Project description:PPARb/d agonist and antagonist response was characterized in (human) monocyte derived macrophages.

Project description:PPARD and RXR genome wide binding in tumor associated macrophages from serous ovarian carcinoma was characterized.

Project description:The PPARD ligand response (agonist and inverse agonist) in monocyte derived macrophages from 3 healthy donors was assesed via RNAseq.

Project description:PPARD in MDM - chipseq

Project description:Genome-wide Analysis of Sp2 Occupancy and Expression Profiling Establish Sp2 as a Sequence-specific Transcription Factor Regulating Fundamental Cellular Processes - ChIPseq

Project description:Analysis of white adipose tissue of PPARb/d knockout mice. Data may point towards putative target genes of PPARb/d and thus the function of PPARb/d in white adipose tissue. Datasets were used to identify glycogen synthase 2 as novel PPAR target. Keywords: gene expression array-based, count

Project description:Stroma secretes complex regulatory signals, including reactive oxygen species, that are involved in mediating cancer development. Ablation of PPARB expression in fibroblastic cells results in modulation of oxidative stress signals that lead By means of gene expression analysis, we seek to identify key gene expression changes in tumor epithelial cells between FSPCre-PPARB -/- and PPARB flox/flox mice.

Project description:Stroma secretes a multitude of regulatory signals that are involved in mediating intestinal development. Ablation of PPARB expression in fibroblastic cells results in modulation of oxidative stress signals that lead to altered intestinal morphology and gene expression profiles Through gene chip expression profiling, we seek to identify key changes in intestinal mucosal gene expression profiling between FSPCre-PPARB flox/flox and PPARB flox/flox mice.

Project description:Solar radiation is the major source of human exposure to UV radiation, the major carcinogen in skin cancers, by triggering a number of cellular responses that can indirectly or directly induce DNA damage. Skin cells attempt to repair these damages by activating cascades of DNA Damage Response mechanisms to safeguard genome integrity, thereby preventing skin cancers. The role of PPARb - a druggable transcription factor, in the development of UV-dependent skin cancers is not mechanistically elucidated. We have shown previously that PPARb knockout mice are less prone to UV-induced skin cancers. Here, we report on our global transcriptomic analysis revealing that PPARb directly regulates gene expression programs associated with cell cycle and DNA repair pathways in normal human epidermal keratinocytes. We show that in these cells, as well as in malignant human keratinocytes and in human melanoma cells, PPARb controls cellular proliferation and cell cycle progression and its depletion leads to cell cycle arrest. We also show that PPARb controls the response of normal human epidermal keratinocytes to UV-induced DNA damage. PPARb depletion decreases the expression and/or activation of multiple effectors of DNA Damage Response (DDR) pathway and favours the apoptotic response of human keratinocytes to UV irradiation. Our preclinical data of a PDX melanoma model demonstrated that the depletion or inhibition of PPARb delays of blocks tumor formation. Our data suggest that PPARb inhibition can be considered as a therapeutic target for the prevention of UV-induced skin cancers in vulnerable population, by attenuating the DDR and eliminating skin cells with high UV-induced mutational burden.

Project description:This experiment was conducted to identify target microRNAs of the peroxisome proliferator-activated receptor (PPAR) in skeletal muscle of transgenic mice that overexpressed PPARalpha or PPARbeta. We have recently demonstrated that skeletal muscle-specific PPARb transgenic (MCK-PPARb) mice exhibit increased exercise endurance, whereas MCK-PPARa mice have reduced exercise performance. Accordingly, we sought to determine whether PPARb and PPARa drive distinct programs involved in muscle fiber type determination. Myosin heavy chain (MHC) immunohistochemical staining of soleus muscle revealed a marked increase in type 1 fibers in the MCK-PPARb muscle compared to non-transgenic (NTG) littermates but a profound reduction in MCK-PPARa muscle. miRNA profiling revealed that levels of miR-208b and miR-499 were increased in MCK-PPARb muscle but reduced in MCK-PPARa muscle. miR-208b and miR-499, which are embedded in the Myh7 and Myh7b genes, respectively, have been shown previously to regulate slow-twitch muscle genes. Lastly, combined inhibition of miR-208b and miR-499 abolished the enhancing effects of PPARb on MHC1 expression in skeletal myotubes, while forced expression of miR-499 in MCK-PPARa muscle completely reversed the type 1 fiber program and exercise capacity. Taken together, these findings demonstrate that miR-208b and miR-499 are necessary to mediate the effects of PPARb and PPARa on muscle fiber type determination.