AIM To identify differences between primed mouse embryonic stem cells(ESCs) and fully functional naive ESCs; to manipulate primed cells into a naive state. METHODS We have cultured 3 lines of cells from different mous...AIM To identify differences between primed mouse embryonic stem cells(ESCs) and fully functional naive ESCs; to manipulate primed cells into a naive state. METHODS We have cultured 3 lines of cells from different mouse strains that have been shown to be naive or primed as determined by generating germline-transmitting chimeras.Cells were put through a battery of tests to measure the different features. RNA from cells was analyzed using microarrays, to determine a priority list of the differentially expressed genes. These were later validated by quantificational real-time polymerase chain reaction. Viral cassettes were created to induce expression of differentially expressed genes in the primed cells through lentiviral transduction. Primed reprogrammed cells were subjected to in-vivo incorporation studies.RESULTS Most results show that both primed and naive cells have similar features(morphology, proliferation rates, stem cell genes expressed). However, there were some genes that were differentially expressed in the na?ve cells relative to the primed cells. Key upregulated genes in na?ve cells include ESRRB, ERAS, ATRX, RNF17, KLF-5, and MYC. After over-expressing some of these genes the primed cells were able to incorporate into embryos in-vivo, re-acquiring a feature previously absent in these cells. CONCLUSION Although there are no notable phenotypic differences, there are key differences in gene expression between these na?ve and primed stem cells. These differences can be overcome through overexpression.展开更多
Trophoblast stem cells (TSCs), which can be derived from the trophoectoderm of a blastocyst, have the ability to sustain self-renewal and differentiate into various placental trophoblast cell types. Meanwhile, essenti...Trophoblast stem cells (TSCs), which can be derived from the trophoectoderm of a blastocyst, have the ability to sustain self-renewal and differentiate into various placental trophoblast cell types. Meanwhile, essential insights into the molecular mechanisms controlling the placental development can be gained by using TSCs as the cell model. Esrrb is a transcription factor that has been shown to play pivotal roles in both embryonic stem cell (ESC) and TSC, but the precise mechanism whereby Esrrb regulates TSC-specific transcriptome during differentiation and reprogramming is still largely unknown. In the present study, we elucidate the function of Esrrb in self-renewal and differentiation of TSCs, as well as during the induced TSC (iTSC) reprogramming. We demonstrate that the precise level of Esrrb is critical for stem state maintenance and further trophoblast differentiation of TSCs, as ectopically expressed Esrrb can partially block the rapid differentiation of TSCs in the absence of fibroblast growth factor 4. However, Esrrb depletion results in downregulation of certain key TSC-specific transcription factors, consequently causing a rapid differentiation of TSCs and these Esrrb-deficient TSCs lose the ability of hemorrhagic lesion formation in vivo. This function of Esrrb is exerted by directly binding and activating a core set of TSC-specific target genes including Cdx2, Eomes, Sox2, Fgfr4, and Bmp4. Furthermore, we show that Esrrb overexpression can facilitate the MEF-to-iTSC conversion. Moreover, Esrrb can substitute for Eomes to generate GEsTM-iTSCs. Thus, our findings provide a better understanding of the molecular mechanism of Esrrb in maintaining TSC self-renewal and during iTSC reprogramming.展开更多
基金Supported by Partially by an NIH translational training,No.T32NS051156a seed grant from the University of Puerto Rico Medical Sciences Campus,No.400100420002+2 种基金the Metropolitan University seed grantthe Duke Neurotransgenic Laboratorysupported,in part,with funding from NIH-NINDS Center Core,No.5P30NS061789
文摘AIM To identify differences between primed mouse embryonic stem cells(ESCs) and fully functional naive ESCs; to manipulate primed cells into a naive state. METHODS We have cultured 3 lines of cells from different mouse strains that have been shown to be naive or primed as determined by generating germline-transmitting chimeras.Cells were put through a battery of tests to measure the different features. RNA from cells was analyzed using microarrays, to determine a priority list of the differentially expressed genes. These were later validated by quantificational real-time polymerase chain reaction. Viral cassettes were created to induce expression of differentially expressed genes in the primed cells through lentiviral transduction. Primed reprogrammed cells were subjected to in-vivo incorporation studies.RESULTS Most results show that both primed and naive cells have similar features(morphology, proliferation rates, stem cell genes expressed). However, there were some genes that were differentially expressed in the na?ve cells relative to the primed cells. Key upregulated genes in na?ve cells include ESRRB, ERAS, ATRX, RNF17, KLF-5, and MYC. After over-expressing some of these genes the primed cells were able to incorporate into embryos in-vivo, re-acquiring a feature previously absent in these cells. CONCLUSION Although there are no notable phenotypic differences, there are key differences in gene expression between these na?ve and primed stem cells. These differences can be overcome through overexpression.
基金the National Key R&D Program of China (2016YFA0100400)the National Natural Science Foundation of China (31721003)+6 种基金the Ministry of Science and Technology of China (2015CB964800, 2015CB964503, and 2018YFA0108900)the National Natural Science Foundation of China (81630035, 31871446, and 31771646)the Shanghai Rising-Star Program (17QA1404200)the Shanghai Chenguang Program (16CG17)the Shanghai Municipal Medical and Health Discipline Construction Projects (2017ZZ02015)National Postdoctoral Program for Innovative Talents (BX201700307)China Postdoctoral Science Foundation (2017M621527).
文摘Trophoblast stem cells (TSCs), which can be derived from the trophoectoderm of a blastocyst, have the ability to sustain self-renewal and differentiate into various placental trophoblast cell types. Meanwhile, essential insights into the molecular mechanisms controlling the placental development can be gained by using TSCs as the cell model. Esrrb is a transcription factor that has been shown to play pivotal roles in both embryonic stem cell (ESC) and TSC, but the precise mechanism whereby Esrrb regulates TSC-specific transcriptome during differentiation and reprogramming is still largely unknown. In the present study, we elucidate the function of Esrrb in self-renewal and differentiation of TSCs, as well as during the induced TSC (iTSC) reprogramming. We demonstrate that the precise level of Esrrb is critical for stem state maintenance and further trophoblast differentiation of TSCs, as ectopically expressed Esrrb can partially block the rapid differentiation of TSCs in the absence of fibroblast growth factor 4. However, Esrrb depletion results in downregulation of certain key TSC-specific transcription factors, consequently causing a rapid differentiation of TSCs and these Esrrb-deficient TSCs lose the ability of hemorrhagic lesion formation in vivo. This function of Esrrb is exerted by directly binding and activating a core set of TSC-specific target genes including Cdx2, Eomes, Sox2, Fgfr4, and Bmp4. Furthermore, we show that Esrrb overexpression can facilitate the MEF-to-iTSC conversion. Moreover, Esrrb can substitute for Eomes to generate GEsTM-iTSCs. Thus, our findings provide a better understanding of the molecular mechanism of Esrrb in maintaining TSC self-renewal and during iTSC reprogramming.
