Embryonic Stem Cells

Pluripotent embryonic stem cells (ESCs) correspond to cells within a developing embryo that have the capacity to generate all the embryonic germ layers (i.e., endoderm, mesoderm and ectoderm), and are able to give rise to all cell types in the body. ESCs may be derived from developing embryos at the pre-implantation blastocyst stage, and specifically from cells within the inner cell mass (ICM). In mice, the pluripotent state of ICM cells (mESCs) is often referred to as a “naïve” state. Following blastocyst implantation, ICM derived cells or mouse epiblast stem cells (mEpiSCs) retain self-renewal capacity but are in a “primed” state of pluripotency. Similarly, conventional ICM derived human ESCs (hESCs) are characterized by “primed” pluripotent properties, a state that is thought to occur in association with the in vitro conditions used for their derivation and maintenance. However, cultivation of naïve hESCs has been achieved through 1) induced expression of pluripotency factors or 2) incubation with specific combinations of small modulating molecules and growth factors.

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Ectoderm Marker	Mesoderm Marker	Endoderm Marker
Trilineage differentiation of mouse embryonic stem cells. Immunocytochemistry/Immunofluorescence staining of mouse embryonic stem cells grown in mouse pluripotent stem cell media. v6.5 Mouse embryonic stem cells (Novus Catalog # NBP1-41162) were cultured in complete StemXVivo Mouse Pluripotent Stem Cell Media (R&D Systems Catalog # CCM025). For differentiation, cells were cultured as embryoid bodies for 5 days, plated onto Cultrex BME-coated plates (R&D Systems Catalog # 3434-005-02) for an additional 5-10 days. (Left) Expression of the ectoderm marker, SOX1, was detected in day 10 cells using Goat Anti-Human/Mouse/Rat SOX1 (Novus Catalog # AF3369) followed by NorthernLights NL557-conjugated Donkey Anti-Goat Secondary Antibody (R&D Systems Catalog # NL001). (Middle) Expression of the mesoderm marker, Smooth Muscle Actin, was detected in 15 days cells using Mouse Anti-Human/Mouse/Rat Smooth Muscle Actin (1A4/asm1) (Novus Catalog # NBP2-33006). (Right) Expression of the endoderm marker, SOX17, was detected in 10 days cells using Goat Anti-SOX17 Affinity Purified Polyclonal Antibody (Novus Catalog # AF1924) followed by NL557-conjugated Donkey Anti-Goat Secondary Antibody. Nuclei were counterstained with DAPI.

How is Pluripotency Confirmed?

ESC pluripotency in vitro and in vivo may be confirmed through various approaches.

• Injection of ESCs into tissues of adult immune-deficient mice to confirm the ability of ESCs to differentiate and form teratomas.
• Spontaneous or directed differentiation of mouse ESCs in vitro to monitor the formation of embryoid bodies (EBs).
  Histological analysis (e.g., Immunohistochemical or Immunocytochemical) of teratomas and EBs serves to confirm differentiation of ESCs into a variety of cell types from endoderm, mesoderm, and ectoderm origin.
• Injection of ESCs into blastocysts for the generation of "chimera mice" confirms germline capacity.

What is the Difference between Naïve and Primed ESCs?

Naïve and primed ESCs share the same capacity for self-renewal and ability to give rise to the three embryonic germ layers. However, only naïve ESCs generate germline chimeras. The expression of specific pluripotency factors differs between stem cells in a naïve vs primed state.

This table contains only a subset of upregulated naïve and primed cell markers. See Ghimire et al. 2018 (mESCs) and Messmer et al. 2019 (hESCs) for a more complete list.

Embryonic Stem Cell Surface Markers

Pluripotent stem cells express a variety of cell surface proteins which may be used for their characterization and isolation from heterogeneous populations under culture conditions. The combined use of pluripotency markers to identify ESCs facilitates downstream applications aimed at the propagation of ESCs or their differentiation towards specific lineages.

H/M Pluripotent Stem Cell Flow Cytometry Kit [FMC001-NOV] - Mouse D3 embryonic stem cells were stained using reagents included in the Human/Mouse Embryonic Stem Cell Multi-Color Flow Cytometry Kit. Cells were analyzed for expression of pluripotent markers including SSEA-1, SSEA-4, Oct-3/4, and SOX2 by flow cytometry. A. Flow cytometric analysis shows that 91.1% of mouse D3 embryonic stem cells are positive for both Oct-3/4 and SSEA1 expression. B. Flow cytometric analysis data shows that 82.6% of mouse D3 embryonic stem cells are positive for SSEA-1 and negative for SSEA-4 a phenotype consistent with mouse embryonic stem cells. C. Flow cytometric analysis shows that mouse D3 embryonic stem cells express the pluripotent marker SOX2.

H/M Pluripotent Stem Cell Flow Cytometry Kit [FMC001-NOV] - BG01V human embryonic stem cells were stained using reagents included in the Human/Mouse Pluripotent Stem Cell Multi-Color Flow Cytometry Kit. Cells were simultaneously analyzed for expression of pluripotent markers including SSEA-1, SSEA-4, Oct-3/4, and SOX2 by flow cytometry. A. Flow cytometry data shows that 91.9% of BG01V human embryonic stem cells are positive for both Oct-3/4 and SSEA4 expression. B. Flow cytometry data shows that 88.5% of BG01V human embryonic stem cells are positive for SSEA-4 and negative for SSEA-1, a phenotype consistent with human embryonic stem cells. C. Flow cytometric analysis shows that BG01V human embryonic stem cells express the pluripotent marker SOX2.

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Select References

Bieberich, E., & Wang, G. (2013). Molecular Mechanisms Underlying Pluripotency. In Pluripotent Stem Cells. https://doi.org/10.5772/55596

Boroviak, T., & Nichols, J. (2017). Primate embryogenesis predicts the hallmarks of human naïve pluripotency. Development (Cambridge). https://doi.org/10.1242/dev.145177

Carstea, A. C. (2009). Germline competence of mouse ES and iPS cell lines: Chimera technologies and genetic background. World Journal of Stem Cells. https://doi.org/10.4252/wjsc.v1.i1.22

Ghimire, S., Van Der Jeught, M., Neupane, J., Roost, M. S., Anckaert, J., Popovic, M., … Heindryckx, B. (2018). Comparative analysis of naive, primed and ground state pluripotency in mouse embryonic stem cells originating from the same genetic background. Scientific Reports. https://doi.org/10.1038/s41598-018-24051-5

Kim, J. S., Choi, H. W., Choi, S., & Do, J. T. (2011). Reprogrammed pluripotent stem cells from somatic cells. International Journal of Stem Cells. https://doi.org/10.15283/ijsc.2011.4.1.1

Kumari, D. (2016). States of Pluripotency: Naïve and Primed Pluripotent Stem Cells. In Pluripotent Stem Cells - From the Bench to the Clinic. https://doi.org/10.5772/63202

Messmer, T., von Meyenn, F., Savino, A., Santos, F., Mohammed, H., Lun, A. T. L., … Reik, W. (2019). Transcriptional Heterogeneity in Naive and Primed Human Pluripotent Stem Cells at Single-Cell Resolution. Cell Reports. https://doi.org/10.1016/j.celrep.2018.12.099

Nichols, J., & Smith, A. (2009). Naive and Primed Pluripotent States. Cell Stem Cell. https://doi.org/10.1016/j.stem.2009.05.015

Trusler, O., Huang, Z., Goodwin, J., & Laslett, A. L. (2018). Cell surface markers for the identification and study of human naive pluripotent stem cells. Stem Cell Research. https://doi.org/10.1016/j.scr.2017.11.017

Weinberger, L., Ayyash, M., Novershtern, N., & Hanna, J. H. (2016). Dynamic stem cell states: Naive to primed pluripotency in rodents and humans. Nature Reviews Molecular Cell Biology. https://doi.org/10.1038/nrm.2015.28

Zhao, W., Ji, X., Zhang, F., Li, L., & Ma, L. (2012). Embryonic Stem Cell Markers. Molecules. https://doi.org/10.3390/molecules17066196