CRISPR engineered mouse embryonic stem cells with Sox2-tdTomato and Gata6-GFP knock-in for endoderm differentiation.

An Embryonic stem line was engineered with CRISPR mediated knock-in to tag the endogenous locus of Sox2 with tdTomato and Gata6 with GFP. The site-specific knock-ins were genotyped by PCR and DNA sequencing. The timely expression of Gata6 and loss of Sox2 upon differentiation in cells and Embryoid bodies (EBs) were studied by microscopy. The GFP and tdtomato expressing population from day 4 EBs showed exclusive expression of GATA6 and SOX2 protein, confirming the appropriate expression of the fluorescent reporters in the cell line.

A NANOG-pERK reciprocal regulatory circuit regulates Nanog autoregulation and ERK signaling dynamics.

The self-renewal and differentiation potential of embryonic stem cells (ESCs) is maintained by the regulated expression of core pluripotency factors. Expression levels of the core pluripotency factor Nanog are tightly regulated by a negative feedback autorepression loop. However, it remains unclear how ESCs perceive NANOG levels and execute autorepression. Here, we show that a dose-dependent induction of Fgfbp1 and Fgfr2 by NANOG activates autocrine-mediated ERK signaling in Nanog-high cells to trigger autorepression. pERK recruits NONO to the Nanog locus to repress transcription by preventing POL2 loading. This Nanog autorepression process establishes a self-perpetuating reciprocal NANOG-pERK regulatory circuit. We further demonstrate that this reciprocal regulatory circuit induces pERK heterogeneity and ERK signaling dynamics in pluripotent stem cells. Collectively our data suggest that NANOG induces Fgfr2 and Fgfbp1 to activate ERK signaling in Nanog-high cells to establish a NANOG-pERK reciprocal regulatory circuit. This circuit regulates ERK signaling dynamics and Nanog autoregulation in pluripotent cells.

C3G Regulates STAT3, ERK, Adhesion Signaling, and Is Essential for Differentiation of Embryonic Stem Cells.

C3G (RAPGEF1), engaged in multiple signaling pathways, is essential for the early development of the mouse. In this study, we have examined its role in mouse embryonic stem cell self-renewal and differentiation. C3G null cells generated by CRISPR mediated knock-in of a targeting vector exhibited enhanced clonogenicity and long-term self-renewal. They did not differentiate in response to LIF withdrawal when compared to the wild type ES cells and were defective for lineage commitment upon teratoma formation in vivo. Gene expression analysis of C3G KO cells showed misregulated expression of a large number of genes compared with WT cells. They express higher levels of self-renewal factors like KLF4 and ESRRB and show high STAT3 activity, and very low ERK activity compared to WT cells. Reintroduction of C3G expression in a KO line partially reverted expression of ESRRB, and KLF4, and ERK activity similar to that seen in WT cells. The expression of self-renewal factors was persistent for a longer time, and induction of lineage-specific markers was not seen when C3G KO cells were induced to form embryoid bodies. C3G KO cells showed poor adhesion and significantly reduced levels of pFAK, pPaxillin, and Integrin-ß1, in addition to downregulation of the cluster of genes involved in cell adhesion, compared to WT cells. Our results show that C3G is essential for the regulation of STAT3, ERK, and adhesion signaling, to maintain pluripotency of mouse embryonic stem cells and enable their lineage commitment for differentiation.

Generation of iPSC from fetal fibroblast cells obtained from an abortus with type-I tri-allelic variants.

An integration free iPSC line was generated from fibroblast obtained from the skin of an aborted fetus in feeder free conditions using episomal based vectors expressing the pluripotency factors. The cell line generated was characterized and tested for pluripotency both in vitro and in vivo by teratoma formation and differentiation into defined lineages and brain organoids. Cell line reported here is shown to be mycoplasma free.