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https://www.arca.fiocruz.br/handle/icict/11402
DOSAGE CHANGES OF A SEGMENT AT 17P13.1 LEAD TO INTELLECTUAL DISABILITY AND MICROCEPHALY AS A RESULT OF COMPLEX GENETIC INTERACTION OF MULTIPLE GENES
Chromosomes, Human, Pair 17/genetics
Molecular Sequence Data
Sequence Analysis, DNA
Author
Fonseca, Claudia Marcia Benedetto de Carvalho
Vasanth, Shivakumar
Shinawi, Marwan
Russell, Chad
Ramocki, Melissa B.
Brown, Chester W.
Graakjaer, Jesper
Bine Skytte, Anne
Morgante, Angela Maria Vianna
Krepischi, Ana Cristina Victorino
Patel, Gayle S.
Immken, LaDonna
Aleck, Kyrieckos
Lim, Cynthia
Cheung, Sau Wai
Rosenberg, Carla
Katsanis, Nicholas
Vasanth, Shivakumar
Shinawi, Marwan
Russell, Chad
Ramocki, Melissa B.
Brown, Chester W.
Graakjaer, Jesper
Bine Skytte, Anne
Morgante, Angela Maria Vianna
Krepischi, Ana Cristina Victorino
Patel, Gayle S.
Immken, LaDonna
Aleck, Kyrieckos
Lim, Cynthia
Cheung, Sau Wai
Rosenberg, Carla
Katsanis, Nicholas
Affilliation
Baylor College of Medicine. Department of Molecular and Human Genetics. Houston, TX, USA /Fundação Oswaldo Cruz. Centro de Pesquisas Rene Rachou. Belo Horizonte, MG, Brazil
Duke University. Center for Human Disease Modeling.Durham, NC, USA
Washington University . Division of Genetics and Genomic Medicine. Department of Pediatrics. St Louis, MO, USA
Duke University. Center for Human Disease Modeling.Durham, NC, USA
Baylor College of Medicine. Department of Pediatrics. Houston, TX, USA/ Texas Children’s Hospital. Houston, TX , USA
Baylor College of Medicine. Department of Molecular and Human Genetics. Houston, TX, USA /Baylor College of Medicine. Department of Pediatrics. Houston, TX, USA/ Texas Children’s Hospital. Houston, TX , USA
Vejle Hospital. Clinical Genetics Department. Vejle, Denmark
Vejle Hospital. Clinical Genetics Department. Vejle, Denmark
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Texas Oncology. Austin, TX, USA
Specially for Children. Austin, TX, USA
Phoenix Children’s Hospital. Phoenix, AZ, USA
Phoenix Children’s Hospital. Phoenix, AZ, USA
Baylor College of Medicine. Department of Molecular and Human Genetics. Houston, TX, USA
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Duke University. Center for Human Disease Modeling. Durham, NC, USA
Duke University. Center for Human Disease Modeling.Durham, NC, USA
Washington University . Division of Genetics and Genomic Medicine. Department of Pediatrics. St Louis, MO, USA
Duke University. Center for Human Disease Modeling.Durham, NC, USA
Baylor College of Medicine. Department of Pediatrics. Houston, TX, USA/ Texas Children’s Hospital. Houston, TX , USA
Baylor College of Medicine. Department of Molecular and Human Genetics. Houston, TX, USA /Baylor College of Medicine. Department of Pediatrics. Houston, TX, USA/ Texas Children’s Hospital. Houston, TX , USA
Vejle Hospital. Clinical Genetics Department. Vejle, Denmark
Vejle Hospital. Clinical Genetics Department. Vejle, Denmark
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Texas Oncology. Austin, TX, USA
Specially for Children. Austin, TX, USA
Phoenix Children’s Hospital. Phoenix, AZ, USA
Phoenix Children’s Hospital. Phoenix, AZ, USA
Baylor College of Medicine. Department of Molecular and Human Genetics. Houston, TX, USA
Universidade de São Paulo. Instituto de Biociencias. Departamento de Genetica e Evolução Biologica. Sao Paulo, SP, Brazil
Duke University. Center for Human Disease Modeling. Durham, NC, USA
Abstract
The 17p13.1 microdeletion syndrome is a recently described genomic disorder with a core clinical phenotype of intellectual disability, poor to absent speech, dysmorphic features, and a constellation of more variable clinical features, most prominently microcephaly. We identified five subjects with copy-number variants (CNVs) on 17p13.1 for whom we performed detailed clinical and molecular studies. Breakpoint mapping and retrospective analysis of published cases refined the smallest region of overlap (SRO) for microcephaly to a genomic interval containing nine genes. Dissection of this phenotype in zebrafish embryos revealed a complex genetic architecture: dosage perturbation of four genes (ASGR1, ACADVL, DVL2, and GABARAP) impeded neurodevelopment and decreased dosage of the same loci caused a reduced mitotic index in vitro. Moreover, epistatic analyses in vivo showed that dosage perturbations of discrete gene pairings induce microcephaly. Taken together, these studies support a model in which concomitant dosage perturbation of multiple genes within the CNV drive the microcephaly and possibly other neurodevelopmental phenotypes associated with rearrangements in the 17p13.1 SRO.
Keywords
Abnormalities, Multiple/geneticsChromosomes, Human, Pair 17/genetics
Molecular Sequence Data
Sequence Analysis, DNA
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