 2024 The Authors. Developmental Medicine & Child Neurology published by John Wiley & Sons Ltd on behalf of Mac Keith Press.)

Published
2024
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40. TREX-1 related Aicardi-Goutières syndrome improved by Janus kinase inhibitor.

Author

Ryckmans C, Donge M, Marchèse A, Mastouri M, Thomee C, Stouffs K, Lieser SL, and Scalais E

Subjects
Male, Pregnancy, Female, Humans, Infant, Atrophy, Janus Kinase Inhibitors, Lymphocytosis cerebrospinal fluid, Lymphocytosis genetics, Nervous System Malformations drug therapy, Nervous System Malformations genetics, Basal Ganglia Diseases diagnosis, Basal Ganglia Diseases drug therapy, Basal Ganglia Diseases genetics, Autoimmune Diseases of the Nervous System drug therapy, Autoimmune Diseases of the Nervous System genetics, Calcinosis genetics, Azetidines, Purines, Pyrazoles, Sulfonamides
Abstract

Aicardi-Goutières syndrome (AGS) is a genetic interferonopathy classically characterized by early onset of severe neurologic injury with basal ganglia calcifications, white matter abnormalities, and progressive cerebral atrophy, along with lymphocytosis and raised interferon alpha (INFα) in the cerebrospinal fluid (CSF). Here, we report a 3 1/2 year-old patient born with prenatal onset AGS, first manifesting as intra-uterine growth retardation. Cranial ultrasonography and cerebral MRI revealed ventriculomegaly and periventricular and basal ganglia calcifications, along with cerebral atrophy. Perinatal infections and known metabolic disorders were excluded. Both CSF lymphocytosis and raised INFα were present. Molecular analysis disclosed two already described compound heterozygous pathogenic variants in TREX1 (c. 309dup, p.(Thr104Hisfs*53) and c. 506G > A, p.(Arg169His)). The evolution was marked by severe global developmental delay with progressive microcephaly. Promptly, the patient developed irritability, quadri-paretic dyskinetic movements, and subsequently tonic seizures. Sensorineural hearing loss was detected as well as glaucoma. Initially, he was symptomatically treated with trihexyphenidyl followed by levetiracetam and topiramate. At age 22 months, baricitinib (0.4 mg/kg/day) was introduced, leading to normal serum INFα levels. Clinically, dyskinetic movements significantly decreased as well as irritability and sleep disturbance. We confirmed that baricitinib was a useful treatment with no major side effect., (© 2023 Wiley Periodicals LLC.)

Published
2024
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41. Children born after assisted reproduction more commonly carry a mitochondrial genotype associating with low birthweight.

Author

Mertens J, Belva F, van Montfoort APA, Regin M, Zambelli F, Seneca S, Couvreu de Deckersberg E, Bonduelle M, Tournaye H, Stouffs K, Barbé K, Smeets HJM, Van de Velde H, Sermon K, Blockeel C, and Spits C

Subjects
Pregnancy, Infant, Newborn, Female, Humans, Pregnancy Outcome, Pregnancy, Multiple, Birth Weight, Mitochondria genetics, DNA, Mitochondrial genetics, Infant, Premature, Premature Birth epidemiology
Abstract

Children conceived through assisted reproductive technologies (ART) have an elevated risk of lower birthweight, yet the underlying cause remains unclear. Our study explores mitochondrial DNA (mtDNA) variants as contributors to birthweight differences by impacting mitochondrial function during prenatal development. We deep-sequenced the mtDNA of 451 ART and spontaneously conceived (SC) individuals, 157 mother-child pairs and 113 individual oocytes from either natural menstrual cycles or after ovarian stimulation (OS) and find that ART individuals carried a different mtDNA genotype than SC individuals, with more de novo non-synonymous variants. These variants, along with rRNA variants, correlate with lower birthweight percentiles, independent of conception mode. Their higher occurrence in ART individuals stems from de novo mutagenesis associated with maternal aging and OS-induced oocyte cohort size. Future research will establish the long-term health consequences of these changes and how these findings will impact the clinical practice and patient counselling in the future., (© 2024. The Author(s).)

Published
2024
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42. Macrocephaly? Do not Forget SUFU.

Author

Rijckmans E, Bordon V, de Ravel T, Baert E, Jansen AC, and Stouffs K

Subjects
Humans, Repressor Proteins, Megalencephaly diagnosis
Abstract

Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Published
2024
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43. Further characterisation of ARX -related disorders in females due to inherited or de novo variants.

Author

Gras M, Heide S, Keren B, Valence S, Garel C, Whalen S, Jansen AC, Keymolen K, Stouffs K, Jennesson M, Poirsier C, Lesca G, Depienne C, Nava C, Rastetter A, Curie A, Cuisset L, Des Portes V, Milh M, Charles P, Mignot C, and Héron D

Subjects
Male, Humans, Female, Genes, Homeobox, Homeodomain Proteins genetics, Mutation genetics, Transcription Factors genetics, Phenotype, Agenesis of Corpus Callosum genetics, Autism Spectrum Disorder genetics, Intellectual Disability genetics, Intellectual Disability pathology
Abstract

The Aristaless-related homeobox ( ARX ) gene is located on the X chromosome and encodes a transcription factor that is essential for brain development. While the clinical spectrum of ARX -related disorders is well described in males, from X linked lissencephaly with abnormal genitalia syndrome to syndromic and non-syndromic intellectual disability (ID), its phenotypic delineation in females is incomplete. Carrier females in ARX families are usually asymptomatic, but ID has been reported in some of them, as well as in others with de novo variants. In this study, we collected the clinical and molecular data of 10 unpublished female patients with de novo ARX pathogenic variants and reviewed the data of 63 females from the literature with either de novo variants (n=10), inherited variants (n=33) or variants of unknown inheritance (n=20). Altogether, the clinical spectrum of females with heterozygous pathogenic ARX variants is broad: 42.5% are asymptomatic, 16.4% have isolated agenesis of the corpus callosum (ACC) or mild symptoms (learning disabilities, autism spectrum disorder, drug-responsive epilepsy) without ID, whereas 41% present with a severe phenotype (ie, ID or developmental and epileptic encephalopathy (DEE)). The ID/DEE phenotype was significantly more prevalent in females carrying de novo variants (75%, n=15/20) versus in those carrying inherited variants (27.3%, n=9/33). ACC was observed in 66.7% (n=24/36) of females who underwent a brain MRI. By refining the clinical spectrum of females carrying ARX pathogenic variants, we show that ID is a frequent sign in females with this X linked condition., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2024. No commercial re-use. See rights and permissions. Published by BMJ.)

Published
2024
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44. Overlapping cortical malformations in patients with pathogenic variants in GRIN1 and GRIN2B .

Author

Brock S, Laquerriere A, Marguet F, Myers SJ, Hongjie Y, Baralle D, Vanderhasselt T, Stouffs K, Keymolen K, Kim S, Allen J, Shaulsky G, Chelly J, Marcorelle P, Aziza J, Villard L, Sacaze E, de Wit MCY, Wilke M, Mancini GMS, Hehr U, Lim D, Mansour S, Traynelis SF, Beneteau C, Denis-Musquer M, Jansen AC, Fry AE, and Bahi-Buisson N

Subjects
Humans, Heterozygote, Homozygote, Nerve Tissue Proteins genetics, Epilepsy, Microcephaly, Receptors, N-Methyl-D-Aspartate genetics
Abstract

Background: Malformations of cortical development (MCDs) have been reported in a subset of patients with pathogenic heterozygous variants in GRIN1 or GRIN2B , genes which encode for subunits of the N-methyl-D-aspartate receptor (NMDAR). The aim of this study was to further define the phenotypic spectrum of NMDAR-related MCDs., Methods: We report the clinical, radiological and molecular features of 7 new patients and review data on 18 previously reported individuals with NMDAR-related MCDs. Neuropathological findings for two individuals with heterozygous variants in GRIN1 are presented. We report the clinical and neuropathological features of one additional individual with homozygous pathogenic variants in GRIN1 ., Results: Heterozygous variants in GRIN1 and GRIN2B were associated with overlapping severe clinical and imaging features, including global developmental delay, epilepsy, diffuse dysgyria, dysmorphic basal ganglia and hippocampi. Neuropathological examination in two fetuses with heterozygous GRIN1 variants suggests that proliferation as well as radial and tangential neuronal migration are impaired. In addition, we show that neuronal migration is also impaired by homozygous GRIN1 variants in an individual with microcephaly with simplified gyral pattern., Conclusion: These findings expand our understanding of the clinical and imaging features of the 'NMDARopathy' spectrum and contribute to our understanding of the likely underlying pathogenic mechanisms leading to MCD in these patients., Competing Interests: Competing interests: SFT is principal investigator on research grants from Biogen and Janssen to Emory; a member of the Scientific Advisory Board for Eumentis, Sage Therapeutics, GRIN2B Foundation and CureGRIN Foundation; co-founder of NeurOp and Agrithera; and coinventor on Emory-owned intellectual property., (© Author(s) (or their employer(s)) 2023. No commercial re-use. See rights and permissions. Published by BMJ.)

Published
2023
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45. Activating RAC1 variants in the switch II region cause a developmental syndrome and alter neuronal morphology.

Author

Banka S, Bennington A, Baker MJ, Rijckmans E, Clemente GD, Ansor NM, Sito H, Prasad P, Anyane-Yeboa K, Badalato L, Dimitrov B, Fitzpatrick D, Hurst ACE, Jansen AC, Kelly MA, Krantz I, Rieubland C, Ross M, Rudy NL, Sanz J, Stouffs K, Xu ZL, Malliri A, Kazanietz MG, and Millard TH

Subjects
Animals, Mice, Neurons, NIH 3T3 Cells, Signal Transduction genetics, Megalencephaly genetics, Neurodevelopmental Disorders genetics, rac1 GTP-Binding Protein
Abstract

RAC1 is a highly conserved Rho GTPase critical for many cellular and developmental processes. De novo missense RAC1 variants cause a highly variable neurodevelopmental disorder. Some of these variants have previously been shown to have a dominant negative effect. Most previously reported patients with this disorder have either severe microcephaly or severe macrocephaly. Here, we describe eight patients with pathogenic missense RAC1 variants affecting residues between Q61 and R68 within the switch II region of RAC1. These patients display variable combinations of developmental delay, intellectual disability, brain anomalies such as polymicrogyria and cardiovascular defects with normocephaly or relatively milder micro- or macrocephaly. Pulldown assays, NIH3T3 fibroblast spreading assays and staining for activated PAK1/2/3 and WAVE2 suggest that these variants increase RAC1 activity and over-activate downstream signalling targets. Axons of neurons isolated from Drosophila embryos expressing the most common of the activating variants are significantly shorter, with an increased density of filopodial protrusions. In vivo, these embryos exhibit frequent defects in axonal organization. Class IV dendritic arborization neurons expressing this variant exhibit a significant reduction in the total area of the dendritic arbour, increased branching and failure of self-avoidance. RNAi knock down of the WAVE regulatory complex component Cyfip significantly rescues these morphological defects. These results establish that activating substitutions affecting residues Q61-R68 within the switch II region of RAC1 cause a developmental syndrome. Our findings reveal that these variants cause altered downstream signalling, resulting in abnormal neuronal morphology and reveal the WAVE regulatory complex/Arp2/3 pathway as a possible therapeutic target for activating RAC1 variants. These insights also have the potential to inform the mechanism and therapy for other disorders caused by variants in genes encoding other Rho GTPases, their regulators and downstream effectors., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2022
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46. Rare pathogenic variants in WNK3 cause X-linked intellectual disability.

Author

Küry S, Zhang J, Besnard T, Caro-Llopis A, Zeng X, Robert SM, Josiah SS, Kiziltug E, Denommé-Pichon AS, Cogné B, Kundishora AJ, Hao LT, Li H, Stevenson RE, Louie RJ, Deb W, Torti E, Vignard V, McWalter K, Raymond FL, Rajabi F, Ranza E, Grozeva D, Coury SA, Blanc X, Brischoux-Boucher E, Keren B, Õunap K, Reinson K, Ilves P, Wentzensen IM, Barr EE, Guihard SH, Charles P, Seaby EG, Monaghan KG, Rio M, van Bever Y, van Slegtenhorst M, Chung WK, Wilson A, Quinquis D, Bréhéret F, Retterer K, Lindenbaum P, Scalais E, Rhodes L, Stouffs K, Pereira EM, Berger SM, Milla SS, Jaykumar AB, Cobb MH, Panchagnula S, Duy PQ, Vincent M, Mercier S, Gilbert-Dussardier B, Le Guillou X, Audebert-Bellanger S, Odent S, Schmitt S, Boisseau P, Bonneau D, Toutain A, Colin E, Pasquier L, Redon R, Bouman A, Rosenfeld JA, Friez MJ, Pérez-Peña H, Akhtar Rizvi SR, Haider S, Antonarakis SE, Schwartz CE, Martínez F, Bézieau S, Kahle KT, and Isidor B

Subjects
Brain abnormalities, Catalytic Domain genetics, Hemizygote, Humans, Loss of Function Mutation, Male, Maternal Inheritance genetics, Mutation, Missense, Phosphorylation, Mental Retardation, X-Linked genetics, Protein Serine-Threonine Kinases chemistry, Protein Serine-Threonine Kinases genetics, Symporters metabolism
Abstract

Purpose: WNK3 kinase (PRKWNK3) has been implicated in the development and function of the brain via its regulation of the cation-chloride cotransporters, but the role of WNK3 in human development is unknown., Method: We ascertained exome or genome sequences of individuals with rare familial or sporadic forms of intellectual disability (ID)., Results: We identified a total of 6 different maternally-inherited, hemizygous, 3 loss-of-function or 3 pathogenic missense variants (p.Pro204Arg, p.Leu300Ser, p.Glu607Val) in WNK3 in 14 male individuals from 6 unrelated families. Affected individuals had ID with variable presence of epilepsy and structural brain defects. WNK3 variants cosegregated with the disease in 3 different families with multiple affected individuals. This included 1 large family previously diagnosed with X-linked Prieto syndrome. WNK3 pathogenic missense variants localize to the catalytic domain and impede the inhibitory phosphorylation of the neuronal-specific chloride cotransporter KCC2 at threonine 1007, a site critically regulated during the development of synaptic inhibition., Conclusion: Pathogenic WNK3 variants cause a rare form of human X-linked ID with variable epilepsy and structural brain abnormalities and implicate impaired phospho-regulation of KCC2 as a pathogenic mechanism., Competing Interests: Conflict of Interest E.T., K.M., K.R., I.M.W., K.G.M., and L.R. are employees of GeneDx, LLC. K.R. is a shareholder of OPKO Health, Inc. The Department of Molecular and Human Genetics at Baylor College of Medicine receives revenue from clinical genetic testing conducted at Baylor Genetics Laboratories. All other authors declare no conflicts of interest., (Copyright © 2022 American College of Medical Genetics and Genomics. Published by Elsevier Inc. All rights reserved.)

Published
2022
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47. Molecular Dissection of Structural Variations Involved in Antithrombin Deficiency.

Author

de la Morena-Barrio B, Orlando C, Sanchis-Juan A, García JL, Padilla J, de la Morena-Barrio ME, Puruunen M, Stouffs K, Cifuentes R, Borràs N, Bravo-Pérez C, Benito R, Cuenca-Guardiola J, Vicente V, Vidal F, Hernández-Rivas JM, Ouwehand W, Jochmans K, and Corral J

Subjects
Antithrombins, Exons genetics, Humans, Introns, Antithrombin III Deficiency genetics, Retroelements
Abstract

Inherited antithrombin deficiency, the most severe form of thrombophilia, is predominantly caused by variants in SERPINC1. Few causal structural variants have been described, usually detected by multiplex ligation-dependent probe amplification or cytogenetic arrays, which only define the gain or loss and the approximate size and location. This study has done a complete dissection of the structural variants affecting SERPINC1 of 39 unrelated patients with antithrombin deficiency using multiplex ligation-dependent probe amplification, comparative genome hybridization array, long-range PCR, and whole genome nanopore sequencing. Structural variants, in all cases only affecting one allele, were deleterious and caused a severe type I deficiency. Most defects were deletions affecting exons of SERPINC1 (82.1%), but the whole cohort was heterogeneous, as tandem duplications, deletion of introns, or retrotransposon insertions were also detected. Their size was also variable, ranging from 193 bp to 8 Mb, and in 54% of the cases involved neighboring genes. All but two structural variants had repetitive elements and/or microhomologies in their breakpoints, suggesting a common mechanism of formation. This study also suggested regions recurrently involved in structural variants causing antithrombin deficiency and found three structural variants with a founder effect: the insertion of a retrotransposon, duplication of exon 6, and a 20-gene deletion. Finally, nanopore sequencing was determined to be the most appropriate method to identify and characterize all structural variants at nucleotide level, independently of their size or type., (Copyright © 2022 Association for Molecular Pathology and American Society for Investigative Pathology. Published by Elsevier Inc. All rights reserved.)

Published
2022
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48. Loss, Gain and Altered Function of GlyR α2 Subunit Mutations in Neurodevelopmental Disorders.

Author

Chen X, Wilson KA, Schaefer N, De Hayr L, Windsor M, Scalais E, van Rijckevorsel G, Stouffs K, Villmann C, O'Mara ML, Lynch JW, and Harvey RJ

Abstract

Glycine receptors (GlyRs) containing the α2 subunit govern cell fate, neuronal migration and synaptogenesis in the developing cortex and spinal cord. Rare missense variants and microdeletions in the X-linked GlyR α2 subunit gene ( GLRA2 ) have been associated with human autism spectrum disorder (ASD), where they typically cause a loss-of-function via protein truncation, reduced cell-surface trafficking and/or reduced glycine sensitivity (e.g., GLRA2 Δex8-9 and extracellular domain variants p.N109S and p.R126Q). However, the GlyR α2 missense variant p.R323L in the intracellular M3-M4 domain results in a gain-of-function characterized by slower synaptic decay times, longer duration active periods and increases in channel conductance. This study reports the functional characterization of four missense variants in GLRA2 associated with ASD or developmental disorders (p.V-22L, p.N38K, p.K213E, p.T269M) using a combination of bioinformatics, molecular dynamics simulations, cellular models of GlyR trafficking and electrophysiology in artificial synapses. The GlyR α2 V-22L variant resulted in altered predicted signal peptide cleavage and a reduction in cell-surface expression, suggestive of a partial loss-of-function . Similarly, GlyR α2 N38K homomers showed reduced cell-surface expression, a reduced affinity for glycine and a reduced magnitude of IPSCs in artificial synapses. By contrast, GlyR α2 K213E homomers showed a slight reduction in cell-surface expression, but IPSCs were larger, with faster rise/decay times, suggesting a gain-of-function . Lastly, GlyR α2 T269M homomers exhibited a high glycine sensitivity accompanied by a substantial leak current, suggestive of an altered function that could dramatically enhance glycinergic signaling. These results may explain the heterogeneity of clinical phenotypes associated with GLRA2 mutations and reveal that missense variants can result in a loss, gain or alteration of GlyR α2 function. In turn, these GlyR α2 missense variants are likely to either negatively or positively deregulate cortical progenitor homeostasis and neuronal migration in the developing brain, leading to changes in cognition, learning, and memory., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Chen, Wilson, Schaefer, De Hayr, Windsor, Scalais, van Rijckevorsel, Stouffs, Villmann, O’Mara, Lynch and Harvey.)

Published
2022
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49. Malformations of cerebral development and clues from the peripheral nervous system: A systematic literature review.

Author

Rijckmans E, Stouffs K, Jansen AC, and Brock S

Subjects
Cerebral Cortex, Humans, Peripheral Nervous System pathology, Drug Resistant Epilepsy complications, Epilepsy genetics, Malformations of Cortical Development genetics, Nervous System Malformations complications, Nervous System Malformations diagnosis, Nervous System Malformations genetics
Abstract

Clinical manifestations of malformations of cortical development (MCD) are variable and can range from mild to severe intellectual disability, cerebral palsy and drug-resistant epilepsy. Besides common clinical features, non-specific or more subtle clinical symptoms may be present in association with different types of MCD. Especially in severely affected individuals, subtle but specific underlying clinical symptoms can be overlooked or overshadowed by the global clinical presentation. To facilitate the interpretation of genetic variants detailed clinical information is indispensable. Detailed (neurological) examination can be helpful in assisting with the diagnostic trajectory, both when referring for genetic work-up as well as when interpreting data from molecular genetic testing. This systematic literature review focusses on different clues derived from the neurological examination and potential further work-up triggered by these signs and symptoms in genetically defined MCDs. A concise overview of specific neurological findings and their associations with MCD subtype and genotype are presented, easily applicable in daily clinical practice. The following pathologies will be discussed: neuropathy, myopathy, muscular dystrophies and spastic paraplegia. In the discussion section, tips and pitfalls are illustrated to improve clinical outcome in the future., (Copyright © 2021 European Paediatric Neurology Society. Published by Elsevier Ltd. All rights reserved.)

Published
2022
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50. Impaired catabolism of free oligosaccharides due to MAN2C1 variants causes a neurodevelopmental disorder.

Author

Maia N, Potelle S, Yildirim H, Duvet S, Akula SK, Schulz C, Wiame E, Gheldof A, O'Kane K, Lai A, Sermon K, Proisy M, Loget P, Attié-Bitach T, Quelin C, Fortuna AM, Soares AR, de Brouwer APM, Van Schaftingen E, Nassogne MC, Walsh CA, Stouffs K, Jorge P, Jansen AC, and Foulquier F

Subjects
Adolescent, Alleles, Brain Stem metabolism, Brain Stem pathology, Cell Line, Tumor, Central Nervous System Cysts metabolism, Central Nervous System Cysts pathology, Cerebellar Vermis metabolism, Cerebellar Vermis pathology, Child, Child, Preschool, Congenital Disorders of Glycosylation metabolism, Congenital Disorders of Glycosylation pathology, Female, Fetus, Glycosylation, Hamartoma metabolism, Hamartoma pathology, Humans, Hypothalamus metabolism, Hypothalamus pathology, Intellectual Disability metabolism, Intellectual Disability pathology, Leukocytes metabolism, Leukocytes pathology, Male, Mannose metabolism, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase genetics, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase metabolism, Polymicrogyria metabolism, Polymicrogyria pathology, Tongue metabolism, Tongue pathology, alpha-Mannosidase deficiency, Central Nervous System Cysts genetics, Congenital Disorders of Glycosylation genetics, Hamartoma genetics, Intellectual Disability genetics, Oligosaccharides metabolism, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase deficiency, Polymicrogyria genetics, alpha-Mannosidase genetics
Abstract

Free oligosaccharides (fOSs) are soluble oligosaccharide species generated during N-glycosylation of proteins. Although little is known about fOS metabolism, the recent identification of NGLY1 deficiency, a congenital disorder of deglycosylation (CDDG) caused by loss of function of an enzyme involved in fOS metabolism, has elicited increased interest in fOS processing. The catabolism of fOSs has been linked to the activity of a specific cytosolic mannosidase, MAN2C1, which cleaves α1,2-, α1,3-, and α1,6-mannose residues. In this study, we report the clinical, biochemical, and molecular features of six individuals, including two fetuses, with bi-allelic pathogenic variants in MAN2C1; the individuals are from four different families. These individuals exhibit dysmorphic facial features, congenital anomalies such as tongue hamartoma, variable degrees of intellectual disability, and brain anomalies including polymicrogyria, interhemispheric cysts, hypothalamic hamartoma, callosal anomalies, and hypoplasia of brainstem and cerebellar vermis. Complementation experiments with isogenic MAN2C1-KO HAP1 cells confirm the pathogenicity of three of the identified MAN2C1 variants. We further demonstrate that MAN2C1 variants lead to accumulation and delay in the processing of fOSs in proband-derived cells. These results emphasize the involvement of MAN2C1 in human neurodevelopmental disease and the importance of fOS catabolism., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021. Published by Elsevier Inc.)

Published
2022
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