CRISPR/Cas9-mediated heterozygous knockout of the autism gene CHD8 and characterization of its transcriptional networks in cerebral organoids derived from iPS cells

Wang, Ping; Mokhtari, Ryan; Pedrosa, Erika; Kirschenbaum, Michael A.; Bayrak, Can; Zheng, Deyou; Lachman, Herbert M.

doi:10.1186/s13229-017-0124-1

Cited by 217 publications

(214 citation statements)

References 146 publications

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“…Mariani and colleagues reported that DLX6‐AS1 were upregulated in cerebral organoids derived from iPSCs made from patents with ASDs . A recent study has also revealed that DLX6‐AS1 upregulated in cerebral organoids derived from the autism gene CHD8 knockout iPSCs …”

Section: Lncrnas In the Central Nervous System (Cns) And Brainmentioning

confidence: 99%

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Long noncoding RNA and its contribution to autism spectrum disorders

Jing

Yang

2017

CNS Neurosci Ther

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Recent studies have indicated that long noncoding RNAs (lncRNAs) play important roles in multiple processes, such as epigenetic regulation, gene expression regulation, development, nutrition-related and other diseases, toxic response, and response to drugs. Although the functional roles and mechanisms of several lncRNAs have been discovered, a better understanding of the vast majority of lncRNAs remains elusive. To understand the functional roles and mechanisms of lncRNAs is critical because these transcripts represent the majority of the transcriptional output of the mammalian genome. Recent studies have also suggested that lncRNAs are more abundant in the human brain and are involved in neurodevelopment and neurodevelopmental disorders, including autism spectrum disorders (ASDs). In this study, we review several known functions of lncRNAs and the potential contribution of lncRNAs to ASDs and to other genetic syndromes that have a similar clinical presentation to ASDs, such as fragile X syndrome and Rett syndrome.

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Section: Lncrnas In the Central Nervous System (Cns) And Brainmentioning

confidence: 99%

“…71 A recent study has also revealed that DLX6-AS1 upregulated in cerebral organoids derived from the autism gene CHD8 knockout iPSCs. 72…”

Section: Lncrnas In the Central Nervous System (Cns) And Brainmentioning

confidence: 99%

Long noncoding RNA and its contribution to autism spectrum disorders

Jing

Yang

2017

CNS Neurosci Ther

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“…First, it has been noted that BORGs, and presumably oMGs within the BORGs, express a transcriptome more closely resembling that of the fetal brain (Camp et al, ), which presents both benefits and disadvantages. While this makes the model well suited for the study of neurodevelopmental disorders, such as autism (Mariani et al, ; P. Wang et al, ), schizophrenia (Ye et al, ), or ZIKA transmission (Muffat et al, ), it also presents problems when attempting to utilize BORGs and oMGs to study diseases that require a more mature brain environment, such as PD or AD. Ormel et al () also demonstrated that oMGs display a diminished expression levels of the key microglia genes P2RY12 and TMEM119 , further suggesting that these cells have not completely obtained a mature, homeostatic signature.…”

Section: Benefits and Limitationsmentioning

confidence: 99%

Human iPSC‐derived microglia: A growing toolset to study the brain's innate immune cells

Hasselmann

Blurton‐Jones

2020

Glia

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Recent advances in the generation of microglia from human induced pluripotent stem cells (iPSCs) have provided exciting new approaches to examine and decipher the biology of microglia. As these techniques continue to evolve to encompass more complex in situ and in vivo paradigms, so too have they begun to yield novel scientific insight into the genetics and function of human microglia. As such, researchers now have access to a toolset comprised of three unique “flavors” of iPSC‐derived microglia: in vitro microglia (iMGs), organoid microglia (oMGs), and xenotransplanted microglia (xMGs). The goal of this review is to discuss the variety of research applications that each of these techniques enables and to highlight recent discoveries that these methods have begun to uncover. By presenting the research paradigms in which each model has been successful, as well as the key benefits and limitations of each approach, it is our hope that this review will help interested researchers to incorporate these techniques into their studies, collectively advancing our understanding of human microglia biology.

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“…Organoid models are now a common tool to study neurodevelopmental disorders, including microcephaly (Lancaster et al, 2013; Li et al, 2017a), autism spectrum disease associated with macrocephaly (Mariani et al, 2017; Wang et al, 2017), lissencephally (Bershteyn et al, 2017; Karzbrun et al, 2018), Rett Syndrom (Mellios et al, 2017), Thymothy syndrome (Birey et al, 2017), lysosomal storage diseases such as Sandhoff disease (Allende et al, 2018), schizophrenia (Srikanth et al, 2018; Stachowiak et al, 2017) and Zika infection on neonatal brain development (reviewed in (Qian et al, 2017). Despite the early success with this approach for disease-modelling, challenges remain.…”

Section: Hpsc Models Of Complex Phenotypes - Cerebral Organoidsmentioning

confidence: 99%

“…The ease and efficiency of the CRISPR/Cas system to target any locus in the genome provides great flexibility to develop genome-wide knock-out, gene activation (CRISPRa), gene suppressor (CRISPRi) or epigenome modifier screens in human cells (Gilbert et al, 2014). Genome-scale CRISPR screens are already used to identify genes implicated in many biologically relevant phenotypes, such as gene essentiality (Wang et al, 2017), caner progression (Chen et al, 2015; Shalem et al, 2014; Shi et al, 2015), drug resistance (Shalem et al, 2014; Wang et al, 2014), viral infection, immune response and vulnerability to bacterial toxins (Zhou et al, 2014). While published genome-scale screens predominantly utilize fast proliferating tumor cell lines, genome-scale phenotypical genetic screens in post-mitotic neuronal cells may be already feasible and become an invaluable tool for drug discovery in neurological diseases.…”

Section: Hpsc-based Drug Discoverymentioning

confidence: 99%

Stem Cells, Genome Editing, and the Path to Translational Medicine

Soldner

Jaenisch

2018

Cell

109

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Summary The derivation of human embryonic stem cells (hESCs) and the stunning discovery that somatic cells can be reprogrammed into human induced pluripotent stem cells (hiPSCs) holds the promise to revolutionize biomedical research and regenerative medicine. In this review, we focus on disorders of the central nervous system and explore how advances in human pluripotent stem cells (hPSCs) coincide with evolutions in genome engineering and genomic technologies to provide realistic opportunities to tackle some of the most devastating complex disorders.

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CRISPR/Cas9-mediated heterozygous knockout of the autism gene CHD8 and characterization of its transcriptional networks in cerebral organoids derived from iPS cells

Cited by 217 publications

References 146 publications

Long noncoding RNA and its contribution to autism spectrum disorders

Long noncoding RNA and its contribution to autism spectrum disorders

Human iPSC‐derived microglia: A growing toolset to study the brain's innate immune cells

Stem Cells, Genome Editing, and the Path to Translational Medicine

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