Project description:The primary cilium is a signaling compartment that interprets Hedgehog signals through changes of its protein, lipid and second messenger compositions. Here, we combine proximity labeling of cilia with quantitative mass spectrometry to unbiasedly profile the time-dependent alterations of the ciliary proteome in response to Hedgehog. This approach correctly identifies the three factors known to undergo Hedgehog-regulated ciliary redistribution and reveals two such additional proteins. First, we find that a regulatory subunit of the cAMP-dependent protein kinase (PKA) rapidly exits cilia together with the G protein-coupled receptor GPR161 in response to Hedgehog; and we propose that the GPR161/PKA module senses and amplifies cAMP signals to modulate ciliary PKA activity. Second, we identify the phosphatase Paladin as a cell type-specific regulator of Hedgehog signaling that enters primary cilia upon pathway activation. The broad applicability of quantitative ciliary proteome profiling promises a rapid characterization of ciliopathies and their underlying signaling malfunctions.

Project description:The primary cilium is a signaling compartment that interprets Hedgehog signals through changes of its protein, lipid and second messenger compositions. Here, we combine proximity labeling of cilia with quantitative mass spectrometry to unbiasedly profile the time-dependent alterations of the ciliary proteome in response to Hedgehog. This approach correctly identifies the three factors known to undergo Hedgehog-regulated ciliary redistribution and reveals two such additional proteins. First, we find that a regulatory subunit of the cAMP-dependent protein kinase (PKA) rapidly exits cilia together with the G protein-coupled receptor GPR161 in response to Hedgehog; and we propose that the GPR161/PKA module senses and amplifies cAMP signals to modulate ciliary PKA activity. Second, we identify the phosphatase Paladin as a cell type-specific regulator of Hedgehog signaling that enters primary cilia upon pathway activation. The broad applicability of quantitative ciliary proteome profiling promises a rapid characterization of ciliopathies and their underlying signaling malfunctions.

Project description:The primary cilium is a signaling compartment that interprets Hedgehog signals through changes of its protein, lipid and second messenger compositions. Here, we combine proximity labeling of cilia with quantitative mass spectrometry to unbiasedly profile the time-dependent alterations of the ciliary proteome in response to Hedgehog. This approach correctly identifies the three factors known to undergo Hedgehog-regulated ciliary redistribution and reveals two such additional proteins. First, we find that a regulatory subunit of the cAMP-dependent protein kinase (PKA) rapidly exits cilia together with the G protein-coupled receptor GPR161 in response to Hedgehog; and we propose that the GPR161/PKA module senses and amplifies cAMP signals to modulate ciliary PKA activity. Second, we identify the phosphatase Paladin as a cell type-specific regulator of Hedgehog signaling that enters primary cilia upon pathway activation. The broad applicability of quantitative ciliary proteome profiling promises a rapid characterization of ciliopathies and their underlying signaling malfunctions.

Project description:Primary cilia are microtubule based sensory organelles important for receiving and processing cellular signals. Recent studies have shown that cilia also release extracellular vesicles (EVs) but little is known about their composition and function. Because EVs have been shown to exert various functions in physiology and pathology, these findings have the potential to fundamentally alter our understanding of how the primary cilium is able to regulate specific signalling pathways in development and disease. Compared to control, ciliary mutant mammalian cells demonstrated increased secretion of small EVs (smEVs) and a change in EV composition. Small RNA sequencing and mass spectrometry identified an enrichment for WNT signalling-associated miRNAs and proteins loaded into ciliary mutant EVs. Furthermore, we show that smEVs secreted from mammalian cells are biologically active and modulate the WNT response in recipient cells. These results highlight a possible new smEV-dependent ciliary signalling mechanism which could provide us with new insights into paracrine ciliary signalling as well as ciliopathy disease pathogenesis.

Project description:Primary cilia are microtubule based sensory organelles that protrude from almost every cell type. Their membrane contains highly specialized receptors important for receiving and processing extracellular signals, which enables them to regulate several signalling pathways. A recently discovered characteristic is that cilia are also able to release extracellular vesicles (EVs) from the ciliary membrane. Since EVs have been shown to exert numerous functions in physiology and pathology, these findings have the potential to dramatically alter our understanding of how the primary cilium is able to regulate various signalling pathways in development and disease. In our study we focused on the release of EVs from a ciliated kidney cell line. Using control and mutant cell lines, in which ciliary trafficking was disrupted, we observed that loss of primary cilia function leads to altered EV secretion and composition in NTA (Nanoparticle Tracking Analysis) and Western blot. Cilia mutant cells released more small EVs compared to control, and their composition was also changed between mutant and control. Protein identification via mass spectrometry identified both cilia- as well as WNT signalling-associated proteins and miRNA sequencing determined WNT-related miRNAs, which were differentially expressed in small EVs isolated from the cilia mutant cell line. Because of the presence of differentially expressed WNT related molecules in these small EVs, we tested whether this would have an effect on the WNT activity of recipient cells. We observed that small EVs secreted from cilia mutant cells differentially modulated the WNT response in recipient cells compared to control. Our results highlight a possible new small EV-dependent ciliary signalling mechanism, since deficient primary cilia lead to a change in EV secretion, resulting in an altered signal transduction. These results provide us with new insights into ciliopathy disease pathogenesis.

Project description:The primary cilium, a signaling organelle projecting from the surface of a cell, controls cellular physiology and behavior. The presence or absence of primary cilia is a distinctive feature of a given tumor type; however, whether and how the primary cilium contributes to tumorigenesis is unknown for most tumors. Medulloblastoma (MB) is a common pediatric brain cancer comprising four groups: SHH, WNT, group 3 (G3), and group 4 (G4). From 111 cases of MB, we show that primary cilia are abundant in SHH and WNT MBs but rare in G3 and G4 MBs. Using WNT and G3 MB mouse models, we show that primary cilia promote WNT MB by facilitating translation of mRNA encoding β-catenin, a major oncoprotein driving WNT MB, whereas cilium loss promotes G3 MB by disrupting cell cycle control and destabilizing the genome. Our findings reveal tumor type–specific ciliary functions and underlying molecular mechanisms. Moreover, we expand the function of primary cilia to translation control and reveal a molecular mechanism by which cilia regulate cell cycle progression, providing new frameworks for studying cilia function in normal and pathologic conditions.

Project description:Cilia are essential organelles that protrude from the cell body. Cilia are made of a microtubule-based structure called the axoneme. In most types of cilia, the ciliary tip is distinct from the rest of the cilium. By analysing Tetrahymena thermophila cells lacking a ciliary tip-enriched protein CEP104/FAP256 by mass spectrometry, we discovered candidates for the central pair cap complex and explained the potential functions of CEP104/FAP256. These data provide new insights into the function of the ciliary tip and the mechanisms of ciliary assembly and length regulation.

Project description:Background & Aims: The primary cilium, an organelle that protrudes from cell surfaces, is essential for sensing extracellular signals. With disturbed cellular communication and chronic liver pathologies, this organelle's dysfunctions have been linked to disorders, including polycystic liver disease (PLD) and Cholangiocarcinoma (CCA). This study aimed to clarify the interaction between primary cilia and the critical regulator of cellular proliferation known as the epidermal growth factor receptor (EGFR) signaling pathway, which has been linked to several clinical conditions. Approach & Results: The study identified abnormal EGFR signaling pathways inside cholangiocytes lacking functioning primary cilia using liver-specific IFT88 knockout mice, a Pkhd1 mutant rat model, and human cell lines with ciliary deficiencies. Cilia-deficient cholangiocytes showed persistent EGFR activation because of impaired receptor degradation, in contrast to their normal counterparts where EGFR localization to cilia promotes appropriate signaling. By using HDAC6 inhibitors to restore primary cilia, EGFR degradation was accelerated, which in turn reduced the maladaptive signaling. Importantly, EGFR was moved to cilia because of experimental intervention with the HDAC6 inhibitor tubastatin A in an orthotopic rat model, along with a reduction in the phosphorylation of ERK. In cholangiocarcinoma and polycystic liver disease cells, concurrent administration of EGFR and HDAC6 inhibitors displayed synergistic anti-proliferative effects that were related to the restoration of functioning primary cilia. Conclusion: The findings of this study shed light on defective ciliary function and robust EGFR signaling with slower receptor turnover. A potential method for treating EGFR-driven pathologies in PLD and CCA is the pharmacological restoration of primary cilia function.

Project description:Primary cilia act as antennas in cell-cell signalling and are crucial for nervous system development. We explored their role in the development of the human cerebral cortex using organoids defective for the ciliary gene INPP5E. We investigated the transcription profile of control and INPP5ED477N/D477N mutant organoids at D25.

Project description:Glioblastoma multiforme (GBM) possesses glioma stem cells (GSCs) that promote self-renewal, tumor propagation, and relapse. Understanding the mechanisms of GSCs self-renewal can offer targeted therapeutic interventions. However, insufficient knowledge of the fundamental biology of GSCs is a significant bottleneck hindering these efforts. Here, we show that patient-derived GSCs recruit an elevated level of proteins that ensure the temporal cilium disassembly, leading to suppressed ciliogenesis. Depleting the cilia disassembly complex components at the ciliary base is sufficient to induce ciliogenesis in a subset of GSCs via sequestering PDGFR-α from its original location to newly induced cilium. Importantly, restoring ciliogenesis caused GSCs to behave like healthy NPCs switching from self-renewal to differentiation. Finally, using an organoid-based glioma invasion assay and brain xenografts in mice, we establish that ciliogenesis-induced differentiation can prevent the infiltration of GSCs into the brain. Our findings illustrate a crucial role for cilium as a molecular switch in determining GSCs' fate and suggest that cilium induction is an attractive strategy to intervene in GSCs proliferation.