Project description:C-type natriuretic peptide (CNP) has been recently identified as an important anabolic regulator of endochondral bone growth, but the molecular mechanism mediating these effects are not completely understood. Here we demonstrate that CNP activates the p38 MAP kinase pathway in chondrocytes and that pharmacological inhibition of p38 blocks the anabolic effects of CNP in a tibia organ culture system. We further show that CNP stimulates endochondral bone growth largely through expansion of the hypertrophic zone of the growth plate, while delaying mineralization. Both effects are reversed by p38 inhibition. We performed Affymetrix microarray analyses to identify CNP target genes in the organ culture system. These studies confirmed that hypertrophic chondrocytes are the main targets of CNP signaling in the growth plate, potentially because cGMP-dependent kinases I and II, important transducers of CNP signaling and are expressed at much higher levels in these cells than in other areas of the tibia. One of the genes most strongly induced by CNP was the Ptgs2 gene, encoding Cox2. Real-time PCR confirmed that Cox2 expression was induced by CNP in hypertrophic chondrocytes, but surprisingly in a p38-independent manner. Moreover, Cox2 inhibition – in contrast to p38 inhibition - did not block the anabolic effects of CNP. In summary, our data identify novel target genes of CNP and demonstrate that the p38 pathway is a novel, essential mediator of CNP effects on endochondral ossification, with potential implications for numerous skeletal diseases. Experiment Overall Design: Tibiae from E15.5 day old embryonic mice were isolated and cultured in minimal media in the presence of vehicle, BSA/HCl (1mM), or C-type natriuretic peptide, CNP (10-6M). On the sixth day of treatment cultured tibias were micro-dissected into the resting/proliferating, hypertrophic, and mineralized areas. Distinct zones from approximately 24 bones were pooled together, from which RNA was isolated using the Qiagen RNeasy Lipid Extraction Kit. Once the quality of total RNA from three independent trials was determined using the Agilent 2100 bioanalyzer, microarray analyses were performed at the London Regional Genomics Centre using MOE430_2.0 Affymetrix arrays. Results were analyzed using GeneSpring 7.2 software.

Project description:C-type natriuretic peptide (CNP) has been recently identified as an important anabolic regulator of endochondral bone growth, but the molecular mechanism mediating these effects are not completely understood. Here we demonstrate that CNP activates the p38 MAP kinase pathway in chondrocytes and that pharmacological inhibition of p38 blocks the anabolic effects of CNP in a tibia organ culture system. We further show that CNP stimulates endochondral bone growth largely through expansion of the hypertrophic zone of the growth plate, while delaying mineralization. Both effects are reversed by p38 inhibition. We performed Affymetrix microarray analyses to identify CNP target genes in the organ culture system. These studies confirmed that hypertrophic chondrocytes are the main targets of CNP signaling in the growth plate, potentially because cGMP-dependent kinases I and II, important transducers of CNP signaling and are expressed at much higher levels in these cells than in other areas of the tibia. One of the genes most strongly induced by CNP was the Ptgs2 gene, encoding Cox2. Real-time PCR confirmed that Cox2 expression was induced by CNP in hypertrophic chondrocytes, but surprisingly in a p38-independent manner. Moreover, Cox2 inhibition – in contrast to p38 inhibition - did not block the anabolic effects of CNP. In summary, our data identify novel target genes of CNP and demonstrate that the p38 pathway is a novel, essential mediator of CNP effects on endochondral ossification, with potential implications for numerous skeletal diseases. Keywords: Growth plate zone comparison and treatment response analysis

Project description:Appendicular skeletal growth and bone mass acquisition are controlled by a variety of growth factors, hormones, and mechanical forces in a dynamic process called endochondral ossification. In long bones, chondrocytes in the growth plate proliferate and undergo hypertrophy to drive bone lengthening and mineralization. Pleckstrin homology (PH) domain and leucine rich repeat phosphatase 1 and 2 (Phlpp1 and Phlpp2) are serine/threonine protein phosphatases that regulate cell proliferation, survival, and maturation via Akt, PKC, Raf1, S6k, and other intracellular signaling cascades. Germline deletion of Phlpp1 suppresses bone lengthening in part through parathyroid hormone receptor-dependent signaling in growth plate chondrocytes. Here, we demonstrate that Phlpp2 does not regulate endochondral ossification, and we define the molecular differences between Phlpp1 and Phlpp2 in chondrocytes. Phlpp2-/- mice are phenotypically indistinguishable from their wildtype (WT) littermates, with similar bone length, bone mass, and growth plate dynamics. Deletion of Phlpp2 had moderate effects on the chondrocyte transcriptome and proteome compared to WT cells. By contrast, Phlpp1/2-/- (double knockout) mice resembled Phlpp1-/- mice phenotypically and chondrocyte phospho-proteomes of Phlpp1-/- and Phlpp1/2-/- chondrocytes were different than WT and Phlpp2-/- chondrocyte phospho-proteomes. Data integration via multiparametric analysis identified alterations in Pdpk1 and Pak1/2 signaling pathways in chondrocytes lacking Phlpp1. In conclusion, these data demonstrate that Phlpp1, but not Phlpp2, regulates endochondral ossification through multiple and complex signaling cascades.

Project description:In this study, we have analyzed DNA methylation characteristics of human mesenchymal stem and progenitor cells (MSPCs) form different tissue sources including bone marrow (BM), white adipose tissue (WAT ), umbilical cord (UC) as well as dermal fibroblasts by using the HumanMethylation450K array. Cells able to form bone through endochondral ossification and attract bone marrow in an innovative in vivo model were compared to cells lacking these capacities. Interestingly only BM-derived MSPCs were capable of bone formation and marrow attraction. These features correlated with unique epigenetic characteristics potentially enabling BM-derived cells to undergo endochondral ossification. 12 samples were hybridised to the Illumina Infinium 450k Human Methylation Beadchip

Project description:Highly pathogenic avian influenza viruses (HPAIV) induce severe inflammation in poultry and men. There is still an ongoing threat that these viruses may acquire the capability to freely spread as novel pandemic virus strains that may cause major morbidity and mortality. One characteristic of HPAIV infections is the induction of a cytokine burst that strongly contributes to viral pathogenicity. It has been suggested, that this cytokine overexpression is an intrinsic feature of infected cells and involves hyperinduction of p38 mitogen activated protein kinase (MAPK). Here we investigate the role of MAPK p38 signaling in the antiviral response against HPAIV in mice as well as in endothelial cells, the latter a primary source for cytokines during systemic infections. Global gene expression profiling of HPAIV infected endothelial cells in the presence of the MAP kinase p38-specific inhibitor SB202190 revealed, that inhibition of MAPK p38 leads to reduced expression of interferon (IFN) and other cytokines after A/Thailand/1(KAN-1)/2004 (H5N1) and A/FPV/Bratislava/79 (H7N7) infection. Furthermore, the expression of interferon stimulated genes (ISGs) after treatment with IFN or conditioned media from HPAIV infected cells was decreased when the target cells were preincubated with SB202190. Finally, promoter analysis confirmed a direct impact of p38 MAPK on the IFN-enhanceosome and ISG-promoter activity. In vivo inhibition of MAP kinase p38 greatly diminishes virus induced cytokine expression concomitant with reduced viral titers, thereby protecting mice from lethal infection. These observations show, that MAPK p38 acts on two levels of the antiviral IFN response: Initially the kinase regulates IFN induction and at a later stage MAPK p38 controls IFN signaling and thereby expression of IFN-stimulated genes. Thus, inhibition of MAP kinase p38 may be an antiviral strategy that significantly protects mice from lethal influenza via suppression of overshooting cytokine expression. HUVEC were infected with FPV in the presence or absence of a p38 MAP kinase inhibitor

Project description:Phlpp1 regulates endochondral ossification via the chondrocyte phospho-proteome

Project description:Appendicular growth and bone mass acquisition are controlled by a variety of growth factors, hormones, and mechanical forces in a dynamic process called endochondral ossification. Chondrocytes in the growth plate must proliferate and undergo hypertrophy to drive growth plate expansion and lay the template for bone. Pleckstrin homology (PH) domain and leucine rich repeat phosphatase 1 and 2 (Phlpp1 and Phlpp2) are protein phosphatases that regulate intracellular signaling cascades through posttranslational modification of AKT, PKC, and S6K, among others. Phlpp1 controls chondrocyte proliferation and survival and germline deletion of Phlpp1 suppresses bone lengthening. Here, we demonstrate that Phlpp2 does not regulate endochondral ossification. Phlpp2-/- mice are phenotypically indistinguishable from their wildtype (WT) littermates, with similar bone length, bone mass, and growth plate dynamics. By contrast, Phlpp1/2-/- mice are phenotypically indistinguishable from Phlpp1-/- mice. Deletion of Phlpp1 or Phlpp2 had moderate effects on the chondrocyte transcriptome and proteome compared to WT control cells. By contrast, Phlpp1-/- and Phlpp1/2-/- chondrocytes had significantly altered phospho-proteomes compared to WT and Phlpp2-/- chondrocytes. Data integration via multiomics analysis revealed that RAF-MEK-ERK signaling was altered in cells lacking Phlpp1. In conclusion, these data demonstrate that Phlpp1, but not Phlpp2, regulates endochondral ossification via the chondrocyte phospho-proteome.

Project description:Two natriuretic peptides, atrial natriuretic peptide (ANP) and brain natriuretic peptide (BNP) act through the common receptor, guanylyl cyclase-A (GC-A) to lower blood pressure, induce diuresis/natriuresis and dilate blood vessels. Recently, we discovered that the excessive cardiac hypertrophy accompanied with cardiac dysfunction was induced in the lactating natriuretic peptide receptor 1 (Npr1, which encodes GC-A)-deficient mice. To clarify the cause of lactation-induced cardic hypertrophy in Npr1-/-, we performed the gene expressions analysis using nulliparous (NP) or postpartum lactating wild-type (Npr1+/+) and Npr1-/- mice. Numerous genes were altered in the postpartum lactating period both in Npr1+/+ and Npr1-/-. Additionally, the involvement of inflammatory responce in the cardiac hypertrophy in lactating-Npr1-/- mice was clarified bythe gene ontology analysis.

Project description:In this study, we have analyzed DNA methylation characteristics of human mesenchymal stem and progenitor cells (MSPCs) form different tissue sources including bone marrow (BM), white adipose tissue (WAT ), umbilical cord (UC) as well as dermal fibroblasts by using the HumanMethylation450K array. Cells able to form bone through endochondral ossification and attract bone marrow in an innovative in vivo model were compared to cells lacking these capacities. Interestingly only BM-derived MSPCs were capable of bone formation and marrow attraction. These features correlated with unique epigenetic characteristics potentially enabling BM-derived cells to undergo endochondral ossification.

Project description:During endochondral fracture repair, a myriad of biochemical and phenotypic changes occur at the chondro-osseuous junction that regulate cartilage to bone conversion. Osteogenic and angiogenic factors have long been studied for accelerating fracture repair. In our concise study, we focused on the neurotrophic factor nerve growth factor (NGF) and its receptor tropomyosin receptor kinase A (TRKA) as understudied therapeutic targets for accelerating endochondral fracture repair. We first characterized endogenous expression of NGF and TRKA during endochondral repair of tibial fractures. We then analyzed gene expression data from β-NGF stimulated hypertrophic cartilage and observed a promotion in endochondral ossification associated markers. Additional gene ontology analyses revealed promotion of genes associated with Wnt activation, PDGF binding, and integrin binding. Subsequent histological analyses of in vivo samples confirmed Wnt activation following local β-NGF injections via reporter mice. Finally, we tested the therapeutic efficacy of local β-NGF injections in mice, which resulted in a decrease of cartilage and increase of bone volume. Moreover, the newly formed bone contained higher trabecular number, connective density, and bone mineral density. Collectively, we demonstrate the ability for β-NGF to promote endochondral fracture repair in a murine model and uncover mechanisms that will serve to further understand the molecular switches that occur during endochondral ossification.