Reprogramming Fibroblasts into Bipotential Hepatic Stem Cells by Defined Factors

Yu, Bing; He, Zhiying; Peng, You; Han, Qingwang; Xiang, Dao; Chen, Fei; Wang, Zhen‐Bo; Liu, Changcheng; Lin, Xiwen; Borjigin, Uyunbilig; Zi, Xiaoyuan; Li, Jianxiu; Zhu, Haiying; Li, Wenlin; Han, Chunsheng; Wangensteen, Kirk J.; Shi, Yufang; Hui, Lijian; Wang, Xin; Hu, Yiping

doi:10.1016/j.stem.2013.06.017

Cited by 147 publications

(156 citation statements)

References 49 publications

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“…The successfully generated iHEP cells from mouse by two separate groups were validated by expressional analysis [37,76]. Induced hepatic stem cells (iHepSCs), which possess the potential to differentiate into both hepatocytic and cholangiocytic cells, were characterized and their potential confirmed by global expression analysis [104]. Again, when a human iHEP reprogramming protocol was published, expressional analysis confirmed hepatocyte gene network activation [24,38].…”

Section: Induced Hepatocytesmentioning

confidence: 90%

Bioinformatic and Genomic Analyses of Cellular Reprogramming and Direct Lineage Conversion

Kareta

2016

Curr Pharmacol Rep

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Cellular reprogramming, whereby cell fate can be changed by the expression of a few defined factors, is a remarkable process that harnesses the innate ability of a cell's own genome to rework its expressional networks and function. Since cell lineages are defined by global regulation of gene expression, transcriptional regulators, and coupled to the epigenetic markings of the chromatin, changing the cell fate necessitates broad changes to these central cellular features. To properly characterize these changes, and the mechanisms that drive them, computational and genomic approaches are perfectly suited to provide a holistic picture of the reprogramming mechanisms. In particular, the use of bioinformatic analysis has been a major driver in the study of cellular reprogramming, as it relates to both induced pluripotency or direct lineage conversion. This review will summarize many of the bioinformatic studies that have advanced our knowledge of reprogramming and address future directions for these investigations.

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Section: Induced Hepatocytesmentioning

confidence: 90%

Bioinformatic and Genomic Analyses of Cellular Reprogramming and Direct Lineage Conversion

Kareta

2016

Curr Pharmacol Rep

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“…In the same time, Chinese research teams 9 reported in independently that new cocktails of transcription factors of Gata4, HNF1alpha, Foxa3, and RNAi-mediated inactivation of p19Arf for direct induction of functional hepatocyte like from mouse tail-tip fibroblasts. Yu et al, 10 brilliantly decided to explore two liver organogenesis transcription factors Hnf1b and Foxa3, to reprogram mouse embryonic fibroblasts into induced hepatic stem cells and successfully converted to induced hepatic stem cells from mouse embryonic fibroblasts. They proved that these induced Figure 1 (a) Conventional route reprogramming methods for pluripotent state and thereafter hepatic differentiation, (b) Shortcut route reprogramming methods for endodermal state and thereafter hepatic differentiation, (c) Hypothetical future shortest route for liver regeneration of acute and chronic liver by local delivery of hepatic endodermal and liver organogenesis transcription factors.…”

Section: Commentsmentioning

confidence: 99%

“…Recently, researchers used such liver specific transcription factors for generation of hepatocyte cells from skin fibroblast cells in vitro. [8][9][10][11][12] The ultimate aim of generation of hepatocytes from skin cells to treat liver diseases. If we know the transcription factors and small molecules which have potential to convert hepatocyte from fibroblast, why not to explore transcription factors and small molecules in vivo directly to repair or regenerating the tissue or organs.…”

Section: Commentsmentioning

confidence: 99%

Shortcut Route for Generation of Functional Hepatocyte Cells from Human Skin Allogenically for Autologous Treatment of Chronic Liver Diseases

Giri

Bader

2014

Journal of Clinical and Experimental Hepatology

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“…In the past, the use of NSCs for the treatment of neurological disease was hindered by limited fetal and adult NSC sources. Recent advances in cellular reprogramming allowed for the generation of induced pluripotent stem cells (iPS) and somatic stem cells from various somatic tissues [2][3][4][5][6]. To that effect, NSCs can be obtained by differentiation from iPS cells [7,8].…”

Section: Introductionmentioning

confidence: 99%

Direct Conversion of Cord Blood CD34+ Cells Into Neural Stem Cells by OCT4

Liao

Huang

et al. 2015

Stem Cells Translational Medicine

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Cellular reprogramming or conversion is a promising strategy to generate desired stem cell types from somatic cells. Neural stem cells (NSCs) have the potential to regenerate central nervous system tissue and repair damage in response to injury. However, NSCs are difficult to isolate from human tissues and expand in sufficient quantities for therapy. Here, we report a method to generate neural stem cells from cord blood CD34-positive cells by ectopic expression of OCT4 in a feeder-free system. The induced cells (iNSCs) show a characteristic NSC-like morphology and can be expanded in vitro for more than 20 passages. In addition, the iNSCs are positive for neural stem cell-specific markers such as Nestin and Musashi-1 and are similar in gene expression patterns to a human neural stem cell line. The iNSCs express distinct transcriptional factors for forebrain, hindbrain, and spinal cord regions. Upon differentiation, the iNSCs are able to commit into multilineage mature neural cells. Following in vivo introduction into NOD/SCID mice, iNSCs can survive and differentiate in the mouse brain 3 months post-transplantation. Alternatively, we were also able to derive iNSCs with an episomal vector expressing OCT4. Our results suggest a novel, efficient approach to generate neural precursor cells that can be potentially used in drug discovery or regenerative medicine for neurological disease and injury. STEM CELLS TRANSLATIONAL MEDICINE 2015;4:755-763 SIGNIFICANCEThis study describes a novel method to generate expandable induced neural stem cells from human cord blood cells in a feeder-free system by a single factor, OCT4. The data are promising for future applications that require the generation of large amounts of autologous neural stem cells in disease modeling and regenerative medicine.

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Reprogramming Fibroblasts into Bipotential Hepatic Stem Cells by Defined Factors

Cited by 147 publications

References 49 publications

Bioinformatic and Genomic Analyses of Cellular Reprogramming and Direct Lineage Conversion

Bioinformatic and Genomic Analyses of Cellular Reprogramming and Direct Lineage Conversion

Shortcut Route for Generation of Functional Hepatocyte Cells from Human Skin Allogenically for Autologous Treatment of Chronic Liver Diseases

Direct Conversion of Cord Blood CD34+ Cells Into Neural Stem Cells by OCT4

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