Project description:Transition from proliferation to quiescence brings about extensive changes in cellular behavior and structure. However, genes critical for establishing and/or for maintaining quiescence are largely unknown. The fission yeast S. pombe is found as an excellent model for studying this problem, because it becomes quiescent under nitrogen starvation. Here we characterize 610 temperature-sensitive (ts) mutants, and identify 33 genes required for entry into and the maintenance of quiescence. These genes cover a broad range of cellular functions in the cytoplasm, membrane and the nucleus, encoding proteins for stress-responsive and cell cycle kinase signaling pathway, actin-bound and osmo-controlling endosome formation, RNA transcription, splicing and ribosome biogenesis, chromatin silencing, biosynthesis of lipid and ATP, cell wall and membrane morphogenesis, protein trafficking and vesicle fusion. We specifically highlight Fcp1, CTD phosphatase of RNA polymerase II, which differentially affects transcription of genes involved in quiescence and proliferation. We propose that the transcriptional role of Fcp1 is central to differentiate quiescence from proliferation. Keywords: cell cycle control, protein trafficking, cortex actin, RNA polymerase II, protein phosphatase

Project description:Transition from proliferation to quiescence brings about extensive changes in cellular behavior and structure. However, genes critical for establishing and/or for maintaining quiescence are largely unknown. The fission yeast S. pombe is found as an excellent model for studying this problem, because it becomes quiescent under nitrogen starvation. Here we characterize 610 temperature-sensitive (ts) mutants, and identify 33 genes required for entry into and the maintenance of quiescence. These genes cover a broad range of cellular functions in the cytoplasm, membrane and the nucleus, encoding proteins for stress-responsive and cell cycle kinase signaling pathway, actin-bound and osmo-controlling endosome formation, RNA transcription, splicing and ribosome biogenesis, chromatin silencing, biosynthesis of lipid and ATP, cell wall and membrane morphogenesis, protein trafficking and vesicle fusion. We specifically highlight Fcp1, CTD phosphatase of RNA polymerase II, which differentially affects transcription of genes involved in quiescence and proliferation. We propose that the transcriptional role of Fcp1 is central to differentiate quiescence from proliferation. Experiment Overall Design: Gene expression profile under nitrogen rich or starved condition at 26ºC or 37ºC in WT (L972) or fcp1-452 ts mutant strain of fission yeast.

Project description:Regulation of subcellular mRNA localisation is a fundamental biological mechanism, which adds a spatial dimension to the diverse layers of post-transcriptional control of gene expression. Insights into this phenomenon have been described in a multitude of cell types and across taxonomic kingdoms, highlighting its biological significance. The cellular compartment in which mRNAs are located may define distinct aspects of the encoded proteins, ranging from production rate and complex formation to localised activity. Ultimately, mRNA localisation supports compartmentalised mechanistic outputs that can respond to local stimuli, orient migration, or even shape cells. We used an unbiased method to profile the RNA-bound proteome in migrating endothelial cells and found that the plasma membrane (PM)-associated A-kinase anchor protein 12 (AKAP12) interacts with various mRNAs, including mRNAs encoding kinases with Actin remodelling activity. To identify transcripts bound by AKAP12, we carried out UV crosslinking experiments followed by RNA immunoprecipitation and high throughput sequencing. Our data offer novel insights in complex mechanisms of spatial control of gene expression.

Project description:Yeast Membrane Bound Polysome

Project description:Prokaryote with membrane-bound nucleus

Project description:Molecular tether-mediated extracellular targeted protein degradation (ePTD) emerges as a promising drug modality. The existing strategies for ePTD have exploited several membrane degrader proteins. However, the current panel of ePTD degraders clearly needs to be expanded, as a given degrader may present tissue-dependent expression and activity. Based on screening of >50 receptors on endocytic rates and on their tissue distribution, we established a resource of potential endocytic carriers that may mediate effective ePTD. We subsequently introduced an adaptable design to assemble “Selected endocytic carrier-targeting chimera (SecTAC)” based on bispecific antibody constructs. The resultant modular chimeras, by co-opting newly identified degraders, directed efficient internalization of extracellular protein cargoes (or nucleic acids). Importantly, shaped by the availability of the corresponding endocytic carrier, the output of a SecTAC could present cell subset selectivity. We also validated the therapeutic potential of SecTAC agents for targeting several cell membrane proteins in tumor cells and primary T cells. Furthermore, we adapted the platform to establish multi-cargo tethers that triggered simultaneous degradation of two cell surface proteins in primary T cells. Taken together, our SecTAC platform has laid the foundation for development of preclinical drug candidates capable of inducing extracellular and membrane target degradation in desirable population of cells.

Project description:Arterial endothelial cells (ECs) have the ability to respond to mechanical forces exerted by laminar fluid shear stress. This response is of importance, as it is protective against vascular diseases such as atherosclerosis and aortic aneurysms. Mechanical forces are transmitted at the sites of adhesion to the basal membrane as well as cell-cell junctions where protein complexes connect to the cellular cytoskeleton to relay force into the cell. Here we present a novel protein complex that connects junctional VE-cadherin and radial actin filaments to the LINC complex in the nuclear membrane. We show that the scaffold protein AmotL2 is essential for the formation of radial actin filaments and the flow-induced alignment of aortic endothelial cells. The deletion of endothelial AmotL2 alters nuclear shape as well as subcellular positioning. Molecular analysis shows that VE-cadherin is mechanically associated with the nuclear membrane via binding to AmotL2 and Actin. Furthermore, the deletion of AmotL2 in ECs provoked a pro-inflammatory response and abdominal aortic aneurysms (AAA) in the aorta of mice on a normal diet. Remarkably, transcriptome analysis of AAA samples from human patients revealed a negative correlation between AmotL2 expression and inflammation of the aortic intima. These findings provide a conceptual framework regarding how mechanotransduction in the junctions is coupled with vascular diseases.

Project description:Arterial endothelial cells (ECs) have the ability to respond to mechanical forces exerted by laminar fluid shear stress. This response is of importance, as it is protective against vascular diseases such as atherosclerosis and aortic aneurysms. Mechanical forces are transmitted at the sites of adhesion to the basal membrane as well as cell-cell junctions where protein complexes connect to the cellular cytoskeleton to relay force into the cell. Here we present a novel protein complex that connects junctional VE-cadherin and radial actin filaments to the LINC complex in the nuclear membrane. We show that the scaffold protein AmotL2 is essential for the formation of radial actin filaments and the flow-induced alignment of aortic endothelial cells. The deletion of endothelial AmotL2 alters nuclear shape as well as subcellular positioning. Molecular analysis shows that VE-cadherin is mechanically associated with the nuclear membrane via binding to AmotL2 and Actin. Furthermore, the deletion of AmotL2 in ECs provoked a pro-inflammatory response and abdominal aortic aneurysms (AAA) in the aorta of mice on a normal diet. Remarkably, transcriptome analysis of AAA samples from human patients revealed a negative correlation between AmotL2 expression and inflammation of the aortic intima. These findings provide a conceptual framework regarding how mechanotransduction in the junctions is coupled with vascular diseases.

Project description:The clathrin and dynamin-independent endocytic pathway (CLIC-GEEC) is the major route of internalization of a large fraction of glycosylphosphatidylinositol-anchored proteins (GPI-APs) and other cell surface receptors. Unlike the clathrin-dependent endocytic pathway, where adaptors recruited to the endocytic pit provide the clues to recruit specific cargo, the CLIC-GEEC pathway is considered to take up portions of the membrane without any specificity. Here, we identified actin-binding protein swiprosin1 as the first cargo adaptor for the CLIC-GEEC pathway. We found that swiprosin1 interacts with active Rab21, a known regulator of integrin endocytosis, and couples Rab21 and the integrin cargo to the CLIC-GEEC endocytic machinery. Our work also identified the previously unknown pathway by which Rab21 mediates integrin endocytosis and linked the CLIC-GEEC pathway to integrin-dependent cancer cell invasion.

Project description:Proximal tubule endocytosis is essential for protecting the kidney from potentially damaging proteinuria and for mediating metabolic pathways, such as the activation of Vitamin D. We have identified the lysosomal membrane protein, Spns1, as a novel iron conductance that is indispensable for the normal endocytic function of the proximal tubule. Conditional knockout of Spns1 with a Cre-lox system in megalin-expressing cells in mice leads to arrest of both pinocytosis and receptor-mediated endocytosis in the proximal tubule. This endocytic defect is associated with iron overload in proximal tubules as measured by immunofluorescence of ferritin abundance and by a reduction in nascent TfRc mRNA transcripts. We have recapitulated previous findings in drosophila and zebrafish that Spns1 knockout causes endolysosomal dysfunction including abnormally enlarged lysosomes. The endocytic defect resulting from conditional Spns1 knockout can be rescued nutritionally with an iron deficient diet or genetically through double knockout of both Spns1 and the Fe2+ transporter, DMT1. Surprisingly, the endocytic defect in mice with Spns1 conditional knockout occurs despite normal megalin expression at the proximal tubule apical membrane. This data raises the possibilty that post-translational regulation of megalin activation may be nutrient-responsive.