Synchronous exocytosis in Paramecium cells. III. Rearrangement of membranes and membrane-associated structural elements after exocytosis performance

Aminoethyldextran (AED) was used to trigger the synchronous release of trichocysts from Paramecium tetraurelia cells (see [8]) by a mechanism involving exocytotic membrane fusion and resealing (see [5]). Ultrastructural changes were analyzed by quantitative evaluation of ultrathin sections. In resting cells the percentage of potential trichocyst-docking sites which are actually occupied by a trichocyst was 58%; 36% of potential docking sites contained ghosts and 6% a "plug" of electron-dense material. We derived from our data that paramecia would discharge permanently and spontaneously trichocysts (without AED) at a rate of 2-3 per min (which we then also verified by counting the spontaneous release rate) and that this value is equivalent to the docking rate. For the synchronous expulsion of trichocysts in response to AED we had determined that the degree of synchrony is more than a hundred times better than in most other systems (see [8]). We have determined the half-lives (HL) for different events involved in exocytosis and re-docking as follows: approximately 3 sec for trichocyst discharge, approximately 3 sec for the formation of ghosts, 8 min for the clearing of ghosts from the cell surface, 4 min for the formation of "plugs". Trichocysts are docked with a HL of 40 min and "plugs" (considered as receptor-type structures for trichocyst docking) disappear with a concomitant HL of 50 min. Evidently the clearing of ghosts allows for re-formation of "plugs" but the respective HL values signal that "plugs" may also be formed anew. The relatively slow decline of the percentage of "plugs" (after their azimuth 15 min after AED triggering) may also indicate the synthesis of new docking sites. After a period of over approximately 3 h following AED triggering, the original situation is roughly re-established and maintained over the whole period of population growth analyzed.     

Synchronous exocytosis in Paramecium cells. IV. Polyamino compounds as potent trigger agents for repeatable trigger-redocking cycles

We found that different polyamino compounds trigger the instantaneous and simultaneous release of trichocysts from Paramecium tetraurelia cells (monoxenically bacterized cultures), provided amino groups are spaced in intervals of approximately 1.0 nm; in this case even diamines or oligopeptides exert some trigger effect. The most potent trigger agent found was aminoethyldextran (AED, MW = 40 kDa) which was used mainly as a derivative with 40 -NH2/molecule. A maximal response (strain K401) was achieved at 1.38 X 10(-6) M, a half maximal response at 1.08 X 10(-6) M. AED acts by a dual effect, i.e., not only by statistically properly spaced amino groups but also by some additional effect of the dextran molecule, since this greatly enhances the effect of oligoamines, although it exerts no trigger effect per se. From a total of approximately 1120 or approximately 1230 trichocysts per cell (strain K401 or 7S) approximately 95% are releasable by AED. In these strains the number of non-releasable trichocysts corresponds closely to the number of undocked trichocysts floating in the cytoplasm, so that practically all trichocysts which are docked to the cell membrane, can be released. (We also analysed different mutant strains for their response to AED.) Massive trichocyst release does not impair cell viability or culture growth, and multiple release-redocking cycles can be performed; up to 5 trigger-docking cycles were tested with individual cells in 12 h intervals. AED-triggered exocytosis requires a free extracellular [Ca2+] of greater than or equal to 10(-5) M; it is inhibited by EGTA (ethyleneglycol-bis(beta-aminoethyl ether)-N,N'-tetraacetate), by a short pH 5.5 shock or by neomycin at 10(-5) M concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

A Ca2+ influx associated with exocytosis is specifically abolished in a Paramecium exocytotic mutant

A Paramecium possesses secretory organelles called trichocysts which are docked beneath the plasma membrane awaiting an external stimulus that triggers their exocytosis. Membrane fusion is the sole event provoked by the stimulation and can therefore be studied per se. Using 3 microM aminoethyl dextran (AED; Plattner, H., H. Matt, H.Kersken, B. Haake, and R. Sturz, 1984. Exp. Cell Res. 151:6-13) as a vital secretagogue, we analyzed the movements of calcium (Ca2+) during the discharge of trichocysts. We showed that (a) external Ca2+, at least at 3 X 10(-7) M, is necessary for AED to induce exocytosis; (b) a dramatic and transient influx of Ca2+ as measured from 45Ca uptake is induced by AED; (c) this influx is independent of the well-characterized voltage- operated Ca2+ channels of the ciliary membranes since it persists in a mutant devoid of these channels; and (d) this influx is specifically abolished in one of the mutants unable to undergo exocytosis, nd12. We propose that the Ca2+ influx induced by AED reflects an increase in membrane permeability through the opening of novel Ca2+ channel or the activation of other Ca2+ transport mechanism in the plasma membrane. The resulting rise in cytosolic Ca2+ concentration would in turn induce membrane fusion. The mutation nd12 would affect a gene product involved in the control of plasma membrane permeability to Ca2+, specifically related to membrane fusion.     

Ca2+ release from subplasmalemmal stores as a primary event during exocytosis in Paramecium cells

A correlated electrophysiological and light microscopic evaluation of trichocyst exocytosis was carried out the Paramecium cells which possess extensive cortical Ca stores with footlike links to the plasmalemma. We used not only intra- but also extracellular recordings to account for polar arrangement of ion channels (while trichocysts can be released from all over the cell surface). With three widely different secretagogues, aminoethyldextran (AED), veratridine and caffeine, similar anterior Nain and posterior Kout currents (both known to be Ca(2+)-dependent) were observed. Direct de- or hyperpolarization induced by current injection failed to trigger exocytosis. For both, exocytotic membrane fusion and secretagogue-induced membrane currents, sensitivity to or availability of Ca2+ appears to be different. Current responses to AED were blocked by W7 or trifluoperazine, while exocytosis remained unaffected. Reducing [Ca2+]o to < or = 0.16 microM (i.e., resting [Ca2+]i) suppressed electrical membrane responses triggered with AED, while we had previously documented normal exocytotic membrane fusion. From this we conclude that the primary effect of AED (as of caffeine) is the mobilization of Ca2+ from the subplasmalemmal pools which not only activates exocytosis (abolished by iontophoretic EGTA injection) but secondarily also spatially segregated plasmalemmal Ca(2+)-dependent ion channels (indicative of subplasmalemmal [Ca2+]i increase, but irrelevant for Ca2+ mobilization). The 45Ca2+ influx previously observed during AED triggering may serve to refill depleted stores. Apart from the insensitivity of our system to depolarization, the mode of direct Ca2+ mobilization from stores by mechanical coupling to the cell membrane (without previous Ca(2+)-influx from outside) closely resembles the model currently discussed for skeletal muscle triads.     

Cytoskeleton-secretory vesicle interactions during the docking of secretory vesicles at the cell membrane in Paramecium tetraurelia cells

Stationary-phase cells of Paramecium tetraurelia have most of their many secretory vesicles ("trichocysts") attached to the cell surface. Log-phase cells contain numerous unoccupied potential docking sites for trichocysts and many free trichocysts in the cytoplasm. To study the possible involvement of cytoskeletal elements, notably of microtubules, in the process of positioning of trichocysts at the cell surface, we took advantage of these stages. Cells were stained with tannic acid and subsequently analyzed by electron microscopy. Semithin sections allowed the determination of structural connections over a range of up to 10 micrometer. Microtubules emanating from ciliary basal bodies are seen in contact with free trichocysts, which appear to be transported, with their tip first, to the cell surface. (This can account for the saltatory movement reported by others). It is noteworthy that the "rails" represented by the microtubules do not directly determine the final attachment site of a trichocyst. Unoccupied attachment sites are characterized by a "plug" of electron-dense material just below the plasma membrane; the "plug" seems to act as a recognition or anchoring site; this material is squeezed out all around the trichocyst attachment zone, once a trichocyst is inserted (Westphal and Plattner, in press. [53]). Slightly below this "plug" we observed fasciae of microfilaments (identified by immunocytochemistry using peroxidase labeled F(ab) fragments against P. tetraurelia actin). Their arrangement is not altered when a trichocyst is docked. These fasciae seem to form a loophole for the insertion of a trichocyst. Trichocyst remain attached to the microtubules originating from the ciliary basal bodies--at least for some time--even after they are firmly installed in the preformed attachment sites. Evidently, the regular arrangement of exocytotic organelles is controlled on three levels: one operating over a long distance from the exocytosis site proper (microtubules), one over a short distance (microfilament bundles), and one directly on the exocytosis site ("plug").     

Serratia marcescens Hemolysin (ShlA) Binds Artificial Membranes and Forms Pores in a Receptor-independent Manner

A non-discharge mutant of Paramecium tetraurelia (nd12-35 degrees C, lacking exocytotic response upon stimulation with the nonpermeable polycationic secretagogue aminoethyldextran, AED), in the pawnA genetic context (d4-500r, lacking ciliary voltage-dependent Ca2+ influx), was shown to lack (45)Ca2+ entry from outside upon AED stimulation. In contrast, cells grown at 25 degrees C behave like the wildtype. To check the functional properties in more detail, fluorochrome-loaded 35 degrees C cells were stimulated, not only with AED (EC(100) = 10(-6) M in wildtype cells), but also with 4-chloro-meta-cresol, (4CmC, 0.5 mM), a permeable activator of ryanodine receptor-type Ca2+ release channels, usually at extracellular [Ca2+] of 50 microM, and eventually with a Ca2+ chelator added. We confirm that pwA-nd12(35 degrees C) cells lack any Ca2+ influx and any exocytosis of trichocysts in response to any stimulus. As we determined by x-ray microanalysis, total calcium content in alveolar sacs (subplasmalemmal stores) known to be mobilized upon exocytosis stimulation in wild-type cells, contain about the same total calcium in 35 degrees C as in 25 degrees C cells, and Ca2+ mobilization from alveoli by AED or 4CmC is also nearly the same. Due to the absence of any AED-induced Ca2+ influx in 35 degrees C cells and normal Ca2+ release from stores found by x-ray microanalysis one can exclude a "CICR"-type mechanism (Ca2+-induced Ca2+ release) and imply that normally a store-operated Ca2+ ("SOC") influx would occur (as in 25 degrees C cells). Furthermore, 35 degrees C cells display a significantly lower basal intracellular [Ca2+], so that any increase upon stimulation may be less expressed or even remain undetected. Under these conditions, any mobilization of Ca2+ from stores cannot compensate for the lack of Ca2+ influx, particularly since normally both components have to cooperate to achieve full exocytotic response. Also striking is our finding that 35 degrees C cells are unable to perform membrane fusion, as analyzed with the Ca2+ ionophore, A23187. These findings were corroborated by cryofixation and freeze-fracture analysis of trichocyst docking sites after AED or 4CmC stimulation, which also revealed no membrane fusion. In sum, in nd12 cells increased culture temperature entails multiple defects, notably insensitivity to any Ca2+ signal, which, moreover, cannot develop properly due to a lower basal [Ca2+] level and the lack of Ca2+ influx, despite normal store activation.     

Trichocysts—Paramecium's Projectile‐like Secretory Organelles

This review summarizes biogenesis, composition, intracellular transport, and possible functions of trichocysts. Trichocyst release by Paramecium is the fastest dense core‐secretory vesicle exocytosis known. This is enabled by the crystalline nature of the trichocyst “body” whose matrix proteins (tmp), upon contact with extracellular Ca²⁺, undergo explosive recrystallization that propagates cooperatively throughout the organelle. Membrane fusion during stimulated trichocyst exocytosis involves Ca²⁺ mobilization from alveolar sacs and tightly coupled store‐operated Ca²⁺‐influx, initiated by activation of ryanodine receptor‐like Ca²⁺‐release channels. Particularly, aminoethyldextran perfectly mimics a physiological function of trichocysts, i.e. defense against predators, by vigorous, local trichocyst discharge. The tmp's contained in the main “body” of a trichocyst are arranged in a defined pattern, resulting in crossstriation, whose period expands upon expulsion. The second part of a trichocyst, the “tip”, contains secretory lectins which diffuse upon discharge. Repulsion from predators may not be the only function of trichocysts. We consider ciliary reversal accompanying stimulated trichocyst exocytosis (also in mutants devoid of depolarization‐activated Ca²⁺ channels) a second, automatically superimposed defense mechanism. A third defensive mechanism may be effectuated by the secretory lectins of the trichocyst tip; they may inhibit toxicyst exocytosis in Dileptus by crosslinking surface proteins (an effect mimicked in Paramecium by antibodies against cell surface components). Some of the proteins, body and tip, are glycosylated as visualized by binding of exogenous lectins. This reflects the biogenetic pathway, from the endoplasmic reticulum via the Golgi apparatus, which is also supported by details from molecular biology. There are fragile links connecting the matrix of a trichocyst with its membrane; these may signal the filling state, full or empty, before and after tmp release upon exocytosis, respectively. This is supported by experimentally produced “frustrated exocytosis”, i.e. membrane fusion without contents release, followed by membrane resealing and entry in a new cycle of reattachment for stimulated exocytosis. There are some more puzzles to be solved: Considering the absence of any detectable Ca²⁺ and of acidity in the organelle, what causes the striking effects of silencing the genes of some specific Ca²⁺‐release channels and of subunits of the H⁺‐ATPase? What determines the inherent polarity of a trichocyst? What precisely causes the inability of trichocyst mutants to dock at the cell membrane? Many details now call for further experimental work to unravel more secrets about these fascinating organelles.     

Lectin binding sites in Paramecium tetraurelia cells. I. Labeling analysis predominantly of secretory components

Though all three lectins tested (ConA, RCA II, WGA) bound to the entire cell membrane, none bound selectively to the docking site of secretory organelles (trichocysts); the same results were achieved with FITC-conjugates, or, on the EM level, with peroxidase- or gold-labeling. Only WGA triggered the release of trichocysts and none of the lectins tested inhibited AED-induced synchronous exocytosis. When exocytosis was triggered synchronously in the presence of any of these three lectins (FITC-conjugates), the resulting ghosts trapped the FITC-lectins and the cell surface was immediately afterwards studded with regularly spaced dots (corresponding to the ghosts located on the regularly spaced exocytosis sites). These disappeared within about 10 min from the cell surface (thus reflecting ghost internalization with a half life of 3 min) and fluorescent label was then found in approximately 6-10 vacuoles, which are several microns in diameter, stain for acid phosphatase and, on the EM level, contain numerous membrane fragments (otherwise not found in this form in digesting vacuoles). We conclude that synchronous massive exocytosis involves lysosomal breakdown rather than reutilization of internalized trichocyst membranes and that these contain lectin binding sites (given the fact free fluorescent probes did not efficiently stain ghosts). Trichocyst contents were analyzed for their lectin binding capacity in situ and on polyacrylamide gels. RCA II yielded intense staining (particularly of "tips"), while ConA (fluorescence concentrated over "bodies") and WGA yielded less staining of trichocyst contents on the light and electron microscopic level. Only ConA- and WGA-staining was inhibitable by an excess of specific sugars, while RCA II binding was not. ConA binding was also confirmed on polyacrylamide gels which also allowed us to assess the rather low degree of glycosylation (approximately 1% by comparison with known glycoprotein standards) of the main trichocyst proteins contained in their expandable "matrix". Since RCA II binding could be due to its own glycosylation residues we looked for an endogenous lectin. The conjecture was substantiated by the binding of FITC-lactose-albumin (inhibitable by a mixture of glucose-galactose). This preliminary new finding may be important for the elucidation of trichocyst function.     

Secretory organelle docking at the cell membrane of Paramecium cells: dedocking and synchronized redocking of trichocysts

We present the first evidence that secretory organelle docking at the cell membrane can be reversed in vivo. In nondischarge (nd) mutants of Paramecium tetraurelia all trichocysts can be detached from the cell surface within 2-3 h by different means, including cytochalasin B (but not D), high cell density, or Ca2+ ionophores. Considering the well-established ultrastructural differences between nd and wild-type (wt) cells, one can conclude that trichocyst docking at the cell periphery involves two docking sites (I, II): Site I ties the organelles to the epiplasm, and site II is the connection to the cell membrane at the fusogenic zone (expressed only in wt cells); both sites are close to the cell surface and only 150 nm apart. When the trigger for detachment of cortically docked trichocysts (high cell density, cytochalasin B) is relieved, trichocysts are synchronously reattached at the cell membrane, within 40-50 min, with a rate of 20-40 organelles/min, which far exceeds spontaneous docking rates. This is therefore also the first report on synchronization of secretory organelle docking. It is shown by radioactive leucine labeling that the same organelles are redocked, because trichocyst biogenesis is minimal under the conditions of de/redocking used. Surprisingly not only redocking but also detachment of trichocysts from the cell surface can be abolished by inhibitors of protein synthesis. Since Ca2+ ionophores mimic the effects of other conditions sufficient to detach trichocysts from the cell surface, we assume that a protein-dependent mechanism sensitive to Ca2+ (or other ions in exchange) may operate in trichocyst detachment. The precise mechanism involved in attachment or detachment of trichocysts remains to be elucidated.     

Secretory organelles of Paramecium cells (trichocysts) are not remarkably acidic compartments.

Acridine orange (AO) trapping in conjunction with fluorescence microscopy was applied to Paramecium cells. Trichocysts were not labeled when analyzed with an image intensification system (as opposed to a lysosomal population). Only with increasing intensity of ultraviolet light (UV) did trichocysts (and to some extent the cytosol) exhibit orange fluorescence, both effects being paralleled by increasing cell damage. Therefore, in comparison with the reported cytosolic pH (6.8), trichocysts cannot be considered as essentially acidic compartments. This is supported by experiments in vitro, using isolated cortex fragments or isolated fractions of membrane-bounded trichocysts (greater than or equal to 90% non-leaky). Again, during UV illumination orange fluorescence was observed even in the absence of ATP and Mg2+. Furthermore, this AO fluorescence and the condensation state of trichocyst contents were not affected by NH3 or by any of the widely differing ion- and H(+)-exchange inhibitors or ionophores tested. Decondensation of trichocyst contents occurred only when Ca2+ ionophore A23187 or X537A was incorporated into trichocyst membranes and when Ca2+ was then added. In this case all trichocysts partially decondensed within their intact membranes. We conclude that AO might be trapped in trichocysts by the abundant acidic secretory components during observation with UV light, rather than by acidic luminal pH.     

Secretory proteins in a ciliate cell: Identification of epitopes common to numerous polypeptides

Secretory vesicles of the ciliate Pseudomicrothorax dubius, called trichocysts, are separated into > 40 proteins by two-dimensional gel electrophoresis. The trichocyst, composed of a shaft and four arms, is in a condensed state when docked in the cell cortex, and it elongates into an extended state during exocytosis. Monoclonal antibodies (mAbs) were raised against trichocyst proteins. Their reactivities were analysed: I) on Western blots of extended, isolated trichocysts by immunolabeling; 2) on entire cells and extended trichocysts by indirect immunofluorescent binding assay (IFA); 3) on semi-thin sectioned cells by IFA; and 4) on ultra-thin sections of cells by immunogold labeling. mAb IV 4E5 labels major trichocyst proteins at 15–19, 22 and 24 kDa, pI 4.6?6.6. The epitope recognized by mAb IV 4E5 is common to as many as 30 proteins and suggests a family of proteins with possible sequence homology. By IFA, the shafts of extended trichocysts are labeled. The shafts of condensed trichocysts are labeled on both semi-thin sections in Lowicryl and ultrathin sections. On semi-thin Epon sections, the part of the trichocyst which is labeled is arm-like. mAb VI 2D12 labels three major trichocyst proteins at 31 kDa, pI 5.0?5.4. The arms of extended trichocysts are labeled by IFA, but are only weakly labeled on ultrathin sections. The shaft of extended trichocysts is labeled by IFA, and the shaft of condensed trichocysts is labeled on ultrathin sections.     

One-way calcium spill-over during signal transduction in Paramecium cells: from the cell cortex into cilia, but not in the reverse direction

We asked to what extent Ca(2+) signals in two different domains of Paramecium cells remain separated during different stimulations. Wild-type (7S) and pawn cells (strain d4-500r, without ciliary voltage-dependent Ca(2+)-channels) were stimulated for trichocyst exocytosis within 80 ms by quenched-flow preparation and analysed by energy-dispersive X-ray microanalysis (EDX), paralleled by fast confocal fluorochrome analysis. We also analysed depolarisation-dependent calcium signalling during ciliary beat rerversal, also by EDX, after 80-ms stimulation in the quenched-flow mode. EDX and fluorochrome analysis enable to register total and free intracellular calcium concentrations, [Ca] and [Ca(2+)], respectively. After exocytosis stimulation we find by both methods that the calcium signal sweeps into the basis of cilia, not only in 7S but also in pawn cells which then also perform ciliary reversal. After depolarisation we see an increase of [Ca] along cilia selectively in 7S, but not in pawn cells. Opposite to exocytosis stimulation, during depolarisation no calcium spill-over into the nearby cytosol and no exocytosis occurs. In sum, we conclude that cilia must contain a very potent Ca(2+) buffering system and that ciliary reversal induction, much more than exocytosis stimulation, involves strict microdomain regulation of Ca(2+) signals.     

Aspects of signal transduction in stimulus exocytosis-coupling in Paramecium

This paper deals with the detailed mechanisms of signal transduction that lead to exocytosis during regulative secretion induced by specific secretagogues in a eukaryotic cell, Paramecium tetraurelia. There are at least three cellular compartments involved in the process: I) the plasma membrane, which contains secretagogue receptors and other transmembrane proteins, II) the cytoplasms, particularly in the region between the cell and secretory vesicle membranes, where molecules may influence interactions of the membranes, and III) the secretory vesicle itself. The ciliated protozoan Paramecium tetraurelia is very well suited for the study of signal transduction events associated with exocytosis because this eukaryotic cell contains thousands of docked secretory vesicles (trichocysts) below the cell membrane which can be induced to release synchronously when triggered with secretagogue. This ensures a high signal-to-noise ratio for events associated with this process. Upon release the trichocyst membrane fuses with the cell membrane and the trichocyst content undergoes a Ca2+-dependent irreversible expansion. Secretory mutants are available which are blocked at different points in the signal transduction pathway. Aspects of the three components mentioned above that will be discussed here include a) the properties of the vesicle content, its pH, and its membrane; b) the role of phosphorylation/dephosphorylation of a cytosolic 63-kilodalton (kDa)Mr protein in membrane fusion; and c) how influx of extracellular Ca2+ required for exocytosis may take place via exocytic Ca2+ channels which may be associated with specific membrane microdomains (fusion rosettes).     

Control of exocytotic processes: cytological and physiological studies of trichocyst mutants in Paramecium tetraurelia

The trichocysts of Paramecium tetraurelia constitute a favorable system for studying secretory process because of the numerous available mutations that block, at various stages, the development of these secretory vesicles, their migration towards and interaction with the cell surface, and their exocytosis. Previous studies of several mutants provided information (a) on the assembly and function of the intramembranous particles arrays in the plasma membrane at trichocyst attachment sites, (b) on the autonomous motility of trichocysts, required for attachment to the cortex, and (c) on a diffusible cytoplasmic factor whose interaction with both trichocyst and plasma membrane is required for exocytosis to take place. We describe here the properties of four more mutants deficient in exocytosis ability, nd6, nd7, tam38, and tam6, which were analyzed by freeze-fracture, microinjection of trichocysts, and assay for repair of the mutational defect through cell-cell interaction during conjugation with wild-type cells. As well as providing confirmation of previous conclusions, our observations show that the mutations nd6 and tam6 (which display striking abnormalities in their plasma membrane particle arrays and are reparable through cell-cell contact but not by microinjection of cytoplasm) affect two distinct properties of the plasma membrane, whereas the other two mutations affect different properties of the trichocysts. Altogether, the mutants so far analyzed now provide a rather comprehensive view of the steps and functions involved in secretory processes in Paramecium and demonstrate that two steps of these processes, trichocyst attachment to the plasma membrane and exocytosis, depend upon specific properties of both the secretory vesicle and the plasma membrane.     

The crystal lattice of Paramecium trichocysts before and after exocytosis by X-ray diffraction and freeze-fracture electron microscopy

Paramecium trichocysts are unusual secretory organelles in that: (a) their crystalline contents are built up from a family of low molecular mass acidic proteins; (b) they have a precise, genetically determined shape; and (c) the crystalline trichocyst contents expand rapidly upon exocytosis to give a second, extracellular form which is also an ordered array. We report here the first step of our study of trichocyst structure. We have used a combination of x-ray powder diffraction, freeze-etching, and freeze-fracture electron microscopy of isolated, untreated trichocysts, and density measurements to show that trichocyst contents are indeed protein crystals and to determine the elementary unit cell of both the compact intracellular and the extended extracellular form.     

Genetic analysis of membrane differentiation in Paramecium. Freeze- fracture study of the trichocyst cycle in wild-type and mutant strains

Using a series of mutants of Paramecium tetraurelia, we demonstrate, for the first time, changes in the internal structure of the cell membrane, as revealed by freeze-fracture, that correspond to specific single gene mutations. On the plasma membrane of Paramecium circular arrays of particles mark the sites of attachment of the tips of the intracellular secretory organelles-trichocysts. In wild-type paramecia, where attached trichocysts can be expelled by exocytosis under various stimuli, the plasma membrane array is composed of a double outer ring of particles (300 nm in diameter) and inside the ring a central rosette (fusion rosette) of particles (76 nm in diameter). Mutant nd9, characterized by a thermosensitive ability to discharge trichocysts, shows the same organization in cells grown at the permissive temperature (18 degrees C), while in cells grown at the nonpermissive temperature (27 degrees C) the rosette is missing. In mutant tam 8, characterized by normal but unattached trichocysts, and in mutant tl, completely devoid of trichocysts, no rosette is formed and the outer rings always show a modified configuration called "parentheses", also found in wild-type and in nd9 (18 degrees C) cells. From this comparison between wild type and mutants, we conclude: (a) that the formation of parentheses is a primary differentiation of the plasma membrane, independent of the presence of trichocysts, while the secondary transformation of parentheses into circular arrays and the formation of the rosette are triggered by interaction between trichocysts and plasma membranes; and (b) that the formation of the rosette is a prerequisite for trichocyst exocytosis.     

Secretory protein decondensation as a distinct, Ca2+-mediated event during the final steps of exocytosis in Paramecium cells

The contents of secretory vesicles ("trichocysts") were isolated in the condensed state from Paramecium cells. It is well known that the majority portion of trichocysts perform a rapid decondensation process during exocytosis, which is visible in the light microscope. We have analyzed this condensed leads to decondensed transition in vitro and determined some relevant parameters. In the condensed state, free phosphate (and possibly magnesium) ions screen local surplus charges. This is supported by x-ray spectra recorded from individual trichocysts (prepared by physical methods) in a scanning transmission electron microscope. Calcium, as well as other ions that eliminate phosphate by precipitation, produces decondensation in vitro. Under in vivo conditions, Ca2+ enters the vesicle lumen from the outside medium, once an exocytic opening has been formed. Consequently, within the intact cell, membrane fusion and protein decondensation take place with optimal timing. Ca2+ might then trigger decondensation in the same way by precipitating phosphate ions (as it does in vitro) and, indeed, such precipitates (again yielding Ca and P signals in x-ray spectra) can be recognized in situ under trigger conditions. As decondensation is a unidirectional, rapid process in Paramecium cells, it would contribute to drive the discharge of the secretory contents to the outside. Further implications on the energetics of exocytosis are discussed.     

Synchronous exocytosis in Paramecium cells. II. Intramembranous changes analysed by freeze-fracturing

Since Paramecium tetraurelia cells were found to discharge synchronously most of their secretory organelles ('trichocysts') when exposed to 10(-6) M aminoethyldextran (AED) [17], this was now used for a freeze-fracture and -etching analysis of intramembranous changes during exocytosis performance, in conjunction with a rapid freezing method. In controls the potential exocytosis sites of the cell membrane revealed a 'rosette' of approximately 8 membrane-intercalated particles (MIPs) within a 300 nm large double 'ring' of MIPs (see [18]). During exocytosis we found the following changes: (a) Membrane fusion starts as a focal event, the smallest recognizable openings measuring 20-30 nm in diameter. (b) The exocytotic opening always forms in the center of the rosette. (c) Rosette MIPs may stay very close to the exocytotic opening, or they may partly be dispersed as the exocytotic opening is formed. (d) No diaphragm is formed during exocytotic membrane fusion. (e) The exocytotic opening is increasing to a size where it fills the total fusogenic zone contained within a ring, but not any further. (f) Rosette MIPs become further dispersed through the rings. (g) Resealing involves the transformation of rings into a collapsed form ('parenthesis'). (h) A resealed exocytosis site contains no conspicuous MIP aggregates, such as rosettes or 'annulus' structures from the trichocyst membrane, indicating a clear separation of both components.     

Membrane behavior of exocytic vesicles. II. Fate of the trichocyst membranes in Paramecium after induced trichocyst discharge.

A specific exocytic process, the discharge of spindle trichocyts of Paramecium caudatum, was examined by means of the electron microscope. This exocytosis is induced by an electric shock simultaneously in nearly all of the trichocysts (ca. 6,000-8,000) of a single cell. Single paramecia were subjected to the shock and then fixed at defined times after the shock so that the temporal sequence of the pattern of changes of the trichocyst membranes after exocytosis could be studied. The trichocyst vacuoles fuse with the plasma membrane only for the length of time required for expulsion to take place. After exocytosis, the membrane of the vacuole does not become incorporated into the plasma membrane; rather, the collapsed vacuole is pinched off and breaks up within the cytoplasm. The membrane vesiculates into small units which can no longer be distinguished from vesicles of the same dimensions that exist normally within the cell's cytoplasm. The entire process is completed within 5-10 min. These results differ from the incorporation of mucocyst membranes into the plasma membrane as proposed for Tetrahymena.