Direct cell reprogramming: approaches, mechanisms and progress

The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion with...

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Vydáno v:	Nature reviews. Molecular cell biology Ročník 22; číslo 6; s. 410 - 424
Hlavní autoři:	Wang, Haofei, Yang, Yuchen, Liu, Jiandong, Qian, Li
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	England Nature Publishing Group 01.06.2021
Témata:	Animals Cardiomyocytes Cell Differentiation - genetics Cell Differentiation - physiology Cell fate Cell Transdifferentiation - genetics Cell Transdifferentiation - physiology Cellular Reprogramming - genetics Cellular Reprogramming - physiology Epigenesis, Genetic - genetics Epigenetics Fibroblasts Humans Maturation Medicine Metabolism Molecular modelling Non-coding RNA Pluripotency Somatic cells Stem cells Therapeutic applications Transcription factors Translation
ISSN:	1471-0072, 1471-0080, 1471-0080
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Abstract	The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion without transitioning through an intermediary pluripotent state. Given that the number of cell types that can be generated by direct reprogramming is rapidly increasing, it has become a promising strategy to produce functional cells for therapeutic purposes. This Review discusses the evolution of direct reprogramming from a transcription factor-based method to a small-molecule-driven approach, the recent progress in enhancing reprogrammed cell maturation, and the challenges associated with in vivo direct reprogramming for translational applications. It also describes our current understanding of the molecular mechanisms underlying direct reprogramming, including the role of transcription factors, epigenetic modifications, non-coding RNAs, and the function of metabolic reprogramming, and highlights novel insights gained from single-cell omics studies.
AbstractList	The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion without transitioning through an intermediary pluripotent state. Given that the number of cell types that can be generated by direct reprogramming is rapidly increasing, it has become a promising strategy to produce functional cells for therapeutic purposes. This Review discusses the evolution of direct reprogramming from a transcription factor-based method to a small-molecule-driven approach, the recent progress in enhancing reprogrammed cell maturation, and the challenges associated with in vivo direct reprogramming for translational applications. It also describes our current understanding of the molecular mechanisms underlying direct reprogramming, including the role of transcription factors, epigenetic modifications, non-coding RNAs, and the function of metabolic reprogramming, and highlights novel insights gained from single-cell omics studies. The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion without transitioning through an intermediary pluripotent state. Given that the number of cell types that can be generated by direct reprogramming is rapidly increasing, it has become a promising strategy to produce functional cells for therapeutic purposes. This Review discusses the evolution of direct reprogramming from a transcription factor-based method to a small-molecule-driven approach, the recent progress in enhancing reprogrammed cell maturation, and the challenges associated with in vivo direct reprogramming for translational applications. It also describes our current understanding of the molecular mechanisms underlying direct reprogramming, including the role of transcription factors, epigenetic modifications, non-coding RNAs, and the function of metabolic reprogramming, and highlights novel insights gained from single-cell omics studies.Direct reprogramming converts cells from one lineage into cells of another without going through an intermediary pluripotent state. This Review describes our current understanding of the molecular mechanisms underlying direct reprogramming as well as the progress in improving its efficiency and the maturation of reprogrammed cells, and the challenges associated with its translational applications. The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion without transitioning through an intermediary pluripotent state. Given that the number of cell types that can be generated by direct reprogramming is rapidly increasing, it has become a promising strategy to produce functional cells for therapeutic purposes. This Review discusses the evolution of direct reprogramming from a transcription factor-based method to a small-molecule-driven approach, the recent progress in enhancing reprogrammed cell maturation, and the challenges associated with in vivo direct reprogramming for translational applications. It also describes our current understanding of the molecular mechanisms underlying direct reprogramming, including the role of transcription factors, epigenetic modifications, non-coding RNAs, and the function of metabolic reprogramming, and highlights novel insights gained from single-cell omics studies.The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional views on cell identity and cell fate determination. Direct reprogramming (also known as transdifferentiation) refers to cell fate conversion without transitioning through an intermediary pluripotent state. Given that the number of cell types that can be generated by direct reprogramming is rapidly increasing, it has become a promising strategy to produce functional cells for therapeutic purposes. This Review discusses the evolution of direct reprogramming from a transcription factor-based method to a small-molecule-driven approach, the recent progress in enhancing reprogrammed cell maturation, and the challenges associated with in vivo direct reprogramming for translational applications. It also describes our current understanding of the molecular mechanisms underlying direct reprogramming, including the role of transcription factors, epigenetic modifications, non-coding RNAs, and the function of metabolic reprogramming, and highlights novel insights gained from single-cell omics studies.
Author	Qian, Li Liu, Jiandong Wang, Haofei Yang, Yuchen
Author_xml	– sequence: 1 givenname: Haofei orcidid: 0000-0001-8914-442X surname: Wang fullname: Wang, Haofei organization: McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA – sequence: 2 givenname: Yuchen surname: Yang fullname: Yang, Yuchen organization: McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA – sequence: 3 givenname: Jiandong surname: Liu fullname: Liu, Jiandong organization: McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA – sequence: 4 givenname: Li orcidid: 0000-0001-7614-5618 surname: Qian fullname: Qian, Li email: li_qian@med.unc.edu, li_qian@med.unc.edu organization: McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA. li_qian@med.unc.edu
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PublicationTitle	Nature reviews. Molecular cell biology
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Snippet	The reprogramming of somatic cells with defined factors, which converts cells from one lineage into cells of another, has greatly reshaped our traditional...
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SubjectTerms	Animals Cardiomyocytes Cell Differentiation - genetics Cell Differentiation - physiology Cell fate Cell Transdifferentiation - genetics Cell Transdifferentiation - physiology Cellular Reprogramming - genetics Cellular Reprogramming - physiology Epigenesis, Genetic - genetics Epigenetics Fibroblasts Humans Maturation Medicine Metabolism Molecular modelling Non-coding RNA Pluripotency Somatic cells Stem cells Therapeutic applications Transcription factors Translation
Title	Direct cell reprogramming: approaches, mechanisms and progress
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