SETD3 regulates endoderm differentiation of mouse embryonic stem cells through canonical Wnt signaling pathway.

With self-renewal and pluripotency features, embryonic stem cells (ESCs) provide an invaluable tool to investigate early cell fate decisions. Pluripotency exit and lineage commitment depend on precise regulation of gene expression that requires coordination between transcription (TF) and chromatin factors in response to various signaling pathways. SET domain-containing 3 (SETD3) is a methyltransferase that can modify histones in the nucleus and actin in the cytoplasm.

Mouse Embryonic Stem Cell Culture in Serum-Containing or 2i Conditions.

With their unique capabilities of self-renewal and differentiation into three germ layers, mouse embryonic stem cells (mESCs) are widely used as an in vitro cellular model for early mammalian developmental studies. mESCs are traditionally cultured in high-serum and LIF-containing medium on a growth-deficient mouse embryonic fibroblast layer. A more recent culturing system with two inhibitors (for GSK3β (CHIR99021) and MEK1/2 (PD0325901)) and LIF enables the derivation of mESC lines from various mouse strains.

Directed Differentiation of Mouse Embryonic Stem Cells to Mesoderm, Endoderm, and Neuroectoderm Lineages.

The self-renewal and pluripotency features of mouse embryonic stem cells (mESCs) make them a great tool to study early mammalian development. Various signaling pathways that shape early mammalian development can be mimicked for in vitro mESC differentiation toward primitive lineages first and more specialized cell types later. Since the precise nature of the molecular mechanisms and the crosstalk between these signaling pathways is yet to be fully understood, there is a high level of variability in the efficiency and synchronicity among available differentiation protocols.