Project description:Head regeneration in Hydra requires the transformation of gastric tissue into a head organizer that produces a head activator and a head inhibitor. Here we report the decipherment of a long-standing question in developmental biology, the identification of the transcription factor Sp5 as a key head inhibitory component. We show that Sp5 has an apical to basal graded expression pattern in intact Hydra, its expression is induced upon Wnt/β-catenin signaling activation and when knocked-down triggers the formation of multiple heads and axes in homeostatic and regenerative conditions. Our data indicate that Sp5 acts in a feed-forward loop to robustly regulate its own expression and that Sp5 prevents head formation by repressing the Wnt3 promoter. This Sp5 mediated Wnt antagonism is conserved and was invented early in metazoan evolution to set up axial patterning.

Project description:Head regeneration in Hydra requires the transformation of gastric tissue into a head organizer that produces a head activator and a head inhibitor. Here we report the decipherment of a long-standing question in developmental biology, the identification of the transcription factor Sp5 as a key head inhibitory component. We show that Sp5 has an apical to basal graded expression pattern in intact Hydra, its expression is induced upon Wnt/β-catenin signaling activation and when knocked-down triggers the formation of multiple heads and axes in homeostatic and regenerative conditions. Our data indicate that Sp5 acts in a feed-forward loop to robustly regulate its own expression and that Sp5 prevents head formation by repressing the Wnt3 promoter. This Sp5 mediated Wnt antagonism is conserved and was invented early in metazoan evolution to set up axial patterning.

Project description:Head regeneration in Hydra requires the transformation of gastric tissue into a head organizer that produces a head activator and a head inhibitor. Here we report the decipherment of a long-standing question in developmental biology, the identification of the transcription factor Sp5 as a key head inhibitory component. We show that Sp5 has an apical to basal graded expression pattern in intact Hydra, its expression is induced upon Wnt/β-catenin signaling activation and when knocked-down triggers the formation of multiple heads and axes in homeostatic and regenerative conditions. Our data indicate that Sp5 acts in a feed-forward loop to robustly regulate its own expression and that Sp5 prevents head formation by repressing the Wnt3 promoter. This Sp5 mediated Wnt antagonism is conserved and was invented early in metazoan evolution to set up axial patterning. To gain insights on the evolution of the transcriptional properties of the Sp5 gene, we analyzed the capacity of the hydra Sp5 and zebrafish Sp5a paralogs to bind to cis-regulatory elements of the contitutively active human genome and to regulate the expression of the corresponding target genes. To this end, we transfected HEK293 cells with plasmids encoding for either hySp5 or zfSp5a proteins and we performed ChIPseq and RNAseq experiments to analyze their genomic occupancies and the changes in the transcriptional profiles induced upon transfection.

Project description:Analysis of gene expression changes that occur in keratinocytes during reprogramming when they are treated with DAPT, a small molecule gamma-secretase inhibitor. The hypothesis tested in the present study was that Notch inhibition by DAPT treatment would promote reprogramming by inhibiting p21 activity while leaving p53 expression intact. Results provide important information of the gene expression changes in response to DAPT treatment, such as changes in the expression of p21, p21-responsive genes, p53, p53-responsive genes involved in apoptosis, and Notch-responsive genes.

Project description:Analysis of gene expression changes that occur in keratinocytes during reprogramming when they are treated with DAPT, a small molecule gamma-secretase inhibitor. The hypothesis tested in the present study was that Notch inhibition by DAPT treatment would promote reprogramming by inhibiting p21 activity while leaving p53 expression intact. Results provide important information of the gene expression changes in response to DAPT treatment, such as changes in the expression of p21, p21-responsive genes, p53, p53-responsive genes involved in apoptosis, and Notch-responsive genes. Total RNA obtained from mouse keratinocytes transduced with reprogramming transcription factors and treated or not treated with DAPT for 4 days or 7 days.

Project description:Differential gene regulation in DAPT-treated Hydra reveals candidate direct Notch signalling targets

Project description:The Notch signaling pathway regulates several processes including development and differentiation and its aberrant regulation leads to several diseases. Here, we investigated the differential chromatin accessibility, genome-wide distribution of the transcription factor RBPJ and the differential regulation of H3K4me1 and H3K4me3 upon pharmacological inhibition of the Notch pathway with gamma-secretase inibibitor (GSI) DAPT in mouse pre-T (Beko) cells.

Project description:The Notch signaling pathway regulates several processes including development and differentiation and its aberrant regulation leads to several diseases. Here, we investigated the differential chromatin accessibility, genome-wide distribution of the transcription factor RBPJ and the differential regulation of H3K4me1 and H3K4me3 upon pharmacological inhibition of the Notch pathway with gamma-secretase inibibitor (GSI) DAPT in mouse pre-T (Beko) cells.

Project description:The Notch signaling pathway regulates several processes including development and differentiation and its aberrant regulation leads to several diseases. Here, we investigated the differential chromatin accessibility, genome-wide distribution of the transcription factor RBPJ and the differential regulation of H3K4me1 and H3K4me3 upon pharmacological inhibition of the Notch pathway with gamma-secretase inibibitor (GSI) DAPT in mouse pre-T (Beko) cells.

Project description:Notch signalling plays crucial roles in mediating cell fate choices in all metazoans largely by specifying the transcriptional output of one cell in response to a neighbouring cell. The DNA-binding protein RBPJ is the principle effector of this pathway in mammals and together with the transcription factor moiety of Notch (NICD) it regulates the expression of target genes. The prevalent view presumes that RBPJ statically occupies consensus binding sites while exchanging repressors for activators in response to NICD. We present the first specific RBPJ chromatin immunoprecipitation and high-throughput sequencing study in mammalian cells. To dissect the mode of transcriptional regulation by RBPJ and identify its direct targets, whole genome binding profiles were generated for RBPJ, its coactivator p300, NICD and the histone H3 modifications H3K4me3, H3K4me1 and H3K27ac in myogenic cells under active or inhibitory Notch signalling conditions. Our results demonstrate dynamic binding of RBPJ in response to Notch activation at essentially all sites co-occupied by NICD. Additionally, we identify a distinct set of sites where RBPJ recruits neither NICD nor p300, and binds DNA statically, irrespective of Notch activity. These findings significantly modify our views on how RBPJ and Notch signalling mediate their activities and consequently impact on cell fate decisions. ChIP (chromatin immunoprecipitation) is followed by deep sequencing to generate genome-wide patterns of RBP-J binding in mouse C2C12 cells under various conditions. Cells were either Notch activated by exposure to immobilized ligand or by overexpression of NICDGFP, or Notch inhibited by treatment with DAPT. Notch activation and inhibition treatments were applied for 6h and 24h. In addition to RBP-J, p300 and NICDGFP were profiled by ChIP-Seq and gene expression was assessed by RNA-Seq.