Clone- and Gene-Specific Aberrations of Parental Imprinting in Human Induced Pluripotent Stem Cells

Pick, Marjorie; Stelzer, Yonatan; Bar‐Nur, Ori; Mayshar, Yoav; Eden, Amir; Benvenisty, Nissim

doi:10.1002/stem.205

Cited by 168 publications

(130 citation statements)

References 18 publications

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“…100 Clone-and gene-specific aberrations of imprinting were also reported in human iPS cells. 101 These studies underscore the importance of the imprint maintenance mechanism in cell reprogramming.…”

Section: Molar Pregnancy Infertility Assisted Reproductive Technolomentioning

confidence: 96%

Genomic imprinting and its relevance to congenital disease, infertility, molar pregnancy and induced pluripotent stem cell

Tomizawa

Sasaki

2012

J Hum Genet

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Genomic imprinting is an epigenetic gene-marking phenomenon that occurs in the germline, whereby genes are expressed from only one of the two parental copies in embryos and adults. Imprinting is essential for normal mammalian development and its disruption can cause various developmental defects and diseases. The process of imprinting in the germline involves DNA methylation of the imprint control regions (ICRs), and resulting parental-specific methylation imprints are maintained in the zygote and act as the marks controlling imprinted gene expression. Recent studies in mice have revealed new factors involved in imprint establishment during gametogenesis and maintenance during early development. Clinical studies have identified cases of imprinting disorders where involvement of factors shared by multiple ICRs for establishment or maintenance is suspected. These include Beckwith-Wiedemann syndrome, transient neonatal diabetes, Silver-Russell syndrome and others. More severe disruptions can lead to recurrent molar pregnancy, miscarriage or infertility. Imprinting defects may also occur during assisted reproductive technology or cell reprogramming. In this review, we summarize our current knowledge on the mechanisms of imprint establishment and maintenance, and discuss the relationship with various human disorders.

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Section: Molar Pregnancy Infertility Assisted Reproductive Technolomentioning

confidence: 96%

Genomic imprinting and its relevance to congenital disease, infertility, molar pregnancy and induced pluripotent stem cell

Tomizawa

Sasaki

2012

J Hum Genet

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“…Because nuclear reprogramming of somatic cells into pluripotent stem cells may involve global erasure of epigenetic marks, it has been argued that the differential methylation that marks the PWS-IC could also be erased during reprogramming, making it difficult to generate an iPSC model of AS (14). In this regard, aberrant DNA methylation at the imprinted H19 and KCNQOT1 genes in iPSCs was recently reported (15). We assessed the methylation imprint in normal, AS, and PWS iPSCs by methylation-specific PCR (16,17).…”

Section: As and Pws Ipscs Maintain The Appropriate Methylation Imprintmentioning

confidence: 99%

Induced pluripotent stem cell models of the genomic imprinting disorders Angelman and Prader–Willi syndromes

Chamberlain

Chen²,

Ng³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

282

247

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Angelman syndrome (AS) and Prader-Willi syndrome (PWS) are neurodevelopmental disorders of genomic imprinting. AS results from loss of function of the ubiquitin protein ligase E3A (UBE3A) gene, whereas the genetic defect in PWS is unknown. Although induced pluripotent stem cells (iPSCs) provide invaluable models of human disease, nuclear reprogramming could limit the usefulness of iPSCs from patients who have AS and PWS should the genomic imprint marks be disturbed by the epigenetic reprogramming process. Our iPSCs derived from patients with AS and PWS show no evidence of DNA methylation imprint erasure at the cis-acting PSW imprinting center. Importantly, we find that, as in normal brain, imprinting of UBE3A is established during neuronal differentiation of AS iPSCs, with the paternal UBE3A allele repressed concomitant with up-regulation of the UBE3A antisense transcript. These iPSC models of genomic imprinting disorders will facilitate investigation of the AS and PWS disease processes and allow study of the developmental timing and mechanism of UBE3A repression in human neurons.antisense transcript | epigenetic | neuronal differentiation A ngelman syndrome (AS) is a neurogenetic disorder characterized by profound intellectual disability, absent speech, frequent seizures, motor dysfunction, and a characteristic happy demeanor (1, 2). Prader-Willi syndrome (PWS) is characterized hyperphagia/obesity; small stature, hands, and feet; and behavioral problems that are likened to obsessive compulsive disorder (3). AS is caused by loss of function of the maternally inherited allele of the E3 ubiquitin ligase UBE3A. UBE3A is subject to tissuespecific genomic imprinting; although both alleles are expressed in most tissues, the paternally inherited allele is repressed in the brain (4-6). Imprinted expression of UBE3A is thought to occur as a result of reciprocal expression of a long noncoding antisense transcript, UBE3A-ATS, which is part of a >600-kb transcript initiating at the differentially methylated PWS imprinting center (IC) located in exon 1 of the SNURF-SNRPN gene (7-9). PWS is associated with the loss of several species of small nucleolar RNAs (snoRNAs) (10); however, its genetic basis is currently unknown, and there is no mouse model that recapitulates all features of PWS.Mouse models of AS have proved significant in studying important aspects of the AS disease mechanism. There are, however, differences in the tissue specificity of the transcript that harbors UBE3A-ATS between humans and mice (11), indicating that the timing and mechanism of UBE3A repression may diverge between these species. The ability to study the developmental timing and mechanism of brain-specific repression of the paternal UBE3A allele in a model of human development is critical for better understanding the AS disease process and for using live neurons from patients with AS to discover previously undescribed therapeutic interventions. Here, we have developed such a model via human induced pluripotent stem cell (iPSC)-technology. ResultsHu...

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“…Since the aberrant silencing of the Dlk1-Dio3 cluster is not frequent in cloned mice produced by nuclear transfer, the oocyte cytoplasm may contain a factor that protects the DMRs of this cluster from de novo DNA methylation. Clone-specific variations in the stability of mono-allelic expression of the imprinted genes were also reported in human iPS cells, but in this case various genes were affected (for example, H19 and KCNQ1OT1) [72].…”

Section: Genomic Imprinting and Cell Reprogramming Technologymentioning

confidence: 77%

Genomic imprinting in mammals: its life cycle, molecular mechanisms and reprogramming

Sasaki

2011

Cell Res

125

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Genomic imprinting, an epigenetic gene-marking phenomenon that occurs in the germline, leads to parental-origin-specific expression of a small subset of genes in mammals. Imprinting has a great impact on normal mammalian development, fetal growth, metabolism and adult behavior. The epigenetic imprints regarding the parental origin are established during male and female gametogenesis, passed to the zygote through fertilization, maintained throughout development and adult life, and erased in primordial germ cells before the new imprints are set. In this review, we focus on the recent discoveries on the mechanisms involved in the reprogramming and maintenance of the imprints. We also discuss the epigenetic changes that occur at imprinted loci in induced pluripotent stem cells.

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Clone- and Gene-Specific Aberrations of Parental Imprinting in Human Induced Pluripotent Stem Cells

Cited by 168 publications

References 18 publications

Genomic imprinting and its relevance to congenital disease, infertility, molar pregnancy and induced pluripotent stem cell

Genomic imprinting and its relevance to congenital disease, infertility, molar pregnancy and induced pluripotent stem cell

Induced pluripotent stem cell models of the genomic imprinting disorders Angelman and Prader–Willi syndromes

Genomic imprinting in mammals: its life cycle, molecular mechanisms and reprogramming

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