RBM47 is a Critical Regulator of Mouse Embryonic Stem Cell Differentiation.

RNA-binding proteins (RBPs) are pivotal for regulating gene expression as they are involved in each step of RNA metabolism. Several RBPs are essential for viable growth and development in mammals. RNA-binding motif 47 (RBM47) is an RRM-containing RBP whose role in mammalian embryonic development is poorly understood yet deemed to be essential since its loss in mouse embryos leads to perinatal lethality. In this study, we attempted to elucidate the significance of RBM47 in cell-fate decisions of mouse embryonic stem cells (mESCs). Downregulation of Rbm47 did not affect mESC maintenance and the cell cycle but perturbed the expression of primitive endoderm (PrE) markers and increased GATA4 + PrE-like cells. However, the PrE misregulation could be reversed by either overexpressing Rbm47 or treating the knockdown mESCs with the inhibitors of FGFR or MEK, suggesting an implication of RBM47 in regulating FGF-ERK signaling. Rbm47 knockdown affected the multi-lineage differentiation potential of mESCs as it regressed teratoma in NSG mice and led to a skewed expression of differentiation markers in serum-induced monolayer differentiation. Further, lineage-specific differentiation revealed that Rbm47 is essential for proper differentiation of mESCs towards neuroectodermal and endodermal fate. Taken together, we assign a hitherto unknown role(s) to RBM47 in a subtle regulation of mESC differentiation.

NSG-70, a new glioblastoma cell line with mixed proneural-mesenchymal features, associates NOTCH1-WNT5A signaling with stem cell maintenance and angiogenesis.

BACKGROUND: Glioblastoma initiation and progression is believed to be driven by Glioma stem cells (GSCs). Activation of NOTCH1 and WNT, and more recently, non-canonical WNT5A signaling, has been demonstrated to regulate self-renewal and differentiation of the GSCs crucially. High expression levels of NOTCH1 and WNT in GBM tumors contribute to the sustenance of GSCs and mediate characteristic phenotypic plasticity, which is reflected by the different subtypes and tremendous intra-tumor heterogeneity. However, the coregulation of NOTCH1 and WNT5A is not well understood. Here, we studied the role of these molecules in regulating the characteristics of different GSC subtypes. METHODS: We established a novel GSC-enriched cell model, referred to as NSG-70, from a patient with recurrent GBM. NSG-70 cells harbor a unique cytogenetic feature, viz. isochromosome 9q. At the same time, its expression profiles indicate that it is a mixed lineage comprising proneural and mesenchymal subtypes. We examined the relevance of NOTCH1 and WNT5A signaling and their coordinated action in GBM using these cells and other patient-derived models representing different GSC subtypes. RESULTS: Our data revealed that the downregulation of NOTCH1 resulted in the suppression of stem cell and mesenchymal markers and significantly reduced the levels of WNT5A. NOTCH1 knockdown also led to a notable reduction in the vasculogenic mimicry of GSCs. Interestingly, knockdown of WNT5A exhibited similar effects and drove quiescent GSC towards proliferation. In a complementary manner, ectopic expression of WNT5A or rhWNT5A treatment rescued the effects of NOTCH1 knockdown. CONCLUSION: The resistance of GSCs towards conventional therapies in part due to subtype interconversion demands therapies targeting specific GSC subtype. Our study suggests the need for a combinatorial approach that could effectively target the NOTCH1-WNT5A signaling axis toward eliminating GSCs.

RNA binding motif 47 (RBM47): emerging roles in vertebrate development, RNA editing and cancer.

RNA-binding proteins (RBPs) are critical players in the post-transcriptional regulation of gene expression and are associated with each event in RNA metabolism. The term 'RNA-binding motif' (RBM) is assigned to novel RBPs with one or more RNA recognition motif (RRM) domains that are mainly involved in the nuclear processing of RNAs. RBM47 is a novel RBP conserved in vertebrates with three RRM domains whose contributions to various aspects of cellular functions are as yet emerging. Loss of RBM47 function affects head morphogenesis in zebrafish embryos and leads to perinatal lethality in mouse embryos, thereby assigning it to be an essential gene in early development of vertebrates. Its function as an essential cofactor for APOBEC1 in C to U RNA editing of several targets through substitution for A1CF in the A1CF-APOBEC1 editosome, established a new paradigm in the field. Recent advances in the understanding of its involvement in cancer progression assigned RBM47 to be a tumor suppressor that acts by inhibiting EMT and Wnt/[Formula: see text]-catenin signaling through post-transcriptional regulation. RBM47 is also required to maintain immune homeostasis, which adds another facet to its regulatory role in cellular functions. Here, we review the emerging roles of RBM47 in various biological contexts and discuss the current gaps in our knowledge alongside future perspectives for the field.