Your search keyword '"Bartnik-Glaska M"' showing total 4 results

1. Diagnostic implications of genetic copy number variation in epilepsy plus

Author

Coppola, A., Cellini, E., Stamberger, H., Saarentaus, E., Cetica, V., Lal, D., Djemie, T., Bartnik-Glaska, M., Ceulemans, B., Helen Cross, J., Deconinck, T., Masi, S. D., Dorn, T., Guerrini, R., Hoffman-Zacharska, D., Kooy, F., Lagae, L., Lench, N., Lemke, J. R., Lucenteforte, E., Madia, F., Mefford, H. C., Morrogh, D., Nuernberg, P., Palotie, A., Schoonjans, A. -S., Striano, P., Szczepanik, E., Tostevin, A., Vermeesch, J. R., Van Esch, H., Van Paesschen, W., Waters, J. J., Weckhuysen, S., Zara, F., Jonghe, P. D., Sisodiya, S. M., Marini, C., Lehesjioki, A. -E., Craiu, D., Talvik, T., Caglayan, H., Serratosa, J., Sterbova, K., Moller, R. S., Hjalgrim, H., Lerche, H., Weber, Y., Helbig, I., von Spiczak, S., Barba, C., Bogaerts, A., Boni, A., Galizia, E. C., Chiari, S., Di Gacomo, G., Ferrari, A., Guarducci, S., Giglio, S., Holmgren, P., Leu, C., Melani, F., Novara, F., Pantaleo, M., Peeters, E., Pisano, T., Rosati, A., Sander, J., Schoeler, N., Stankiewicz, P., Striano, S., Suls, A., Traverso, M., Vandeweyer, G., Van Dijck, A., Zuffardi, O., Coppola, Antonietta, Cellini, Elena, Stamberger, Hannah, Saarentaus, Elmo, Cetica, Valentina, Lal, Denni, Djémié, Tania, Bartnik-Glaska, Magdalena, Ceulemans, Berten, Helen Cross, J., Deconinck, Tine, Masi, Salvatore De, Dorn, Thoma, Guerrini, Renzo, Hoffman-Zacharska, Dorotha, Kooy, Frank, Lagae, Lieven, Lench, Nichola, Lemke, Johannes R., Lucenteforte, Ersilia, Madia, Francesca, Mefford, Heather C., Morrogh, Deborah, Nuernberg, Peter, Palotie, Aarno, Schoonjans, An-Sofie, Striano, Pasquale, Szczepanik, Elzbieta, Tostevin, Anna, Vermeesch, Joris R., Van Esch, Hilde, Van Paesschen, Wim, Waters, Jonathan J, Weckhuysen, Sarah, Zara, Federico, Jonghe, Peter De, Sisodiya, Sanjay M., Marini, Carla, Lehesjioki, Anna-Elina, Craiu, Dana, Talvik, Tiina, Caglayan, Hande, Serratosa, Jose, Sterbova, Katalin, Møller, Rikke S., Hjalgrim, Helle, Lerche, Holger, Weber, Yvonne, Helbig, Ingo, von Spiczak, Sarah, Barba, Carmen, Bogaerts, Anneleen, Boni, Antonella, Galizia, Elisabeth Caruana, Chiari, Sara, Di Gacomo, Gianpiero, Ferrari, Annarita, Guarducci, Silvia, Giglio, Sabrina, Holmgren, Philip, Leu, Costin, Melani, Federico, Novara, Francesca, Pantaleo, Marilena, Peeters, Elke, Pisano, Tiziana, Rosati, Anna, Sander, Josemir, Schoeler, Natasha, Stankiewicz, Pawel, Striano, Salvatore, Suls, Arvid, Traverso, Monica, Vandeweyer, Geert, Van Dijck, Anke, and Zuffardi, Orsetta

Subjects

epilepsy gene, Epilepsy, DNA Copy Number Variations, Genotype, Comorbidity, array CGH, copy number variants, epilepsy genes, SNP array, Phenotype, Neurology, mental disorders, Full‐length Original Research, Humans, copy number variant, Genetic Predisposition to Disease, Neurology (clinical)

Abstract

Summary Objective Copy number variations (CNVs) represent a significant genetic risk for several neurodevelopmental disorders including epilepsy. As knowledge increases, reanalysis of existing data is essential. Reliable estimates of the contribution of CNVs to epilepsies from sizeable populations are not available. Methods We assembled a cohort of 1255 patients with preexisting array comparative genomic hybridization or single nucleotide polymorphism array based CNV data. All patients had “epilepsy plus,” defined as epilepsy with comorbid features, including intellectual disability, psychiatric symptoms, and other neurological and nonneurological features. CNV classification was conducted using a systematic filtering workflow adapted to epilepsy. Results Of 1097 patients remaining after genetic data quality control, 120 individuals (10.9%) carried at least one autosomal CNV classified as pathogenic; 19 individuals (1.7%) carried at least one autosomal CNV classified as possibly pathogenic. Eleven patients (1%) carried more than one (possibly) pathogenic CNV. We identified CNVs covering recently reported (HNRNPU) or emerging (RORB) epilepsy genes, and further delineated the phenotype associated with mutations of these genes. Additional novel epilepsy candidate genes emerge from our study. Comparing phenotypic features of pathogenic CNV carriers to those of noncarriers of pathogenic CNVs, we show that patients with nonneurological comorbidities, especially dysmorphism, were more likely to carry pathogenic CNVs (odds ratio = 4.09, confidence interval = 2.51‐6.68; P = 2.34 × 10−9). Meta‐analysis including data from published control groups showed that the presence or absence of epilepsy did not affect the detected frequency of CNVs. Significance The use of a specifically adapted workflow enabled identification of pathogenic autosomal CNVs in 10.9% of patients with epilepsy plus, which rose to 12.7% when we also considered possibly pathogenic CNVs. Our data indicate that epilepsy with comorbid features should be considered an indication for patients to be selected for a diagnostic algorithm including CNV detection. Collaborative large‐scale CNV reanalysis leads to novel declaration of pathogenicity in unexplained cases and can promote discovery of promising candidate epilepsy genes.

Published

2019

2. Cytogenomic features of Richter transformation.

Author

Woroniecka R, Rymkiewicz G, Bystydzienski Z, Pienkowska-Grela B, Rygier J, Malawska N, Wojtkowska K, Goral N, Blachnio K, Chmielewski M, Bartnik-Glaska M, and Grygalewicz B

Abstract

Background: Richter transformation (RT) is the development of aggressive lymphoma in patients with chronic lymphocytic leukemia (CLL) or small lymphocytic lymphoma (SLL). This rare disease is characterised by dismal prognosis. In recent years, there has been a deeper understanding of RT molecular pathogenesis, and disruptions of apoptosis (TP53) and proliferation (CDKN2A, MYC, NOTCH1) has been described as typical aberrations in RT., Results: A single-institution cohort of 33 RT patients were investigated by karyotyping, fluorescence in situ hybridization and single nucleotide polymorphism/copy number (CN) arrays. Most of RTs were typically manifested by diffuse large B-cell lymphoma, not otherwise specified, among the remaining cases one was classified as high-grade B-cell lymphoma with 11q aberrations. The most frequent alterations (40-60% of cases) were represented by MYC rearrangement/gain, deletions of TP53 and CDKN2A, IGH rearrangement and 13q14 deletion. Several other frequent lesions included losses of 14q24.1-q32.33, 7q31.33-q36.3, and gain of 5q35.2. Analysis of 13 CLL/SLL-RT pairs showed that RT arised from the CLL/SLL by acquiring of 10 ~ 12 cytogenetic or CN lesions/case, but without acquisition of loss of heterozygosity regions. Our result affirmed the higher genetic complexity in RT than CLL/SLL and confirmed the linear features of RT clonal evolution as predominant., Conclusions: Cytogenomic profile was concordant with the literature data, however the role of IGH rearrangement, 14q deletion and 5q35.2 gain need to be explored. We anticipate that further characterization of RT lesions will probably facilitate better understanding of the RT clonal evolution., (© 2023. The Author(s).)

Published

2023

3. How does terminal 21q22 deletion really manifest? Delineation based on prenatal diagnosis and literature review.

Author

Wielgos M, Kosinski P, Jedrzejak P, Krajewska-Walasek M, Bartnik-Glaska M, Nowakowska B, and Jezela-Stanek A

Subjects

Adult, Chromosome Disorders diagnosis, Chromosome Disorders genetics, Female, Fetal Growth Retardation genetics, Humans, Monosomy genetics, Pregnancy, Chromosome Deletion, Chromosomes, Human, Pair 21 genetics, Monosomy diagnosis, Prenatal Diagnosis methods

Abstract

Objective: Most genetic disorders, especially rare and manifested with an unspecific constellation of developmental anomalies, are challenging to diagnose before birth. The paper aims to present a rare case of terminal 21q22 deletion to extend the knowledge on this rare genetic disease, mostly to facilitate prenatal guidance by pointing the diagnostic features., Case Report: The fetus was diagnosed prenatally, at 21 weeks of gestation, due to ultrasound markers detected in a routine ultrasound scan. Post-mortem dysmorphological assessment has verified the diagnosis. To the best of our knowledge, this is the second report of prenatal presentation of partial monosomy 21q., Conclusion: By giving the detailed phenotype description and presenting a comprehensive literature review on the subject, we delineate its phenotype, which was different from what has been shown in the literature. Specifically, the clinical presentation of aberration within regions 2 and 3 (referring to the term proposed by Lyle et al., in 2009) of 21q22 bands is not characterised by multiple or severe malformations, which matters for prenatal counselling and diagnostics., Competing Interests: Declaration of competing interest All authors declare no conflict of interest., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

4. Diagnostic implications of genetic copy number variation in epilepsy plus.

Author

Coppola A, Cellini E, Stamberger H, Saarentaus E, Cetica V, Lal D, Djémié T, Bartnik-Glaska M, Ceulemans B, Helen Cross J, Deconinck T, Masi S, Dorn T, Guerrini R, Hoffman-Zacharska D, Kooy F, Lagae L, Lench N, Lemke JR, Lucenteforte E, Madia F, Mefford HC, Morrogh D, Nuernberg P, Palotie A, Schoonjans AS, Striano P, Szczepanik E, Tostevin A, Vermeesch JR, Van Esch H, Van Paesschen W, Waters JJ, Weckhuysen S, Zara F, De Jonghe P, Sisodiya SM, and Marini C

Subjects

Comorbidity, DNA Copy Number Variations, Epilepsy complications, Genetic Predisposition to Disease, Genotype, Humans, Phenotype, Epilepsy genetics

Abstract

Objective: Copy number variations (CNVs) represent a significant genetic risk for several neurodevelopmental disorders including epilepsy. As knowledge increases, reanalysis of existing data is essential. Reliable estimates of the contribution of CNVs to epilepsies from sizeable populations are not available., Methods: We assembled a cohort of 1255 patients with preexisting array comparative genomic hybridization or single nucleotide polymorphism array based CNV data. All patients had "epilepsy plus," defined as epilepsy with comorbid features, including intellectual disability, psychiatric symptoms, and other neurological and nonneurological features. CNV classification was conducted using a systematic filtering workflow adapted to epilepsy., Results: Of 1097 patients remaining after genetic data quality control, 120 individuals (10.9%) carried at least one autosomal CNV classified as pathogenic; 19 individuals (1.7%) carried at least one autosomal CNV classified as possibly pathogenic. Eleven patients (1%) carried more than one (possibly) pathogenic CNV. We identified CNVs covering recently reported (HNRNPU) or emerging (RORB) epilepsy genes, and further delineated the phenotype associated with mutations of these genes. Additional novel epilepsy candidate genes emerge from our study. Comparing phenotypic features of pathogenic CNV carriers to those of noncarriers of pathogenic CNVs, we show that patients with nonneurological comorbidities, especially dysmorphism, were more likely to carry pathogenic CNVs (odds ratio = 4.09, confidence interval = 2.51-6.68; P = 2.34 × 10 -9 ). Meta-analysis including data from published control groups showed that the presence or absence of epilepsy did not affect the detected frequency of CNVs., Significance: The use of a specifically adapted workflow enabled identification of pathogenic autosomal CNVs in 10.9% of patients with epilepsy plus, which rose to 12.7% when we also considered possibly pathogenic CNVs. Our data indicate that epilepsy with comorbid features should be considered an indication for patients to be selected for a diagnostic algorithm including CNV detection. Collaborative large-scale CNV reanalysis leads to novel declaration of pathogenicity in unexplained cases and can promote discovery of promising candidate epilepsy genes., (© 2019 The Authors. Epilepsia published by Wiley Periodicals, Inc. on behalf of International League Against Epilepsy.)

Published

2019