Induced Pluripotent Stem Cells from Patients with Huntington's Disease Show CAG-Repeat-Expansion-Associated Phenotypes

Mattis, Virginia B.; Svendsen, Soshana; Ebert, Allison D.; Svendsen, Clive N.; King, Alvin R.; Casale, Malcolm; Winokur, Sara T.; Batugedara, Gayani; Vawter, Marquis P.; Donovan, Peter; Lock, Leslie F.; Thompson, Leslie M.; Zhu, Yu; Fossale, Elisa; Atwal, Ranjit Singh; Gillis, Tammy; Mysore, Jayalakshmi Srinidhi; Li, Jian Hong; Seong, Ihnsik; Shen, Yiping; Chen, Xiaoli; Wheeler, Vanessa C.; MacDonald, Marcy E.; Gusella, James F.; Akimov, Sergey; Arbez, Nicolas; Juopperi, Tarja; Ratovitski, Tamara; Chiang, Jason; Kim, Woon Roung; Chighladze, Eka; Watkin, Erin E.; Zhong, Chun; Makri, Georgia; Cole, Robert N.; Margolis, Russell L.; Song, Hongjun; Ming, Guo‐li; Ross, Christopher A.; Kaye, Julia; Daub, Aaron; Sharma, Punita; Mason, Amanda; Finkbeiner, Steven; Yu, Junying; Thomson, James A.; Rushton, David J.; Brazier, Stephen P.; Battersby, Alysia; Redfern, Amanda; Tseng, Hsui Er; Harrison, Alexander W.; Kemp, Paul J.; Allen, Nicholas Denby; Onorati, Marco; Castiglioni, Valentina; Cattaneo, Elena; Arjomand, Jamshid

doi:10.1016/j.stem.2012.04.027

Cited by 419 publications

(362 citation statements)

References 49 publications

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“…Nonetheless, some transplanted PD patients did experience durable benefit, providing at least a proof-of-principal in favor of dopaminergic neuronal transplantation. The generation of midbrain dopaminergic neurons (64, 65) and medium spiny neurons (66, 67) from human PSCs (64–67) thus permit a leap forward in the availability of well-defined engraftable neurons of relative phenotypic homogeneity. This advance should enable a new generation of therapeutic trials less compromised by donor variability and compositional heterogeneity.…”

Section: Neurologic and Retinal Diseasesmentioning

confidence: 99%

Use of differentiated pluripotent stem cells in replacement therapy for treating disease

Fox

Daley

Goldman

et al. 2014

Science

243

165

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Patient-derived pluripotent stem cells (PSC) directed to various cell fates holds promise as source material for treating numerous disorders. The availability of precisely differentiated PSC-derived cells will dramatically impact blood component and hematopoietic stem cell therapies, and should facilitate treatment of diabetes, some forms of liver disease and neurologic disorders, retinal diseases, and possibly heart disease. Although an unlimited supply of specific cell types are needed, other barriers must be overcome. This review of the state of cell therapies highlights important challenges. Successful cell transplantation will require optimizing the best cell type and site for engraftment, overcoming limitations to cell migration and tissue integration, and occasionally needing to control immunologic reactivity. Collaboration among scientists, clinicians, and industry is critical for generating new stem cell-based therapies.

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Section: Neurologic and Retinal Diseasesmentioning

confidence: 99%

Use of differentiated pluripotent stem cells in replacement therapy for treating disease

Fox

Daley

Goldman

et al. 2014

Science

243

165

View full text Add to dashboard Cite

show abstract

“…iPS cell technologies have been used to examine the mechanisms of multiple disorders including amyotrophic lateral sclerosis (ALS) (Egawa et al. 2012), Huntington's disease (HD) (HD iPSC Consortium 2012), and Parkinson's disease (PD) (Devine et al. 2011).…”

Section: Introductionmentioning

confidence: 99%

Using iPSC‐derived human DA neurons from opioid‐dependent subjects to study dopamine dynamics

et al. 2016

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IntroductionThe dopaminergic (DA) system plays important roles in addiction. However, human DA neurons from drug‐dependent subjects were not available for study until recent development in inducible pluripotent stem cells (iPSCs) technology.MethodsIn this study, we produced DA neurons differentiated using iPSCs derived from opioid‐dependent and control subjects carrying different 3′ VNTR (variable number tandem repeat) polymorphism in the human dopamine transporter (DAT or SLC6A3). In addition, the effects of valproic acid (VPA) exposures on iPSC‐derived human DA neurons are also examined.ResultsWe present the first evidence suggesting that the 3′ VNTR polymorphism in the hDAT gene affects DAT expression level in iPSC‐derived human DA neurons. In human DA neurons, which provide an appropriate cellular milieu, VPA treatment alters the expression of several genes important for dopaminergic neuron function including DAT, Nurr1, and TH; this might partly explain its action in regulating addictive behaviors. VPA treatment also significantly increased DA D2 receptor (Drd2) expression, especially in the opioid‐dependent iPSC cell lines.ConclusionsOur data suggest that human iPSC‐derived DA neurons may be useful in in vitro experimental model to examine the effects of genetic variation in gene regulation, to examine the underlying mechanisms in neurological disorders including drug addiction, and to serve as a platform for therapeutic development.

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“…For example, efficient protocols have been developed to make neural crest by dual-SMAD inhibition/WNT activation (Chambers et al, 2013). Protocols have been reported for making many brain cell types from stem cells, including dopaminergic neurons (Studer, 2012; Sun et al, 2013; Sundberg et al, 2013), motor neurons (Bilican et al, 2012; Boulting et al, 2011; Di Giorgio et al, 2007), forebrain-like neurons (HD iPSC Consortium et al, 2012), striatal neurons (Aubry et al, 2008), cortical interneurons (Maroof et al, 2013), retinal cells (Jin and Takahashi, 2012); oligodendrocytes (Czepiel et al, 2011; Ogawa et al, 2011; Wang et al, 2013; Yang et al, 2013) and astrocytes (Emdad et al, 2012; Serio et al, 2013). Neurons and neural progenitors can be produced directly from other types of somatic cells without having to first make those cells pluripotent (Ambasudhan et al, 2011; Kim et al, 2011; Vierbuchen et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…For the first time, a skin or blood cell from a patient with a neurological or psychiatric disease can be reprogrammed to become a cell type of the nervous system, thereby creating a genetically faithful human model of disease (Churko et al, 2013; Hayes and Zavazava, 2013; Wray et al, 2012). Already, several models have been developed that exhibit disease-relevant phenotypes (Table 1) for Huntington's disease (HD) (HD iPSC Consortium et al, 2012; Zhang et al, 2010), amyotrophic lateral sclerosis (ALS) (Barmada et al; Bilican et al, 2012; Burkhardt et al, 2013; Donnelly et al, 2013; Egawa et al, 2012; Sareen et al, 2013; Serio et al, 2013), spinal muscular atrophy (Ebert et al, 2009), Parkinson's disease (Cooper et al, 2012; Skibinski et al, 2014), schizophrenia (Brennand et al, 2011), and Alzheimer's disease (AD)(Israel et al, 2012). In principle, genetic and small-molecule screens can be conducted in what might be the most physiologically relevant cell-based model of neurological disease ever developed.…”

Section: Introductionmentioning

confidence: 99%

Cell-Based Screening: Extracting Meaning from Complex Data

Finkbeiner

Frumkin

Kassner

2015

Neuron

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Summary Unbiased discovery approaches have the potential to uncover neurobiological insights into CNS disease and lead to the development of therapies. Here we review lessons learned from imaging-based screening approaches and recent advances in these areas, including powerful new computational tools to synthesize complex data into more useful knowledge that can reliably guide future research and development.

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Induced Pluripotent Stem Cells from Patients with Huntington's Disease Show CAG-Repeat-Expansion-Associated Phenotypes

Cited by 419 publications

References 49 publications

Use of differentiated pluripotent stem cells in replacement therapy for treating disease

Use of differentiated pluripotent stem cells in replacement therapy for treating disease

Using iPSC‐derived human DA neurons from opioid‐dependent subjects to study dopamine dynamics

Cell-Based Screening: Extracting Meaning from Complex Data

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