Project description:Ciliopathy patient variants reveal organelle-specific functions for TUBB4B in axonemal microtubules

Project description:Intracellular bacterial pathogens such as Coxiella burnetii evade their host's immune response by secreting effector proteins that bind and modify host proteins, thereby reshaping cell signaling pathways that help establish a replication-friendly niche. Previous research has identified Filamentation induced by cyclic AMP (Fic) enzymes as effector proteins in bacterial infections that modify their target proteins via the post-translational modification AMPylation. Fic enzymes use adenosine triphosphate (ATP) as co-substrate to transfer the adenosine monophosphate (AMP) group to a hydroxyl-containing side chain of their target protein. Many representatives of this enzyme class contain an autoinhibitory helix that suppresses AMPylation activity in vitro by contacting the active site. The mechanisms reversing this inhibition are incompletely understood. Extensive studies of the only human Fic protein FICD have revealed that FICD can switch between AMPylation and the reversal of this modification, deAMPylation, by a monomer-dimer transition. However, so far FICD remained the only example where deAMPylation by dimerization could be shown. Here we identify the protein product of C. burnetii CBU_0822, termed C. burnetii Fic 2 (CbFic2), to AMPylate host cell histone H3 at S10 and S28. We show that CbFic2 is a bifunctional enzyme, both capable of AMPylation as well as deAMPylation, and is regulated by the binding of DNA via its C-terminal helix-turn-helix domain. We propose that CbFic2 is capable of AMPylation in its monomeric form, and that binding to DNA induces a deAMPylating dimer.

Project description:Study of Trypanosoma ZMYND12’s ortholog (TbTAX-1) confirmed an axonemal localization of the protein and knockdown of TbTAX-1 using RNAi induced dramatic flagellar motility defects as observed in human. Co-immunoprecipitation assays and ultra-structure expansion microscopy in Trypanosoma brucei then formally demonstrated that ZMYND12 and TTC29 directly interact and belong to the same axonemal complex. Subsequent comparative proteomics analysis in Trypanosoma and Ttc29 KO mice models also identified DNAH1 as a new interacting protein of both ZMYND12 and TTC29 proteins. These data evidenced the critical role of ZMYND12 for flagellum function and assembly in humans and Trypanosoma through its interaction with other axonemal partners such as TTC29 and DNAH1 in the same complex.

Project description:To recruit phagocytes, apoptotic cells characteristically release ATP, which functions as a “danger” signal. Here, we found that the culture supernatant of apoptotic cells activated the macrophages to express anti-inflammatory genes such as NR4A and Thbs1. A high level of AMP accumulated in the apoptotic cell supernatant in a Pannexin1-dependent manner. A nucleotidase inhibitor and A2a adenosine receptor antagonist inhibited the apoptotic supernatant-induced gene expression, suggesting AMP was metabolized to adenosine by an ecto-5’-nucleotidase expressed on macrophages, to activate the macrophage A2a adenosine receptor. Intraperitoneal injection of zymosan into AdoR A2a- or Panx1-deficient mice produced high, sustained levels of inflammatory mediators in the peritoneal lavage. These results indicated that AMP from apoptotic cells suppresses inflammation as a “calm down” signal. If apoptotic cells produce “danger” or “anti-danger” signal(s), we rationalized that such signals would activate gene expression in macrophages. To investigate this possibility, we examined the effect of the culture supernatant from apoptotic cells on macrophage gene expression by using microarrays.

Project description:Adenine nucleotides represent crucial immunomodulators in the extracellular environment. The ectonucleotidases CD39 and CD73 are responsible for the sequential catabolism of ATP to adenosine via AMP, thereby promoting an anti-inflammatory milieu induced by the “adenosine halo”. AMPD2 intracellularly mediates AMP deamination to IMP, thus constituting an ambiguous mediator both enhancing the degradation of inflammatory ATP and reducing the formation of protective adenosine. Here, we show that this enzyme is expressed on the cell surface of human immune cells and its predominance may[BF1] modify inflammatory states by altering the extracellular milieu. Surface AMPD2 (eAMPD2) expression on monocytes was verified by immunoblot, mass spectrometry, surface biotinylation, and immunofluorescence microscopy. Flow cytometry revealed enhanced monocytic eAMPD2 expression after TLR stimulation. PBMCs from patients with rheumatoid arthritis displayed significantly higher levels of eAMPD2 expression compared to healthy controls. Furthermore, we observed that extracellular adenosine production was not impaired by an enhanced eAMPD2 expression, while IMP exerted anti-inflammatory effects. In summary, our study identifies eAMPD2 as a novel regulator of the extracellular ATP-adenosine balance adding to the immunomodulatory CD39-CD73 system.

Project description:We performed proteomics analysis to discover effector proteins for the post-transcriptional regulation of PD-L1 onhuman macrophages stimulated by adenosine signal.

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: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.