Putative Dental Pulp‐Derived Stem/Stromal Cells Promote Proliferation and Differentiation of Endogenous Neural Cells in the Hippocampus of Mice

Until now, interest in dental pulp stem/stromal cell (DPSC) research has centered on mineralization and tooth repair. Beginning a new paradigm in DPSC research, we grafted undifferentiated, untreated DPSCs into the hippocampus of immune‐suppressed mice. The rhesus DPSC (rDPSC) line used was establis...

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Veröffentlicht in:	Stem cells (Dayton, Ohio) Ohio), 2008-10, Vol.26 (10), p.2654-2663
Hauptverfasser:	Huang, Anderson Hsien‐Cheng, Snyder, Brooke R., Cheng, Pei‐Hsun, Chan, Anthony W.S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Antigens, Surface - metabolism Biomarkers - metabolism Bone marrow/mesenchymal stem/stromal cells Cell Differentiation - drug effects Cell Line Cell Proliferation - drug effects Cell Separation Cell therapy Dental Pulp - cytology Dental Pulp - transplantation Dental pulp stem/stromal cells Gene Transfer Techniques Graft Rejection - prevention & control Higher primates Hippocampus - cytology Humans Immunosuppressive Agents - pharmacology Macaca mulatta Mice Nerve Growth Factors - metabolism Neurons - cytology Neurons - drug effects Rhesus monkey Stem Cell Transplantation Stem Cells - cytology Stem Cells - drug effects Stromal Cells - cytology Stromal Cells - drug effects Stromal Cells - transplantation Telomere - metabolism
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creator	Huang, Anderson Hsien‐Cheng Snyder, Brooke R. Cheng, Pei‐Hsun Chan, Anthony W.S.
description	Until now, interest in dental pulp stem/stromal cell (DPSC) research has centered on mineralization and tooth repair. Beginning a new paradigm in DPSC research, we grafted undifferentiated, untreated DPSCs into the hippocampus of immune‐suppressed mice. The rhesus DPSC (rDPSC) line used was established from the dental pulp of rhesus macaques and found to be similar to human bone marrow/mesenchymal stem cells, which express Nanog, Rex‐1, Oct‐4, and various cell surface antigens, and have multipotent differentiation capability. Implantation of rDPSCs into the hippocampus of mice stimulated proliferation of endogenous neural cells and resulted in the recruitment of pre‐existing Nestin+ neural progenitor cells (NPCs) and β‐tubulin‐III+ mature neurons to the site of the graft. Additionally, many cells born during the first 7 days after implantation proliferated, forming NPCs and neurons, and, to a lesser extent, underwent astrogliosis, forming astrocytes and microglia, by 30 days after implantation. Although the DPSC graft itself was short term, it had long‐term effects by promoting growth factor signaling. Implantation of DPSCs enhanced the expression of ciliary neurotrophic factor, vascular endothelial growth factor, and fibroblast growth factor for up to 30 days after implantation. In conclusion, grafting rDPSCs promotes proliferation, cell recruitment, and maturation of endogenous stem/progenitor cells by modulating the local microenvironment. Our results suggest that DPSCs have a valuable, unique therapeutic potential, specifically as a stimulator and modulator of the local repair response in the central nervous system. DPSCs would be a preferable cell source for therapy due to the possibility of a “personalized” stem cell, avoiding the problems associated with host immune rejection. Disclosure of potential conflicts of interest is found at the end of this article.
doi_str_mv	10.1634/stemcells.2008-0285
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Although the DPSC graft itself was short term, it had long‐term effects by promoting growth factor signaling. Implantation of DPSCs enhanced the expression of ciliary neurotrophic factor, vascular endothelial growth factor, and fibroblast growth factor for up to 30 days after implantation. In conclusion, grafting rDPSCs promotes proliferation, cell recruitment, and maturation of endogenous stem/progenitor cells by modulating the local microenvironment. Our results suggest that DPSCs have a valuable, unique therapeutic potential, specifically as a stimulator and modulator of the local repair response in the central nervous system. DPSCs would be a preferable cell source for therapy due to the possibility of a “personalized” stem cell, avoiding the problems associated with host immune rejection. 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Although the DPSC graft itself was short term, it had long‐term effects by promoting growth factor signaling. Implantation of DPSCs enhanced the expression of ciliary neurotrophic factor, vascular endothelial growth factor, and fibroblast growth factor for up to 30 days after implantation. In conclusion, grafting rDPSCs promotes proliferation, cell recruitment, and maturation of endogenous stem/progenitor cells by modulating the local microenvironment. Our results suggest that DPSCs have a valuable, unique therapeutic potential, specifically as a stimulator and modulator of the local repair response in the central nervous system. DPSCs would be a preferable cell source for therapy due to the possibility of a “personalized” stem cell, avoiding the problems associated with host immune rejection. 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Beginning a new paradigm in DPSC research, we grafted undifferentiated, untreated DPSCs into the hippocampus of immune‐suppressed mice. The rhesus DPSC (rDPSC) line used was established from the dental pulp of rhesus macaques and found to be similar to human bone marrow/mesenchymal stem cells, which express Nanog, Rex‐1, Oct‐4, and various cell surface antigens, and have multipotent differentiation capability. Implantation of rDPSCs into the hippocampus of mice stimulated proliferation of endogenous neural cells and resulted in the recruitment of pre‐existing Nestin+ neural progenitor cells (NPCs) and β‐tubulin‐III+ mature neurons to the site of the graft. Additionally, many cells born during the first 7 days after implantation proliferated, forming NPCs and neurons, and, to a lesser extent, underwent astrogliosis, forming astrocytes and microglia, by 30 days after implantation. Although the DPSC graft itself was short term, it had long‐term effects by promoting growth factor signaling. Implantation of DPSCs enhanced the expression of ciliary neurotrophic factor, vascular endothelial growth factor, and fibroblast growth factor for up to 30 days after implantation. In conclusion, grafting rDPSCs promotes proliferation, cell recruitment, and maturation of endogenous stem/progenitor cells by modulating the local microenvironment. Our results suggest that DPSCs have a valuable, unique therapeutic potential, specifically as a stimulator and modulator of the local repair response in the central nervous system. DPSCs would be a preferable cell source for therapy due to the possibility of a “personalized” stem cell, avoiding the problems associated with host immune rejection. 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source	Oxford University Press Journals All Titles (1996-Current); MEDLINE; EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection
subjects	Animals Antigens, Surface - metabolism Biomarkers - metabolism Bone marrow/mesenchymal stem/stromal cells Cell Differentiation - drug effects Cell Line Cell Proliferation - drug effects Cell Separation Cell therapy Dental Pulp - cytology Dental Pulp - transplantation Dental pulp stem/stromal cells Gene Transfer Techniques Graft Rejection - prevention & control Higher primates Hippocampus - cytology Humans Immunosuppressive Agents - pharmacology Macaca mulatta Mice Nerve Growth Factors - metabolism Neurons - cytology Neurons - drug effects Rhesus monkey Stem Cell Transplantation Stem Cells - cytology Stem Cells - drug effects Stromal Cells - cytology Stromal Cells - drug effects Stromal Cells - transplantation Telomere - metabolism
title	Putative Dental Pulp‐Derived Stem/Stromal Cells Promote Proliferation and Differentiation of Endogenous Neural Cells in the Hippocampus of Mice
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