Loss of UBE3A expression, a gene regulated by genomic imprinting, causes Angelman Syndrome (AS), a rare neurodevelopmental disorder. The UBE3A gene encodes an E3 ubiquitin ligase with three known protein isoforms in humans. Studies in mouse suggest that the human isoforms may have differences in localization and neuronal function. A recent case study reported mild AS phenotypes in individuals lacking one specific isoform. Here we have used CRISPR/Cas9 to generate isogenic human embryonic stem cells (hESCs) that lack the individual protein isoforms. We demonstrate that isoform 1 accounts for the majority of UBE3A protein in hESCs and neurons. We also show that UBE3A predominantly localizes to the cytoplasm in both wild type and isoform-null cells. Finally, we show that neurons lacking isoform 1 display a less severe electrophysiological AS phenotype.
Prader-Willi syndrome (PWS) is characterized by neonatal hypotonia, developmental delay, and hyperphagia/obesity. This disorder is caused by the absence of paternally-expressed gene products from chromosome 15q11-q13. We previously demonstrated that knocking out ZNF274, a KRAB-domain zinc finger protein capable of recruiting epigenetic machinery to deposit the H3K9me3 repressive histone modification, can activate expression from the normally silent maternal allele of SNORD116 in neurons derived from PWS iPSCs. However, ZNF274 has many other targets in the genome in addition to SNORD116. Depleting ZNF274 will surely affect the expression of other important genes and disrupt other pathways. Here we used CRISPR/Cas9 to delete ZNF274 binding sites at the SNORD116 locus to determine whether activation of the maternal copy of SNORD116 could be achieved without altering ZNF274 protein levels. We obtained similar activation of gene expression from the normally silenced maternal allele in neurons derived from PWS iPSCs, compared to ZNF274 knockout, demonstrating that ZNF274 is directly involved in the repression of SNORD116. These results suggest that interfering with ZNF274 binding at the maternal SNORD116 locus is a potential therapeutic strategy for PWS.
Angelman syndrome (AS) is a rare neurodevelopmental disorder caused by loss of function of the maternally inherited UBE3A allele. In neurons, the paternal allele of UBE3A is silenced in cis by the long noncoding RNA, UBE3A-ATS. Unsilencing paternal UBE3A by reducing UBE3A-ATS is a promising therapeutic approach for the treatment of AS. Here we show that targeted cleavage of UBE3A-ATS using antisense oligonucleotides (ASOs) restores UBE3A and rescues electrophysiological phenotypes in human AS neurons. We demonstrate that cleavage of UBE3A-ATS results in termination of its transcription by displacement of RNA Polymerase II. Reduced transcription of UBE3A-ATS allows transcription of UBE3A to proceed to completion, providing definitive evidence for the transcriptional interference model of paternal UBE3A silencing. These insights into the mechanism by which ASOs restore UBE3A inform the future development of nucleotide-based approaches for the treatment of AS, including alternative strategies for cleaving UBE3A-ATS that can be developed for long-term restoration of UBE3A function.
Loss of UBE3A expression, a gene regulated by genomic imprinting, causes Angelman Syndrome (AS), a rare neurodevelopmental disorder. The UBE3A gene encodes an E3 ubiquitin ligase with three known protein isoforms in humans. Studies in mouse suggest that the human isoforms may have differences in localization and neuronal function. A recent case study reported mild AS phenotypes in individuals lacking one specific isoform. Here we have used CRISPR/Cas9 to generate isogenic human embryonic stem cells (hESCs) that lack the individual protein isoforms. We demonstrate that isoform 1 accounts for the majority of UBE3A protein in hESCs and neurons. We also show that UBE3A predominantly localizes to the cytoplasm in both wild type and isoform-null cells. Finally, we show that neurons lacking isoform 1 display a less severe electrophysiological AS phenotype.Angelman Syndrome (AS) is a rare neurodevelopmental disorder that affects 1 in 15,000 individuals, and is characterized by severe seizures, intellectual disability, absent speech, ataxia, and happy affect 1 . AS is caused by loss of function from the maternally-inherited copy of UBE3A. UBE3A is regulated by tissue-specific genomic imprintingit is expressed exclusively from the maternal allele in neurons and is expressed biallelically in other cell types 2,3 . UBE3A encodes an E3 ubiquitin ligase that forms polyubiquitin chains to substrates, targeting them for degradation by the 26S proteasome 4 . In humans, there are three known UBE3A protein isoforms 5 , all of which include the Homologous to E6AP Carboxy Terminus (HECT) domain and are thus capable of functioning as an E3 ligase. Human isoforms 2 and 3 only differ from human isoform 1 by 23 and 20 amino acids, respectively, at their N termini 6 (Fig 1a). While there has been little published research examining the human protein isoforms in human cells, human isoforms ectopically expressed in mouse indicate that the isoforms likely have differences in localization and function 7-9 . Furthermore, it is currently unknown whether the different human isoforms have different abundances or functions. This knowledge is important as some therapeutic avenues currently being explored for AS involve delivery and expression of exogenous UBE3A transgenes using vector-based delivery 10 . For these approaches, knowledge of which of the protein isoforms need to be replaced in AS is essential.Recently, Sadhwani and colleagues published three cases of AS in two different families caused by missense mutations at the isoform 1 translational start site 11 . Interestingly, these patients present with milder phenotypes than AS patients with 15q11-q13 deletions or other UBE3A loss of function mutations, including normal gait and use of syntactic speech. This data, coupled with the fact that the human and mouse isoforms are not entirely conserved, illustrates the need to study the human UBE3A protein isoforms specifically, as they may play a role in both normal neuronal function and in disease. Here, we have used human embryonic stem cells (h...
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