Project description:Pluripotency of embryonic stem cells (ESCs) can be functionally assessed according to their developmental potency. Tetraploid complementation, through which an entire organism is produced from donor pluripotent cells, is taken as the most stringent test for pluripotency. It remains unclear whether ESCs from other species besides mice can pass this test. Here we show that the rat ESCs at very early passages are also capable to produce fertile offspring by tetraploid complementation, however, this capacity is rapidly lost during culture due to the loss of genomic imprinting. Our findings support that the naïve ground state pluripotency exists in rat and can be captured in rat ESCs, yet may be subjected to species-specific regulations, which have implications for the derivation and application of naïve pluripotent stem cells in other species including human.

Project description:Pluripotent mouse embryonic stem cells (ESCs) were originally derived and stably maintained on feeder cells such as inactivated mouse embryo fibroblasts, and can generate complete ESC-pups by tetraploid embryo complementation (TEC), the most stringent functional test of naive pluripotency. Remarkably, 2i (inhibitors of Mek and Gsk3β signaling) medium with LIF in the absence of serum and feeders was developed to achieve ground state of mouse ESCs, and also has been successfully used for derivation of germline competent ESCs in other species such as rat. Notably, 2i-culture gives rise to transcriptional profiles and epigenetic landscapes quite distinct from serum-based ESCs. To better understand transcriptional landscape and signal transductions, we performed RNA-seq analysis of ESCs cultured in four different conditions: serum without feeder, serum with feeder, serum with feeder and 2i, and N2B27+2i.

Project description:Ectopic expression of four transcription factors including Oct4, Sox2, Klf4 and c-Myc in differentiated fibroblast cells could reset the cell fate of fibroblast cells to pluripotent state. Subsequently, fully pluripotency of these so-called induced pluripotent stem cells (iPSCs) has been demonstrated as viable mice could be generated autonomously from iPS cells through tetraploid blastocyst complementation. Moreover, the generation of human and patient-specific iPS cells have raised the possibility of utilizing iPS cells clinically. However, the utilization of c-Myc in iPS cells induction greatly increased the incidence of tumorigenecity in the iPS-chimeric mice and also might hinder the clinical application of human iPS cells in the future. Fortunately, c-Myc has been recently found dispensable for iPS induction even though the iPS induction efficiency is greatly reduced in the absence of c-Myc. However, it remains unknown if these three factors-induced iPS cells are fully pluripotent. In the present study, we have successfully demonstrated that 3-factor iPS cells could also be fully pluripotent as viable mice could be generated from 3-factor iPS cells autonomously via tetraploid complementation and moreover, our data indicated that the pluripotency regulatory mechanism in 3-factor iPS cells might be distinct from 4-factor iPS cells. We compared the gene expression profile of iPS cells with and without the tetraploid embryo complementation competence. Three biological repeats were included for each line.

Project description:Pluripotent stem cells (PSCs) provide a powerful tool to produce transgenic animals for biomedical research. However, impaired PSC contribution to chimerism and most notably the germline oftentimes impedes production of genetically modified animals, rendering techniques that expediate PSC contribution to the germline highly desirable. Blastocyst complementation denotes a technique which purposes to generate organs, tissues or cells in animal chimeras via microinjection of PSCs into genetically compromised blastocyst-stage embryos. Here we report on successful blastocyst complementation of the male germline in adult chimeras following microinjection of mouse or rat PSCs into mouse blastocysts mutated for Tsc22d3, an essential gene for spermatozoa production. Microinjection of mouse embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) into Tsc22d3-KnockOut (KO) blastocyst-stage embryos gave rise to intraspecies chimeras embodying functional spermatozoa, which were solely derived from microinjected PSCs. Furthermore, microinjection of rat ESCs into Tsc22d3-KO mouse embryos gave rise to viable mouse-rat chimeras that exhibited extensive contribution of rat cells to various organs. Notably, multiple mouse-rat chimeras showed contribution of rat ESCs to the male germline, solely harboring rat spermatids and spermatozoa that were rat ESC-derived and could fertilize rat oocytes. Collectively, this study reports a method for exclusive production of functional germ cells of one species in another via blastocyst complementation with PSCs. Implications of this study extend to development of transgenic rats via sterile mice, and may further assist efforts to generate xenogeneic gametes from endangered animal species.  

Project description:Pluripotent stem cells (PSCs) provide a powerful tool to produce transgenic animals for biomedical research. However, impaired PSC contribution to chimerism and most notably the germline oftentimes impedes production of genetically modified animals, rendering techniques that expediate PSC contribution to the germline highly desirable. Blastocyst complementation denotes a technique which purposes to generate organs, tissues or cells in animal chimeras via microinjection of PSCs into genetically compromised blastocyst-stage embryos. Here we report on successful blastocyst complementation of the male germline in adult chimeras following microinjection of mouse or rat PSCs into mouse blastocysts mutated for Tsc22d3, an essential gene for spermatozoa production. Microinjection of mouse embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) into Tsc22d3-KnockOut (KO) blastocyst-stage embryos gave rise to intraspecies chimeras embodying functional spermatozoa, which were solely derived from microinjected PSCs. Furthermore, microinjection of rat ESCs into Tsc22d3-KO mouse embryos gave rise to viable mouse-rat chimeras that exhibited extensive contribution of rat cells to various organs. Notably, multiple mouse-rat chimeras showed contribution of rat ESCs to the male germline, solely harboring rat spermatids and spermatozoa that were rat ESC-derived and could fertilize rat oocytes. Collectively, this study reports a method for exclusive production of functional germ cells of one species in another via blastocyst complementation with PSCs. Implications of this study extend to development of transgenic rats via sterile mice, and may further assist efforts to generate xenogeneic gametes from endangered animal species.

Project description:It has been well established that (LIF) is essential for maintaining naive pluripotency of ESCs. Oncostatin M (OSM) is a member of the IL-6 family of cytokines which share gp130 as a receptor subunit, and the OSM-gp130 complex can recruit either LIF receptor β or OSM receptor β. Here we show that OSM can completely replace LIF to maintain naive pluripotency of mouse ESCs. Mouse ESCs cultured in the presence of LIF or OSM not only express pluripotency genes at similar levels but also exhibit the same developmental pluripotency as evidenced by generation of germline competent chimeras, supporting previous findings. Moreover, we demonstrate that mESCs cultured in OSM produce viable all-ESC pups by tetraploid embryo complementation (TEC) assay, the most stringent functional test of authentic pluripotency. Furthermore, the telomere length and telomerase activity also are crucial for unlimited self-renewal and genomic stability of mESCs, and these do not differ in mESCs cultured under OSM or LIF. The transcriptome of mESCs cultured in OSM overall is very similar to that of LIF, and OSM activates Stat3 signaling pathway, like LIF. Additionally, OSM upregulates pentose and glucuronate interconversions, ascorbate and aldarate metabolism, steroid and retinol metabolism pathways. Although the significance of these pathways remains to be determined, our data shows that OSM can maintain the naive pluripotent stem cells in the absence of LIF.

Project description:Pluripotent stem cells (PSCs) provide a powerful tool to produce transgenic animals for biomedical research. However, impaired PSC contribution to chimerism and most notably the germline oftentimes impedes production of genetically modified animals, rendering techniques that expediate PSC contribution to the germline highly desirable. Blastocyst complementation denotes a technique which purposes to generate organs, tissues or cells in animal chimeras via microinjection of PSCs into genetically compromised blastocyst-stage embryos. Here we report on successful blastocyst complementation of the male germline in adult chimeras following microinjection of mouse or rat PSCs into mouse blastocysts mutated for Tsc22d3, an essential gene for spermatozoa production. Microinjection of mouse embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) into Tsc22d3-KnockOut (KO) blastocyst-stage embryos gave rise to intraspecies chimeras embodying functional spermatozoa, which were solely derived from microinjected PSCs. Furthermore, microinjection of rat ESCs into Tsc22d3-KO mouse embryos gave rise to viable mouse-rat chimeras that exhibited extensive contribution of rat cells to various organs. Notably, multiple mouse-rat chimeras showed contribution of rat ESCs to the male germline, solely harboring rat spermatids and spermatozoa that were rat ESC-derived and could fertilize rat oocytes. Collectively, this study reports a method for exclusive production of functional germ cells of one species in another via blastocyst complementation with PSCs. Implications of this study extend to development of transgenic rats via sterile mice, and may further assist efforts to generate xenogeneic gametes from endangered animal species.  

Project description:Pluripotent stem cells (PSCs) provide a powerful tool to produce transgenic animals for biomedical research. However, impaired PSC contribution to chimerism and most notably to the germline oftentimes impedes production of genetically modified animals, rendering techniques that expediate PSC contribution to the germline highly desirable. Blastocyst complementation denotes a technique which purposes to generate organs, tissues or cells in animal chimeras following microinjection of PSCs into genetically compromised blastocyst-stage embryos. Here, we report on successful blastocyst complementation of the male germline in adult chimeras via microinjection of mouse or rat PSCs into mouse blastocysts mutated for Tsc22d3, an essential gene for spermatozoa production. Microinjection of mouse embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) into Tsc22d3-KnockOut (KO) blastocyst-stage embryos gave rise to intraspecies chimeras embodying functional spermatozoa, which were solely derived from the microinjected PSCs. Furthermore, microinjection of rat ESCs into Tsc22d3-KO mouse embryos gave rise to viable mouse-rat chimeras that exhibited extensive contribution of rat cells to various tissues and organs. Notably, multiple mouse-rat chimeras showed contribution of rat ESCs to the male germline, solely harboring rat spermatids and spermatozoa that were rat ESC-derived and could fertilize rat oocytes. Collectively, this study reports on a method for exclusive germ cell production of one species in another via blastocyst complementation with PSCs. Implications of this study may extend to development of transgenic rat gametes in sterile mice and could further assist efforts to generate germ cells from endangered animal species.

Project description:Ectopic expression of four transcription factors including Oct4, Sox2, Klf4 and c-Myc in differentiated fibroblast cells could reset the cell fate of fibroblast cells to pluripotent state. Subsequently, fully pluripotency of these so-called induced pluripotent stem cells (iPSCs) has been demonstrated as viable mice could be generated autonomously from iPS cells through tetraploid blastocyst complementation. Moreover, the generation of human and patient-specific iPS cells have raised the possibility of utilizing iPS cells clinically. However, the utilization of c-Myc in iPS cells induction greatly increased the incidence of tumorigenecity in the iPS-chimeric mice and also might hinder the clinical application of human iPS cells in the future. Fortunately, c-Myc has been recently found dispensable for iPS induction even though the iPS induction efficiency is greatly reduced in the absence of c-Myc. However, it remains unknown if these three factors-induced iPS cells are fully pluripotent. In the present study, we have successfully demonstrated that 3-factor iPS cells could also be fully pluripotent as viable mice could be generated from 3-factor iPS cells autonomously via tetraploid complementation and moreover, our data indicated that the pluripotency regulatory mechanism in 3-factor iPS cells might be distinct from 4-factor iPS cells.

Project description:Oncostatin M maintains naïve pluripotency of mESCs by tetraploid embryo complementation (TEC) assay