Cold-sensitive Ca2+ Influx in Paramecium

The concentration of intracellular calcium, [Ca²⁺] _i , in Paramecium was imaged during cold-sensitive response by monitoring fluorescence of two calcium-sensitive dyes, Fluo-3 and Fura-Red. Cooling of a deciliated Paramecium caused a transient increase in [Ca²⁺] _i at the anterior region of the cell. Increase in [Ca²⁺] _i was not observed at any region in Ca²⁺-free solution. Under the electrophysiological recording, a transient depolarization of the cell was observed in response to cooling. On the voltage-clamped cell, cooling induced a transient inward current under conditions where K⁺ currents were suppressed. These membrane depolarizations and inward currents in response to cooling were lost upon removing extracellular Ca²⁺. The cold-induced inward current was lost upon replacing extracellular Ca²⁺ with equimolar concentration of Co²⁺, Mg²⁺ or Mn²⁺, but it was not affected significantly by replacing with equimolar concentration of Ba²⁺ or Sr²⁺. These results indicate that Paramecium cells have Ca²⁺ channels that are permeable to Ca²⁺, Ba²⁺ and Sr²⁺ in the anterior soma membrane and the channels are opened by cooling. Received: 1 April 1996/Revised: 23 July 1996     

In vivo Paramecium mutants show that calmodulin orchestrates membrane responses to stimuli.

Paramecium generates a Ca2+ action potential and can be considered a one-cell animal. Rises in internal [Ca2+] open membrane channels that specifically pass K+, or Na+. Mutational and patch-clamp studies showed that these channels, like enzymes, are activated by Ca(2+)-calmodulin. Viable CaM mutants of Paramecium have altered transmembrane currents and easily recognizable eccentricities in their swimming behavior, i.e. in their responses to ionic, chemical, heat, or touch stimuli. Their CaMs have amino-acid substitutions in either C- or N-terminal lobes but not the central helix. Surprisingly, these mutations naturally fall into two classes: C-lobe mutants (S101F, I136T, M145V) have little or no Ca(2+)-dependent K+ currents and thus over-react to stimuli. N-lobe mutants (E54K, G40E+D50N, V35I+D50N) have little or no Ca(2+)-dependent Na+ current and thus under-react to certain stimuli. Each mutation also has pleiotropic effects on other ion currents. These results suggest a bipartite separation of CaM functions, a separation consistent with the recent studies of Ca(2+)-ATPase by Kosk-Kosicka et al. [41, 55]. It appears that a major function of Ca(2+)-calmodulin in vivo is to orchestrate enzymes and channels, at or near the plasma membrane. The orchestrated actions of these effectors are not for vegetative growth at steady state but for transient responses to stimuli epitomized by those of electrically excitable cells.     

Sodium uptake and membrane excitation in Paramecium

Although the phenotypes of many membrane-excitation mutants of Paramecium are best expressed in Na+-containing solutions, little is known about the role of Na+ in membrane excitation in Paramecium. By measuring 22Na fluxes, we have shown that: (a) The total cellular Na+ content is equivalent to a cytoplasmic concentration of 3--4 mM, if the Na+ concentration is uniform throughout the cell. (b) The kinetics of Na+ uptake can be divided into a saturable Na+ uptake with an apparent Km = 0.15 mM and a nonsaturable Na+ uptake seen at higher Na+ concentrations up to 20 mM. (c) The rate of Na+ uptake in high Na+ solutions is correlated with the duration of backward swimming and membrane excitation in wild type Paramecium and the mutants fast-2 and paranoiac. (d) Na+ uptake is inhibited at 4 degrees C. From these results, we postulate that Na+ uptake is faster when the membrane is depolarized than when it is at the resting potential level.     

Antibodies to the ciliary membrane of Paramecium tetraurelia alter membrane excitability

Immobilization of Paramecium followed the binding of antibodies to the major proteins of the ciliary membrane (the immobilization antigens, i- antigens, approximately 250,000 mol wt). Immunoelectron microscopy showed this binding to be serotype-specific and to occur over the entire cell surface. Antibody binding also reduced the current through the Ca-channel of the excitable ciliary membrane as monitored using a voltage-clamp. The residual Ca-current appeared normal in its voltage sensitivity and kinetics. As a secondary consequence of antibody binding, the Ca-induced K-current was also reduced. The resting membrane characteristics and other activatable currents, however, were not significantly altered by the antibody treatment. Since monovalent fragments of the antibodies also reduced the current but did not immobilize the cell, the electrophysiological effects were not the secondary consequences of immobilization. Antibodies against the second most abundant family of proteins (42,000-45,000 mol wt) had similar electrophysiological effects as revealed by experiments in which the Paramecia and the serum were heterologous with respect to the i-antigen but homologous with respect to the 42,000-45,000-mol-wt proteins. Protease treatment, shown to remove the surface antigen, also caused a reduction of the Ca-inward current. The loss of the inward Ca-current does not seem to be due to a drop in the driving force for Ca++ entry since increasing the external Ca++ or reducing the internal Ca++ (through EGTA injection) did not restore the current. Here we discuss the possibilities that (a) the major proteins define the functional environment of the Ca-channel and that (b) the Ca-channel is more susceptible to certain general changes in the membrane.     

Mating-reactive membrane vesicles from cilia of Paramecium caudatum

Membrane vesicles with a high mating reactivity were obtained from cilia of Paramecium caudatum by treatment with a solution containing 2 M urea and 0.1 mM Na2-EDTA. All processes of conjugation were induced in cells of the complementary mating type by approximately 10 mug/ml proteins of the vesicles. Electron microscope observation showed that the membrane vesicles have a diameter of 100-150 nm. Electrophoretic analysis on SDS polyacrylamide gel revealed no significant difference in polypeptide patterns of the particles from the two complementary mating types.     

Cold-sensitive Mutants of Neurospora crassa

Cold-sensitive mutants of the eucaryote Neurospora crassa have been isolated by a modification of the filtration-enrichment technique of Catcheside. The mutants include osmotic remedial, auxotrophic, transport, and incorporation deficient isolates.     

Characteristics of the digestive vacuole membrane of the alga-bearing ciliate Paramecium bursaria

Cells of the ciliate Paramecium bursaria harbor symbiotic Chlorella spp. in their cytoplasm. To establish endosymbiosis with alga-free P. bursaria, symbiotic algae must leave the digestive vacuole (DV) to appear in the cytoplasm by budding of the DV membrane. This budding was induced not only by intact algae but also by boiled or fixed algae. However, this budding was not induced when food bacteria or India ink were ingested into the DVs. These results raise the possibility that P. bursaria can recognize sizes of the contents in the DVs. To elucidate this possibility, microbeads with various diameters were mixed with alga-free P. bursaria and traced their fate. Microbeads with 0.20μm diameter did not induce budding of the DVs. Microbeads with 0.80μm diameter produced DVs of 5-10μm diameter at 3min after mixing; then the DVs fragmented and became vacuoles of 2-5μm diameter until 3h after mixing. Each microbead with a diameter larger than 3.00μm induced budding similarly to symbiotic Chlorella. These observations reveal that induction of DV budding depends on the size of the contents in the DVs. Dynasore, a dynamin inhibitor, greatly inhibited DV budding, suggesting that dynamin might be involved in DV budding.     

Cationic inhibition of Ca current and Ca-dependent ciliary responses in Paramecium

The Paramecium cell membrane was voltage-clamped under K current suppression conditions. Ciliary beating was registered using high-speed video microscopy. Depolarizing step pulses activated a transient inward current and induced reversed ciliary beating. Very strong positive steps inhibited ciliary reversal during the pulse suggesting inhibition of the Ca influx. We call the potential, which is sufficiently positive to induce transition from reversed to normal ciliary beating, the transition potential. The transition potential rose with increasing external Ca²⁺ showing saturation beyond 1 mM Ca²⁺. Addition of Mg²⁺, Ba²⁺ or K⁺ to the 1 mM Ca²⁺ bathing solution depressed the transition potential in a concentration-dependent manner. The depolarization-activated inward Ca current increased with rising external Ca concentration, and addition of either Mg²⁺, Ba²⁺ or K²⁺ diminished the inward Ca current. The diverging results of Ca²⁺-dependent positive shifts, and Mg²⁺-(Ba²⁺-, K⁺-) dependent negative shifts in transition potential are compared with shifts of V_Imax. It is concluded that external cations bind competitively — in addition to membrane surface charges — to affinity sites of Ca channel, where they specifically modulate permeation of calcium.     

Dense-core secretory vesicle docking and exocytotic membrane fusion in Paramecium cells

Work with Paramecium has contributed to the actual understanding of certain aspects of exocytosis regulation, including membrane fusion. The system is faster and more synchronous than any other dense-core vesicle system described and its highly regular design facilitates correlation of functional and ultrastructural (freeze-fracture) features. From early times on, several crucial aspects of exocytosis regulation have been found in Paramecium cells, e.g. genetically controlled microdomains (with distinct ultrastructure) for organelle docking and membrane fusion, involvement of calmodulin in establishing such microdomains, priming by ATP, occurrence of focal fusion with active participation of integral and peripheral proteins, decay of a population of integral proteins ("rosettes", mandatory for fusion capacity) into subunits and their lateral dispersal during fusion, etc. The size of rosette particles and their dispersal upon focal fusion would be directly compatible with proteolipid V(0) subunits of a V-ATPase, much better than the size predicted for oligomeric SNARE pins (SCAMPs are unknown from Paramecium at this time). However, there are some restrictions for a straightforward interpretation of ultrastructural results. The rather pointed, nipple-like tip of the trichocyst membrane could accommodate only one (or very few) potential V(0) counterpart(s), while the overlaying domain of the cell membrane contains numerous rosette particles. Particle size is compatible with V(0), but larger than that assumed for the SNARE complexes. When membrane fusion is induced in the presence of antibodies against cell surface components, focal fusion is seen to occur with dispersing rosette particles but without dispersal of their subunits and without pore expansion. Clearly, this is required for completing fusion and pore expansion. After cloning SNARE and V(0) components in Paramecium (with increasing details becoming rapidly available), we may soon be able to address the question more directly, whether any of these components or some new ones to be detected, serve exocytotic and/or any other membrane fusions in Paramecium.     

Decoupling of exocytotic membrane fusion from protein discharge in Paramecium cells

Under certain conditions it is possible in Paramecium cells to induce selectively the fusion of the secretory organelle membrane with the cell membrane without the involvement of any further steps (release of secretory contents, etc.). A Ca2+-mobilizing fusogen was used in the presence of components which inhibit the discharge of the secretory contents (Mg2+ and EGTA, mainly). One can thus produce many exocytotic openings with the secretory contents (which are normally vigorously discharged) still retained.     

Paramecium tredecaurelia of the Paramecium aurelia complex in Israel

The paper concerns the finding of a new habitat (Kiryat Motzkin, north of Haifa, Israel) of Paramecium tredecaurelia from the P. aurelia complex. This is only the forth known locality of the species in the world. Previously, its strains were obtained from widely separated localities: the River Seine, Paris, France; Benenitra, Madagascar, and the Cuernavaca Valley, Taxco, Mexico. The studied strain originating from Israel was identified as P. tredecaurelia on the basis of the strong (90%) conjugation between the complementary mating type of the examined clones with the appropriate standard strain 209 of P. tredecaurelia from Paris, France (restricted to odd mating type). However, the strain from Israel is restricted to the even mating type.     

Membrane potential responses controlling chemodispersal of Paramecium caudatum from quinine

Membrane potential responses of a ciliate protozoan Paramecium caudatum to the external application of quinine were investigated in relation to its motile activities. Wild-type specimens swimming in the reference solution did not enter into a quinine-containing (0.5 mM) test solution due to avoiding responses exhibited at the border between the two solutions, and therefore stayed in the reference solution (chemodispersal). Squirting of a quinine-containing test solution over a wild-type specimen evoked a train of action potentials superimposed on a depolarizing chemoreceptor potential. Squirting of a quinine-containing test solution over a CNR-mutant specimen defective in voltage-gated Ca²⁺ channel evoked only chemoreceptor potentials, which consisted of an initial transient depolarization, a following transient hyperpolarization and a sustained depolarization. A current-evoked action potential became larger in its amplitude and longer in its duration with the external application of quinine. Under the voltage-clamp condition, the fast inward current did not change whereas the delayed outward current decreased with the external application of quinine. It is concluded that quinine is a potent repellent for Paramecium because it produces a depolarizing chemoreceptor potential which evokes action potentials and prolongs the duration of the action potential.     

Paramecium sexaurelia of the Paramecium aurelia species complex in Thailand

The clones originating from Thailand, Phuket Island, were identified as Paramecium sexaurelia.     

"Cold-sensitive" mutants of the Lac repressor

Thirteen of more than 4,000 single-amino-acid-replacement mutants of the Lac repressor, generated by suppression of amber nonsense mutants, were characterized as having a cold-sensitive phenotype. However, when expressed as missense mutations, none of the replacements cause cold sensitivity, implicating the suppression mechanism as being responsible for this phenotype.     

Cloning and sequencing of a protein involved in phagosomal membrane fusion in Paramecium

An mAb was raised to the C5 phagosomal antigen in Paramecium multimicronucleatum. To determine its function, the cDNA and genomic DNA encoding C5 were cloned. This antigen consisted of 315 amino acid residues with a predicted molecular weight of 36,594, a value similar to that determined by SDS-PAGE. Sequence comparisons uncovered a low but significant homology with a Schizosaccharomyces pombe protein and the C-terminal half of the beta-fructofuranosidase protein of Zymomonas mobilis. Lacking an obvious transmembrane domain or a possible signal sequence at the N terminus, C5 was predicted to be a soluble protein, whereas immunofluorescence data showed that it was present on the membranes of vesicles and digestive vacuoles (DVs). In cells that were minimally permeabilized but with intact DVs, C5 was found to be located on the cytosolic surface of the DV membranes. Immunoblotting of proteins from the purified and KCl-washed DVs showed that C5 was tightly bound to the DV membranes. Cryoelectron microscopy also confirmed that C5 was on the cytosolic surface of the discoidal vesicles, acidosomes, and lysosomes, organelles known to fuse with the membranes of the cytopharynx, the DVs of stages I (DV-I) and II (DV-II), respectively. Although C5 was concentrated more on the mature than on the young DV membranes, the striking observation was that the cytopharyngeal membrane that is derived from the discoidal vesicles was almost devoid of C5. Approximately 80% of the C5 was lost from the discoidal vesicle-derived membrane after this membrane fused with the cytopharyngeal membrane. Microinjection of the mAb to C5 greatly inhibited the fusion of the discoidal vesicles with the cytopharyngeal membrane and thus the incorporation of the discoidal vesicle membranes into the DV membranes. Taken together, these results suggest that C5 is a membrane protein that is involved in binding and/or fusion of the discoidal vesicles with the cytopharyngeal membrane that leads to DV formation.