A Novel Mecp2Y120D Knock-in Model Displays Similar Behavioral Traits But Distinct Molecular Features Compared to the Mecp2-Null Mouse Implying Precision Medicine for the Treatment of Rett Syndrome

MeCP2 is a fundamental protein associated with several neurological disorders, including Rett syndrome. It is considered a multifunctional factor with a prominent role in regulating chromatin structure; however, a full comprehension of the consequences of its deficiency is still lacking. Here, we ch...

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Veröffentlicht in:Molecular neurobiology 2019-07, Vol.56 (7), p.4838-4854
Hauptverfasser: Gandaglia, Anna, Brivio, Elena, Carli, Sara, Palmieri, Michela, Bedogni, Francesco, Stefanelli, Gilda, Bergo, Anna, Leva, Barbara, Cattaneo, Chiara, Pizzamiglio, Lara, Cicerone, Marco, Bianchi, Veronica, Kilstrup-Nielsen, Charlotte, D’Annessa, Ilda, Di Marino, Daniele, D’Adamo, Patrizia, Antonucci, Flavia, Frasca, Angelisa, Landsberger, Nicoletta
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container_end_page 4854
container_issue 7
container_start_page 4838
container_title Molecular neurobiology
container_volume 56
creator Gandaglia, Anna
Brivio, Elena
Carli, Sara
Palmieri, Michela
Bedogni, Francesco
Stefanelli, Gilda
Bergo, Anna
Leva, Barbara
Cattaneo, Chiara
Pizzamiglio, Lara
Cicerone, Marco
Bianchi, Veronica
Kilstrup-Nielsen, Charlotte
D’Annessa, Ilda
Di Marino, Daniele
D’Adamo, Patrizia
Antonucci, Flavia
Frasca, Angelisa
Landsberger, Nicoletta
description MeCP2 is a fundamental protein associated with several neurological disorders, including Rett syndrome. It is considered a multifunctional factor with a prominent role in regulating chromatin structure; however, a full comprehension of the consequences of its deficiency is still lacking. Here, we characterize a novel mouse model of Mecp2 bearing the human mutation Y120D, which is localized in the methyl-binding domain. As most models of Mecp2 , the Mecp2 Y120D mouse develops a severe Rett-like phenotype. This mutation alters the interaction of the protein with chromatin, but surprisingly, it also impairs its association with corepressors independently on the involved interacting domains. These features, which become overt mainly in the mature brain, cause a more accessible and transcriptionally active chromatin structure; conversely, in the Mecp2 -null brain, we find a less accessible and transcriptionally inactive chromatin. By demonstrating that different MECP2 mutations can produce concordant neurological phenotypes but discordant molecular features, we highlight the importance of considering personalized approaches for the treatment of Rett syndrome.
doi_str_mv 10.1007/s12035-018-1412-2
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subjects Biomedical and Life Sciences
Biomedicine
Cell Biology
Neurobiology
Neurology
Neurosciences
title A Novel Mecp2Y120D Knock-in Model Displays Similar Behavioral Traits But Distinct Molecular Features Compared to the Mecp2-Null Mouse Implying Precision Medicine for the Treatment of Rett Syndrome
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