Efficient Generation of Human iPSCs by a Synthetic Self-Replicative RNA

Yoshioka, Naohisa; Gros, Edwige; Li, Hairi; Kumar, Shantanu; Deacon, Dekker C.; Maron, Cornelia; Muotri, Alysson R.; Neil, C.; Fu, Xiang‐Dong; Yu, Benjamin; Dowdy, Steven F.

doi:10.1016/j.stem.2013.06.001

Cited by 264 publications

(276 citation statements)

References 27 publications

(44 reference statements)

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“…Epigenetic studies of produced iPSCs traced epigenetic memory or reminiscent marks, such as residual DNA methylation signatures of the starting cell types during early passages of iPSCs (34,35) which could explain the mechanisms behind such observations. Alternative strategies such as non-integrative vectors (36), adenoviruses (37), repeated mRNA transfection (38,39,40), protein transduction (41), and transposon-based transgene removal (42) have been successfully applied to develop transgene-free iPSC lines. This progression towards safe iPSC generation (reviewed in (43)) offers a promising technology for medical pertinence.…”

Section: Patient-specific Cell Sourcesmentioning

confidence: 99%

THERAPY OF ENDOCRINE DISEASE: Islet transplantation for type 1 diabetes: so close and yet so far away

Khosravi‐Maharlooei¹,

Hajizadeh‐Saffar²,

Tahamtani³

et al. 2015

European Journal of Endocrinology

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Over the past decades, tremendous efforts have been made to establish pancreatic islet transplantation as a standard therapy for type 1 diabetes. Recent advances in islet transplantation have resulted in steady improvements in the 5-year insulin independence rates for diabetic patients. Here we review the key challenges encountered in the islet transplantation field which include islet source limitation, sub-optimal engraftment of islets, lack of oxygen and blood supply for transplanted islets, and immune rejection of islets. Additionally, we discuss possible solutions for these challenges.

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Section: Patient-specific Cell Sourcesmentioning

confidence: 99%

THERAPY OF ENDOCRINE DISEASE: Islet transplantation for type 1 diabetes: so close and yet so far away

Khosravi‐Maharlooei¹,

Hajizadeh‐Saffar²,

Tahamtani³

et al. 2015

European Journal of Endocrinology

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“…5). Such synthetic, noninfectious RNA replicons encoding the reprogramming factors were recently used to generate footprint-free iPSCs [16]. DNA-based alphaviral vectors are reported [123][124][125].…”

Section: Alphaviral Vectors and Rna Repliconmentioning

confidence: 99%

“…To achieve these goals, many distinct technologies are employed in current reprogramming protocols. These include nonintegrating adenoviral vectors [7], excisable PiggyBac (PB) transposon [8], excision of transgenes with the Cre-Lox system upon completion of reprogramming [9,10], repeated transfection with conventional plasmids [11], minicircle DNA [12], Epstein-Barr virus-based replicating episomal plasmids [4][5][6], protein transduction [13], mRNA transfection [14], negative-sense RNA vectors (Sendai viral vector) [15], positive-sense RNA vector/replicons [16], and the use of polycistrons mediated by 2A peptide [9,11], and/or Internal Ribosome Entry Site (IRES) [4]. This review summarizes information relative to vector designs and factor delivery systems used in current reprogramming protocols.…”

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confidence: 99%

Vectorology and Factor Delivery in Induced Pluripotent Stem Cell Reprogramming

2014

Stem Cells and Development

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Induced pluripotent stem cell (iPSC) reprogramming requires sustained expression of multiple reprogramming factors for a limited period of time (10-30 days). Conventional iPSC reprogramming was achieved using lentiviral or simple retroviral vectors. Retroviral reprogramming has flaws of insertional mutagenesis, uncontrolled silencing, residual expression and re-activation of transgenes, and immunogenicity. To overcome these issues, various technologies were explored, including adenoviral vectors, protein transduction, RNA transfection, minicircle DNA, excisable PiggyBac (PB) transposon, Cre-lox excision system, negative-sense RNA replicon, positive-sense RNA replicon, Epstein-Barr virus-based episomal plasmids, and repeated transfections of plasmids. This review provides summaries of the main vectorologies and factor delivery systems used in current reprogramming protocols.

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“…Therefore, iPSCs must be screened to select free cells for further applications (Gonzalez et al, 2009). To date, the safest technique of iPSC production is induction of pluripotency via mRNA (Warren et al, 2012;Yoshioka et al, 2013) or protein (Kim et al, 2009;Lee et al, 2012). These iPSCs are called "clean" iPSCs.…”

Section: Cell Fate and Reprogrammingmentioning

confidence: 99%

Direct reprogramming of somatic cells: an update

Pham

2015

Biomed Res Ther

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Abstract-Direct epigenetic reprogramming is a technique that converts a differentiated adult cell into another differentiated cell-such fibroblasts to cardiomyocytes-without passage through an undifferentiated pluripotent stage. This novel technology is opening doors in biological research and regenerative medicine. Some preliminary studies about direct reprogramming started in the 1980s when differentiated adult cells could be converted into other differentiated cells by overexpressing transcription-factor genes. These studies also showed that differentiated cells have plasticity. Direct reprogramming can be a powerful tool in biological research and regenerative medicine, especially the new frontier of personalized medicine. This review aims to summarize all direct reprogramming studies of somatic cells by master control genes as well as potential applications of these techniques in research and treatment of selected human diseases.

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Efficient Generation of Human iPSCs by a Synthetic Self-Replicative RNA

Cited by 264 publications

References 27 publications

THERAPY OF ENDOCRINE DISEASE: Islet transplantation for type 1 diabetes: so close and yet so far away

THERAPY OF ENDOCRINE DISEASE: Islet transplantation for type 1 diabetes: so close and yet so far away

Vectorology and Factor Delivery in Induced Pluripotent Stem Cell Reprogramming

Direct reprogramming of somatic cells: an update

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