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.

The striated bands of Paramecium are immunologically distinct from the centrin-specific infraciliary lattice and cytostomal cord.

The pellicle of Paramecium has three two-dimensionally arrayed systems that occupy separate but closely paralleling planes. All three systems are now distinguishable by their differing immunological properties. This study focused on the two deeper systems. The infraciliary lattice lies innermost and labels with centrin-specific antibodies. The middle system, the striated bands, is specifically labeled with a monoclonal antibody that we have raised to a 110 kDa cortical antigen in P. multimicronucleatum. This antibody labels a similar geometric cortical pattern in at least two species, P. multimicronucleatum and P. tetraurelia. Centrin-specific structures appear to be net-like in the above two species but show a more interrupted pattern in P. caudatum. The cytostomal cord is an essentially unbranched extension of the net-like infraciliary lattice and, like it, is centrin-specific. The cord has a unique association with the alveolar sacs which suggest these calcium-storing compartments contribute to the calcium fluxes required for contraction of the cord. A structural rather than a contractile function is favored for the striated bands, based solely on their morphology.

High resolution view of the true cytosolic membrane surface of phagosomes of known ages purified from Paramecium.

Techniques were used for viewing the true cytosolic surfaces of the membranes of intracellular organelles by field emission scanning electron microscopy (SEM). Cells of Paramecium multimicronucleatum were fed briefly with magnetic beads followed by a chase which advanced the newly formed digestive vacuoles (DVs) to predetermined ages. These bead-containing phagosomes were isolated from the whole cell homogenates with a magnet and were determined to be intact by fluorescence microscopy. Antigenically, these DVs were similar to those in situ. The DVs prepared for transmission electron microscopy or SEM showed extensive adherence of cellular debris. The use of 0.2 M KCl in the wash buffer eliminated much of this debris and exposed the true vacuolar surfaces. Three populations of tightly bound vesicles and numerous globular particles of 10 to 20 nm became visible on the DV surfaces. The attached vesicles, having diameters of approximately 300 and approximately 200 nm each, corresponded to the acidosomes and lysosomes that are known to be associated with the DV-I and DV-II, respectively. High resolution SEM also revealed a third set of small vesicles (50-150 nm), which were previously not known to be associated with DVs. The 10 to 20 nm globular particles were judged to be the cytosolic extensions of transmembrane protein complexes as their patterns of distribution on DVs of various ages corresponded to the transmembrane particles previously seen in these membranes in freeze-fracture studies.

Hyperosmotic stress leads to reversible dissociation of the proton pump-bearing tubules from the contractile vacuole complex in Paramecium.

To study the effect of hyperosmotic stress on the structure and function of the contractile vacuole complex of Paramecium multimicronucleatum, we employed two different monoclonal antibody markers: one to a decorated spongiome antigen (A4) and a second to an antigen found on all other membranes of the contractile vacuole complex (G4). A hyperosmotic condition was produced by adding sorbitol to the axenic culture medium which induced both dose- and time-dependent decreases in the vacuole's expulsion rate. The addition of 150 mM sorbitol to the medium (making a final osmolarity of 230 mOsmol) was sufficient to completely stop the expulsion of the contractile vacuole. Immunofluorescence demonstrated that the blocking of fluid output was accompanied by the disappearance of most fluorescence labeling from the decorated spongiome (the A4 antigen). Electron microscopy revealed that the disappearance of the labeling was accompanied by the disappearance of the decorated tubules from around the collecting canals. These tubules vesiculate. The other membranes of the contractile vacuole complex remained unaffected which was demonstrated by both electron microscopy and indirect immunolabeling using the mAb against the G4 antigen. These results show that the decorated spongiome is formed from a distinct membrane pool separate from that of the smooth spongiome, collecting canals and the contractile vacuole. Recovery of the decorated spongiome rapidly followed the return of the cell to an isotonic environment and was completed within 3 hours. Decorated tubule recovery paralleled the recovery of the function of the contractile vacuole. Recovery was also observed during continuous hyperosmotic treatment with the reappearance of the contractile vacuole activity starting at 3 hours and stabilizing at around 10 hours of incubation. Functional recovery under these conditions was accompanied by a reappearance of the decorated tubules but the total fluid output was always lower than for cells in an isotonic environment. Thus, cells were shown to be capable of adapting to high hyperosmotic conditions. We conclude that the dissociation and reassociation of the decorated spongiome is an important regulatory feature controlling the activity of the contractile vacuole complex and of intracellular osmoregulation in Paramecium.

The pegs on the decorated tubules of the contractile vacuole complex of Paramecium are proton pumps.

Our previous study has shown that the decorated tubules (collectively known as the decorated spongiome) of the contractile vacuole complex (CVC) in Paramecium are the site of fluid segregation, as the binding of microinjected monoclonal antibody (mAb) DS-1 to the tubules reduced the CVC's fluid output. In this study, we showed by immunogold labeling on cryosections that the antigenic sites for mAb DS-1 were located on the 15 nm 'pegs' protruding from the cytosolic surface of the decorated tubules. In immunofluorescence studies, both polyclonal antibodies against the subunits of the V-ATPase of Dictyostelium discoideum and against the 57 kDa B-subunit of the V-ATPase of chromaffin granules gave identical labeling patterns to that produced by mAb DS-1. On cryosections, all three antigens were located most consistently near or on the pegs of the decorated tubules. These data support the notion that the pegs on the membrane of the decorated tubules represent the V1 complex of a proton pump. Concanamycin B, a potent inhibitor of V-ATPase activity and of acidification of lysosomes and endosomes, strongly and reversibly inhibited fluid output from the CVC but had minimal effect on the integrity of the decorated spongiome as observed by immunofluorescence. Such inhibition suggests that a V-ATPase is intimately involved in fluid segregation. Exposing Paramecium to 12 degrees C or 1 degrees C for 30 minutes resulted in the dissociation of the decorated tubules from the smooth spongiome that borders the collecting canals; thus the DS-1-reactive A4 antigen, the 75 kDa and 66 kDa antigens were all found dispersed in the cytosol.(ABSTRACT TRUNCATED AT 250 WORDS)

Rapid bulk replacement of acceptor membrane by donor membrane during phagosome to phagoacidosome transformation in Paramecium.

The extent to which a donor membrane will be retrieved, or if it is retrieved at all after it fuses with an acceptor membrane, is usually difficult to determine. We have studied the dynamics of membrane retrieval in the phagosome system of Paramecium multimicronucleatum using six monoclonal antibody markers. Our previous freeze-fracture and transmission electron microscopic studies have indicated that extensive changes take place in the membrane of the young phagosome as it progresses through its cycle. Using immunofluorescence and immunoelectron microscopy to determine the times of entry and exit of these individual antigens into the digestive vacuole system, we showed that two hydrophilic antigens, one located on the cytosolic and one on the lumenal side of the discoidal membrane (phagosome membrane precursor), were completely retrieved from the phagosome by tubulation within the first three minutes. At the same time that this membrane was retrieved, membrane from a second population of vesicles, the acidosomes, fused with the phagosome to produce the phagoacidosome. On the basis of immunogold localization on cryosections of a total of six antigens, the two specific for phagosome/discoidal vesicle membrane as well as four specific for the acidosome/phagoacidosome membrane, this replacement is total. We also showed that in the presence of the actin-active drug cytochalasin B, this replacement was essentially prevented. However, when vacuole acidification was neutralized by ammonium chloride, this replacement process continued unaffected after a lag. Consequently, acidification, per se, is not required to trigger the replacement of the phagosome membrane. We conclude, on the basis of these studies as well as our previous freeze-fracture studies that during phagoacidosome formation most of the acceptor membrane is retrieved and is replaced by the donor membrane. This shows that at least one cell type possesses the mechanisms needed to substantially replace the membrane of a phagosomal compartment when radical and rapid changes are needed to modulate the digestive and absorptive processes.

22S axonemal dynein is preassembled and functional prior to being transported to and attached on the axonemes.

In an earlier study we reported the isolation of a cytoplasmic dynein from the cytosol of Paramecium multimicronucleatum. In this study we report the isolation and characterization of two cytosolic axonemal dyneins (22S and 12S) as well as a 19S cytoplasmic dynein from the cytosol of whole or deciliated cells using preformed bovine brain microtubules. These three dynein species were characterized according to mass, morphology, vanadate photocleavage patterns, CTPase/ATPase ratios, Km and Vmax values, temperature optima and reactivity with a mAb. For comparison, 22S and 12S axonemal dyneins (ADs) were also isolated and purified from the demembranated axonemes. The 22S and 12S soluble dyneins appear to be related to ciliary ADs in that the 22S soluble dynein is three-headed while the 12S is a one-headed dynein, as determined by negative staining. Ciliary ADs and their corresponding 22S and 12S soluble dyneins isolated from the cytosol also have similar Km and Vmax values as well as vanadate photocleavage patterns and temperature optima. A mAb raised against the soluble 22S dynein reacted with the 22S ciliary dyneins but not the 12S axonemal or the 19S cytoplasmic dynein. All isolated dyneins supported similar microtubule gliding rates but had different ionic requirements for the translocation buffer. These results suggest that: (i) the two soluble 22S and 12S dyneins are precursor molecules of the ciliary dyneins, (ii) the subunits of the outer arm dynein are already assembled in the cytosol as a three-headed bouquet, and (iii) the 22S and 12S soluble dyneins are functional prior to being transported and attached to the axonemes of the cilia.

Osmoregulation in Paramecium: the locus of fluid segregation in the contractile vacuole complex.

In a previous study, monoclonal antibody DS-1 was found to specifically label the decorated spongiome along the radial arms of the contractile vacuole complexes in Paramecium multimicronucleatum. Fluorescein isothiocyanate-conjugated DS-1, when injected into cells, labels the radial arms initially, but with increasing postinjection time both the intensity of fluorescence and the number of fluorescently labeled radial arms were reduced. When these cells were fixed after 45 minutes and probed indirectly using a second fluorochrome, little new label was seen on the already fluorescein-labeled radial arms. Thin sections showed that the amount of decorated tubules along some collecting canals decreased from the proximal to the distal end and vesicles, which were never seen in control cells, appeared next to the decorated spongiome. These results suggested that the decorated spongiome was undergoing disassembly and sequestration into one region of the cell. The injected DS-1 also reduced the expulsion frequency of the contractile vacuoles in a dose-, time- and site-dependent manner. The contractile vacuole complexes near the injection site were affected more than those farther from the site, but the sizes of both contractile vacuoles were only transiently affected so that fluid output per cell was reduced by approximately 60%. Beyond 45 minutes postinjection, both the expulsion frequency and total fluid output began to recover as the DS-1 was sequestered into one part of the cell. This region persisted in cells up to 18 hours but disappeared by 24 hours, which coincided with the full recovery of the expulsion frequency and of decorated spongiome along the radial arms. The contractile vacuole, the collecting canals and the smooth spongiome were morphologically unaffected. These results indicate that when the decorated spongiome is dissociated from the contractile vacuole complex, the complex's function is strongly inhibited, showing the decorated spongiome to be the site of fluid segregation.