Your search keyword '"Gambin, Tomasz"' showing total 13 results

1. Bi-allelic Pathogenic Variants in TUBGCP2 Cause Microcephaly and Lissencephaly Spectrum Disorders.

Author

Mitani, Tadahiro, Punetha, Jaya, Akalin, Ibrahim, Pehlivan, Davut, Dawidziuk, Mateusz, Coban Akdemir, Zeynep, Yilmaz, Sarenur, Aslan, Ezgi, Hunter, Jill V., Hijazi, Hadia, Grochowski, Christopher M., Jhangiani, Shalini N., Karaca, Ender, Fatih, Jawid M., Iwanowski, Piotr, Gambin, Tomasz, Wlasienko, Pawel, Goszczanska-Ciuchta, Alicja, Bekiesinska-Figatowska, Monika, and Hosseini, Masoumeh

Subjects

*MICROCEPHALY, *MICROTUBULE-associated proteins, *DEVELOPMENTAL delay, *DISEASES, *NEURAL development, *MICROTUBULES, *RECESSIVE genes

Abstract

Lissencephaly comprises a spectrum of malformations of cortical development. This spectrum includes agyria, pachygyria, and subcortical band heterotopia; each represents anatomical malformations of brain cortical development caused by neuronal migration defects. The molecular etiologies of neuronal migration anomalies are highly enriched for genes encoding microtubules and microtubule-associated proteins, and this enrichment highlights the critical role for these genes in cortical growth and gyrification. Using exome sequencing and family based rare variant analyses, we identified a homozygous variant (c.997C>T [p.Arg333Cys]) in TUBGCP2, encoding gamma-tubulin complex protein 2 (GCP2), in two individuals from a consanguineous family; both individuals presented with microcephaly and developmental delay. GCP2 forms the multiprotein γ-tubulin ring complex (γ-TuRC) together with γ-tubulin and other GCPs to regulate the assembly of microtubules. By querying clinical exome sequencing cases and through GeneMatcher-facilitated collaborations, we found three additional families with bi-allelic variation and similarly affected phenotypes including a homozygous variant (c.1843G>C [p.Ala615Pro]) in two families and compound heterozygous variants consisting of one missense variant (c.889C>T [p.Arg297Cys]) and one splice variant (c.2025-2A>G) in another family. Brain imaging from all five affected individuals revealed varying degrees of cortical malformations including pachygyria and subcortical band heterotopia, presumably caused by disruption of neuronal migration. Our data demonstrate that pathogenic variants in TUBGCP2 cause an autosomal recessive neurodevelopmental trait consisting of a neuronal migration disorder, and our data implicate GCP2 as a core component of γ-TuRC in neuronal migrating cells. [ABSTRACT FROM AUTHOR]

Published

2019

2. Complex Compound Inheritance of Lethal Lung Developmental Disorders Due to Disruption of the TBX-FGF Pathway.

Author

Karolak, Justyna A., Vincent, Marie, Deutsch, Gail, Gambin, Tomasz, Cogné, Benjamin, Pichon, Olivier, Vetrini, Francesco, Mefford, Heather C., Dines, Jennifer N., Golden-Grant, Katie, Dipple, Katrina, Freed, Amanda S., Leppig, Kathleen A., Dishop, Megan, Mowat, David, Bennetts, Bruce, Gifford, Andrew J., Weber, Martin A., Lee, Anna F., and Boerkoel, Cornelius F.

Subjects

*LUNG development, *MORPHOGENESIS, *LUNG diseases, *DELETION mutation, *HISTOPATHOLOGY

Abstract

Primary defects in lung branching morphogenesis, resulting in neonatal lethal pulmonary hypoplasias, are incompletely understood. To elucidate the pathogenetics of human lung development, we studied a unique collection of samples obtained from deceased individuals with clinically and histopathologically diagnosed interstitial neonatal lung disorders: acinar dysplasia (n = 14), congenital alveolar dysplasia (n = 2), and other lethal lung hypoplasias (n = 10). We identified rare heterozygous copy-number variant deletions or single-nucleotide variants (SNVs) involving TBX4 (n = 8 and n = 2, respectively) or FGF10 (n = 2 and n = 2, respectively) in 16/26 (61%) individuals. In addition to TBX4 , the overlapping ∼2 Mb recurrent and nonrecurrent deletions at 17q23.1q23.2 identified in seven individuals with lung hypoplasia also remove a lung-specific enhancer region. Individuals with coding variants involving either TBX4 or FGF10 also harbored at least one non-coding SNV in the predicted lung-specific enhancer region, which was absent in 13 control individuals with the overlapping deletions but without any structural lung anomalies. The occurrence of rare coding variants involving TBX4 or FGF10 with the putative hypomorphic non-coding SNVs implies a complex compound inheritance of these pulmonary hypoplasias. Moreover, they support the importance of TBX4-FGF10-FGFR2 epithelial-mesenchymal signaling in human lung organogenesis and help to explain the histopathological continuum observed in these rare lethal developmental disorders of the lung. [ABSTRACT FROM AUTHOR]

Published

2019

3. Identifying Genes Whose Mutant Transcripts Cause Dominant Disease Traits by Potential Gain-of-Function Alleles.

Author

Coban-Akdemir, Zeynep, White, Janson J., Song, Xiaofei, Jhangiani, Shalini N., Fatih, Jawid M., Gambin, Tomasz, Bayram, Yavuz, Chinn, Ivan K., Karaca, Ender, Punetha, Jaya, Poli, Cecilia, Boerwinkle, Eric, Shaw, Chad A., Orange, Jordan S., Gibbs, Richard A., Lappalainen, Tuuli, Lupski, James R., and Carvalho, Claudia M.B.

Subjects

*GAIN-of-function mutations, *ALLELES, *STOP codons, *ATHEROSCLEROSIS risk factors, *PHENOTYPES

Abstract

Premature termination codon (PTC)-bearing transcripts are often degraded by nonsense-mediated decay (NMD) resulting in loss-of-function (LoF) alleles. However, not all PTCs result in LoF mutations, i.e., some such transcripts escape NMD and are translated to truncated peptide products that result in disease due to gain-of-function (GoF) effects. Since the location of the PTC is a major factor determining transcript fate, we hypothesized that depletion of protein-truncating variants (PTVs) within the gene region predicted to escape NMD in control databases could provide a rank for genic susceptibility for disease through GoF versus LoF. We developed an NMD escape intolerance score to rank genes based on the depletion of PTVs that would render them able to escape NMD using the Atherosclerosis Risk in Communities Study (ARIC) and the Exome Aggregation Consortium (ExAC) control databases, which was further used to screen the Baylor-Center for Mendelian Genomics disease database. This analysis revealed 1,996 genes significantly depleted for PTVs that are predicted to escape from NMD, i.e., PTVesc; further studies provided evidence that revealed a subset as candidate genes underlying Mendelian phenotypes. Importantly, these genes have characteristically low pLI scores, which can cause them to be overlooked as candidates for dominant diseases. Collectively, we demonstrate that this NMD escape intolerance score is an effective and efficient tool for gene discovery in Mendelian diseases due to production of truncated or altered proteins. More importantly, we provide a complementary analytical tool to aid identification of genes associated with dominant traits through a mechanism distinct from LoF. [ABSTRACT FROM AUTHOR]

Published

2018

4. De Novo Disruption of the Proteasome Regulatory Subunit PSMD12 Causes a Syndromic Neurodevelopmental Disorder.

Author

Küry, Sébastien, Besnard, Thomas, Ebstein, Frédéric, Khan, Tahir N., Gambin, Tomasz, Douglas, Jessica, Bacino, Carlos A., Sanders, Stephan J., Lehmann, Andrea, Latypova, Xénia, Khan, Kamal, Pacault, Mathilde, Sacharow, Stephanie, Glaser, Kimberly, Bieth, Eric, Perrin-Sabourin, Laurence, Jacquemont, Marie-Line, Cho, Megan T., Roeder, Elizabeth, and Denommé-Pichon, Anne-Sophie

Subjects

*PROTEASOMES, *NEURODEGENERATION, *POINT mutation (Biology), *CATALYTIC activity, *DELETION mutation, *GENETICS

Abstract

Degradation of proteins by the ubiquitin-proteasome system (UPS) is an essential biological process in the development of eukaryotic organisms. Dysregulation of this mechanism leads to numerous human neurodegenerative or neurodevelopmental disorders. Through a multi-center collaboration, we identified six de novo genomic deletions and four de novo point mutations involving PSMD12 , encoding the non-ATPase subunit PSMD12 (aka RPN5) of the 19S regulator of 26S proteasome complex, in unrelated individuals with intellectual disability, congenital malformations, ophthalmologic anomalies, feeding difficulties, deafness, and subtle dysmorphic facial features. We observed reduced PSMD12 levels and an accumulation of ubiquitinated proteins without any impairment of proteasome catalytic activity. Our PSMD12 loss-of-function zebrafish CRISPR/Cas9 model exhibited microcephaly, decreased convolution of the renal tubules, and abnormal craniofacial morphology. Our data support the biological importance of PSMD12 as a scaffolding subunit in proteasome function during development and neurogenesis in particular; they enable the definition of a neurodevelopmental disorder due to PSMD12 variants, expanding the phenotypic spectrum of UPS-dependent disorders. [ABSTRACT FROM AUTHOR]

Published

2017

5. Recurrent Muscle Weakness with Rhabdomyolysis, Metabolic Crises, and Cardiac Arrhythmia Due to Bi-allelic TANGO2 Mutations.

Author

Lalani, Seema R., Liu, Pengfei, Rosenfeld, Jill A., Watkin, Levi B., Chiang, Theodore, Leduc, Magalie S., Zhu, Wenmiao, Ding, Yan, Pan, Shujuan, Vetrini, Francesco, Miyake, Christina Y., Shinawi, Marwan, Gambin, Tomasz, Eldomery, Mohammad K., Akdemir, Zeynep Hande Coban, Emrick, Lisa, Wilnai, Yael, Schelley, Susan, Koenig, Mary Kay, and Memon, Nada

Subjects

*RHABDOMYOLYSIS, *GENETIC mutation, *ARRHYTHMIA, *MUSCLE weakness, *ALLELES, *GENETICS

Abstract

The underlying genetic etiology of rhabdomyolysis remains elusive in a significant fraction of individuals presenting with recurrent metabolic crises and muscle weakness. Using exome sequencing, we identified bi-allelic mutations in TANGO2 encoding transport and Golgi organization 2 homolog ( Drosophila ) in 12 subjects with episodic rhabdomyolysis, hypoglycemia, hyperammonemia, and susceptibility to life-threatening cardiac tachyarrhythmias. A recurrent homozygous c.460G>A (p.Gly154Arg) mutation was found in four unrelated individuals of Hispanic / Latino origin, and a homozygous ∼34 kb deletion affecting exons 3–9 was observed in two families of European ancestry. One individual of mixed Hispanic/European descent was found to be compound heterozygous for c.460G>A (p.Gly154Arg) and the deletion of exons 3–9. Additionally, a homozygous exons 4–6 deletion was identified in a consanguineous Middle Eastern Arab family. No homozygotes have been reported for these changes in control databases. Fibroblasts derived from a subject with the recurrent c.460G>A (p.Gly154Arg) mutation showed evidence of increased endoplasmic reticulum stress and a reduction in Golgi volume density in comparison to control. Our results show that the c.460G>A (p.Gly154Arg) mutation and the exons 3–9 heterozygous deletion in TANGO2 are recurrent pathogenic alleles present in the Latino/Hispanic and European populations, respectively, causing considerable morbidity in the homozygotes in these populations. [ABSTRACT FROM AUTHOR]

Published

2016

6. Genes that Affect Brain Structure and Function Identified by Rare Variant Analyses of Mendelian Neurologic Disease.

Author

Karaca, Ender, Harel, Tamar, Pehlivan, Davut, Jhangiani, Shalini N., Gambin, Tomasz, Coban Akdemir, Zeynep, Gonzaga-Jauregui, Claudia, Erdin, Serkan, Bayram, Yavuz, Campbell, Ian M., Hunter, Jill V., Atik, Mehmed M., Van Esch, Hilde, Yuan, Bo, Wiszniewski, Wojciech, Isikay, Sedat, Yesil, Gozde, Yuregir, Ozge O., Tug Bozdogan, Sevcan, and Aslan, Huseyin

Subjects

*BRAIN physiology, *BRAIN function localization, *HUMAN genetic variation, *NEUROLOGICAL disorders, *NUCLEOTIDE sequencing, *CELL communication, *DNA copy number variations

Abstract

Summary Development of the human nervous system involves complex interactions among fundamental cellular processes and requires a multitude of genes, many of which remain to be associated with human disease. We applied whole exome sequencing to 128 mostly consanguineous families with neurogenetic disorders that often included brain malformations. Rare variant analyses for both single nucleotide variant (SNV) and copy number variant (CNV) alleles allowed for identification of 45 novel variants in 43 known disease genes, 41 candidate genes, and CNVs in 10 families, with an overall potential molecular cause identified in >85% of families studied. Among the candidate genes identified, we found PRUNE , VARS , and DHX37 in multiple families and homozygous loss-of-function variants in AGBL2 , SLC18A2 , SMARCA1 , UBQLN1 , and CPLX1 . Neuroimaging and in silico analysis of functional and expression proximity between candidate and known disease genes allowed for further understanding of genetic networks underlying specific types of brain malformations. Video Abstract [ABSTRACT FROM AUTHOR]

Published

2015

7. The Genetic Basis of Mendelian Phenotypes: Discoveries, Challenges, and Opportunities.

Author

Chong, Jessica X., Buckingham, Kati J., Jhangiani, Shalini N., Boehm, Corinne, Sobreira, Nara, Smith, Joshua D., Harrell, Tanya M., McMillin, Margaret J., Wiszniewski, Wojciech, Gambin, Tomasz, Coban Akdemir, Zeynep H., Doheny, Kimberly, Scott, Alan F., Avramopoulos, Dimitri, Chakravarti, Aravinda, Hoover-Fong, Julie, Mathews, Debra, Witmer, P. Dane, Ling, Hua, and Hetrick, Kurt

Subjects

*HUMAN genetic variation, *HUMAN phenotype, *GENETIC regulation, *NUCLEOTIDE sequence, *DATA analysis

Abstract

Discovering the genetic basis of a Mendelian phenotype establishes a causal link between genotype and phenotype, making possible carrier and population screening and direct diagnosis. Such discoveries also contribute to our knowledge of gene function, gene regulation, development, and biological mechanisms that can be used for developing new therapeutics. As of February 2015, 2,937 genes underlying 4,163 Mendelian phenotypes have been discovered, but the genes underlying ∼50% (i.e., 3,152) of all known Mendelian phenotypes are still unknown, and many more Mendelian conditions have yet to be recognized. This is a formidable gap in biomedical knowledge. Accordingly, in December 2011, the NIH established the Centers for Mendelian Genomics (CMGs) to provide the collaborative framework and infrastructure necessary for undertaking large-scale whole-exome sequencing and discovery of the genetic variants responsible for Mendelian phenotypes. In partnership with 529 investigators from 261 institutions in 36 countries, the CMGs assessed 18,863 samples from 8,838 families representing 579 known and 470 novel Mendelian phenotypes as of January 2015. This collaborative effort has identified 956 genes, including 375 not previously associated with human health, that underlie a Mendelian phenotype. These results provide insight into study design and analytical strategies, identify novel mechanisms of disease, and reveal the extensive clinical variability of Mendelian phenotypes. Discovering the gene underlying every Mendelian phenotype will require tackling challenges such as worldwide ascertainment and phenotypic characterization of families affected by Mendelian conditions, improvement in sequencing and analytical techniques, and pervasive sharing of phenotypic and genomic data among researchers, clinicians, and families. [ABSTRACT FROM AUTHOR]

Published

2015

8. DVL1 Frameshift Mutations Clustering in the Penultimate Exon Cause Autosomal-Dominant Robinow Syndrome.

Author

White, Janson, Mazzeu, Juliana F., Hoischen, Alexander, Jhangiani, Shalini N., Gambin, Tomasz, Alcino, Michele Calijorne, Penney, Samantha, Saraiva, Jorge M., Hove, Hanne, Skovby, Flemming, Kayserili, Hülya, Estrella, Elicia, Vulto-van Silfhout, Anneke T., Steehouwer, Marloes, Muzny, Donna M., Sutton, V. Reid, Gibbs, Richard A., Lupski, James R., Brunner, Han G., and van Bon, Bregje W.M.

Subjects

*FRAMESHIFT mutation, *GENETIC disorders, *EXONS (Genetics), *NUCLEOTIDE sequencing, *HUMAN genetic variation, *WNT genes

Abstract

Robinow syndrome is a genetically heterogeneous disorder characterized by mesomelic limb shortening, genital hypoplasia, and distinctive facial features and for which both autosomal-recessive and autosomal-dominant inheritance patterns have been described. Causative variants in the non-canonical signaling gene WNT5A underlie a subset of autosomal-dominant Robinow syndrome (DRS) cases, but most individuals with DRS remain without a molecular diagnosis. We performed whole-exome sequencing in four unrelated DRS-affected individuals without coding mutations in WNT5A and found heterozygous DVL1 exon 14 mutations in three of them. Targeted Sanger sequencing in additional subjects with DRS uncovered DVL1 exon 14 mutations in five individuals, including a pair of monozygotic twins. In total, six distinct frameshift mutations were found in eight subjects, and all were heterozygous truncating variants within the penultimate exon of DVL1 . In five families in which samples from unaffected parents were available, the variants were demonstrated to represent de novo mutations. All variant alleles are predicted to result in a premature termination codon within the last exon, escape nonsense-mediated decay (NMD), and most likely generate a C-terminally truncated protein with a distinct −1 reading-frame terminus. Study of the transcripts extracted from affected subjects’ leukocytes confirmed expression of both wild-type and variant alleles, supporting the hypothesis that mutant mRNA escapes NMD. Genomic variants identified in our study suggest that truncation of the C-terminal domain of DVL1, a protein hypothesized to have a downstream role in the Wnt-5a non-canonical pathway, is a common cause of DRS. [ABSTRACT FROM AUTHOR]

Published

2015

9. A Drosophila Genetic Resource of Mutants to Study Mechanisms Underlying Human Genetic Diseases.

Author

Yamamoto, Shinya, Jaiswal, Manish, Charng, Wu-Lin, Gambin, Tomasz, Karaca, Ender, Mirzaa, Ghayda, Wiszniewski, Wojciech, Sandoval, Hector, Haelterman, Nele A., Xiong, Bo, Zhang, Ke, Bayat, Vafa, David, Gabriela, Li, Tongchao, Chen, Kuchuan, Gala, Upasana, Harel, Tamar, Pehlivan, Davut, Penney, Samantha, and Vissers, Lisenka E.L.M.

Subjects

*GENETIC disorders, *DROSOPHILA, *INVERTEBRATES as laboratory animals, *GENETIC mutation, *CHROMOSOMES

Abstract

Summary Invertebrate model systems are powerful tools for studying human disease owing to their genetic tractability and ease of screening. We conducted a mosaic genetic screen of lethal mutations on the Drosophila X chromosome to identify genes required for the development, function, and maintenance of the nervous system. We identified 165 genes, most of whose function has not been studied in vivo. In parallel, we investigated rare variant alleles in 1,929 human exomes from families with unsolved Mendelian disease. Genes that are essential in flies and have multiple human homologs were found to be likely to be associated with human diseases. Merging the human data sets with the fly genes allowed us to identify disease-associated mutations in six families and to provide insights into microcephaly associated with brain dysgenesis. This bidirectional synergism between fly genetics and human genomics facilitates the functional annotation of evolutionarily conserved genes involved in human health. [ABSTRACT FROM AUTHOR]

Published

2014

10. PGM3 Mutations Cause a Congenital Disorder of Glycosylation with Severe Immunodeficiency and Skeletal Dysplasia.

Author

Stray-Pedersen, Asbjørg, Backe, Paul H., Sorte, Hanne S., Mørkrid, Lars, Chokshi, Niti Y., Erichsen, Hans Christian, Gambin, Tomasz, Elgstøen, Katja B. P., Bjørås, Magnar, Wlodarski, Marcin W., Krüger, Marcus, Jhangiani, Shalini N., Muzny, Donna M., Patel, Ankita, Raymond, Kimiyo M., Sasa, Ghadir S., Krance, Robert A., Martinez, Caridad A., Abraham, Shirley M., and Speckmann, Carsten

Subjects

*PHOSPHOGLUCOMUTASE, *GENETIC mutation, *CONGENITAL disorders, *GLYCOSYLATION, *IMMUNODEFICIENCY, *SKELETAL dysplasia, *URIDINE diphosphate, *RNA sequencing

Abstract

Human phosphoglucomutase 3 (PGM3) catalyzes the conversion of N-acetyl-glucosamine (GlcNAc)-6-phosphate into GlcNAc-1-phosphate during the synthesis of uridine diphosphate (UDP)-GlcNAc, a sugar nucleotide critical to multiple glycosylation pathways. We identified three unrelated children with recurrent infections, congenital leukopenia including neutropenia, B and T cell lymphopenia, and progression to bone marrow failure. Whole-exome sequencing demonstrated deleterious mutations in PGM3 in all three subjects, delineating their disease to be due to an unsuspected congenital disorder of glycosylation (CDG). Functional studies of the disease-associated PGM3 variants in E. coli cells demonstrated reduced PGM3 activity for all mutants tested. Two of the three children had skeletal anomalies resembling Desbuquois dysplasia: short stature, brachydactyly, dysmorphic facial features, and intellectual disability. However, these additional features were absent in the third child, showing the clinical variability of the disease. Two children received hematopoietic stem cell transplantation of cord blood and bone marrow from matched related donors; both had successful engraftment and correction of neutropenia and lymphopenia. We define PGM3-CDG as a treatable immunodeficiency, document the power of whole-exome sequencing in gene discoveries for rare disorders, and illustrate the utility of genomic analyses in studying combined and variable phenotypes. [ABSTRACT FROM AUTHOR]

Published

2014

11. Human CLP1 Mutations Alter tRNA Biogenesis, Affecting Both Peripheral and Central Nervous System Function.

Author

Karaca, Ender, Weitzer, Stefan, Pehlivan, Davut, Shiraishi, Hiroshi, Gogakos, Tasos, Hanada, Toshikatsu, Jhangiani, Shalini?N., Wiszniewski, Wojciech, Withers, Marjorie, Campbell, Ian?M., Erdin, Serkan, Isikay, Sedat, Franco, Luis?M., Gonzaga-Jauregui, Claudia, Gambin, Tomasz, Gelowani, Violet, Hunter, Jill?V., Yesil, Gozde, Koparir, Erkan, and Yilmaz, Sarenur

Subjects

*GENETIC mutation, *TRANSFER RNA, *PERIPHERAL nervous system, *CENTRAL nervous system, *RNA splicing, *NEUROMUSCULAR diseases, *MOTOR neurons, *PARALYSIS

Abstract

Summary: CLP1 is a RNA kinase involved in tRNA splicing. Recently, CLP1 kinase-dead mice were shown to display a neuromuscular disorder with loss of motor neurons and muscle paralysis. Human genome analyses now identified a CLP1 homozygous missense mutation (p.R140H) in five unrelated families, leading to a loss of CLP1 interaction with the tRNA splicing endonuclease (TSEN) complex, largely reduced pre-tRNA cleavage activity, and accumulation of linear tRNA introns. The affected individuals develop severe motor-sensory defects, cortical dysgenesis, and microcephaly. Mice carrying kinase-dead CLP1 also displayed microcephaly and reduced cortical brain volume due to the enhanced cell death of neuronal progenitors that is associated with reduced numbers of cortical neurons. Our data elucidate a neurological syndrome defined by CLP1 mutations that impair tRNA splicing. Reduction of a founder mutation to homozygosity illustrates the importance of rare variations in disease and supports the clan genomics hypothesis. [Copyright &y& Elsevier]

Published

2014

12. An Organismal CNV Mutator Phenotype Restricted to Early Human Development.

Author

Liu, Pengfei, Yuan, Bo, Carvalho, Claudia M.B., Wuster, Arthur, Walter, Klaudia, Zhang, Ling, Gambin, Tomasz, Chong, Zechen, Campbell, Ian M., Coban Akdemir, Zeynep, Gelowani, Violet, Writzl, Karin, Bacino, Carlos A., Lindsay, Sarah J., Withers, Marjorie, Gonzaga-Jauregui, Claudia, Wiszniewska, Joanna, Scull, Jennifer, Stankiewicz, Paweł, and Jhangiani, Shalini N.

Subjects

*GENETIC disorders, *HUMAN evolution, *PHENOTYPES, *GENOMES, *EMBRYOLOGY, *MUTAGENESIS

Abstract

Summary De novo copy number variants (dnCNVs) arising at multiple loci in a personal genome have usually been considered to reflect cancer somatic genomic instabilities. We describe a multiple dnCNV (MdnCNV) phenomenon in which individuals with genomic disorders carry five to ten constitutional dnCNVs. These CNVs originate from independent formation incidences, are predominantly tandem duplications or complex gains, exhibit breakpoint junction features reminiscent of replicative repair, and show increased de novo point mutations flanking the rearrangement junctions. The active CNV mutation shower appears to be restricted to a transient perizygotic period. We propose that a defect in the CNV formation process is responsible for the “CNV-mutator state,” and this state is dampened after early embryogenesis. The constitutional MdnCNV phenomenon resembles chromosomal instability in various cancers. Investigations of this phenomenon may provide unique access to understanding genomic disorders, structural variant mutagenesis, human evolution, and cancer biology. [ABSTRACT FROM AUTHOR]

Published

2017

13. Exome Sequence Analysis Suggests that Genetic Burden Contributes to Phenotypic Variability and Complex Neuropathy.

Author

Gonzaga-Jauregui C, Harel T, Gambin T, Kousi M, Griffin LB, Francescatto L, Ozes B, Karaca E, Jhangiani SN, Bainbridge MN, Lawson KS, Pehlivan D, Okamoto Y, Withers M, Mancias P, Slavotinek A, Reitnauer PJ, Goksungur MT, Shy M, Crawford TO, Koenig M, Willer J, Flores BN, Pediaditrakis I, Us O, Wiszniewski W, Parman Y, Antonellis A, Muzny DM, Katsanis N, Battaloglu E, Boerwinkle E, Gibbs RA, and Lupski JR

Subjects

Animals, Female, Genetic Variation, HSP40 Heat-Shock Proteins genetics, Humans, Male, Mutation, Myelin P2 Protein genetics, Pedigree, Penetrance, Serine C-Palmitoyltransferase genetics, Suppression, Genetic, Zebrafish, Charcot-Marie-Tooth Disease genetics, Exome, Genetic Load, Peripheral Nervous System Diseases genetics, Phenotype

Abstract

Charcot-Marie-Tooth (CMT) disease is a clinically and genetically heterogeneous distal symmetric polyneuropathy. Whole-exome sequencing (WES) of 40 individuals from 37 unrelated families with CMT-like peripheral neuropathy refractory to molecular diagnosis identified apparent causal mutations in ∼ 45% (17/37) of families. Three candidate disease genes are proposed, supported by a combination of genetic and in vivo studies. Aggregate analysis of mutation data revealed a significantly increased number of rare variants across 58 neuropathy-associated genes in subjects versus controls, confirmed in a second ethnically discrete neuropathy cohort, suggesting that mutation burden potentially contributes to phenotypic variability. Neuropathy genes shown to have highly penetrant Mendelizing variants (HPMVs) and implicated by burden in families were shown to interact genetically in a zebrafish assay exacerbating the phenotype established by the suppression of single genes. Our findings suggest that the combinatorial effect of rare variants contributes to disease burden and variable expressivity., (Copyright © 2015 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2015