Project description:Defects in cilia genes that is critical in cilia formation and function can cause complicated ciliopathy syndromes involving multiple organs and tissues; however, the underlying regulatory mechanisms of cilia gene networks in ciliopathy are largely unknown. Here, we define the genome-wide redistribution of chromatin accessibilities and extensive divergence of cilia genes expression programs happened in ciliopathy. Mechanistically, the distinct ciliopathy-activated accessible regions (CAAs) are characterized to positively regulate robust changes of flanking cilia genes, which are a key transcriptional feature of cilia required for the response to developmental signals. Moreover, the single transcriptional factors, ETS1, can be recruited to CAAs thus prominently reconstructing chromatin accessibility in ciliopathy. CAAs collapse driven by ETS1 suppression subsequently cause defective cilia formation and impaired developmental signal transduction, which eventually develops ciliopathy phenotypes of short fins and pericardium edema in larval fishes. Therefore, our results depicted a dynamic landscape of chromatin accessibility in ciliopathy, and uncover an insightful role of ETS1 in controlling global cilia genes transcriptional program by reprogramming widespread chromatin state.

Project description:Defects in cilia genes that is critical in cilia formation and function can cause complicated ciliopathy syndromes involving multiple organs and tissues; however, the underlying regulatory mechanisms of cilia gene networks in ciliopathy are largely unknown. Here, we define the genome-wide redistribution of chromatin accessibilities and extensive divergence of cilia genes expression programs happened in ciliopathy. Mechanistically, the distinct ciliopathy-activated accessible regions (CAAs) are characterized to positively regulate robust changes of flanking cilia genes, which are a key transcriptional feature of cilia required for the response to developmental signals. Moreover, the single transcriptional factors, ETS1, can be recruited to CAAs thus prominently reconstructing chromatin accessibility in ciliopathy. CAAs collapse driven by ETS1 suppression subsequently cause defective cilia formation and impaired developmental signal transduction, which eventually develops ciliopathy phenotypes of short fins and pericardium edema in larval fishes. Therefore, our results depicted a dynamic landscape of chromatin accessibility in ciliopathy, and uncover an insightful role of ETS1 in controlling global cilia genes transcriptional program by reprogramming widespread chromatin state.

Project description:Defects in cilia genes that is critical in cilia formation and function can cause complicated ciliopathy syndromes involving multiple organs and tissues; however, the underlying regulatory mechanisms of cilia gene networks in ciliopathy are largely unknown. Here, we define the genome-wide redistribution of chromatin accessibilities and extensive divergence of cilia genes expression programs happened in ciliopathy. Mechanistically, the distinct ciliopathy-activated accessible regions (CAAs) are characterized to positively regulate robust changes of flanking cilia genes, which are a key transcriptional feature of cilia required for the response to developmental signals. Moreover, the single transcriptional factors, ETS1, can be recruited to CAAs thus prominently reconstructing chromatin accessibility in ciliopathy. CAAs collapse driven by ETS1 suppression subsequently cause defective cilia formation and impaired developmental signal transduction, which eventually develops ciliopathy phenotypes of short fins and pericardium edema in larval fishes. Therefore, our results depicted a dynamic landscape of chromatin accessibility in ciliopathy, and uncover an insightful role of ETS1 in controlling global cilia genes transcriptional program by reprogramming widespread chromatin state.

Project description:Ciliopathies comprise a spectrum of inherited disorders involving different organ systems such as the central nervous system, the skeleton, and the kidney1. The cilium is a hair-like organelle at the cell surface that acts as a sensor and signal transducer2. Many ciliopathy manifestations can be linked to deficient cilia function, yet it is unclear how a cilium defect results in nephronophthisis (NPHP), the most prevalent renal manifestation in children, characterized by inflammation, interstitial fibrosis, and renal cysts3. Here, we report that deletion of the serine threonine kinase Lkb1 in the mouse kidney results in cardinal features of nephronophthisis. An in-vivo proteomic interaction screen revealed ANKS3, a known interaction partner of the nephronophthisis protein NPHP1, and its interactor NEK7 as novel binding partners of LKB1. Lkb1 genetically interacts with Nphp1 in zebrafish. Unbiased transcriptional analysis in-vitro and in-vivo revealed that the chemokine CCL2 is upregulated in Lkb1 deficiency and is accompanied by recruitment of CCR2 expressing mononuclear cells in the kidney. CCL2 regulation requires NPHP1, ANKS3 and NEK7. These findings link LKB1 and ciliopathy proteins to immune regulation and explain how mutations in NPHP proteins result in fibrosis of the kidney.

Project description:Ciliopathies comprise a spectrum of inherited disorders involving different organ systems such as the central nervous system, the skeleton, and the kidney1. The cilium is a hair-like organelle at the cell surface that acts as a sensor and signal transducer2. Many ciliopathy manifestations can be linked to deficient cilia function, yet it is unclear how a cilium defect results in nephronophthisis (NPHP), the most prevalent renal manifestation in children, characterized by inflammation, interstitial fibrosis, and renal cysts3. Here, we report that deletion of the serine threonine kinase Lkb1 in the mouse kidney results in cardinal features of nephronophthisis. An in-vivo proteomic interaction screen revealed ANKS3, a known interaction partner of the nephronophthisis protein NPHP1, and its interactor NEK7 as novel binding partners of LKB1. Lkb1 genetically interacts with Nphp1 in zebrafish. Unbiased transcriptional analysis in-vitro and in-vivo revealed that the chemokine CCL2 is upregulated in Lkb1 deficiency and is accompanied by recruitment of CCR2 expressing mononuclear cells in the kidney. CCL2 regulation requires NPHP1, ANKS3 and NEK7. These findings link LKB1 and ciliopathy proteins to immune regulation and explain how mutations in NPHP proteins result in fibrosis of the kidney.

Project description:Tubulin, one of the most abundant cytoskeletal building blocks, exhibits extensive isotype diversity in humans. Displaying high similarity, whether these distinct isotypes form cell-type and context specific microtubule structures is poorly understood. Studying a cohort of 11 patients with the motile ciliopathy primary ciliary dyskinesia as well as mouse mutants, we report mutations in the TUBB4B isotype specifically perturb centriole and cilium biogenesis. We demonstrate that distinct TUBB4B mutations differentially affect microtubule dynamics and cilia formation in a dominant negative manner. Finally, structure-function studies reveal that different TUBB4B mutations disrupt distinct tubulin interfaces allowing clear stratification of patients into three classes of ciliopathic disease. These findings illustrate that specific tubulin isotypes have unique and non-redundant subcellular functions and establishes the missing link between human tubulinopathies and ciliopathies.

Project description:Oral-facial-digital syndromes (OFD) are a heterogeneous group of congenital disorders characterized by malformations of the face and oral cavity, and digit anomalies. To date, mutations in 12 ciliary-related genes have been identified to cause several OFD types suggesting OFDs constitute a subgroup of developmental ciliopathies. Through homozygosity mapping and exome sequencing performed on two families with variable OFD type 2, we identified distinct germline mutations in INTS13, a subunit of the Integrator Complex. This 14-component complex associates with RNAPII and can cleave nascent RNA to modulate gene expression. We determined that INTS13 utilizes a discrete domain within its C-terminus to bind the Integrator cleavage module, which is disrupted by the identified germline INTS13 mutations. Depletion of INTS13 disrupts ciliogenesis in human cultured cells and causes dysregulation of a broad collection of ciliary genes. Accordingly, its knockdown in Xenopus embryos lead to motile cilia anomalies. Altogether, we show that mutations in INTS13 cause an autosomal recessive ciliopathy, which reveal key interactions within Integrator components.

Project description:Mitosis segregates into each daughter cell two centrioles, the older of which is uniquely capable of generating a cilium. How this older centriole, called the mother centriole, initiates ciliogenesis remains poorly understood. We have identified an evolutionarily conserved complex comprised of CEP90, OFD1, MNR and FOPNL. Human mutations in CEP90, MNR and OFD1 cause ciliopathies. Super-resolution microscopy revealed that this complex forms a ring at the distal centriole. Centrioles of cells lacking MNR or CEP90 failed to assemble distal appendages and cannot generate cilia. In addition to the centrioles, complex members localized to centriolar satellites, proteinaceous granules surrounding the centrioles. Disruption of satellites did not affect distal appendage assembly, indicating that the centriolar pool is required for ciliogenesis. Consistent with an essential role in ciliogenesis, mice lacking MNR or CEP90 did not assemble cilia, did not survive beyond embryonic day 9.5, and did not transduce Hedgehog signals. In addition to ciliogenesis, MNR, but not CEP90, restrained centriolar length. MNR recruited both OFD1, required for centriolar length control, and CEP90, which recruits CEP83 to root distal appendages. Thus, an evolutionarily conserved ciliopathy-associated complex functions at the distal centriole to control centriole length and assemble distal appendages.

Project description:Combining proteomics, in vivo imaging and genetic analysis of proteins linked to planar cell polarity (Inturned, Fuzzy and Wdpcp), we identified and characterized a new genetic module, which we term CPLANE (ciliogenesis and planar polarity effector), and an extensive associated protein network. CPLANE proteins physically and functionally interact with the poorly understood ciliopathy-associated protein Jbts17 at basal bodies, where they act to recruit a specific subset of IFT-A proteins. In the absence of CPLANE, defective IFT-A particles enter the axoneme and IFT-B trafficking is severely perturbed. Accordingly, mutation of CPLANE genes elicits specific ciliopathy phenotypes in mouse models and is associated with ciliopathies in human patients.

Project description:Ets1 can directly bind key TFH genes, regulating their expression . Loss of Ets1 results in the pre-mature expression of TFH-genes in Non-TFH cells. We wished to analyze if loss of Ets1 correlated with changes in chromatin accessibility especially in TFH gene loci.