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Auteur C. H. KIM |
Documents disponibles écrits par cet auteur (2)
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Disruption of PHF21A causes syndromic intellectual disability with craniofacial anomalies, epilepsy, hypotonia, and neurobehavioral problems including autism / H. G. KIM in Molecular Autism, 10 (2019)
[article]
Titre : Disruption of PHF21A causes syndromic intellectual disability with craniofacial anomalies, epilepsy, hypotonia, and neurobehavioral problems including autism Type de document : Texte imprimé et/ou numérique Auteurs : H. G. KIM, Auteur ; J. A. ROSENFELD, Auteur ; D. A. SCOTT, Auteur ; G. BENEDICTE, Auteur ; J. D. LABONNE, Auteur ; J. BROWN, Auteur ; M. MCGUIRE, Auteur ; S. MAHIDA, Auteur ; S. NAIDU, Auteur ; J. GUTIERREZ, Auteur ; G. LESCA, Auteur ; V. DES PORTES, Auteur ; A. L. BRUEL, Auteur ; A. SORLIN, Auteur ; F. XIA, Auteur ; Y. CAPRI, Auteur ; E. MULLER, Auteur ; D. MCKNIGHT, Auteur ; E. TORTI, Auteur ; F. RUSCHENDORF, Auteur ; O. HUMMEL, Auteur ; Z. ISLAM, Auteur ; P. R. KOLATKAR, Auteur ; L. C. LAYMAN, Auteur ; D. RYU, Auteur ; I. K. KONG, Auteur ; S. MADAN-KHETARPAL, Auteur ; C. H. KIM, Auteur Article en page(s) : 35 p. Langues : Anglais (eng) Mots-clés : AT Hook domain Autism spectrum disorder (ASD) Bhc80 Intellectual disability (ID) Intrinsically disordered region (IDR) Kdm1a Neurodevelopmental disorders Phf21a Potocki-Shaffer syndrome (PSS) Index. décimale : PER Périodiques Résumé : Background: PHF21A has been associated with intellectual disability and craniofacial anomalies based on its deletion in the Potocki-Shaffer syndrome region at 11p11.2 and its disruption in three patients with balanced translocations. In addition, three patients with de novo truncating mutations in PHF21A were reported recently. Here, we analyze genomic data from seven unrelated individuals with mutations in PHF21A and provide detailed clinical descriptions, further expanding the phenotype associated with PHF21A haploinsufficiency. Methods: Diagnostic trio whole exome sequencing, Sanger sequencing, use of GeneMatcher, targeted gene panel sequencing, and MiSeq sequencing techniques were used to identify and confirm variants. RT-qPCR was used to measure the normal expression pattern of PHF21A in multiple human tissues including 13 different brain tissues. Protein-DNA modeling was performed to substantiate the pathogenicity of the missense mutation. Results: We have identified seven heterozygous coding mutations, among which six are de novo (not maternal in one). Mutations include four frameshifts, one nonsense mutation in two patients, and one heterozygous missense mutation in the AT Hook domain, predicted to be deleterious and likely to cause loss of PHF21A function. We also found a new C-terminal domain composed of an intrinsically disordered region. This domain is truncated in six patients and thus likely to play an important role in the function of PHF21A, suggesting that haploinsufficiency is the likely underlying mechanism in the phenotype of seven patients. Our results extend the phenotypic spectrum of PHF21A mutations by adding autism spectrum disorder, epilepsy, hypotonia, and neurobehavioral problems. Furthermore, PHF21A is highly expressed in the human fetal brain, which is consistent with the neurodevelopmental phenotype. Conclusion: Deleterious nonsense, frameshift, and missense mutations disrupting the AT Hook domain and/or an intrinsically disordered region in PHF21A were found to be associated with autism spectrum disorder, epilepsy, hypotonia, neurobehavioral problems, tapering fingers, clinodactyly, and syndactyly, in addition to intellectual disability and craniofacial anomalies. This suggests that PHF21A is involved in autism spectrum disorder and intellectual disability, and its haploinsufficiency causes a diverse neurological phenotype. En ligne : https://dx.doi.org/10.1186/s13229-019-0286-0 Permalink : https://www.cra-rhone-alpes.org/cid/opac_css/index.php?lvl=notice_display&id=408
in Molecular Autism > 10 (2019) . - 35 p.[article] Disruption of PHF21A causes syndromic intellectual disability with craniofacial anomalies, epilepsy, hypotonia, and neurobehavioral problems including autism [Texte imprimé et/ou numérique] / H. G. KIM, Auteur ; J. A. ROSENFELD, Auteur ; D. A. SCOTT, Auteur ; G. BENEDICTE, Auteur ; J. D. LABONNE, Auteur ; J. BROWN, Auteur ; M. MCGUIRE, Auteur ; S. MAHIDA, Auteur ; S. NAIDU, Auteur ; J. GUTIERREZ, Auteur ; G. LESCA, Auteur ; V. DES PORTES, Auteur ; A. L. BRUEL, Auteur ; A. SORLIN, Auteur ; F. XIA, Auteur ; Y. CAPRI, Auteur ; E. MULLER, Auteur ; D. MCKNIGHT, Auteur ; E. TORTI, Auteur ; F. RUSCHENDORF, Auteur ; O. HUMMEL, Auteur ; Z. ISLAM, Auteur ; P. R. KOLATKAR, Auteur ; L. C. LAYMAN, Auteur ; D. RYU, Auteur ; I. K. KONG, Auteur ; S. MADAN-KHETARPAL, Auteur ; C. H. KIM, Auteur . - 35 p.
Langues : Anglais (eng)
in Molecular Autism > 10 (2019) . - 35 p.
Mots-clés : AT Hook domain Autism spectrum disorder (ASD) Bhc80 Intellectual disability (ID) Intrinsically disordered region (IDR) Kdm1a Neurodevelopmental disorders Phf21a Potocki-Shaffer syndrome (PSS) Index. décimale : PER Périodiques Résumé : Background: PHF21A has been associated with intellectual disability and craniofacial anomalies based on its deletion in the Potocki-Shaffer syndrome region at 11p11.2 and its disruption in three patients with balanced translocations. In addition, three patients with de novo truncating mutations in PHF21A were reported recently. Here, we analyze genomic data from seven unrelated individuals with mutations in PHF21A and provide detailed clinical descriptions, further expanding the phenotype associated with PHF21A haploinsufficiency. Methods: Diagnostic trio whole exome sequencing, Sanger sequencing, use of GeneMatcher, targeted gene panel sequencing, and MiSeq sequencing techniques were used to identify and confirm variants. RT-qPCR was used to measure the normal expression pattern of PHF21A in multiple human tissues including 13 different brain tissues. Protein-DNA modeling was performed to substantiate the pathogenicity of the missense mutation. Results: We have identified seven heterozygous coding mutations, among which six are de novo (not maternal in one). Mutations include four frameshifts, one nonsense mutation in two patients, and one heterozygous missense mutation in the AT Hook domain, predicted to be deleterious and likely to cause loss of PHF21A function. We also found a new C-terminal domain composed of an intrinsically disordered region. This domain is truncated in six patients and thus likely to play an important role in the function of PHF21A, suggesting that haploinsufficiency is the likely underlying mechanism in the phenotype of seven patients. Our results extend the phenotypic spectrum of PHF21A mutations by adding autism spectrum disorder, epilepsy, hypotonia, and neurobehavioral problems. Furthermore, PHF21A is highly expressed in the human fetal brain, which is consistent with the neurodevelopmental phenotype. Conclusion: Deleterious nonsense, frameshift, and missense mutations disrupting the AT Hook domain and/or an intrinsically disordered region in PHF21A were found to be associated with autism spectrum disorder, epilepsy, hypotonia, neurobehavioral problems, tapering fingers, clinodactyly, and syndactyly, in addition to intellectual disability and craniofacial anomalies. This suggests that PHF21A is involved in autism spectrum disorder and intellectual disability, and its haploinsufficiency causes a diverse neurological phenotype. En ligne : https://dx.doi.org/10.1186/s13229-019-0286-0 Permalink : https://www.cra-rhone-alpes.org/cid/opac_css/index.php?lvl=notice_display&id=408 Zebrafish knockout of Down syndrome gene, DYRK1A, shows social impairments relevant to autism / O. H. KIM in Molecular Autism, 8 (2017)
[article]
Titre : Zebrafish knockout of Down syndrome gene, DYRK1A, shows social impairments relevant to autism Type de document : Texte imprimé et/ou numérique Auteurs : O. H. KIM, Auteur ; H. J. CHO, Auteur ; E. HAN, Auteur ; T. I. HONG, Auteur ; K. ARIYASIRI, Auteur ; J. H. CHOI, Auteur ; K. S. HWANG, Auteur ; Y. M. JEONG, Auteur ; S. Y. YANG, Auteur ; K. YU, Auteur ; D. S. PARK, Auteur ; H. W. OH, Auteur ; E. E. DAVIS, Auteur ; C. E. SCHWARTZ, Auteur ; J. S. LEE, Auteur ; H. G. KIM, Auteur ; C. H. KIM, Auteur Article en page(s) : 50p. Langues : Anglais (eng) Mots-clés : Autism Dyrk1a Down syndrome Group behavior Knockout Shoaling Social interaction Zebrafish Index. décimale : PER Périodiques Résumé : BACKGROUND: DYRK1A maps to the Down syndrome critical region at 21q22. Mutations in this kinase-encoding gene have been reported to cause microcephaly associated with either intellectual disability or autism in humans. Intellectual disability accompanied by microcephaly was recapitulated in a murine model by overexpressing Dyrk1a which mimicked Down syndrome phenotypes. However, given embryonic lethality in homozygous knockout (KO) mice, no murine model studies could present sufficient evidence to link Dyrk1a dysfunction with autism. To understand the molecular mechanisms underlying microcephaly and autism spectrum disorders (ASD), we established an in vivo dyrk1aa KO model using zebrafish. METHODS: We identified a patient with a mutation in the DYRK1A gene using microarray analysis. Circumventing the barrier of murine model studies, we generated a dyrk1aa KO zebrafish using transcription activator-like effector nuclease (TALEN)-mediated genome editing. For social behavioral tests, we have established a social interaction test, shoaling assay, and group behavior assay. For molecular analysis, we examined the neuronal activity in specific brain regions of dyrk1aa KO zebrafish through in situ hybridization with various probes including c-fos and crh which are the molecular markers for stress response. RESULTS: Microarray detected an intragenic microdeletion of DYRK1A in an individual with microcephaly and autism. From behavioral tests of social interaction and group behavior, dyrk1aa KO zebrafish exhibited social impairments that reproduce human phenotypes of autism in a vertebrate animal model. Social impairment in dyrk1aa KO zebrafish was further confirmed by molecular analysis of c-fos and crh expression. Transcriptional expression of c-fos and crh was lower than that of wild type fish in specific hypothalamic regions, suggesting that KO fish brains are less activated by social context. CONCLUSIONS: In this study, we established a zebrafish model to validate a candidate gene for autism in a vertebrate animal. These results illustrate the functional deficiency of DYRK1A as an underlying disease mechanism for autism. We also propose simple social behavioral assays as a tool for the broader study of autism candidate genes. En ligne : http://dx.doi.org/10.1186/s13229-017-0168-2 Permalink : https://www.cra-rhone-alpes.org/cid/opac_css/index.php?lvl=notice_display&id=330
in Molecular Autism > 8 (2017) . - 50p.[article] Zebrafish knockout of Down syndrome gene, DYRK1A, shows social impairments relevant to autism [Texte imprimé et/ou numérique] / O. H. KIM, Auteur ; H. J. CHO, Auteur ; E. HAN, Auteur ; T. I. HONG, Auteur ; K. ARIYASIRI, Auteur ; J. H. CHOI, Auteur ; K. S. HWANG, Auteur ; Y. M. JEONG, Auteur ; S. Y. YANG, Auteur ; K. YU, Auteur ; D. S. PARK, Auteur ; H. W. OH, Auteur ; E. E. DAVIS, Auteur ; C. E. SCHWARTZ, Auteur ; J. S. LEE, Auteur ; H. G. KIM, Auteur ; C. H. KIM, Auteur . - 50p.
Langues : Anglais (eng)
in Molecular Autism > 8 (2017) . - 50p.
Mots-clés : Autism Dyrk1a Down syndrome Group behavior Knockout Shoaling Social interaction Zebrafish Index. décimale : PER Périodiques Résumé : BACKGROUND: DYRK1A maps to the Down syndrome critical region at 21q22. Mutations in this kinase-encoding gene have been reported to cause microcephaly associated with either intellectual disability or autism in humans. Intellectual disability accompanied by microcephaly was recapitulated in a murine model by overexpressing Dyrk1a which mimicked Down syndrome phenotypes. However, given embryonic lethality in homozygous knockout (KO) mice, no murine model studies could present sufficient evidence to link Dyrk1a dysfunction with autism. To understand the molecular mechanisms underlying microcephaly and autism spectrum disorders (ASD), we established an in vivo dyrk1aa KO model using zebrafish. METHODS: We identified a patient with a mutation in the DYRK1A gene using microarray analysis. Circumventing the barrier of murine model studies, we generated a dyrk1aa KO zebrafish using transcription activator-like effector nuclease (TALEN)-mediated genome editing. For social behavioral tests, we have established a social interaction test, shoaling assay, and group behavior assay. For molecular analysis, we examined the neuronal activity in specific brain regions of dyrk1aa KO zebrafish through in situ hybridization with various probes including c-fos and crh which are the molecular markers for stress response. RESULTS: Microarray detected an intragenic microdeletion of DYRK1A in an individual with microcephaly and autism. From behavioral tests of social interaction and group behavior, dyrk1aa KO zebrafish exhibited social impairments that reproduce human phenotypes of autism in a vertebrate animal model. Social impairment in dyrk1aa KO zebrafish was further confirmed by molecular analysis of c-fos and crh expression. Transcriptional expression of c-fos and crh was lower than that of wild type fish in specific hypothalamic regions, suggesting that KO fish brains are less activated by social context. CONCLUSIONS: In this study, we established a zebrafish model to validate a candidate gene for autism in a vertebrate animal. These results illustrate the functional deficiency of DYRK1A as an underlying disease mechanism for autism. We also propose simple social behavioral assays as a tool for the broader study of autism candidate genes. En ligne : http://dx.doi.org/10.1186/s13229-017-0168-2 Permalink : https://www.cra-rhone-alpes.org/cid/opac_css/index.php?lvl=notice_display&id=330