vm3g6x1x

Property	Value
?:abstract	Variations in the Forkhead Box G1 (FOXG1) gene cause FOXG1 syndrome spectrum, including the congenital variant of Rett syndrome, characterized by early onset of regression, Rett-like and jerky movements, and cortical visual impairment. Due to the largely unknown pathophysiological mechanisms downstream the impairment of this transcriptional regulator, a specific treatment is not yet available. Since both haploinsufficiency and hyper-expression of FOXG1 cause diseases in humans, we reasoned that adding a gene under nonnative regulatory sequences would be a risky strategy as opposed to a genome editing approach where the mutated gene is reversed into wild-type. Here, we demonstrate that an adeno-associated viruses (AAVs)-coupled CRISPR/Cas9 system is able to target and correct FOXG1 variants in patient-derived fibroblasts, induced Pluripotent Stem Cells (iPSCs) and iPSC-derived neurons. Variant-specific single-guide RNAs (sgRNAs) and donor DNAs have been selected and cloned together with a mCherry/EGFP reporter system. Specific sgRNA recognition sequences were inserted upstream and downstream Cas9 CDS to allow self-cleavage and inactivation. We demonstrated that AAV serotypes vary in transduction efficiency depending on the target cell type, the best being AAV9 in fibroblasts and iPSC-derived neurons, and AAV2 in iPSCs. Next-generation sequencing (NGS) of mCherry(+)/EGFP(+) transfected cells demonstrated that the mutated alleles were repaired with high efficiency (20–35% reversion) and precision both in terms of allelic discrimination and off-target activity. The genome editing strategy tested in this study has proven to precisely repair FOXG1 and delivery through an AAV9-based system represents a step forward toward the development of a therapy for Rett syndrome.
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?:creator	<https://research.tib.eu/covid-19/entity/Croci%2C_Susanna%3B_Carriero%2C_Miriam_Lucia%3B_Capitani%2C_Katia%3B_Daga%2C_Sergio%3B_Donati%2C_Francesco%3B_Papa%2C_Filomena_Tiziana%3B_Frullanti%2C_Elisa%3B_Lopergolo%2C_Diego%3B_Lamacchia%2C_Vittoria%3B_Tita%2C_Rossella%3B_Giliberti%2C_Annarita%3B_Benetti%2C_Elisa%3B_Niccheri%2C_Francesca%3B_Furini%2C_Simone%3B_Lo_Rizzo%2C_Caterina%3B_Conticello%2C_Silvestro_Giovanni%3B_Renieri%2C_Alessandra%3B_Meloni%2C_Ilaria>
?:doi	10.1038/s41431-020-0652-6
?:doi	<https://research.tib.eu/covid-19/entity/10.1038/s41431-020-0652-6>
?:externalLink	<https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7608362/>
?:journal	Eur_J_Hum_Genet
?:license	no-cc
?:pdf_json_files	document_parses/pdf_json/a0674979cc15c4340590a98e196bba12b5c69d2e.json
?:pmc_json_files	document_parses/pmc_json/PMC7608362.xml.json
?:pmcid	<https://research.tib.eu/covid-19/entity/PMC7608362>
?:pmid	<https://research.tib.eu/covid-19/entity/32541681>
?:pmid	32541681
?:publication_isRelatedTo_Disease	<https://research.tib.eu/covid-19/entity/COVID-19>
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?:sha_id	<https://research.tib.eu/covid-19/entity/a0674979cc15c4340590a98e196bba12b5c69d2e>
?:source	PMC
?:title	AAV-mediated FOXG1 gene editing in human Rett primary cells
?:type	<https://research.tib.eu/covid-19/vocab/Publication>
?:year	2020-06-15

Property

Value

?:abstract

Variations in the Forkhead Box G1 (FOXG1) gene cause FOXG1 syndrome spectrum, including the congenital variant of Rett syndrome, characterized by early onset of regression, Rett-like and jerky movements, and cortical visual impairment. Due to the largely unknown pathophysiological mechanisms downstream the impairment of this transcriptional regulator, a specific treatment is not yet available. Since both haploinsufficiency and hyper-expression of FOXG1 cause diseases in humans, we reasoned that adding a gene under nonnative regulatory sequences would be a risky strategy as opposed to a genome editing approach where the mutated gene is reversed into wild-type. Here, we demonstrate that an adeno-associated viruses (AAVs)-coupled CRISPR/Cas9 system is able to target and correct FOXG1 variants in patient-derived fibroblasts, induced Pluripotent Stem Cells (iPSCs) and iPSC-derived neurons. Variant-specific single-guide RNAs (sgRNAs) and donor DNAs have been selected and cloned together with a mCherry/EGFP reporter system. Specific sgRNA recognition sequences were inserted upstream and downstream Cas9 CDS to allow self-cleavage and inactivation. We demonstrated that AAV serotypes vary in transduction efficiency depending on the target cell type, the best being AAV9 in fibroblasts and iPSC-derived neurons, and AAV2 in iPSCs. Next-generation sequencing (NGS) of mCherry(+)/EGFP(+) transfected cells demonstrated that the mutated alleles were repaired with high efficiency (20–35% reversion) and precision both in terms of allelic discrimination and off-target activity. The genome editing strategy tested in this study has proven to precisely repair FOXG1 and delivery through an AAV9-based system represents a step forward toward the development of a therapy for Rett syndrome.

is ?:annotates of