Basal body positioning and anchoring in the multiciliated cell Paramecium tetraurelia: roles of OFD1 and VFL3

Additional file 4: Figure S4. Decrease of the GFP signal in GFP-OFD1 transformants after OFD1 depletion. The efficiency of the OFD1 RNAi vector to inactivate the corresponding gene was evaluated by following the fluorescence in GFP-OFD1 expressing cells upon inactivation. The cell is representative of n>25. Projections of confocal sections passing through the dorsal surface of transformant expressing GFP-OFD1 after divisions upon inactivation (A) with the control vector or (B) with the vector specific of OFD1. Red: basal bodies labelled with 1D5; green: GFP-OFD1. After divisions parental basal bodies and new basal bodies assembled during the inactivation are mixed within the rows. In the control cell (A), GFP-OFD1 localizes at all basal bodies (arrows in the insets point corresponding basal bodies) indicating that the tagged protein is continuously expressed. Upon inactivation with the OFD1 specific vector (B), only a fraction of basal bodies are associated with the GFP labelling. These basal bodies correspond to those present at the cell surface before the RNAi, as demonstrated by their regular alignment into antero-posterior rows. By contrast new basal bodies, assembled in erratic localisations, are not associated with GFP-labelling (arrows in B). This correlation between the mislocalisation, specific for OFD1 depletion, and the absence of labelling indicates that the expression of the GFP-OFD1 is affected (Arrowheads in the inset)

The maintenance of centriole appendages and motile cilia basal body anchoring relies on TBCCD1

Centrosomes are organelles consisting of two structurally and functionally distinct centrioles, with the mother centriole having complex distal (DA) and subdistal appendages (SDA). Despite their importance, how appendages are assembled and maintained remains unclear. This study investigated human TBCCD1, a centrosomal protein essential for centrosome positioning, to uncover its localization and role at centrioles. We found that TBCCD1 localizes at both proximal and distal regions of the two centrioles, forming a complex structure spanning from SDA to DA and extending inside and outside the centriole lumen. TBCCD1 depletion caused centrosome mispositioning, which was partially rescued by taxol, and the loss of microtubules (MTs) anchored to centrosomes. TBCCD1 depletion also reduced levels of SDA proteins involved in MT anchoring such as Centriolin/CEP110, Ninein, and CEP170. Additionally, TBCCD1 was essential for the correct positioning of motile cilia basal bodies and associated structures in Paramecium. This study reveals that TBCCD1 is an evolutionarily conserved protein essential for centriole and basal body localization and appendage assembly and maintenance. A BioID screening also linked TBCCD1 to ciliopathy-associated protein networks.info:eu-repo/semantics/publishedVersio

Cildb: a knowledgebase for centrosomes and cilia

Ciliopathies, pleiotropic diseases provoked by defects in the structure or function of cilia or flagella, reflect the multiple roles of cilia during development, in stem cells, in somatic organs and germ cells. High throughput studies have revealed several hundred proteins that are involved in the composition, function or biogenesis of cilia. The corresponding genes are potential candidates for orphan ciliopathies. To study ciliary genes, model organisms are used in which particular questions on motility, sensory or developmental functions can be approached by genetics. In the course of high throughput studies of cilia in Paramecium tetraurelia, we were confronted with the problem of comparing our results with those obtained in other model organisms. We therefore developed a novel knowledgebase, Cildb, that integrates ciliary data from heterogeneous sources. Cildb links orthology relationships among 18 species to high throughput ciliary studies, and to OMIM data on human hereditary diseases. The web interface of Cildb comprises three tools, BioMart for complex queries, BLAST for sequence homology searches and GBrowse for browsing the human genome in relation to OMIM information for human diseases. Cildb can be used for interspecies comparisons, building candidate ciliary proteomes in any species, or identifying candidate ciliopathy genes

C11orf70 Mutations Disrupting the Intraflagellar Transport-Dependent Assembly of Multiple Axonemal Dyneins Cause Primary Ciliary Dyskinesia

Primary ciliary dyskinesia (PCD) is a genetically and phenotypically heterogeneous disorder characterized by destructive respiratory disease and laterality abnormalities due to randomized left-right body asymmetry. PCD is mostly caused by mutations affecting the core axoneme structure of motile cilia that is essential for movement. Genes that cause PCD when mutated include a group that encode proteins essential for the assembly of the ciliary dynein motors and the active transport process that delivers them from their cytoplasmic assembly site into the axoneme. We screened a cohort of affected individuals for disease-causing mutations using a targeted next generation sequencing panel and identified two unrelated families (three affected children) with mutations in the uncharacterized C11orf70 gene (official gene name CFAP300). The affected children share a consistent PCD phenotype from early life with laterality defects and immotile respiratory cilia displaying combined loss of inner and outer dynein arms (IDA+ODA). Phylogenetic analysis shows C11orf70 is highly conserved, distributed across species similarly to proteins involved in the intraflagellar transport (IFT)-dependant assembly of axonemal dyneins. Paramecium C11orf70 RNAi knockdown led to combined loss of ciliary IDA+ODA with reduced cilia beating and swim velocity. Tagged C11orf70 in Paramecium and Chlamydomonas localizes mainly in the cytoplasm with a small amount in the ciliary component. IFT139/TTC21B (IFT-A protein) and FLA10 (IFT kinesin) depletion experiments show that its transport within cilia is IFT dependent. During ciliogenesis, C11orf70 accumulates at the ciliary tips in a similar distribution to the IFT-B protein IFT46. In summary, C11orf70 is essential for assembly of dynein arms and C11orf70 mutations cause defective cilia motility and PCD

Mutations in Outer Dynein Arm Heavy Chain DNAH9 Cause Motile Cilia Defects and Situs Inversus

International audienceMotile cilia move body fluids and gametes and the beating of cilia lining the airway epithelial surfaces ensures that they are kept clear and protected from inhaled pathogens and consequent respiratory infections. Dynein motor proteins provide mechanical force for cilia beating. Dynein mutations are a common cause of primary ciliary dyskinesia (PCD), an inherited condition characterized by deficient mucociliary clearance and chronic respiratory disease coupled with laterality disturbances and subfertility. Using next-generation sequencing, we detected mutations in the ciliary outer dynein arm (ODA) heavy chain gene DNAH9 in individuals from PCD clinics with situs inversus and in one case male infertility. DNAH9 and its partner heavy chain DNAH5 localize to type 2 ODAs of the distal cilium and in DNAH9-mutated nasal respiratory epithelial cilia we found a loss of DNAH9/DNAH5-containing type 2 ODAs that was restricted to the distal cilia region. This confers a reduced beating frequency with a subtle beating pattern defect affecting the motility of the distal cilia portion. 3D electron tomography ultrastructural studies confirmed regional loss of ODAs from the distal cilium, manifesting as either loss of whole ODA or partial loss of ODA volume. Paramecium DNAH9 knockdown confirms an evolutionarily conserved function for DNAH9 in cilia motility and ODA stability. We find that DNAH9 is widely expressed in the airways, despite DNAH9 mutations appearing to confer symptoms restricted to the upper respiratory tract. In summary, DNAH9 mutations reduce cilia function but some respiratory mucociliary clearance potential may be retained, widening the PCD disease spectrum

Étude de la fonction de la protéine Bug22p dans différents organismes

Les cils sont des organites très conservés au cours de l évolution des eucaryotes et présents à la surface de presque tous les types cellulaires. Ils sont constitués d une structure microtubulaire, l axonème, entourée d une membrane en continuité avec la membrane plasmique. Ils sont nucléés par un corps basal, centriole ancré à la surface cellulaire. Grâce aux nombreux récepteurs qu ils concentrent à leur membrane, tous les cils sont des senseurs de leur environnement. Ils peuvent aussi être motiles et assurer, par leur battement coordonné, le déplacement relatif de la cellule et du fluide environnant. Tandis que cil et structure centriolaire, hérités du premier eucaryote, ont été perdus par certains champignons et par les plantes supérieures, certains gènes codant des protéines ciliaires et centriolaires sont pourtant retrouvés dans le génome de ces espèces. Cette conservation de protéines sans l organite suggère soit que ces protéines interviennent dans un même processus moléculaire utilisé dans plusieurs organites, soit qu elles jouent des rôles dans des processus moléculaires distincts via leur interaction avec différents types de partenaires.J ai choisi d étudier l une de ces protéines ciliaires et centriolaires, Bug22p, hautement conservée en séquence protéique entre l'homme et la paramécie, mais également présente chez les plantes supérieures. J ai mené cette étude principalement sur la paramécie, système modèle pour la biogénèse des corps basaux et des cils, mais aussi sur des cellules de mammifère et de végétaux supérieurs. Si Bug22p est impliquée dans la détermination du battement ciliaire chez la paramécie, elle se localise également dans des cils immotiles de cellules de mammifère suggérant que son activité ciliaire n est pas réduite à cette seule fonction. Des expériences d inactivation génique suggèrent par ailleurs un lien entre l activité de Bug22p et la polyglycylation. Sa surexpression dans les cellules de mammifère en culture entraîne l apparition d extensions cellulaires et une augmentation des réseaux de tubulines acétylées probablement associées à une stabilisation des microtubules. L'ensemble de mes résultats suggère donc un rôle de Bug22p dans la régulation de modifications post-traductionnelles. En plus d être présente dans les structures ciliaires, Bug22p se localise aussi bien dans les noyaux de la paramécie que dans ceux des cellules humaines et des plantes supérieures Arabidopsis et Nicotiana. Ces observations ouvrent un nouveau champ d études. En effet, si l on sait que les tubulines ciliaires sont soumises à différentes modifications post-traductionnelles telles que polyglycylation ou acétylation, ce type de modifications touchent également des protéines nucléaires régulant ainsi le trafic de protéines nucléaires ou l expression génique. Nous pouvons donc avancer l hypothèse selon laquelle Bug22p agirait sur la régulation de ces modifications dans le cil et dans le noyau. Il serait donc intéressant de caractériser les modifications post-traductionnelles chez les plantes supérieures afin de vérifier une possible implication de Bug22p dans leur régulation et donc comprendre les raisons de sa conservation chez les végétaux.Cilia, organelles that have been conserved throughout the evolution of eukaryotes, are found at the surface of most cell types. They are composed of a microtubular structure, the axoneme, surrounded by a membrane continuous to the plasma membrane. Cilia are nucleated by basal body, which is a centriole anchored to the cell surface. Cilia are environmental sensors concentrated in the ciliary membrane. Cilia can be motile and ensure the relative movement of the cell with respect to the surrounding fluid by their coordinated beating. While cilia and centriolar structures inherited from the first eukaryote have been lost by certain fungi and higher plants, certain genes encoding ciliary and centriolar proteins are found in the genomes of organisms lacking these structures. The conservation of these proteins without organelle suggests that these proteins are involved in the same molecular process into different organelles or proteins are involved into different processes through some interactions with different partners.I chose to study the ciliary and centriolar protein, Bug22p, highly conserved between human and Paramecium proteins sequences, and also present in higher plants. My work addressed this study primarily on Paramecium, a model system for biogenesis of basal bodies and cilia, and I also pursued investigation of mammalian cells and higher plants. I was able to show that Bug22p is necessary for efficient Paramecium ciliary beating, but I also localized in the immotile cilia of mammalian cells suggesting that Bug22p is not only restricted to the motile ciliary function. By knockdown experiments in Paramecium, I obtained evidence that Bug22p is involved in polyglycylation. Bug22p overexpression in mammalian cells led to the appearance of cell extensions and increased acetylated tubulin networks consistent with microtubule stabilization. My results suggest that Bug22p may regulate post-translational proteins modifications.Bug22p is also localized in the nuclei of Paramecium, human and higher plants such as Arabidopsis and Nicotiana. These observations open a new field of study. The axoneme microtubules are highly modified by post-translational modifications such as acetylation and polyglycylation; we know that in the nucleus, theses modifications are involved in the control of nuclear trafficking of some proteins and the regulation of gene expression. We can therefore speculate that Bug22p acts on the regulation of these changes in the cilium and in the nucleus. Finally, it would be interesting to characterize the post-translational modifications in higher plants to verify the possible involvement of Bug22p in their regulation and thus understand the meaning of its conservation in higher plants lacking cilia.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Etude des centrines et des protéines de type SFI1p dans le réseau infraciliaire de paramécie

ORSAY-PARIS 11-BU Sciences (914712101) / SudocSudocFranceF

Nd6p, a Novel Protein with RCC1-Like Domains Involved in Exocytosis in Paramecium tetraurelia

In Paramecium tetraurelia, the regulated secretory pathway of dense core granules called trichocysts can be altered by mutation and genetically studied. Seventeen nondischarge (ND) genes controlling exocytosis have already been identified by a genetic approach. The site of action of the studied mutations is one of the three compartments, the cytosol, trichocyst, or plasma membrane. The only ND genes cloned to date correspond to mutants affected in the cytosol or in the trichocyst compartment. In this work, we investigated a representative of the third compartment, the plasma membrane, by cloning the ND6 gene. This gene encodes a 1,925-amino-acid protein containing two domains homologous to the regulator of chromosome condensation 1 (RCC1). In parallel, 10 new alleles of the ND6 gene were isolated. Nine of the 12 available mutations mapped in the RCC1-like domains, showing their importance for the Nd6 protein (Nd6p) function. The RCC1 protein is well known for its guanine exchange factor activity towards the small GTPase Ran but also for its involvement in membrane fusion during nuclear envelope assembly. Other proteins with RCC1-like domains are also involved in intracellular membrane fusion, but none has been described yet as involved in exocytosis. The case of Nd6p is thus the first report of such a protein with a documented role in exocytosis