Project description:Srrm2 splicing factor is a novel gene implicated in developmental disorders and diseases. However, the role of Srrm2 in early mammalian development remains unexplored. Here, we show that Srrm2 expression dosage is critical for maintaining embryonic stem cell pluripotency and cell identity. Srrm2 heterozygosity promotes loss of stemness characterized by the coexistence of cells expressing naive and formative markers, together with large gene expression shifts, including in serum-response transcription factor targets and differentiation-related genes. Depletion of Srrm2 by RNA interference in embryonic stem cells identified splicing misregulation of specific genes, often linked to exon skipping. These results show that Srrm2 dosage is key in controlling stemness and cell fate decisions. Our findings unveil Srrm2’s molecular and cellular implications in development, shedding light on the involvement of splicing regulators in early embryogenesis, developmental diseases and tumorigenesis.
Project description:Srrm2 splicing factor is a novel gene implicated in developmental disorders and diseases. However, the role of Srrm2 in early mammalian development remains unexplored. Here, we show that Srrm2 expression dosage is critical for maintaining embryonic stem cell pluripotency and cell identity. Srrm2 heterozygosity promotes loss of stemness characterized by the coexistence of cells expressing naive and formative markers, together with large gene expression shifts, including in serum-response transcription factor targets and differentiation-related genes. Depletion of Srrm2 by RNA interference in embryonic stem cells identified splicing misregulation of specific genes, often linked to exon skipping. These results show that Srrm2 dosage is key in controlling stemness and cell fate decisions. Our findings unveil Srrm2’s molecular and cellular implications in development, shedding light on the involvement of splicing regulators in early embryogenesis, developmental diseases and tumorigenesis.
Project description:Srrm2 splicing factor is a novel gene implicated in developmental disorders and diseases. However, the role of Srrm2 in early mammalian development remains unexplored. Here, we show that Srrm2 expression dosage is critical for maintaining embryonic stem cell pluripotency and cell identity. Srrm2 heterozygosity promotes loss of stemness characterized by the coexistence of cells expressing naive and formative markers, together with large gene expression shifts, including in serum-response transcription factor targets and differentiation-related genes. Depletion of Srrm2 by RNA interference in embryonic stem cells identified splicing misregulation of specific genes, often linked to exon skipping. These results show that Srrm2 dosage is key in controlling stemness and cell fate decisions. Our findings unveil Srrm2’s molecular and cellular implications in development, shedding light on the involvement of splicing regulators in early embryogenesis, developmental diseases and tumorigenesis.
Project description:SRRM2 is a nuclear-speckle marker containing multiple disordered domains, whose dysfunction is associated with several human diseases. Using mainly EGFP-SRRM2 knock-in HEK293T cells, we show that SRRM2 forms biomolecular condensates satisfying most hallmarks of liquid-liquid phase separation, including spherical shape, dynamic rearrangement, coalescence and concentration dependence supported by in vitro experiments. Live-cell imaging shows that SRRM2 organizes nuclear speckles along the cell cycle. As bona-fide splicing factor present in spliceosome structures, SRRM2 deficiency induces skipping of cassette exons with short introns and weak splice sites, tending to change large protein domains. In THP-1 myeloid-like cells, SRRM2 depletion compromises cell viability, upregulates differentiation markers, and sensitizes cells to anti-leukemia drugs. SRRM2 induces a FES splice isoform that attenuates innate inflammatory responses, and MUC1 isoforms that undergo shedding with oncogenic properties. We conclude that SRRM2 acts as a scaffold to organize nuclear speckles, regulating alternative splicing in innate immunity and cell homeostasis.
