The ejectisomes of the flagellate Chilomonas paramecium: visualization by freeze-fracture and isolation techniques

Freeze-fracture procedures were used to visualize ejectisomes and adjacent plasma membrane specializations in the flagellate protozoan Chilomonas paramecium. The ejectisomes are membrane-bounded, cylindrically rolled, extrusive organelles. Small ones occur in large number beneath the plasma membrane of the body and considerably larger ones are located around the gullet membrane. The intra-membrane particle distribution is different in each type. In small ejectisomes, the portion of the membrane in contact with the plasma membrane of the body has a P-face rosette of five particles while the plasma membrane has not been observed with a rosette. Small ejectisomes and plasma membrane both contain aggregations of particles a short distance from the contact or docking site. Slightly beneath the plasma membrane is the periplastic sheet with which we speculate the small ejectisomes interact during the docking phenomenon. No obvious rosettes have been observed in large ejectisomes. Some other ejectisomal structures are presented and discussed.     

N-ethylmaleimide-sensitive factor is required to organize functional exocytotic microdomains in paramecium

In exocytosis, secretory granules contact plasma membrane at sites where microdomains can be observed, which are sometimes marked by intramembranous particle arrays. Such arrays are particularly obvious when membrane fusion is frozen at a subterminal stage, e.g., in neuromuscular junctions and ciliate exocytotic sites. In Paramecium, a genetic approach has shown that the "rosettes" of intramembranous particles are essential for stimulated exocytosis of secretory granules, the trichocysts. The identification of two genes encoding the N-ethylmaleimide-sensitive factor (NSF), a chaperone ATPase involved in organelle docking, prompted us to analyze its potential role in trichocyst exocytosis using a gene-silencing strategy. Here we show that NSF deprivation strongly interferes with rosette assembly but does not disturb the functioning of exocytotic sites already formed. We conclude that rosette organization involves ubiquitous partners of the fusion machinery and discuss where NSF could intervene in this mechanism.     

Periplaststruktur und Organisation der Plasmamembran vonRhodomonas spec. (Cryptophyceae)

Summary The periplast of the CryptophyceaeRhodomonas has a hexagonal substructure. This substructure is caused by periplast plates. In freeze fracture replicas of the plasma membrane, there are corresponding hexagonal areas with numerous particles. These areas are separated by regions with less particles. Aggregates of particles, partly rosette-like, indicate insertion sites of ejectisomes.

     

A comparative study of periplast structure inCryptomonas cryophila andC. ovata (Cryptophyceae)

Summary Freeze-fracture followed by deep-etch was used with transmission electron microscopy to characterize and compare the periplasts of two cryptomonads,Cryptomonas ovata andC. cryophila. The periplast ofC. ovata consists of a dense surface mat of granular/fibrillar material overlying a series of polygonal plates attached to the undersurface of the plasma membrane (PM) at their upturned edges. Fracture faces of the PM reveal a highly stable substructure with distinct patterns of intra-membrane particles (IMPs) associated with the underlying plates; a role for the PM in plate development is indicated. The surface periplast component ofC. cryophila exhibits a cover of morphologically complex, overlapping heptagonal scales (termed rosette scales) in addition to elongate fibrils. The arrangement of IMPs within the PM is predominantly random and the inner periplast component consists of a sheet with regular pores where ejectisomes are located. The sheet does not appear closely associated with the PM. The combination of features exhibited by the periplast ofC. cryophila warrants its inclusion as a new type within theCryptophyceae.     

KATABLEPHARIS OVALIS,A COLORLESS FLAGELLATE WITH INTERESTING CYTOLOGICAL CHARACTERISTICS1

Katablepharis ovalis Skuja, isolated from an impoundment in Colorado, has a cell covering composed of two layers over the cell body and flagella. The outer component of the cell covering contains 25-nm-diameter hexagonal scales arranged in rows. The inner component of the cell covering is composed of a layer of interwoven microfibrils. The inner component of the cell covering is joined to the plasma membrane by one or more attachment strips that always occur outside, and along, one of the microtubular groups of the outer array. The attachment strips resemble hemidesmosomes and are composed of rows of electron-dense material, 12 nm apart, that protrude through the plasma membrane into the extracellular space, to attach to the inner wall. The two flagella are inserted subapically into a raised area of the cell. The flagella do not have any fibrillar or tubular hairs and are covered only by the two-layered cell covering. The cell has an inner and outer array of microtubules, both of which are spindle-shaped, arising at the anterior end of the cell and continuing into the posterior end of the cell. A single large Golgi apparatus occurs in the anterior cytoplasm. The nucleus is in the center of the cell. Two rows of large ejectisomes occur posterior to the area of flagellar attachment. Smaller ejectisomes occur under the plasma membrane in the posterior and medial areas of the cell. Each ejectisome is composed of a single body containing a spirally wound, tapered ribbon. On discharge, the ejectisome ribbon rolls inward, creating a tubular structure. The possible relationship between Katablepharis, the green algae, and the cryptophytes is discussed.     

The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants

The cytoplasmic domain of the rosette terminal complex has been imaged in situ in patches of plasma membrane isolated from tobacco BY-2 protoplasts. By partially extracting the plasma membrane lipids, cellulose microfibrils were observed through the plasma membrane. Rosette terminal complexes were identified on the basis of their association with the ends of these cellulose microfibrils. The cytoplasmic domain of the rosette terminal complex has been shown to be hexagonal in shape and has been measured to be 45-50 nm in diameter and 30-35 nm tall. These findings demonstrate that the terminal complex does indeed have a substantial cytoplasmic component, and that the hexagonal array observed in the lipid bilayer by freeze fracture is actually only a small part of the overall complex. These findings will allow better modeling of the terminal complex and may facilitate predictions of how many proteins are associated with the rosette terminal complex in vivo.     

New membrane assembly in IgE receptor-mediated exocytosis

Summary The presence of excess membrane has been observed in the secretory granules of mast cells activated via the physiological mechanism of IgE receptor-mediated exocytosis. This excess membrane is the result of ade novo assembly from phospholipid, cholesterol, and other membrane components stored in the quiescent granule. Following receptor stimulation, membrane bilayer structures of varying size and shape can be seen in the subperigranular membrane space where the perigranular membrane has lifted away from the granule matrix. Vesicles as small as 25 nm in outer diameter are frequently found beneath the perigranular membrane at the site of granule fusion. Membrane in the form of elongated vesicles, tubes, or sheets has also been observed. The wide variation in size and shape of the newly assembled membrane may reflect the spontaneity of the entropy-driven membrane generation process and the fluid characteristic of the biological membrane in general. Fusion of the newly assembled membrane with the perigranular membrane enables the activated granule to enlarge. This rapid expansion process of the perigranular membrane may be the principal mechanism by which an activated granule can achieve contact with the plasma membrane in order to generate pore formation. The fact that new membrane assembly also occurs in the IgE receptor-mediated granule exocytosis, supports our observation thatde novo membrane generation is an inherent step in the mechanism of mast cell granule exocytosis. Whether new membrane assembly is a common step in the mechanism of secretory granule exocytosis in general, must await careful reinvestigation of other secretory systems.     

Quick-freeze,deep-etch visualization of exocytosis in anterior pituitary secretory cells: localization and possible roles of actin and annexin II

The exocytotic process in the anterior pituitary secretory cells was studied using quick-freeze deep-etch electron microscopy, fluorescein-isothiocyanate-phalloidin staining, heavy meromyosin decoration, and immuno-electron microscopy. The subcortical actin filaments are distributed unevenly in the peripheral cytoplasm. Few secretory granules are seen beneath the plasma membrane in the region where the peripheral cytoplasm is occupied by numerous subcortical actin filaments. On the contrary, in the region free of the subcortical actin filaments, many secretory granules lie in contact with the plasma membrane. Thus, the subcortical actin filaments may control the approach of the secretory granules to the plasma membrane in these cells. The granule and plasma membranes that lie in close proximity are linked by intervening strands. Unfused portions of both membranes remain linked by these strands during membrane fusion and opening. These strands may be involved in membrane contact, fusion and opening during exocytosis. Annexin II (calpactin I) has been demonstrated immunocytochemically to be localized at the contact sites between the granule and plasma membranes, and is therefore a possible component of the intervening strands. Membrane fusion starts within focal regions of both membranes less than 50 nm in diameter. The plasma membrane shows inward depressions toward the underlying granules immediately before fusion. The disappearance of intramembranous particles from the exocytotic site of the membrane has not been observed.     

Ultrastructural Features of Allantosoma intestinalis,a Suctorian Ciliate Isolated from the Large Intestine of the Horse1

ABSTRACT. Allantosoma intestinalis, a suctorian ciliate isolated from the intestine of the horse, was studied utilizing light and electron optical methods. These small sausage-shaped organisms have a varying number of tentacles (between one and 12) located at each extremity of the body. The microtubular axoneme of each tentacle in cross-section consists of two files of microtubules arranged in a daisy-like configuration. Haptocysts occur in the tentacle shaft, abutted to the plasma membrane of the knob of the tentacle, and in the cell body. The haptocysts are bottle-shaped, with prominent annular striations around their midportion. The cell is covered by three membranes, an outer plasma membrane, an outer alveolar, and an inner alveolar membrane. A thin epiplasmic layer is found beneath the inner alveolar membrane, and a single row of microtubules underlies the epiplasm. The subpellicular microtubules are arranged parallel to each other forming a corset around the cell along the long axis: such a system is not characteristic of suctorians. A field of diminutive kinetosomes (each 180 nm long, max. of 15 per field), lacking cilia, was found below the cortex. The function of these prokinetosomes is unknown. A ciliated swarmer has not been observed, only the nonciliated adult. The characteristics of Allantosoma are compared with those of other suctorian genera.     

Ultrastructure of the membrane attachment sites of the extrusomes of Ciliophrys marina and Heterophrys marina (Actinopoda)

Summary The actinopods Ciliophrys marina and Heterophrys marina both have membrane bounded extrusomes attached to their cellular and axopodial membranes. The extrusomes of C. marina, the muciferous bodies, are fairly simple in structure and contain a homogeneous osmiophilic substance. Their attachment site is characterized by a rectangular array of freeze fracture particles in the cell membrane. The extrusomes of H. marina, the conicysts, are more complex and contain a two-part osmiophilic body. The attachment site of conicysts is characterized by a rosette of 8 freeze fracture particles very similar to the 9-particle rosette found at the mucocyst attachment sites in Tetrahymena. Furthermore, intracytoplasmic bridges connect the conicyst and cell membrane faces, and a specialized fibrillar structure is found on the cell membrane in the region of conicyst attachment. The various possible roles for such particle arrays are discussed and their presence in virtually all extrusomes is predicted.Supported by USPHS GM01021 and HL13849     

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.     

Cell walls,plasma membranes,and dictyosomes during zygote maturation ofClosterium ehrenbergii

Summary The cell wall formation and its correlation with the plasma membrane and dictyosome were investigated by an electron microscope in the zygote cells ofClosterium ehrenbergii. During zygote maturation, six wall layers were formed outside the plasma membrane. Wall layer III was the thickest layer and consisted of microfibril bundles. Dictyosomes produced flat vesicles during formation of wall layer III. Hexagonal arrays of rosette particles appeared in the plasma membrane in this period, thus confirming the simultaneous occurrence of flat vesicles and hexagonal particle arrays in the formation of microfibril bundles even at different stages of the life cycle. Wall layer VI was second in thickness and consisted of single microfibrils. Neither flat vesicles nor hexagonal particle arrays were observed during formation of this layer.     

Freeze-fracture images of exocytosis and endocytosis in anterior pituitary cells of rabbits and mice

Summary Freeze-fracture images of exocytosis and endocytosis were studied in various kinds of secretory cells of the anterior pituitary of mice and rabbits. Exocytotic figures are frequently observed in thin section of the anterior pituitary cells. In freeze-fracture images, small elevated membrane areas without membrane particles are often seen on the PF of the plasma membrane of the secretory cells. There is a secretory granule in the cytoplasm just beneath the particle-free membrane area, and limiting membrane of the granule is also devoid of the membrane particles at the part facing the plasma membrane. The fusion of membranes for exocytosis may occur at this particle-free area.The limiting membrane of the granule which is continuous with the plasma membrane is almost always coated after release of the granule core. This invagination of coated membrane may be an initiation site for the membrane retrieval after exocytosis. In freeze-fracture images, this depressed region with an accumulation of the membrane particles is observed on the PF of the plasma membrane. This particle-rich depressed region is thought to correspond to the coated area of the plasma membrane observed in thin section. It is thought that the membrane retrieval by pinocytosis initiates at the particle-rich depressed region of the plasma membrane.This study was supported by a grant from the Japan Ministry of Education     

Tritrichomonas foetus: Fine Structure of Freeze-Fractured Membranes1

ABSTRACT. Freeze-fracture techniques reveal differences in fine structure between the anterior three flagella of Tritrichomonas foetus and its recurrent flagellum. The anterior flagella have rosettes of 9–12 intramembranous particles on both the P and E faces. The recurrent flagellum lacks rosettes but has ribbon-like arrays of particles along the length of the flagellum, which may be involved in the flagellum's attachment to the cell body. This flagellum is attached to the membrane of the cell body along a distinct groove that contains few discernible particles. Some large intramembranous particles are visible on the P face of the cell body membrane at the point where the flagellum emerges from the cell body. The randomly distributed particles on the P and E faces of the plasma membrane have a particle density of 919/μm² and 468/μm² respectively, and there are areas on both faces that are devoid of particles. Freeze-fracture techniques also reveal numerous fenestrations in the membrane of the Golgi complex and about 24 pores per μm² in the nuclear. membrane.     

Structural organization of the "zipper line" in Drosophila species with giant spermatozoa

The "zipper line" of Drosophila melanogaster and of Drosophila species characterized by giant spermatozoa (D. hydei, D. kanekoi and D. bifurca) was studied by electron microscopy using conventional thin-sections, lectin labeling and freeze-fracture replicas. In cross sections the membrane specializations are located either at the level of the short cistern close to the large mitochondrial derivative where a small tuft of glycocalyx is visible or, in species characterized by long spermatozoa, along a cistern beneath the plasma membrane. In correspondence of such cistern, the plasma membrane exhibits a thick and extended glycocalyx. At this level, as well as at the short tuft of D. melanogaster, alpha-mannose residues were detected. The "zipper" of D. melanogaster consists of rows of intramembrane particles longitudinally disposed along the sperm tail and associated with the external face of the plasma membrane. On the protoplasmatic face a narrow ribbon of transversal grooves is visible. Freeze-fracture replicas have revealed, in the region characterized by extended glycocalyx, the presence of a large ribbon of intramembrane particles disposed in parallel transversal rows, associated with the protoplasmatic membrane face. On the complementary external face a ribbon of parallel transversal grooves was observed. It is suggested that membrane specializations are mechanical devices to protect spermatozoa from torsion and bending in the seminal vesicles and then in the female storage organ.     

An electron-microscope and freeze-fracture study of the egg cortex of Brachydanio rerio

Summary We have examined the cortex of the teleost (Brachydanio rerio) egg before and during exocytosis of cortical granules by scanning, transmission, and freeze-fracture electron microscopy. In the unactivated egg, the P-face of the plasma membrane exhibits a random distribution of intramembranous particles, showing a density of 959/m² and an average diameter of 8 nm. Particles over P- and E-faces of the membranes of cortical granules are substantially larger and display a significantly lower density. An anastomosing cortical endoplasmic reticulum forms close associations with both the plasma membrane of the egg and the membranes of cortical granules. Exocytosis begins with cortical granules pushing up beneath the plasma membrane to form domeshaped swellings, coupled with an apparent clearing of particles from the site of contact between the apposed membranes. A depression in the particle-free plasma membrane appears to mark sites of fusion and pore formation between cortical granules and plasma membranes. Profiles of exocytotic vesicles undergo a predictable sequence of morphological change, but maintain their identity in the egg surface during this transformation. Coated vesicles form at sites of cortical granule breakdown. Differences in particle density between cortical granules and egg plasma membranes persist during transformation of the exocytotic profiles. This suggests that constituents of the 2 membrane domains remain segregated and do not intermix rapidly, lending support to the view that the process of membrane retrieval is selective (i.e., cortical granule membrane is removed).     

Docking of chromaffin granules—A necessary step in exocytosis?

Putative docking of secretory vesicles comprising recognition of and attachment to future fusion sites in the plasma membrane has been investigated in chromaffin cells of the bovine adrenal medulla and in rat phaeochromocytoma (PC 12) cells. Upon permeabilization with digitonin, secretion can be stimulated in both cell types by indreasing the free Ca²⁺-concentration to M levels. Secretory activity can be elicited up to 1 hr after starting permeabilization and despite the loss of soluble cytoplasmic components indicating a stable attachment of granules to the plasma membrane awaiting the trigger for fusion. Docked granules can be observed in the electron microscope in permeabilized PC 12 cells which contain a large proportion of their granules aligned underneath the plasma membrane. The population of putatively docked granules in chromaffin cells cannot be as readily discerned due to the dispersal of granules throughout the cytoplasm. Further experiments comparing PC 12 and chromaffin cells suggest that active docking but not transport of granules can still be performed by permeabilized cells in the presence of Ca²⁺: a short (2 min) pulse of Ca²⁺ in PC 12 cells leads to the secretion of almost all releasable hormone over a 15 min observation period whereas, in chromaffin cells, with only a small proportion of granules docked, withdrawal of Ca²⁺ leads to an immediate halt in secretion. Transport of chromaffin granules from the Golgi to the plasma membrane docking sites seems to depend on a mechanism sensitive to permeabilization. This is shown by the difference in the amount of hormone released from the two permeabilized cell types, reflecting the contrast in the proportion of granules docked to the plasma membrane in PC 12 or chromaffin cells. Neither docking nor the docked state are influenced by cytochalasine B or colchicine. The permeabilized cell system is a valuable technique for thein vitro study of interaction between secretory vesicles and their target membrane.     

Genetic characterization of the secretory mutants ofParamecium caudatum

Summary Two trichocyst-nondischarge (TND) mutants ofParamecium caudatum, tndl andtnd2, are unable to discharge the trichocyst matrix (tmx) in response to chemical stimuli, although they contain many docked trichocysts at predetermined sites in the cortex. Freeze-fracture electron microscopy (FEM) of the plasma membrane showed thattndl possess two typical intramembrane particle arrays at the trichocyst docking site in the cortex, the outer ring and the inner rosette, as observed in wild-type (WT) cells, whereastnd2 possess the ring but not the rosette. The tmx of both TND mutants are able to expand when they are freed and exposed to an extracellular medium containing 1.5 mM Ca²⁺. When mutant cells were treated with ionophore A23187 and Ca²⁺, tmx-expansion took place intnd2, but not intndl cells. Thetnd2 mutant could be rescued by an injection of the WT cytoplasm and also by partial cell fusion during conjugation with the WT andtndl cells. However, the secretion capacity oftndl was not restored either by a microinjection of the WT cytoplasm or by the conjugating pair formation. Freeze-fracture electron microscopy on the double homozygote fortndl andtndl genes, revealed only the parenthesis instead of the ring and the rosette, indicating that trichocysts do not dock to the cortical site. Double mutation at thetndl andtndl loci caused a decrease in the number of the trichocysts at the cortical site. These results suggest that cooperative action of the two TND genes is necessary for stable docking of the trichocysts to the cortical sites.Abbreviations FEM freeze-fracture electron microscopy - IMP intramembrane particle - TD trichocyst discharge: tmx trichocyst matrix - TND trichocyst nondischarge - WT wild-type     

A COMPLEMENTARY FREEZE-FRACTURE STUDY OF CHRYSOCHROMULINA CHITON (HAPTOPHYCEAE)

Complementary freeze-fracture replicas and high resolution tantalum-tungsten shadowing have been used in a study of the membanes of the marine alga Chrysochromulina chiton. Membrane particle populations range from 38/100 nm² in the plastid to 2/100 nm² in the pyrenoid cap membrane. Membrane asymmetry was evident in all membranes, but was most obvious in those with higher particle numbers. In all complementary replica pairs, particles were always more numerous on protoplasmic fracture faces. Small, particle-free areas with bordering particles were also seen as recurring membrane features. Complementarity of matching fracture faces was seen for very small background granularity patterns and for large membrane components, but not for particles. Complementarity can also be seen in non-membranous fracture faces both within and external to the cell, suggesting the presence of polymeric materials in these areas that produce “particles” due to plastic deformation.     

Particle Assemblies in the Plasma Membrane of Tetrahymena: Relationship to Cell Surface Topography and Cellular Morphogenesis1

During a freeze-fracture electron microscopical study of the plasma membrane of Tetrahymena, several different types of organized particle assemblies were observed. Three of these were found only on the protoplasmic face and were localized in the anterior-ventral region of the cell. These consisted of plate-like arrays composed of 4–25 triplet rows of small 3–4 nm particles; long, paired linear arrays localized at the tops of cortical ridges and composed of 7–8 nm particles; and elongated tetragonal arrays located in the grooves between ridges and composed of approximately 10 nm particles. The distribution of these arrays is consistent with roles in cellular morphogenesis, chemoreception, or cell-cell pairing during conjugation. In addition, a unique particle track associated with the cytoproct (anal pore) was observed in the external face of the plasma membrane. Furthermore, the protoplasmic face of the plasma membrane is characterized by a high density of particles organized into localized microarrays, consisting of small paracrystals or strings, which exhibit a loose higher-order patterning most evident toward the anterior end of the cell. Particle distributions on the protoplasmic face do not appear to be significantly altered by conditions that cause clumping of alveolar membrane particles. Taken together, these observations are consistent with the idea that the proteins of the plasma membrane are highly ordered and relatively immobile and that the structure of the plasma membrane is regionally differentiated.