Molecular characterization of the major membrane skeletal protein in the ciliate Tetrahymena pyriformis suggests n-plication of an early evolutionary intermediate filament protein subdomain.

Epiplasmin C is the major protein component of the membrane skeleton in the ciliate Tetrahymena pyriformis. Cloning and analysis of the gene encoding epiplasmin C showed this protein to be a previously unrecognized protein. In particular, epiplasmin C was shown to lack the canonical features of already known epiplasmic proteins in ciliates and flagellates. By means of hydrophobic cluster analysis (HCA), it has been shown that epiplasmin C is constituted of a repeat of 25 domains of 40 residues each. These domains are related and can be grouped in two families called types I and types II. Connections between types I and types II present rules that can be evidenced in the sequence itself, thus enforcing the validity of the splitting of the domains. Using these repeated domains as queries, significant structural similarities were demonstrated with an extra six heptads shared by nuclear lamins and invertebrate cytoplasmic intermediate filament proteins and deleted in the cytoplasmic intermediate filament protein lineage at the protostome-deuterostome branching in the eukaryotic phylogenetic tree.

Use of a heterologous monoclonal antibody for cloning and detection of glial fibrillary acidic protein in the bovine ventricular ependyma.

From protozoans to vertebrates, ciliated cells are characterized by well-developed cytoskeletal structures. An outstanding example is the epiplasm, a thick, submembranous skeleton that serves to anchor basal bodies and other cell surface-related organelles in ciliated protozoans. An epiplasm-like cytoskeleton has not yet been observed in metazoan ciliated cells. In a previous study, we reported on MAb E501, a monoclonal antibody raised against epiplasmin-C, the major membrane skeletal protein in the ciliate Tetrahymena pyriformis. It was shown that MAb E501 cross-reacts with glial fibrillary acidic protein (GFAP), the class III intermediate filament protein found in astrocytes and other related glial elements. Here we used a post-embedding immunogold-staining method to localize MAb E501 cross-reactive antigens in ciliated cells from the ventricular ependyma in bovine embryos. When ependymocytes were treated with MAb E501, the ciliated region of the cell cortex was devoid of significant labeling. Instead, a gold particle deposit was evident around the nucleus, with only conventional ependymocytes being immunostained. Similar results were obtained by utilizing a rabbit antiserum against GFAP, revealing glial filaments and indicating an astroglial lineage of conventional bovine ependymocytes. In contrast, secretory ependymocytes of the subcommissural organ (SCO) were not stained by either of the two antibodies. Using MAb E501 as a heterologous probe, we cloned bovine GFAP cDNA. In situ hybridization experiments failed to detect GFAP transcripts in SCO ependymocytes, confirming the abscence of immunoreactivity in these cells.

Centrin-like filaments in the cytopharyngeal apparatus of the ciliates Nassula and Furgasonia: evidence for a relationship with microtubular structures.

The cytopharyngeal apparatus in the Nassulinid ciliates Nassula and Furgasonia is a highly specialized microtubular/filamentous organelle designed for ingestion of organisms such as filamentous bacteria. From studies on living cells, it was previously shown that this organelle, also called "feeding basket," guides the filamentous bacteria and manipulates them to some extent during the early steps of ingestion. This results in a complex sequence of movements where the basket is successively dilated and constricted in its upper part. Whereas some of these movements (dilation) seem to be intrinsic to the microtubular components of the basket, others (constriction) are believed to be mediated by contractile filamentous structures [Tucker, 1968: J. Cell Sci. 3:493-514]. In this study, we have used antibodies raised against ciliate centrins to demonstrate these proteins by Western blot and immunocytochemical methods in Nassula and Furgasonia. In both ciliates, a 20-kDa centrin immunoanalog was localized in the upper (contractile) part of the cytopharyngeal apparatus. Immunoelectron microscopy revealed that cytopharyngeal centrin is engaged in filamentous material, forming a sphincter-like structure possibly involved in the movements of contraction. Interestingly, physical links were noted between filaments labeled for centrin and cytopharyngeal microtubules. The mechanistic implications of these findings are discussed.

Calmyonemin: a 23 kDa analogue of algal centrin occurring in contractile myonemes of Eudiplodinium maggii (ciliate).

Myonemes are bundles of thin filaments (3-6 nm in diameter) which mediate calcium-induced contraction of the whole or only parts of the cell body in a number of protists. In Eudiplodinium maggii, a rumen ciliate which lacks a uniform ciliation of the cell body, myonemes converge toward the bases of apical ciliary zones that can be retracted under stress conditions, entailing immobilization of the cell. An mAB (A69) has been produced that identifies a calcium-binding protein by immunoblot, immunoprecipitation experiments and specifically labels the myonemes in immunoelectron microscopy. Solubility properties, apparent molecular weight (23 kDa) and isoelectric point (4.9) of the myonemal protein, are similar to the values reported for the calcium-modulated contractile protein centrin. Western-blot analysis indicates that the 23 kDa protein cross-reacts antigenically with anti-centrin antibodies. In addition, the 23 kDa protein displays calcium-induced changes in both electrophoretic and chromatographic behaviour, and contains calcium-binding domains that conform to the EF-hand structure, as known for centrin. Based on these observations, we conclude that a calcium-binding protein with major similarities to centrin occurs in the myonemes of E. maggii. We postulate that this protein plays an essential role in myoneme-mediated retraction of the ciliature.

Immunological characterization of trichocyst proteins in the ciliate Pseudomicrothorax dubius.

Ejectable trichocysts were isolated from the ciliate Pseudomicrothorax dubius. Polyclonal antibodies were raised against three groups of trichocyst proteins: G1 (30-31 kDa), G2 (26-27 kDa) and G3 (15-20 kDa). By indirect immunofluorescence, the three antisera strongly label the shafts of ejected trichocysts and the proximal ends of condensed trichocysts within the cells. By immunogold labeling for electron microscopy, the three sera specifically recognize the shafts of both extended and condensed trichocysts and shaft precursors in pretrichocysts as well. On one-dimensional immunoblots of isolated trichocysts, anti-G1 serum recognizes the G1 proteins, anti-G2 serum detects G2 proteins and some G1 proteins, and anti-G3 serum reacts with 15 bands, mainly the G3 and (30-41)-kDa proteins. In cells with and without trichocysts, the sera recognize non-ejectable trichocyst proteins at 41-42 kDa and 47 kDa. On two-dimensional immunoblots of isolated trichocysts, anti-G1 serum labels proteins with a pI of 4.75-5.7, anti-G2 serum labels proteins with a pI of 4.75-6.25 and anti-G3 serum labels proteins with a pI of 4.7-6.6. Analyses of cells with and without trichocysts allow identification of possible precursors between 41 and 47 kDa. Some are in the same pI range as their putative products, but others, labeled by anti-G3 serum, are less acidic than most of their mature products.

A human centrosomal protein is immunologically related to basal body-associated proteins from lower eucaryotes and is involved in the nucleation of microtubules.

Isolation of centrosomes from human cells has revealed a proteic pattern which is both complex and specific. As the most prominent structural element of centrosomes in animal cells, the centriole which is present as two copies, is a highly conserved structure, we have attempted to identify centrosomal proteins on the basis of immunocross-reaction with proteins identified in basal bodies from lower eucaryotes. We report that two antibodies, one raised against the Ca(+)-binding protein centrin (Salisbury, J. L., A. T. Baron, B. Surek, and M. Melkonian. 1984. J. Cell Biol. 99:962-970) and the other directed against a 230-kD protein isolated from the infraciliary cytoskeletal lattice of the protozoan Polyplastron m., decorate the centrosome of human cultured cells, and identify one of the major centrosomal components revealed as a doublet of 62/64 kD. Moreover the nucleation reaction of microtubules, which can be efficiently produced on isolated centrosomes, is blocked by the antibodies, a result which strongly implicates the 62/64-kD protein in this centrosomal activity. We also show that the 62/64-kD protein remains insoluble in conditions (0.5 M KI or 8 M urea) which are capable of extracting most of the centrosomal proteins. Immunocytochemical localization by EM of isolated centrosomes revealed the association of this 62/64-kD doublet with the intercentriolar link and the pericentriolar lattice. Our results suggest that conservation of structure in the centrosome from divergent organisms could be matched by conservation of proteins and activity, evidence for the maintenance of a specific function, which could involve Ca2+, associated with the microtubule organizing centers.

Proteins of the plasma membrane skeleton in entodiniomorphid ciliates: An immunological study using monoclonal antibodies.

We have previously reported biochemical evidence suggesting that a 58 Kd protein (p 58) is a major constituent of the membrane skeleton of the ciliated protozoan Entodinium bursa. In this study, monoclonal antibodies were produced in order to determine the distribution of p 58 in the four entodiniomorphids Entodinium bursa, Eudiplodinium maggii, Epidinium caudatum and Polyplastron multivesiculatum. Two clones, 78-116-4 and 76-12-7, were selected from a set of hybridomas obtained using either p 58 or whole proteins from cytoskeletal preparations of Eudiplodinium maggii as immunogens. Specificity tests by Western blot analysis indicate that MABs 78-116-4 and 76-12-7 both recognize p 58 in Entodinium bursa and protein ranging from 59 to 62 Kd in the three other species examined. Immunocytochemical evidence is presented which confirms that 78-116-4 and 76-12-7 antigens are located in the membrane skeleton. This suggests that the latter may represent homologous proteins implicated in the maintenance of a consistent pattern of cortical organization in the entodiniomorphid ciliates.

Expression of a ciliate gene in Escherichia coli using a suppressor tRNA to read the UAA and UAG glutamine codons.

Most ciliates use a particular genetic code where the standard stop codons UAA and UAG encode glutamine. Ciliate genes cannot therefore be expressed in heterologous systems such as Escherichia coli. To overcome this problem, we worked out a system of inducible suppression to permit efficient readthrough of UAAs and UAGs: a strong UAA tRNA suppressor that inserts glutamic acid was cloned downstream from a tac promoter whose efficiency was reduced by a transcription terminator. This system proved to be operational (1) to suppress UAG mutations by wobble pairing in an E. coli lacI-lacZ gene fusion and (2) to read through at least eight UAA glutamine codons in a Paramecium alpha-tubulin gene, as detected by Western blotting and colony hybridization. This work opens the way for cloning Ciliate genes from expression libraries and for expressing particular sequences without extended in vitro mutagenesis. A similar approach can be envisaged for expression of genes from Mycoplasma, mitochondria or other genomes that use non-standard genetic codes.

Evidence for common epitopes among proteins of the membrane skeleton of a ciliate, an euglenoid and a dinoflagellate.

The cytoskeleton of many protists comprises an extensive submembranous epiplasm which contributes to cell shape and integration of cell membranes with underlying structures according to the species-specific cortical architecture. Using various extraction procedures, epiplasm-enriched fractions have been isolated from the ciliate Pseudomicrothorax dubius, the euglenoid Euglena acus and the dinoflagellate Noctiluca scintillans. Comparative gel electrophoretic analysis of such preparations reveals heterogeneity of protein composition, the major polypeptides differing in size. Antibodies raised against epiplasmic proteins from these three organisms have permitted the confirmation of submembranous localization of the antigens by immunoelectron microscopy. Heterologous reactions performed by means of combined immunocytochemical and immunoblotting procedures indicate the existence of common epitopes among major proteins making up the bulk of the epiplasm of the three species examined. These findings suggest that proteins of the epiplasm have significantly diverged during evolution while conserving structural domains essential for their cytoskeletal function. It is postulated that these common domains may underly the ability of epiplasmic proteins to assemble into an ordered spatial organization, typical of the highly differentiated cortex of unicellular micro-organisms.

Evidence for a Ca2+-binding protein associated to non-actin microfilamentous systems in two ciliated protozoans.

Electrophoretic distributions of proteins of isolated cortical cytoskeletons from two ciliated protozoans (Isotricha, Polyplastron) were compared in order to reveal any components common to non-actin microfilamentous structures. A low molecular weight protein (Mr approximately 22 kD) characterized by Ca2+-induced shifts in mobility on SDS-polyacrylamide gels was identified in both ciliates. Two-dimensional electrophoretic coordinates and peptide maps of Ca2+-binding proteins from Isotricha and Polyplastron are fairly similar, suggesting conservation of the same molecular species. In addition, an antiserum raised against two proteins (22-23 KD) from the filamentous ecto-endoplasmic boundary of Isotricha, one of which corresponds to the Ca2+-binding protein, cross-reacts specifically with that of Polyplastron. Using an immunogold staining procedure, the Ca2+-binding protein of Polyplastron was shown also to be located in a cortical microfilamentous layer. This protein is probably different from calmodulin. We postulate that it is involved in the control of the ordering of non-actin microfilaments within the cortex of ciliates.

Biochemical and immunological characterization of the microfibrillar ecto-endoplasmic boundary in the ciliate Isotricha prostoma.

The cytoplasm of the ciliated protozoan Isotricha prostoma is compartmented by a continuous fibrillar system made up of a double layer of 4 nm-diameter filaments: the microfibrillar ecto-endoplasmic boundary (EEB). Isolation of this structure after treatment of the cells in a buffer of low ionic strength in the presence of the detergent Triton X-100 evidenced connections linking the two filamentous layers. One dimensional electrophoresis on SDS-polyacrylamide gel of EEB fractions revealed several major proteins with apparent molecular weights between 11 and 23 K. Of these, two neighboring bands of MW22 and 23 K were removed from gels and used as antigens to obtain rabbit antibodies. The antiserum obtained reacted specifically with injected proteins as shown by the technique of immunological detection on nitrocellulose sheets using the peroxidase reaction product. Electron microscopy localization of the antigens with anti-IgG coupled with colloidal gold showed significant labeling of the EEB within the cortex of Isotricha permeabilized with Triton X-100. We hope that the 22-23 K antiserum will prove to be a useful tool for the comparative study of other non-actin filament systems in Protozoa.