Paramecium, a Model to Study Ciliary Beating and Ciliogenesis: Insights From Cutting-Edge Approaches.

Cilia are ubiquitous and highly conserved extensions that endow the cell with motility and sensory functions. They were present in the first eukaryotes and conserved throughout evolution (Carvalho-Santos et al., 2011). Paramecium has around 4,000 motile cilia on its surface arranged in longitudinal rows, beating in waves to ensure movement and feeding. As with cilia in other model organisms, direction and speed of Paramecium ciliary beating is under bioelectric control of ciliary ion channels. In multiciliated cells of metazoans as well as paramecia, the cilia become physically entrained to beat in metachronal waves. This ciliated organism, Paramecium, is an attractive model for multidisciplinary approaches to dissect the location, structure and function of ciliary ion channels and other proteins involved in ciliary beating. Swimming behavior also can be a read-out of the role of cilia in sensory signal transduction. A cilium emanates from a BB, structurally equivalent to the centriole anchored at the cell surface, and elongates an axoneme composed of microtubule doublets enclosed in a ciliary membrane contiguous with the plasma membrane. The connection between the BB and the axoneme constitutes the transition zone, which serves as a diffusion barrier between the intracellular space and the cilium, defining the ciliary compartment. Human pathologies affecting cilia structure or function, are called ciliopathies, which are caused by gene mutations. For that reason, the molecular mechanisms and structural aspects of cilia assembly and function are actively studied using a variety of model systems, ranging from unicellular organisms to metazoa. In this review, we will highlight the use of Paramecium as a model to decipher ciliary beating mechanisms as well as high resolution insights into BB structure and anchoring. We will show that study of cilia in Paramecium promotes our understanding of cilia formation and function. In addition, we demonstrate that Paramecium could be a useful tool to validate candidate genes for ciliopathies.

Centrosomal association of histone macroH2A1.2 in embryonic stem cells and somatic cells.

The histone 2A variant macroH2A1.2 is expressed in female and male mammals and is implicated in X-chromosome inactivation and autosomal gene silencing. In undifferentiated and early differentiating murine embryonic stem (ES) cells a cytosolic pool of macroH2A1.2 has recently been reported and found to be associated with the centrosome. Here, we show that the centrosomal association of macroH2A1.2 is a widespread phenomenon and is not restricted to undifferentiated and early differentiating ES cells. By indirect immunofluorescence we detect macroH2A1.2 protein in a juxtanuclear structure that duplicates once per cell cycle and colocalizes with centrosomal gamma-tubulin in both XX and XY ES cells prior to and throughout their differentiation. MacroH2A1.2 localization to the centrosome is also observed in female and male somatic cells, both in interphase and in mitosis. Biochemical analysis demonstrates that the association between macroH2A1.2 and the centrosome in somatic cells is stable, as macroH2A1.2 copurifies with centrosomes isolated from human lymphoblasts. Therefore, in addition to a nuclear pool of macroH2A1.2 a fraction of the histone is associated with the centrosome in various cell types and throughout ES cell differentiation.

Centrosome structure and microtubule nucleation in animal cells.

Genetic studies in the budding yeast have led to the molecular characterization of gamma-tubulin associated proteins and to the identification of orthologues in animal cells. While the gamma-tubulin complex is more complex in animal cells than in budding yeast, its function is probably maintained throughout evolution. In this review we discuss some of the possible regulations of the nucleation activity in the light of the centrosome structure. A potential cross-talk between microtubule nucleation and centrosome duplication is suggested by some, still scarce, data.

Characterization of the human homologue of the yeast spc98p and its association with gamma-tubulin.

A trimeric complex formed by Tub4p, the budding yeast gamma-tubulin, and the two spindle pole body components, Spc98p and Spc97p, has recently been characterized in Saccharomyces cerevisiae. We reasoned that crucial functions, such as the control of microtubule nucleation, could be maintained among divergent species. SPC98-related sequences were searched in dbEST using the BLASTN program. Primers derived from the human expressed sequence tag matching SPC98 were used to clone the 5' and 3' cDNA ends by rapid amplification of cDNA ends (RACE)-PCR. The human Spc98 cDNA presents an alternative splicing at the 3' end. The deduced protein possesses 22% identity and 45% similarity with the yeast homologue. We further report that the human Spc98p, like gamma-tubulin, is concentrated at the centrosome, although a large fraction is found in cytosolic complexes. Sucrose gradient sedimentation of the cytosolic fraction and immunoprecipitation experiments demonstrate that both gamma-tubulin and HsSpc98p are in the same complex. Interestingly, Xenopus sperm centrosomes, which are incompetent for microtubule nucleation before their activation in the egg cytoplasm, were found to contain similar amounts of both Spc98p and gamma-tubulin to human somatic centrosomes, which are competent for microtubule nucleation. Finally, affinity-purified antibodies against Spc98p inhibit microtubule nucleation on isolated centrosomes, as well as in microinjected cells, suggesting that this novel protein is indeed required for the nucleation reaction.

Identification of an Spc110p-related protein in vertebrates.

Although varying in size and complexity, centrosomes have conserved functions throughout the evolutionary range of eukaryotes, and thus may display conserved components. In this work, we took advantage of the recent advances in the isolation of the budding yeast spindle pole body, the development of specific immunological probes and the molecular characterisation of genes involved in spindle pole body duplication or assembly. Screening a monoclonal antibody library against Saccharomyces cerevisiae spindle pole body components, we found that two monoclonal antibodies, directed against two different parts of the yeast Spc110p, decorate the centrosome from mammalian cells in an asymmetrical manner. Western blot experiments identified a 100 kDa protein specifically enriched in centrosome preparations from human cells. This protein is phosphorylated during mitosis and is tightly associated with the centrosome: only denaturing conditions such as 8 M urea were able to solubilise it. Purified immunoglobulins directed against Spc110p inhibit microtubule nucleation on isolated human centrosomes, using brain phosphocellulose-tubulin or Xenopus egg extract tubulin. This result suggested that the centrosomal 100 kDa protein could be involved in a microtubule nucleation complex. To test this hypothesis, we turned to Xenopus species, in which mAb anti-Spc110p decorated centrosomes from somatic cells and identified a 116 kDa protein in egg extract. We performed a partial purification of the gamma-tubulin-ring complex from egg extract. Sucrose gradient sedimentation, immunoprecipitation and native gels demonstrated that the Xenopus 116 kDa protein and gamma-tubulin were found in the same complex. Altogether, these results suggest the existence of an yeast Spc110-related protein in vertebrate centrosomes which is involved in microtubule nucleation.

A peripheral protein associated with the cis-Golgi network redistributes in the intermediate compartment upon brefeldin A treatment.

Human autoantibodies offer unique tools for the study of cellular constituents since they usually recognize highly conserved components, the most difficult to detect due to their low immunogenicity. The serum from a patient with Sjögren's syndrome (RM serum) showing a very high reactivity to the Golgi complex has been shown to immunoprecipitate and to immunodetect by Western blotting experiments a protein mol wt 210,000 (p210) that was shown to be peripheral and cytoplasmically disposed. A close examination of the p210 labeling revealed some differences with Golgi markers: RM serum staining was slightly more extensive than several Golgi markers and showed a discontinuous or granular appearance. Nocodazole induced a specific and early segregation of many p210-associated vesicles or tubules from Golgi apparatus. Upon brefeldin A treatment, p210 did not redistribute in the ER as did other Golgi proteins. In contrast, it exhibited a vesicular pattern reminiscent to that displayed by proteins residing in the intermediate compartment. Double staining immunofluorescence using the RM serum and the marker of the intermediate compartment, p58, revealed segregation of both proteins in control conditions but colocalization in BFA-treated cells. We have further demonstrated by combining different drug treatments that p210-containing elements in brefeldin A-treated cells belong indeed to the intermediate compartment. Experiments on brefeldin A recovery suggested that these p210 elements might play a role in reformation and repositioning of the Golgi apparatus. Ultrastructural localization performed by immunoperoxidase staining allowed us to establish that p210 interacted with the external side of an abundant tubulo-vesicular system on the cis side of the Golgi complex which extended to connecting structures and vesicles between saccules or stacks of cisternae, p210 appears to be a novel protein residing in the cis-Golgi network that may cycle between the Golgi apparatus and the intermediate compartment.

Secretion in yeast. Purification and in vitro translocation of chemical amounts of prepro-alpha-factor.

The Saccharomyces cerevisiae mating pheromone precursor, prepro-alpha-factor, can be translocated across yeast endoplasmic reticulum membranes post-translationally in an in vitro system. This characteristic makes prepro-alpha-factor potentially useful as a probe in the biochemical dissection of the mechanism of this basic cellular process. Efforts have been limited by the inability to isolate sufficient quantities of such secretory protein precursors in a translocation-competent form. We report here the one-step purification of chemical amounts of translocation-competent prepro-alpha-factor using nickel ion affinity chromatography on nitrilotriacetate resin. An oligonucleotide encoding 6 histidine residues was inserted into a genomic clone encoding prepro-alpha-factor 5' of the naturally occurring translational stop codon by site-directed mutagenesis. The construct was expressed at high levels in a SecY- strain of Escherichia coli. The produced preprotein was solubilized in 6 M guanidine hydrochloride and bound to nitrilotriacetate resin. Prepro-alpha-factor was recovered at a purity in excess of 95% by elution with 0.25 M imidazole, 8 M urea, which competitively displaced the histidine affinity tag from the nickel column. The chemical amounts of prepro-alpha-factor obtained in this way were determined to be competent for translocation across yeast microsomal membranes and for subsequent modifications such as signal sequence cleavage and N-linked glycosylation.

Modulation of expression and cell surface distribution of N-CAM during myogenesis in vitro.

We have studied the modulation of expression and surface distribution of the molecular forms of the neural cell adhesion molecule (N-CAM) during myogenesis in vitro. We found one minor and two major N-CAM forms-180, 145 and 125 kDa respectively in primary cultures of mouse muscle cells. The 180 and 145 kDa forms were present in myoblasts before fusion. At fusion, total N-CAM increased with no 180 kDa polypeptide, but with a new 125 kDa form, together with the 145 kDa form. We determined the localization of N-CAM on the myotube surface and compared it to that of the acetylcholine receptor. N-CAM but not the receptor was found on the myoblast surface before fusion. Both proteins were uniformly distributed on the cell surface of early myotubes. Then, bright spots appeared, rapidly followed by the formation of clusters of both the acetylcholine receptor and N-CAM, at the time contractile activity was established. However these clusters were never colocalized, except after synapse formation. N-CAM clusters, but not acetylcholine receptor clusters, were dispersed following Nocodazole-induced microtubule depolymerization. We further observed that patching of N-CAM by divalent anti-N-CAM antibodies had no effect on acetylcholine receptor clusters. These results suggest that there is no mechanochemical link between the receptor and N-CAM. In myotubes, part of the 125 kDa form was released from the cell surface by the phosphatidylinositol phospholipase C. This phosphatidylinositol anchored form was mostly present outside the clusters where the 145 kDa form seems to be concentrated. Another pool of 125 kDa was insoluble in non-ionic detergent and was extracted by 0.1% SDS only. We suggest that the SDS extracted 125 kDa N-CAM is present in basal lamina. Thus, specific N-CAM forms with different interactions with basal lamina or cytoskeleton and cell surface distribution are induced during myogenesis and may be responsible for decisive modifications of cell-cell interactions involved in myoblast fusion and synaptogenesis.

Receptor-triggered polyphosphoinositide turnover produces less cytosolic free calcium in cultured dysgenic myotubes than in normal myotubes.

Myotubes prepared from mice with muscular dysgenesis (mdg) were used to further elucidate the putative role of inositol triphosphate (InsP3) in excitation-contraction (E-C) coupling of skeletal muscle. The mdg mutation is characterized by an uncoupling of the E-C coupling. InsP3 production in normal and mdg/mdg myotube cultures and its relation to the levels of cytosolic free calcium were analyzed. Basal and ATP-stimulated levels of InsP3 were equal in normal and mdg/mdg myotube cultures. In contrast, the transient increases of cytosolic free calcium in mdg/mdg myotubes in culture were generally much lower than those in normal ones. This suggests that the defect in dysgenic myotubes does not rest on the InsP3 formation but on the InsP3-triggered transduction of excitation and/or the induction of calcium release from internal stores.

Unusual organization of desmin intermediate filaments in muscular dysgenesis and TTX-treated myotubes.

Cytoskeletal intermediate filaments were studied in muscular dysgenesis (mdg) and tetrodotoxin-treated inactive mouse embryo muscle cultures during myofibrillogenesis. Both muscular dysgenesis and tetrodotoxin-treated muscles are characterized in vitro by a total lack of contractile activity and an abnormal development of myofibrils. We studied the organization of the microtubule and intermediate filament networks with immunofluorescence, using anti-tubulin, anti-vimentin, and anti-desmin antibodies during normal and mdg/mdg myogenesis in vitro. Mdg/mdg myotubes present a heterogeneous microtubule network with scattered areas of decreased microtubule density. At the myoblast stage, cells expressed both vimentin and desmin. After fusion only desmin expression is revealed. In mutant myotubes the desmin network remains in a diffuse position and does not reorganize itself transversely, as it does during normal myogenesis. The absence of a mature organization of the desmin network in mdg/mdg myotubes is accompanied by a lack of organization of myofibrils. The role of muscle activity in the organization of myofibrils and desmin filaments was tested in two ways: (i) mdg/mdg myotubes were rendered active by coculturing with normal spinal cord cells, and (ii) normal myotubes were treated with tetrodotoxin (TTX) to suppress contractions. Mdg/mdg innervated myotubes showed cross-striated myofibrils, whereas desmin filaments remained diffuse. TTX-treated myotubes possessed disorganized myofibrils and a very unusual pattern of distribution of desmin: intensively stained desmin aggregates were superimposed upon the diffuse network. We conclude, on the basis of these results, that myofibrillar organization does not directly involve intermediate filaments but does need contractile activity.

Excitation-contraction uncoupling in the developing skeletal muscle of the muscular dysgenesis mouse embryo.

The muscular dysgenesis recessive autosomal mutation is characterized by a total lack of muscular contraction and a myofibrillar non-organization. Many abnormalities involved in the excitation-contraction coupling are found in mdg/mdg myotubes: 1) the internal structural organization of the membrane coupling between the sarcoplasmic reticulum (SR) and the transverse (T)-tubule forming the triadic association is defective: the triad number is decreased in the muscle and there are a lack of periodic densities between the SR and T-tubule apposed membranes. 2) the voltage-dependent Ca2+ channel contents, identified by binding with the specific blocker PN 200-110, are decreased. The two fast (30 ms) and slow (100 ms) Ca2+ currents present in normal myotubes are absent in mdg/mdg myotubes in vitro. 3) the Ca2+-dependent K+ conductance triggering an action potential followed by a long lasting after hyperpolarization (ahp) is absent in mdg/mdg myotubes. This indicates a lack of the free intracellular Ca2+ increased by the action potential. These results suggest that: 1) the lack of differentiated triadic junctions is directly correlated with very low amounts of voltage-dependent Ca2+ channels; 2) the low amount of Ca2+ channels results directly in decreased Ca2+ currents; 3) the decreased Ca2+ currents are the consequence of the low intracellular Ca2+ concentration which is not sufficient to trigger a contraction. However, the addition of normal motoneurones to mdg/mdg myotubes in culture induces, few days later, an increase in Ca2+ currents.

The Golgi apparatus remains associated with microtubule organizing centers during myogenesis.

In vitro myogenesis involves a dramatic reorganization of the microtubular network, characterized principally by the relocalization of microtubule nucleating sites at the surface of the nuclei in myotubes, in marked contrast with the classical pericentriolar localization observed in myoblasts (Tassin, A. M., B. Maro, and M. Bornens, 1985, J. Cell Biol., 100:35-46). Since a spatial relationship between the Golgi apparatus and the centrosome is observed in most animal cells, we have decided to follow the fate of the Golgi apparatus during myogenesis by an immunocytochemical approach, using wheat germ agglutinin and an affinity-purified anti-galactosyltransferase. We show that Golgi apparatus in myotubes displays a perinuclear distribution which is strikingly different from the polarized juxtanuclear organization observed in myoblasts. As a result, the Golgi apparatus in myotubes is situated close to the microtubule organizing center (MTOC), the cis-side being situated at a fixed distance from the nuclear envelope, a situation which suggests the existence of a structural association between the Golgi apparatus and the nuclear periphery. This is supported by experiments of microtubule depolymerization by nocodazole, in which a minimal effect was observed on Golgi apparatus localization in myotubes in contrast with the dramatic scattering observed in myoblasts. In both cell types, electron microscopy reveals that microtubule disruption generates individual dictyosomes; this suggests that the connecting structures between dictyosomes are principally affected. This structural dependency of the Golgi apparatus upon microtubules is not apparently accompanied by a reverse dependency of MTOC structure or function upon Golgi apparatus activity. Golgi apparatus modification by monensin, as effective in myotubes as in myoblasts, is without apparent effect on MTOC localization or activity and on microtubule stability. The main result of our study is to show that in a cell type where the MTOC is dissociated from centrioles and where antero-posterior polarity has disappeared, the association between the Golgi apparatus and the MTOC is maintained. The significance of such a tight association is discussed.

Biosynthesis of laminin and fibronectin by rat satellite cells during myogenesis in vitro.

The biosynthesis of fibronectin and laminin was studied in satellite cells cultured from adult rat muscles before (day 4) and after fusion and formation of myotubes (day 14) using (35S) methionine as a tracer. The kinetics of incorporation into immunoprecipitable fibronectin and laminin were recorded at intervals from 1.5 to 24 hours of incubation with the tracer from the cells, the pericellular matrix and the culture medium. The rate of synthesis of fibronectin and laminin expressed as dpm/microgram DNA were constant from the mononucleated cell to the myotube state. Both glycoproteins were detected in the cells and in the pericellular matrix. When the results were expressed as the percentage of incorporation into total protein, major changes could be observed in the early phase of the kinetic studies in the cells and the pericellular matrix. Both showed an increase from the mononucleated myoblast to myotube, suggesting that an increasing fraction of total protein biosynthesis is directed towards these two extracellular matrix glycoproteins. At the same time, there was a decrease in the secretion into the medium of freshly synthesized radiolabeled fibronectin and laminin. Our results confirm the synthesis of varying ratios of both extracellular matrix macromolecules by undifferentiated mononucleated myogenic cells as well as myotubes.

Fate of microtubule-organizing centers during myogenesis in vitro.

Microtubule organization and nucleation were studied during in vitro human myogenesis by immunocytology that used monoclonal and polyclonal antitubulin antibodies and a rabbit nonimmune serum that reacts with human centrosomes. In myoblasts, we observed a classical microtubule network centered on juxtanuclear centrosomes. Myotubes possessed numerous microtubules organized in parallel without any apparent nucleation centers. Centrosomes in these cells were not associated one to each nucleus but were often clustered in the vicinity of nuclei groups. They were significantly smaller than those of the mononucleated cells. The periphery of each nucleus in myotubes was labeled with the serum that labels centrosomes suggesting a profound reorganization of microtubule-nucleating material. Regrowth experiments after Nocodazole treatment established that microtubules were growing from the periphery of the nuclei. The redistribution of nucleating material was shown to take place early after myoblast fusion. Such a phenomenon appears to be specific to myogenic differentiation in that artificially induced polykaryons behaved differently: the centrosomes aggregated to form only one or a few giant nucleating centers and the nuclei did not participate directly in the nucleation of microtubules. The significance of these results is discussed in relation to the possible role of the centrosome in establishing cell polarity.