Project description:Target deconvolution of small molecule hits from phenotypic screens presents a major challenge. Illustrative of these are the many screens that have been conducted to find inhibitors for the Hedgehog (Hh) signaling pathway – a major developmental pathway with many implications in health and disease - with many hits but very few identified cellular targets. We here present a strategy for target identification based on Proteolysis-Targeting Chimeras (PROTACs), combined with label-free quantitative proteomics. We developed a PROTAC based on the downstream Hedgehog Pathway Inhibitor-1 (HPI-1), a phenotypic screen hit with unknown cellular target. Using our Hedgehog Pathway PROTAC (HPP) we identified and validated BET bromodomains to be the cellular targets of HPI-1. Furthermore, we found that HPP-9 has a unique mechanism of action as a long-acting Hh pathway inhibitor through prolonged BET bromodomain degradation. Collectively, we provide a powerful PROTAC-based approach for target deconvolution, that has answered the longstanding question of the cellular target of HPI-1 and yielded the first PROTAC that acts on the Hh pathway.

Project description:Target deconvolution of small molecule hits from phenotypic screens presents a major challenge. Illustrative of these are the many screens that have been conducted to find inhibitors for the Hedgehog (Hh) signaling pathway – a major developmental pathway with many implications in health and disease - with many hits but very few identified cellular targets. We here present a strategy for target identification based on Proteolysis-Targeting Chimeras (PROTACs), combined with label-free quantitative proteomics. We developed a PROTAC based on the downstream Hedgehog Pathway Inhibitor-1 (HPI-1), a phenotypic screen hit with unknown cellular target. Using our Hedgehog Pathway PROTAC (HPP) we identified and validated BET bromodomains to be the cellular targets of HPI-1. Furthermore, we found that HPP-9 has a unique mechanism of action as a long-acting Hh pathway inhibitor through prolonged BET bromodomain degradation. Collectively, we provide a powerful PROTAC-based approach for target deconvolution, that has answered the longstanding question of the cellular target of HPI-1 and yielded the first PROTAC that acts on the Hh pathway.

Project description:Aberrant activation of Hedgehog pathway is responsible for initiation and maintenance of various cancers, including medulloblastoma (MB), basal cell carcinoma (BCC), and other solid and hematological tumors. Therefore, targeting Hh pathway represents promising therapeutic prospects for Hh-driven cancers. In recent years, tremendous efforts have been dedicated to the discovery of Hh pathway inhibitor. While the majority of Hh pathway inhibitors target the upstream membrane protein Smoothened (SMO). Here, we performed Next Generation Sequencing to reveal the target genes of Hh pathway by treating mouse SHH-subtype medulloblastoma cells (SmoWT) with SMO inhibitor (GDC0449) or DMSO.

Project description:MZ1 is a newly designed pan-BET-targeting PROTAC that binds to target proteins (BET proteins such as BRD2, BRD3, and BRD4) and recruits them to the ubiquitin/protease pathway for selective destruction. However, the role of MZ1 in NB models has yet to be determined. The effect of MZ1 on NB cells was investigated using RNA-seq analysis in this work. MZ1 is a newly designed pan-BET-targeting PROTAC that binds to target proteins (BET proteins such as BRD2, BRD3, and BRD4) and recruits them to the ubiquitin/protease pathway for selective destruction. However, the role of MZ1 in NB models has yet to be determined. The effect of MZ1 on NB cells was investigated using RNA-seq analysis in this work.

Project description:Paracrine Hedgehog (Hh) signaling regulates growth and patterning in many Drosophila organs. We mapped chromatin binding sites for Cubitus interruptus (Ci), the transcription factor that mediates outputs of Hh signal transduction, and we analyzed transcription profiles of control and mutant embryos to identify genes that are regulated by Hh. Putative targets we identified include several Hh pathway components, most previously identified targets, and many targets that are novel. Analysis of expression patterns of pathway components and target genes gave evidence of autocrine Hh signaling in the optic primordium of the embryo. And, every Hh target we analyzed that is not a pathway component appeared to be regulated by Hh in a tissue-specific manner. We present evidence that Hh-dependent tissue specificity is dependent upon transcription factors that are Hh-independent, suggesting that “pre-patterns” of transcription factors partner with Ci to make Hh-dependent gene expression position-specific. Analysis of the expression profiles of loss of function mutantations in core components of the Hh signaling pathway. A total of 14 samples were analysed consisting of comparisons of hh-, ci-, smo-, ptc-, and Cim1-m4 (Activator) mis-expression embryos compared to wt sibling embryos.

Project description:Paracrine Hedgehog (Hh) signaling regulates growth and patterning in many Drosophila organs. We mapped chromatin binding sites for Cubitus interruptus (Ci), the transcription factor that mediates outputs of Hh signal transduction, and we analyzed transcription profiles of control and mutant embryos to identify genes that are regulated by Hh. Putative targets we identified include several Hh pathway components, most previously identified targets, and many targets that are novel. Analysis of expression patterns of pathway components and target genes gave evidence of autocrine Hh signaling in the optic primordium of the embryo. And, every Hh target we analyzed that is not a pathway component appeared to be regulated by Hh in a tissue-specific manner. We present evidence that Hh-dependent tissue specificity is dependent upon transcription factors that are Hh-independent, suggesting that “pre-patterns” of transcription factors partner with Ci to make Hh-dependent gene expression position-specific. We utilized the DamID method to identify regions of CiAct methylated genomic DNA in stage 10-11 Drosophila embryos. Comparison of DamCiAct directed methylation vs. Dam Alone background methylation using 3 replicate experiments.

Project description:Paracrine Hedgehog (Hh) signaling regulates growth and patterning in many Drosophila organs. We mapped chromatin binding sites for Cubitus interruptus (Ci), the transcription factor that mediates outputs of Hh signal transduction, and we analyzed transcription profiles of control and mutant embryos to identify genes that are regulated by Hh. Putative targets we identified include several Hh pathway components, most previously identified targets, and many targets that are novel. Analysis of expression patterns of pathway components and target genes gave evidence of autocrine Hh signaling in the optic primordium of the embryo. And, every Hh target we analyzed that is not a pathway component appeared to be regulated by Hh in a tissue-specific manner. We present evidence that Hh-dependent tissue specificity is dependent upon transcription factors that are Hh-independent, suggesting that “pre-patterns” of transcription factors partner with Ci to make Hh-dependent gene expression position-specific. We utilized the DamID method to identify regions of CiRep methylated genomic DNA in stage 10-11 Drosophila embryos. Comparison of DamCiRep directed methylation vs. Dam Alone background methylation using 3 replicate experiments.

Project description:Osteoarthritis (OA) is a common degenerative disease of the joint. Data from our lab indicates that Hedgehog (Hh) signaling is activated in human OA and murine models of OA (Lin et al., 2009, Nature Medicine). To identify Hh target genes, microarray analyses were performed to detect changes in gene expression when the Hh pathway was inhibited in human OA cartilage samples. Identifying Hh target genes in chondrocytes will elucidate key regulatory networks that govern chondrocyte homeostasis and provide novel therapeutic strategies for OA.

Project description:Misactivation of the Hedgehog (Hh) pathway can cause cancers such as medulloblastomas, the most common malignant brain tumor in children, and basal cell carcinomas, the most common cancer in the United States. Hedgehog signals are transmitted through primary cilia, where Hedgehog ligands bind to Patched1 and activate Smoothened through interactions with cilia-associated sterol lipids. The gene expression programs driving cellular responses to ciliary Hh signals are incompletely understood. Thus, to define Hh target genes, we performed RNA sequencing of cells after treatment with Hh ligands (Shh, Dhh, Ihh), cilia-associated lipids (7b,27-dihydroxycholesterol, 24(S),25-epoxycholesterol), or synthetic lipids or small molecules that activate Smoothened (20(S)-hydroxycholesterol, SAG). Treatment with Hh pathway agonists identified a core gene expression program comprised of 155 genes driving lipid synthesis, metabolism, signaling, adhesion, or angiogenesis. These datasets were integrated with RNA sequencing of Hh-human medulloblastomas (n=?), a Math1-Cre SmoM2 mouse genetic model of Hh-associated medulloblastoma (n=?), and human basal cell carcinomas (n=10) to ascertain how malignant Hh signaling differs from canonical Hh signaling. We discover a conserved response to ciliary Hh signals in human or mouse medulloblastomas, including known target genes such as Gli1 or Ptch1, and novel target genes such as Hsd11b1 or Retnla. Importantly, mechanistic studies reveal Hsd11b1 to be a putative negative regulator of Hh signaling that is dysregulated in malignancies. We further demonstrate Retnla to be a positive regulator of Hh signaling that drives expression of Hsd11b2, a druggable dependency underlying Hedgehog-associated medulloblastoma. Orthotopic implantation of neuroepithelial stem cells that overexpress either Hsd11b1 and Retnla demonstrate that tumors derived Hsd11ß1 overexpression are more primitive and less aggressive whereas Retnla overexpression forms tumors that are more differentiated and behave more aggressively. In sum, we illuminate the first comprehensive transcriptome of Hh signaling and highlight the intricate interplay between Hh signaling and lipid metabolism that Hh-dependent malignancies dysregulate to drive tumor progression.

Project description:Paracrine Hedgehog (Hh) signaling regulates growth and patterning in many Drosophila organs. We mapped chromatin binding sites for Cubitus interruptus (Ci), the transcription factor that mediates outputs of Hh signal transduction, and we analyzed transcription profiles of control and mutant embryos to identify genes that are regulated by Hh. Putative targets we identified include several Hh pathway components, most previously identified targets, and many targets that are novel. Analysis of expression patterns of pathway components and target genes gave evidence of autocrine Hh signaling in the optic primordium of the embryo. And, every Hh target we analyzed that is not a pathway component appeared to be regulated by Hh in a tissue-specific manner. We present evidence that Hh-dependent tissue specificity is dependent upon transcription factors that are Hh-independent, suggesting that “pre-patterns” of transcription factors partner with Ci to make Hh-dependent gene expression position-specific.