Project description:Analysis of the gene expression profile in differentiating rat CG4-EPOR oligodendrocytes treated with EPO, LIF or their combination for 1h or 20h Gene expression was measured undifferentiated CG4-EPOR cells and in differentiating cells at 1h and 20h in 5 conditions: control, EPO 10ng/ml, LIF 0.2ng/ml, LIF 10ng/ml, EPO 10ng/ml+LIF 10ng/ml); 3 or 4 replicates.

Project description:The regulatory system of erythropoiesis through erythropoietin (EPO) and its receptor (EPOR) is essential for vertebrates' life. In humans, EPO affects the erythroid progenitors and stimulates proliferation and differentiation. The EPO-EPOR axis is mainly mediated by the JAK2-STAT5 pathway. After terminal maturation, erythrocytes lost EPOR expression; however, erythrocytes of amphibian Xenopus tropicalis maintain EPOR expression even after their terminal maturation. Because erythrocytes of vertebrates except for adult mammals are nucleated, we hypothesized that EPO can alter its transcriptional state. To explore the effects of EPO on Xenopus mature erythrocytes, we performed RNA-Seq analysis on EPO-stimulated Xenopus peripheral blood cells. The EPO-stimulated group showed increased expression of direct target genes of STAT such as cish, socs3, and socs1 indicating a functional signal transduction system. Furthermore, we observed several EPO-responsive genes that were not reported in mammalian erythroid progenitors. These findings suggest the functional difference between enucleated erythrocytes in adult mammals and nucleated erythrocytes in fetal mammals and non-mammalian vertebrates.

Project description:The present study was undertaken to test the hypothesis that EPO may promote the formation of abdominal aortic aneurysm (AAA) via angiogenesis and inflammatory response. We injected EPO in different doses to Apoe-/- and WT mice, used EPO mAb in Apoe-/- mice with AngII stimulation, injected a selective activator of the heterodimer receptors of EPO into Apoe-/- and WT mice, and created CRISPR-mediated EPOR knockout (Epor+/-Apoe-/-) mice. In addition, we measured serum EPO concentration in healthy controls and patients with AAA, and performed a series of in vitro and ex vivo experiments in ECs, SMCs, and macrophages. Our results showed that EPO dose-dependently promoted the formation of AAA, with a high occurrence rate in both Apoe-/- and WT mice, and there was a close relationship between serum concentration of EPO and the incidence of AAA in Apoe-/- and WT mice receiving AngII or EPO treatment. The major mechanism involved angiogenesis, inflammatory response, SMCs apoptosis and collagen degradation via EPO-EPOR-JAK2/STAT5 signaling pathway in vascular cells. Administration of EPO neutralizing antibody suppressed AngII-induced AAA formation, and the incidence of AAA was dramatically reduced in Epor+/-Apoe-/- versus Apoe-/- mice after AngII infusion. In addition, serum EPO concentration was substantially higher in patients with AAA than in healthy subjects and correlated with the size of AAA in patients. In conclusion, EPO promotes the formation of AAA in both Apoe-/- and WT mice likely via enhanced angiogenesis, inflammation, SMCs apoptosis and collagen degradation, and EPO/EPOR signaling is essential for AngII-induced and possibly human AAA.

Project description:Erythropoietin (EPO), named after its role in hematopoiesis, is also expressed in the mammalian brain. In clinical settings, recombinant EPO had revealed a remarkable improvement of cognitive functions, but the underlying mechanisms have remained obscure. Animal studies demonstrated, however, that neuronal EPO effects are independent of an elevated hematocrit. Here, we show with a novel line of reporter mice that cognitive challenge leads to local/endogenous hypoxia in hippocampal pyramidal neurons where it induces enhanced expression of both EPO and EPO receptor (EPOR). High-dose EPO administration, which amplifies auto/paracrine EPO/EPOR signaling, prompts the emergence of new CA1 neurons and enhanced dendritic spine densities. Single cell sequencing reveals rapid increase in newly differentiating neurons. Importantly, improved performance on complex running wheels after EPO treatment is imitated by exposure to mild exogenous/inspiratory hypoxia. All these effects depend on neuronal expression of the Epor gene. Taken together, this suggests a novel cellular model of neuroplasticity in which neuronal networks, challenged by cognitive tasks, drift into transient hypoxia which becomes a trigger of neuronal EPO/EPOR expression. This regulatory circle causes long-lasting neuroplastic adaptation, and as fundamental cellular mechanism, may be relevant for strategies aiming at cognitive improvement.

Project description:Analysis of the gene expression profile in differentiating rat CG4-EPOR oligodendrocytes treated with EPO, LIF or their combination for 1h or 20h

Project description:Analysis of the miRNA expression profile in differentiating rat CG4-EPOR oligodendrocytes treated with EPO, LIF or their combination for 1h or 20h

Project description:Erythropoietin (EPO) has multiple functions beyond stimulating erythrocytosis, including modulation of T cell immunity. Effects EPO in transplantation and associated mechanisms remain incompletely understood. We analyzed outcomes and performed cellular and molecular mechanistic assessments in murine wild type (WT) and conditional EPO receptor (EPOR) knockout recipients of cardiac allografts. In translational studies, we tested EPO’s effects in a non-human primate system.

Project description:Erythropoietin (EPO) is the primary regulator of erythropoiesis in the mammalian fetus and the adult through interaction with erythropoietin receptor (EPOR). Deficiency of EPO induces anemia that is a major cause of death in patients with chronic kidney disease. Thus, development of safe treatment for anemia is an urgent issue. In this study, we investigated the effect of γ-aminobutyric acid (GABA) on serum EPO level and erythropoiesis, and its mechanism was elucidated in rat. GABA significantly (P < 0.05) increased EPO level in serum and expression levels of EPO and EPOR in a dose dependent manner. GABA increased the expression levels of HIF-1 and HIF-2 in a dose dependent manner compared with the negative control; while GABA did not affect the expression of prolyl-hydroxylase domain protein-2α (PHD-2α) gene, an oxygen sensor. GABA supplementation alters energy production pathway resulted in hypoxic condition, which increases EPO level in rat through overexpression of HIF-1 and HIF-2. This study shows a new physiological role of GABA in EPO production and thus GABA could contribute to the prevention of anemia by using alone or in combination with other anemia treating drugs.

Project description:RNA-sequencing of proliferating, doxorubicin-induced senescent, palbociclib (CDK4/6i)-induced senescent and INK128-induced diapause-like human melanoma SK-MEL-147 cells and human NSCLC A549

Project description:This is the core model described in the article: Covering a Broad Dynamic Range: Information Processing at the Erythropoietin Receptor Verena Becker, Marcel Schilling, Julie Bachmann, Ute Baumann, Andreas Raue, Thomas Maiwald, Jens Timmer and Ursula Klingmüller; Science Published Online May 20, 2010; DOI: 10.1126/science.1184913 PMID: 20488988 Abstract: Cell surface receptors convert extracellular cues into receptor activation, thereby triggering intracellular signaling networks and controlling cellular decisions. A major unresolved issue is the identification of receptor properties that critically determine processing of ligand-encoded information. We show by mathematical modeling of quantitative data and experimental validation that rapid ligand depletion and replenishment of cell surface receptor are characteristic features of the erythropoietin (Epo) receptor (EpoR). The amount of Epo-EpoR complexes and EpoR activation integrated over time corresponds linearly to ligand input, covering a broad range of ligand concentrations. This relation solely depends on EpoR turnover independent of ligand binding, suggesting an essential role of large intracellular receptor pools. These receptor properties enable the system to cope with basal and acute demand in the hematopoietic system. SBML model exported from PottersWheel. % PottersWheel model definition file function m = BeckerSchilling2010_EpoR_CoreModel() m = pwGetEmptyModel(); %% Meta information m.ID = 'BeckerSchilling2010_EpoR_CoreModel'; m.name = 'BeckerSchilling2010_EpoR_CoreModel'; m.description = 'BeckerSchilling2010_EpoR_CoreModel'; m.authors = {'Verena Becker',' Marcel Schilling'}; m.dates = {'2010'}; m.type = 'PW-2-0-42'; %% X: Dynamic variables % m = pwAddX(m, ID, startValue, type, minValue, maxValue, unit, compartment, name, description, typeOfStartValue) m = pwAddX(m, 'EpoR' , 516, 'fix' , 0, 10000, [], 'cell', [] , [] , [] , [] , 'protein.generic'); m = pwAddX(m, 'Epo' , 2030.19, 'global', 1890, 2310, [], 'cell', [] , [] , [] , [] , 'protein.generic'); m = pwAddX(m, 'Epo_EpoR' , 0, 'fix' , 0, 10000, [], 'cell', [] , [] , [] , [] , 'protein.generic'); m = pwAddX(m, 'Epo_EpoRi', 0, 'fix' , 0, 10000, [], 'cell', [] , [] , [] , [] , 'protein.generic'); m = pwAddX(m, 'dEpoi' , 0, 'fix' , 0, 10000, [], 'cell', [] , [] , [] , [] , 'protein.generic'); m = pwAddX(m, 'dEpoe' , 0, 'fix' , 0, 10000, [], 'cell', [] , [] , [] , [] , 'protein.generic'); %% R: Reactions % m = pwAddR(m, reactants, products, modifiers, type, options, rateSignature, parameters, description, ID, name, fast, compartments, parameterTrunks, designerPropsR, stoichiometry, reversible) m = pwAddR(m, { }, {'EpoR' }, { }, 'C' , [] , 'k1*k2', {'kt','Bmax'}, [], 'reaction0001'); m = pwAddR(m, {'EpoR' }, { }, { }, 'MA', [] , [] , {'kt' }, [], 'reaction0002'); m = pwAddR(m, {'Epo','EpoR'}, {'Epo_EpoR' }, { }, 'MA', [] , [] , {'kon' }, [], 'reaction0003'); m = pwAddR(m, {'Epo_EpoR' }, {'Epo','EpoR'}, { }, 'MA', [] , [] , {'koff' }, [], 'reaction0004'); m = pwAddR(m, {'Epo_EpoR' }, {'Epo_EpoRi' }, { }, 'MA', [] , [] , {'ke' }, [], 'reaction0005'); m = pwAddR(m, {'Epo_EpoRi' }, {'Epo','EpoR'}, { }, 'MA', [] , [] , {'kex' }, [], 'reaction0006'); m = pwAddR(m, {'Epo_EpoRi' }, {'dEpoi' }, { }, 'MA', [] , [] , {'kdi' }, [], 'reaction0007'); m = pwAddR(m, {'Epo_EpoRi' }, {'dEpoe' }, { }, 'MA', [] , [] , {'kde' }, [], 'reaction0008'); %% C: Compartments % m = pwAddC(m, ID, size, outside, spatialDimensions, name, unit, constant) m = pwAddC(m, 'cell', 1); %% K: Dynamical parameters % m = pwAddK(m, ID, value, type, minValue, maxValue, unit, name, description) m = pwAddK(m, 'kt' , 0.0329366 , 'global', 1e-007, 1000); m = pwAddK(m, 'Bmax', 516 , 'fix' , 492 , 540 ); m = pwAddK(m, 'kon' , 0.00010496, 'global', 1e-007, 1000); m = pwAddK(m, 'koff', 0.0172135 , 'global', 1e-007, 1000); m = pwAddK(m, 'ke' , 0.0748267 , 'global', 1e-007, 1000); m = pwAddK(m, 'kex' , 0.00993805, 'global', 1e-007, 1000); m = pwAddK(m, 'kdi' , 0.00317871, 'global', 1e-007, 1000); m = pwAddK(m, 'kde' , 0.0164042 , 'global', 1e-007, 1000); %% Default sampling time points m.t = 0:3:99; %% Y: Observables % m = pwAddY(m, rhs, ID, scalingParameter, errorModel, noiseType, unit, name, description, alternativeIDs, designerProps) m = pwAddY(m, 'Epo + dEpoe' , 'Epo_extracellular_obs'); m = pwAddY(m, 'Epo_EpoR' , 'Epo_cellsurface_obs' ); m = pwAddY(m, 'Epo_EpoRi + dEpoi', 'Epo_intracellular_obs'); %% S: Scaling parameters % m = pwAddS(m, ID, value, type, minValue, maxValue, unit, name, description) m = pwAddS(m, 'scale_Epo_extracellular_obs', 1, 'fix', 0, 100); m = pwAddS(m, 'scale_Epo_cellsurface_obs' , 1, 'fix', 0, 100); m = pwAddS(m, 'scale_Epo_intracellular_obs', 1, 'fix', 0, 100); %% Designer properties (do not modify) m.designerPropsM = [1 1 1 0 0 0 400 250 600 400 1 1 1 0 0 0 0]; This model originates from BioModels Database: A Database of Annotated Published Models. It is copyright (c) 2005-2010 The BioModels.net Team. For more information see the terms of use . To cite BioModels Database, please use: Li C, Donizelli M, Rodriguez N, Dharuri H, Endler L, Chelliah V, Li L, He E, Henry A, Stefan MI, Snoep JL, Hucka M, Le Novère N, Laibe C (2010) BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. BMC Syst Biol., 4:92.