Project description:A biophysical basis for the diffusion-restricted behavior of Xist RNA

Project description:ETVs dictate hPSC differentiation by tuning biophysical properties

Project description:Here we reveal a biophysical basis for the spreading behavior of Xist RNA on the inactive X-chromosome (Xi). Xist and HNRNPK together drive a liquid-liquid phase separation (LLPS) that encapsulates the Xi. HNRNPK and Xist exert mutual pulling forces that lead to RNA internalization into the condensate. While HNRNPK is sufficient for condensate formation, Xist induces a further phase transition into a "soft" droplet by altering elasticity, adhesiveness, and wetting properties of the condensate in vitro. Once phase transition occurs, other Xist-interacting factors are internalized and concentrated within the condensate. We attribute LLPS to HNRNPK's RGG and Xist's Repeat B (RepB) motifs. Mutating these motifs causes Xist diffusion, disrupts Polycomb recruitment, and precludes the required mixing of Xi chromatin for establishing the Xi superstructure. Thus, phase transitions driven by RepB and HNRNPK create a membrane-less subnuclear compartment for the localization and limited diffusion of Xist ribonucleoprotein complexes on the Xi.

Project description:Here we reveal a biophysical basis for the spreading behavior of Xist RNA on the inactive X-chromosome (Xi). Xist and HNRNPK together drive a liquid-liquid phase separation (LLPS) that encapsulates the Xi. HNRNPK and Xist exert mutual pulling forces that lead to RNA internalization into the condensate. While HNRNPK is sufficient for condensate formation, Xist induces a further phase transition into a "soft" droplet by altering elasticity, adhesiveness, and wetting properties of the condensate in vitro. Once phase transition occurs, other Xist-interacting factors are internalized and concentrated within the condensate. We attribute LLPS to HNRNPK's RGG and Xist's Repeat B (RepB) motifs. Mutating these motifs causes Xist diffusion, disrupts Polycomb recruitment, and precludes the required mixing of Xi chromatin for establishing the Xi superstructure. Thus, phase transitions driven by RepB and HNRNPK create a membrane-less subnuclear compartment for the localization and limited diffusion of Xist ribonucleoprotein complexes on the Xi.

Project description:Here we reveal a biophysical basis for the spreading behavior of Xist RNA on the inactive X-chromosome (Xi). Xist and HNRNPK together drive a liquid-liquid phase separation (LLPS) that encapsulates the Xi. HNRNPK and Xist exert mutual pulling forces that lead to RNA internalization into the condensate. While HNRNPK is sufficient for condensate formation, Xist induces a further phase transition into a "soft" droplet by altering elasticity, adhesiveness, and wetting properties of the condensate in vitro. Once phase transition occurs, other Xist-interacting factors are internalized and concentrated within the condensate. We attribute LLPS to HNRNPK's RGG and Xist's Repeat B (RepB) motifs. Mutating these motifs causes Xist diffusion, disrupts Polycomb recruitment, and precludes the required mixing of Xi chromatin for establishing the Xi superstructure. Thus, phase transitions driven by RepB and HNRNPK create a membrane-less subnuclear compartment for the localization and limited diffusion of Xist ribonucleoprotein complexes on the Xi.

Project description:Here we reveal a biophysical basis for the spreading behavior of Xist RNA on the inactive X-chromosome (Xi). Xist and HNRNPK together drive a liquid-liquid phase separation (LLPS) that encapsulates the Xi. HNRNPK and Xist exert mutual pulling forces that lead to RNA internalization into the condensate. While HNRNPK is sufficient for condensate formation, Xist induces a further phase transition into a "soft" droplet by altering elasticity, adhesiveness, and wetting properties of the condensate in vitro. Once phase transition occurs, other Xist-interacting factors are internalized and concentrated within the condensate. We attribute LLPS to HNRNPK's RGG and Xist's Repeat B (RepB) motifs. Mutating these motifs causes Xist diffusion, disrupts Polycomb recruitment, and precludes the required mixing of Xi chromatin for establishing the Xi superstructure. Thus, phase transitions driven by RepB and HNRNPK create a membrane-less subnuclear compartment for the localization and limited diffusion of Xist ribonucleoprotein complexes on the Xi.

Project description:Postnatal respiration requires the bulk formation of alveoli that produces extensive surface area for gas diffusion from epithelium to the circulatory system. Alveolar morphogenesis initiates at late gestation or postnatal stage during mammalian development and is mediated by coordination among epithelial, mesenchymal and endothelial cells. Here we show that stromal cells produce Heparan Sulfate Glycosaminoglycan (HS-GAG) to maintain a niche for alveolar development by modulating both the biophysical and biochemical cues. HS is predominantly enriched in myofibroblasts in postnatal murine lungs, and genetic ablation of HS synthase gene Ext1 in fibroblast populations results in enlarged and simplified alveolar structures. HS is selectively required for the cell identity of a subset of alveolar myofibroblasts (PDGFRαhi αSMA+) residing in the distal alveolar region, which exhibit contractile properties and maintain WNT signaling activity to support normal proliferation and differentiation of alveolar epithelial cells. HS is essential to prevent precocious apoptosis of alveolar myofibroblasts. We show that these processes are dependent upon FGF/MAPK signaling and forced activation of MAPK/ERK signaling partially corrected alveolar simplification along with restoration of alveolar myofibroblast identity and AT2 cell proliferation in HS deficient mice. These data reveal HS as an essential orchestrator for developing alveolar niche critical for generation of gas exchange units.

Project description:Postnatal respiration requires the bulk formation of alveoli that produces extensive surface area for gas diffusion from epithelium to the circulatory system. Alveolar morphogenesis initiates at late gestation or postnatal stage during mammalian development and is mediated by coordination among epithelial, mesenchymal and endothelial cells. Here we show that stromal cells produce Heparan Sulfate Glycosaminoglycan (HS-GAG) to maintain a niche for alveolar development by modulating both the biophysical and biochemical cues. HS is predominantly enriched in myofibroblasts in postnatal murine lungs, and genetic ablation of HS synthase gene Ext1 in fibroblast populations results in enlarged and simplified alveolar structures. HS is selectively required for the cell identity of a subset of alveolar myofibroblasts (PDGFRαhi αSMA+) residing in the distal alveolar region, which exhibit contractile properties and maintain WNT signaling activity to support normal proliferation and differentiation of alveolar epithelial cells. HS is essential to prevent precocious apoptosis of alveolar myofibroblasts. We show that these processes are dependent upon FGF/MAPK signaling and forced activation of MAPK/ERK signaling partially corrected alveolar simplification along with restoration of alveolar myofibroblast identity and AT2 cell proliferation in HS deficient mice. These data reveal HS as an essential orchestrator for developing alveolar niche critical for generation of gas exchange units.

Project description:Pregnancy places a metabolic burden on the body including the liver, which is responsible for ensuring adequate nutrition for the maternal and fetal systems. To gain a better understanding of liver adaptation, this study investigates metabolic shifts occurring in livers of pregnant rats. Metabolic capacities of the livers of pregnant and non-pregnant female Wistar rats were assessed using comprehensive metabolic models. Kinetic metabolic models were generated for each animal based on protein abundance data from proteomics analysis allowing for a subject-specific assessment of hepatic metabolic functions. Additionally, tissue stiffness, viscosity, and water diffusion obtained from magnetic resonance imaging and elastography were correlated with metabolic capabilities to study the relationship between metabolic function and biophysical properties. Proteome profiling revealed differences in protein expression in the livers of pregnant and non-pregnant animals. Functional analysis showed significant variations in metabolic capacities. Livers of pregnant rats had reduced capacities in carbohydrate and fatty acid metabolism, along with altered urea synthesis. Additionally, there were associations between metabolic functions and biophysical properties highlighting potential links between changes in liver structure and metabolic capacities during pregnancy. In summary, our work reveals extensive hepatic metabolic changes in pregnant rats. The liver adapts to maintain stability but may struggle to respond to nutrient imbalances, especially at low glucose levels. The study, employing a personalized approach combining proteomics, kinetic modeling, and advanced imaging, sheds light on the intricate interplay between hepatic adaptations and medical imaging markers, providing a foundation for further investigations into the implications for maternal and fetal health.

Project description:Effect of short-term glucose withdrawal and glucose refeeding after short-term glucose withdrawal on gene expression of MCF7 cells