Project description:To unveil cell fate decision pathways during osteoclast differentiation at single-cell resolution, we performed single-cell RNA sequencing (scRNA-seq) on the osteoclast culture system, in parallel with bulk RNA-seq and proteome analyses

Project description:Differentiation proceeds along a continuum of increasingly fate-restricted intermediates, referred to as canalization1,2. Canalization is essential for stabilizing cell fate, but the mechanisms that underlie robust canalization are unclear. Here we show that the BRG1/BRM-associated factor (BAF) chromatin-remodelling complex ATPase gene Brm safeguards cell identity during directed cardiogenesis of mouse embryonic stem cells. Despite the establishment of a well-differentiated precardiac mesoderm, Brm-/- cells predominantly became neural precursors, violating germ layer assignment. Trajectory inference showed a sudden acquisition of a non-mesodermal identity in Brm-/- cells. Mechanistically, the loss of Brm prevented de novo accessibility of primed cardiac enhancers while increasing the expression of neurogenic factor POU3F1, preventing the binding of the neural suppressor REST and shifting the composition of BRG1 complexes. The identity switch caused by the Brm mutation was overcome by increasing BMP4 levels during mesoderm induction. Mathematical modelling supports these observations and demonstrates that Brm deletion affects cell fate trajectory by modifying saddle-node bifurcations2. In the mouse embryo, Brm deletion exacerbated mesoderm-deleted Brg1-mutant phenotypes, severely compromising cardiogenesis, and reveals an in vivo role for Brm. Our results show that Brm is a compensable safeguard of the fidelity of mesoderm chromatin states, and support a model in which developmental canalization is not a rigid irreversible path, but a highly plastic trajectory.

Project description:Stepwise cell fate decision pathways during osteoclastogenesis at single-cell resolution

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Function of ARID1A during osteoclastogenesis

Project description:Successful immune responses are dependent on a precisely controlled balance between transcription and mRNA degradation. mRNA decay is driven through RNA-binding proteins (RBP), yet it remains unclear, how and when an individual mRNA molecule is selected for degradation. We investigated this fundamental question by using the anti-inflammatory RBP tristetraprolin (TTP, also known as Zfp36) as a model. Here, we show that TTP determines the fate of its targets concomitantly with their synthesis by binding to the pre-mRNA in the nucleus. Furthermore, we provide evidence that TTP orchestrates the target destabilization via a hierarchical molecular assembly that culminates by the association of mature mRNA with the RNA degradation machinery in the cytoplasm. The early fate decision in the life cycle of a TTP target mRNA prevents the translation of inflammatory mediators, particularly cytokine mRNAs, and promotes efficient cessation of the immune response. Importantly, the TTP homolog ZFP36L1 displays similar characteristics, suggesting a conserved mode of action within the ZFP36 family of RBPs.

Project description:We show that ARID1A promotes osteoclastogenesis

Project description:We show that ARID1A promotes osteoclastogenesis

Project description:We show that ARID1A promotes osteoclastogenesis

Project description:The generation of terminally differentiated cell lineages during organogenesis requires multiple, coordinated cell fate choice steps. However, this process has not been clearly delineated, especially in complex solid organs such as the pancreas. Here, we performed single-cell RNA-sequencing in pancreatic cells sorted from multiple genetically modified reporter mouse strains at embryonic stages E9.5-E17.5. We deciphered the developmental trajectories and regulatory strategies of the exocrine and endocrine pancreatic lineages as well as intermediate progenitor populations along the developmental pathways. Notably, we discovered previously undefined programs representing the earliest events in islet α- and β-cell lineage allocation as well as the developmental pathway of the "first wave" of α-cell generation. Furthermore, we demonstrated that repressing ERK pathway activity is essential for inducing both α- and β-lineage differentiation. This study provides key insights into the regulatory mechanisms underlying cell fate choice and stepwise cell fate commitment and can be used as a resource to guide the induction of functional islet lineage cells from stem cells in vitro.