The fine structure of the midgut in the mite Anystis baccarum (L.) (Acari, Actinedida: Anystidae)

The ventriculus and the midgut caeca of the fed females of Anystis baccarum (L.) were investigated by using light and electron microscopy. In addition to the main type of polyfunctional digestive cells, special secretory cells were detected in the anterior region of the ventriculus. The shape and the ultrastructure of the digestive cells vary depending on their physiological state. Intracellular digestion, absorption or excretion processes prevail at different stages of the cell cycle. The secretory cells are characterized by the presence of extensive rough endoplasmic reticulum, filling whole space of the cell. These cells do not contain the apical network of pinocytotic canals, which are typical for the digestive cells. Three types of secretory granules were found in the cytoplasm of the secretory cells that probably correspond to three sequential stages of granulogenesis. The primary secretory granules are formed by the fusion of Golgi vesicles. The primary granules fuse to form complex vesicles with heterogeneous contents. These secondary granules aggregate to form very large inclusions of high electron density (tertiary secretory granules), which probably represent the storage of the secretory product. All types of secretory granules were observed close to the apical plasmalemma.     

The role of calcium in fusion of artificial vesicles.

Small phospholipid vesicles (liposomes) fuse upon calcium addition as demonstrated by electron microscopy, light absorbance increases, and mixing of original liposome contents within the boundaries of the fused liposome. The integrity of the fusion event is demonstrated by a novel assay based on the luminescence of firefly extract when mixed with ATP. Subsequent addition of valinomycin or the calcium ionophore A23187 leads to further fusion as shown by electron microscopy, light microscopy, and additional absorbance increase. Concomitant with this second absorbance increase is an increase in the amount of calcium that associates with the liposomes. This increased calcium association is more than can be accounted for by equilibration of 5 mM Ca2+ across the membrane and must indicate exposure of extra calcium binding sites. Binding of calcium to the inner side of the membrane may catalyze the second stage of liposome fusion.     

Correlative light and electron microscopy imaging of autophagy in a zebrafish infection model

High-resolution imaging of autophagy has been used intensively in cell culture studies, but so far it has been difficult to visualize this process in detail in whole animal models. In this study we present a versatile method for high-resolution imaging of microbial infection in zebrafish larvae by injecting pathogens into the tail fin. This allows visualization of autophagic compartments by light and electron microscopy, which makes it possible to correlate images acquired by the 2 techniques. Using this method we have studied the autophagy response against Mycobacterium marinum infection. We show that mycobacteria during the progress of infection are frequently associated with GFP-Lc3-positive vesicles, and that 2 types of GFP-Lc3-positive vesicles were observed. The majority of these vesicles were approximately 1 μm in size and in close vicinity of bacteria, and a smaller number of GFP-Lc3-positive vesicles was larger in size and were observed to contain bacteria. Quantitative data showed that these larger vesicles occurred significantly more in leukocytes than in other cell types, and that approximately 70% of these vesicles were positive for a lysosomal marker. Using electron microscopy, it was found that approximately 5% of intracellular bacteria were present in autophagic vacuoles and that the remaining intracellular bacteria were present in phagosomes, lysosomes, free inside the cytoplasm or occurred as large aggregates. Based on correlation of light and electron microscopy images, it was shown that GFP-Lc3-positive vesicles displayed autophagic morphology. This study provides a new approach for injection of pathogens into the tail fin, which allows combined light and electron microscopy imaging in vivo and opens new research directions for studying autophagy process related to infectious diseases.     

The fine structure of the hypertrophont of the parasitic apostome Synophrya (Ciliophora,Apostomatida)

The hypertrophont stage of the parasitic apostome ciliate Synophrya was studied by light microscopy and transmission electron microscopy. This invasive stage of the ciliate was found within the gill lamellae and gill raphes of the longspine swimming crab Portunus spinicarpus. The ciliates elicited a melanized host reaction that walled off the parasite from the host. Additionally the ciliate produced a cyst wall of ～0.16-2.0 μm in thickness that further isolated the parasite. A mouth was not observed, as the internal stage of this ciliate takes in material via endocytosis across the entire surface. The outer surface was irregular, with folds, membrane pillows, and vesicles connected to the outer membrane. The hypertrophont had a sparce ciliature, with well developed kinetodesmal fibers connecting the kinetosomes. Within the cytoplasm the cell had numerous vacuoles, lipid droplets, and large plaquettes of material. The massive reticulate macronucleus had globular and elongated chromatin bodies, and was the most distinctive organelle within the cell.     

FINE STRUCTURE CHANGES DURING FUNCTION OF THE DIGESTIVE GLAND OF VENUS'S-FLYTRAP

Changes in the structure of the digestive gland cells of Venus's-flytrap during the digestive process have been studied with light and electron microscopy. Large vacuolar lipid-protein inclusions break up and become smaller; however, they never completely disappear during the entire 7-10-day cycle. Dictyosomes in the resting digestive gland are associated with small, inconspicuous vesicles, whereas during the digestive cycle two types of prominent vesicles are observed on the peripheral tubules. Changes in plastid fine structure are complex and involve the disappearance of lipid globules and the tubular complex, followed by the formation of microtubules on the thylakoids and cisternae on the outer plastid membrane. Mitochondrial fine structure changes from the small cristae and light matrix of the resting state to large cristae and a very dense matrix representative of a change to a state where phosphorylation is tightly coupled to electron transport. Pronounced changes which occur in the cell envelope (cell wall and membrane taken together) are apparently associated with secretion of the digestive fluid. Numerous other changes are observed such as polysome formation, multivesicular body formation, mitochondria division, and changes which can be attributed in general to elevated cell activity.     

Actin is required for endocytic trafficking in the malaria parasite Plasmodium falciparum

The intra-erythrocytic stages of the malaria parasite endocytose large quantities of the surrounding erythrocyte cytoplasm and deliver it to a digestive food vacuole via endocytic vesicles. Digestion provides amino acids for parasite protein synthesis and is required to maintain the osmotic integrity of the host cell. The parasite endocytic pathway has been described morphologically by electron microscopy, but the molecular mechanisms that mediate and regulate it remain elusive. Given the involvement of actin in endocytosis in other eukaryotes, we have used actin inhibitors to assess the requirement for this protein in the endocytic pathway of the human malaria parasite, Plasmodium falciparum . Treatment of cultures with cytochalasin D did not affect haemoglobin levels in the parasites when co-administered with protease inhibitors, and neither did it affect the uptake of the endocytic tracer horseradish peroxidase, suggesting the absence of actin in the mechanism of endocytosis. However, in the absence of protease inhibitors, treated parasites contained increased levels of haemoglobin due to an accumulation of enlarged endocytic vesicles, as determined by immunofluorescence and electron microscopy, suggesting a role for actin in vesicle trafficking, possibly by mediating vesicle maturation and/or fusion to the digestive vacuole. In contrast to cytochalasin D, treatment with jasplakinolide led to an inhibition of endocytosis, an accumulation of vesicles closer to the plasma membrane and a marked concentration of actin in the parasite cortex. We propose that the stabilization of cortical actin filaments by jasplakinolide interferes with normal endocytic vesicle formation and migration from the cell periphery.     

Absorption of ferritin by cells of the digestive gland in Nassarius tegula (Gastropoda : Prosobranchia)

Within 12 min after the prosobranch snail, Nassarius, begins feeding on ferritin-labeled food, ferritin reaches the lumen of the digestive gland and is absorbed by the digestive cells lining the gland. Within the digestive cells, the ferritin is present in coated pinocytotic vesicles, in microvesicles and in macrovesicles. It is probable that ferritin (and components of the food as well) progresses rapidly in order from the gland lumen to the pinocytotic vesicles to the microvesicles to the macrovesicles. The macro vesicles are presumably an important site of intracellular digestion.     

Correlative light and electron microscopy imaging of autophagy in a zebrafish infection model

High-resolution imaging of autophagy has been used intensively in cell culture studies, but so far it has been difficult to visualize this process in detail in whole animal models. In this study we present a versatile method for high-resolution imaging of microbial infection in zebrafish larvae by injecting pathogens into the tail fin. This allows visualization of autophagic compartments by light and electron microscopy, which makes it possible to correlate images acquired by the 2 techniques. Using this method we have studied the autophagy response against Mycobacterium marinum infection. We show that mycobacteria during the progress of infection are frequently associated with GFP-Lc3-positive vesicles, and that 2 types of GFP-Lc3-positive vesicles were observed. The majority of these vesicles were approximately 1 μm in size and in close vicinity of bacteria, and a smaller number of GFP-Lc3-positive vesicles was larger in size and were observed to contain bacteria. Quantitative data showed that these larger vesicles occurred significantly more in leukocytes than in other cell types, and that approximately 70% of these vesicles were positive for a lysosomal marker. Using electron microscopy, it was found that approximately 5% of intracellular bacteria were present in autophagic vacuoles and that the remaining intracellular bacteria were present in phagosomes, lysosomes, free inside the cytoplasm or occurred as large aggregates. Based on correlation of light and electron microscopy images, it was shown that GFP-Lc3-positive vesicles displayed autophagic morphology. This study provides a new approach for injection of pathogens into the tail fin, which allows combined light and electron microscopy imaging in vivo and opens new research directions for studying autophagy process related to infectious diseases.     

The digestive gland of Viviparus ater (Mollusca, Gastropoda, Prosobranchia): an ultrastructural and histochemical study

The digestive gland of Viviparus ater was studied using histochemical and ultrastructural methods. Only one cell type was observed in the tubule epithelium of the gland. The cells are involved in an endocytotic process mediated by clathrin-coated vesicles and in the intracellular digestion of food materials (thus they can be regarded as digestive cells). The different stages of digestion and exocytotic extrusion of residual bodies into the tubule lumen were shown by electron microscopy. Very few, small mucocytes are scattered among the digestive cells. Calcium concretions, glycogen-containing cells and endocrine cells are scattered in the area of connective tissue present among the digestive tubules.     

Genetic Analysis of Myoblast Fusion: blown fuse Is Required for Progression Beyond the Prefusion Complex

The events of myoblast fusion in Drosophila are dissected here by combining genetic analysis with light and electron microscopy. We describe a new and essential intermediate step in the process, the formation of a prefusion complex consisting of “paired vesicles.” These pairs of vesicles from different cells align with each other across apposed plasma membranes. This prefusion complex resolves into dense membrane plaques between apposed cells; these cells then establish cytoplasmic continuity by fusion of small areas of plasma membrane followed by vesiculation of apposed membranes. Different steps in this process are specifically blocked by mutations in four genes required for myoblast fusion. One of these genes, blown fuse, encodes a novel cytoplasmic protein expressed in unfused myoblasts that is essential for progression beyond the prefusion complex stage.     

FOOD VACUOLE MEMBRANE GROWTH WITH MICROTUBULE-ASSOCIATED MEMBRANE TRANSPORT IN PARAMECIUM

Evidence from a morphological study of the oral apparatus of Paramecium caudatum using electron microscope techniques have shown the existence of an elaborate structural system which is apparently designed to recycle digestive-vacuole membrane. Disk-shaped vesicles are filtered out of the cytoplasm by a group of microtubular ribbons. The vesicles, after being transported to the cytostome-cytopharynx region in association with these ribbons, accumulate next to the cytopharynx before they become fused with the cytopharyngeal membrane. This fusion allows the nascent food vacuole to grow and increase its membrane surface area. The morphology of this cytostome-cytopharynx region is described in detail and illustrated with a three-dimensional drawing of a portion of this region and a clay sculpture of the oral apparatus of Paramecium. Evidence from the literature for the transformation of food vacuole membrane into disk-shaped vesicles both from condensing food vacuoles in the endoplasm and from egested food vacuoles at the cytoproct is presented. This transformation would complete a system of digestive vacuole membrane recycling.     

Fusion and fragmentation of phospholipid vesicles by apohemoglobin at low pH.

Human apohemoglobin in acidic media was found to induce fusion of phosphatidylcholine/phosphatidylserine (1:1) vesicles at low protein concentration but to fragment the same vesicles to form micellar complex at high protein concentration. The fusion was demonstrated by size increase, vesicle content mixing, lipid mixing, and electron microscopy. The micellization of phospholipid vesicles was observed by light scattering, gel filtration, and electron microscopy. The hydrophobic labeling of the apohemoglobin/vesicle complex followed by CNBr cleavage of apohemoglobin showed that an N-terminal segment of the beta subunit with a molecular weight of approximately 6,000 seems to be mainly involved in the fusion process, but the whole sequences of both alpha and beta chains participate in the micellization process.     

Preparation and characterization of F-protein vesicles isolated from Sendai virus by means of octyl glucoside

We have demonstrated that Triton X-100 is always present in F-protein vesicles at concentrations that can provoke cell lysis. In order to avoid any misinterpretation of the fusogenic capacity of this protein, we solubilized the Sendai virus using octyl glucoside, which can be totally removed from the F protein preparation in less than 16 h by dialysis in the presence of absorbent beads. F-glycoprotein preparations preserved their ability to lyse erythrocytes in the presence of lectins and to induce cell-vesicle fusion as demonstrated by ESR studies. These vesicles were characterized by electron microscopy and SDS-polyacrylamide gel electrophoresis. Lipid analysis of these preparations by thin-layer chromatography indicated that they had the same proportion of lipids as virus envelopes, with slight variations in the sphingomyelin content and the cholesterol/phospholipid molar ratio. F-protein vesicles of different sizes can be obtained by adding exogenous lipids before detergent removal. The hemolytic activity of the vesicles was retained over a large range of lipid concentrations. We conclude that F-protein vesicles prepared with octyl glucoside are convenient tools for studying the fusogenic mechanism of this protein and improving the fusion process between liposomes and cells.     

Anatomy and ultrastructure of the salivary gland in the thorax of the honeybee worker,Apis mellifera (Insecta,Hymenoptera)

Summary The thoracic salivary gland of the worker honeybee was investigated by dissection, light microscopy, scanning electron microscopy, and transmission electron microscopy. The glands are paired and each lateral half consists of two parts, a smaller external and a larger internal lobe. The lobes are composed of densely packed secretory tubes and ducts, the tubes of which often show ramifications. A reservoir is packed within the anterior medial part of the gland. The secretory tubes are composed of two types of cells, secretory cells, which are most frequent, and parietal cells. Secretory cells are characterized by a basal labyrinth, abundant rough endoplasmic reticulum, dark secretory vesicles, light vesicles of different sizes, and apical microvilli. Parietal cells are smaller and have a characteristically lobed nucleus and no secretory vesicles. Between the cells there are intercellular canaliculi. In the center of each tube there is an extracellular space with a central cuticular channel. The abundance of rough endoplasmic reticulum and the rare occurrence of smooth endoplasmic reticulum implies a saliva with proteins but rarely with pheromones. Between the secretory tubes there are frequently neuronal profiles which are partly in contact with the secretory cells. Thus a nervous control of this gland is, in contrast to previous investigations, clearly demonstrated. The axonal endings contain dark neurosecretory vesicles as well as light synaptic vesicles. Large parts of the glands are surrounded by a thin tissue sheath which has a smooth surface towards the secretory tubes and shows irregular protrusions towards the outer side. This sheath is considered to be a tracheal air sac, and due to its large extension is probably of importance for the hemolymph flow in the thorax.     

Reaction characteristics and mechanisms of lipid bilayer vesicle fusion

Small unilamellar lipid bilayer vesicles were prepared from brain phosphatidylserine, egg phosphatidylcholine, and synthetic dipalmitoylphosphatidylcholine, and were fused into larger structures by freezing and thawing, addition of calcium chloride, and passage through the lipid phase transition temperature. Fusion reactions were studied by electron microscopy, light scattering, and use of fluorescent probes. Fusion was accompanied by leakage of lipid vesicle constituents and of water-soluble solutes in the inner vesicle compartments, and by uptake of these types of components from the external solution. Such leakage was greater during fusion by freezing than by Ca²⁺. Passage through the transition temperature produced a moderate degree of fusion, without loss of membrane components. It is concluded that each fusion method gives rise to a characteristic size or narrow range of sizes of fusion products. The fraction of small vesicles fused into larger structure depends on the method of vesicle preparation, composition of the lipid bilayer, and composition of the external solution. Fusion is induced by creation of a discontinuity in the bilayer or by removal of water associated with the bilayer. The amount of water removed controls the extent of fusion. This is maximized in bilayers when in the liquid-crystal phase, as against the gel phase, in vesicles made by ethanol injection, as against sonication, and in charged bilayers, as against neutral ones.     

Structure and behavior of contractile vacuoles inChlamydomonas reinhardtii

Summary The contractile vacuole (CV) cycle ofChlamydomonas reinhardtii has been investigated by videomicroscopy and electron microscopy. Correlation of the two kinds of observation indicates that the total cycle (15 s under the hypo-osmotic conditions used for videomicroscopy) can be divided into early, middle, and late stages. In the early stage (early diastole, about 3 s long) numerous small vesicles about 70–120 nm in diameter are present. In the middle stage (mid-diastole, about 6 s long), the vesicles appear to fuse with one another to form the contractile vacuole proper. In the late stage (late diastole, also about 6 s long), the CV increases in diameter by the continued fusion of small vesicles with the vacuole, and makes contact with the plasma membrane. The CV then rapidly decreases in size (systole, about 0.2 s). In isosmotic media, CVs do not appear to be functioning; under these conditions, the CV regions contain numerous small vesicles typical of the earliest stage of diastole. Fine structure observations have provided no evidence for a two-component CV system such as has been observed in some other cell types. Electron microscopy of cryofixed and freeze-substituted cells suggests that the irregularity of the profiles of larger vesicles and vacuoles and some other morphological details seen in conventionally fixed cells may be shrinkage artefacts. This study thus defines some of the membrane events in the normal contractile vacuole cycle ofChlamydomonas, and provides a morphological and temporal basis for the study of membrane fusion and fluid transport across membranes in a cell favorable for genetic analysis.Abbrevations CV contractile vacuole - PM plasma membrane     

Adhesion of bacteria to epithelial cell surfaces within the reticulo-rumen of cattle.

Blocks of tissue were removed from various locations in the bovine digestive tract and fixed and processed for transmission and scanning electron microscopy by techniques that retained adherent bacteria. The distribution of bacteria on the surface of epithelial cells was examined by scanning electron microscopy. This showed intermittent colonization of the epithelia with the formation of occasional microcolonies of morphologically similar bacterial cells. Transmission electron microscopy of ruthenium red-stained material showed the presence of both the glycocalyx of the bovine epithelial cells and fibrous carbohydrate coats surrounding adherent bacteria. The carbohydrate coats appeared to mediate the attachment of bacteria to the epithelium, to food particles, and to each other so that microcolonies were formed. Careful examination of the bacterial colonization of keratinized cells in the process of being sloughed from the surface of the stratified squamous epithelium of the rumen showed that these dead cells were digested by adherent bacteria of a limited number of morphological types. The spatial relationship of this mixed, adherent, microbial population to living and dead epithelial cells and to food particles indicates that digestive processes of some importance may be accomplished by this stationary component of the microbial flora of the digestive tract.     

Adhesion of bacteria to epithelial cell surfaces within the reticulo-rumen of cattle

Blocks of tissue were removed from various locations in the bovine digestive tract and fixed and processed for transmission and scanning electron microscopy by techniques that retained adherent bacteria. The distribution of bacteria on the surface of epithelial cells was examined by scanning electron microscopy. This showed intermittent colonization of the epithelia with the formation of occasional microcolonies of morphologically similar bacterial cells. Transmission electron microscopy of ruthenium red-stained material showed the presence of both the glycocalyx of the bovine epithelial cells and fibrous carbohydrate coats surrounding adherent bacteria. The carbohydrate coats appeared to mediate the attachment of bacteria to the epithelium, to food particles, and to each other so that microcolonies were formed. Careful examination of the bacterial colonization of keratinized cells in the process of being sloughed from the surface of the stratified squamous epithelium of the rumen showed that these dead cells were digested by adherent bacteria of a limited number of morphological types. The spatial relationship of this mixed, adherent, microbial population to living and dead epithelial cells and to food particles indicates that digestive processes of some importance may be accomplished by this stationary component of the microbial flora of the digestive tract.     

Digestive system membranes: freeze-fracture evidence for differentiation and flow in Paramecium

Freeze-fractured membranes of digestive vacuoles of randomly feeding Paramecium caudatum exhibit dramatic differences in intramembrane particle (IMP) number and distribution on both E- and P-fracture faces. By pulse-feeding latex spheres to cells we have demonstrated that these differences are related to the age of the digestive vacuoles, and that the membranes of such vacuoles undergo a specific sequence of changes during the digestive cycle. Young digestive vacuoles (DV-I; less than or equal to 6 min), nascent vacuoles still connected to the cytopharynx, and discoidal vesicles, from which vacuole membrane is derived, all have a highly particulate E face and a less particulate P face. As early as 3 min after feeding, a second category of digestive vacuoles (DV-II) can be recognized, which are both considerably smaller in diameter and lack particles on their E face. These findings suggest that the endocytic removal of DV-I membrane material associated with the formation of DV-II vacuoles involves a concomitant and selective removal of E-face particles, as essentially no changes are seen in the density of P-face particles on the two types of vacuoles. Beginning at 10 min the first DV-III vacuoles are encountered. These are both larger than the DV-II vacuoles and possess very prominent E-face particles, which resemble those on the E face of the numerous lysosomes bordering the digestive vacuoles. DV-III vacuoles also exhibit a substantial increase in P-face particles. These membrane changes closely parallel, and are probably correlated with, the physiological events occurring within the vacuole lumen: concentration of food, killing of prey, and digestion. Calculations of the amount of membrane removed from DV-I to form DV-II and of the increase in membrane surface area during the transition from DV-II to DV-III indicate that as much as 90% of the initial phagosome (DV-I) membrane can be removed before digestion begins. The enlargment of DV-II must be caused by fusion with adjacent lysosomes which also contribute the new populations of IMPs to the DV- III membrane. The appearance of numerous endocytic structures on older DV-III vacuoles suggests that membrane is retrieved from DV-III before defecation.     

A kinetic and structural study of two-step aggregation and fusion of neutral phospholipid vesicles promoted by serum albumin at low pH

The addition of bovine serum albumin (BSA) to 25 ± 5 nm diameter single bilayer phosphatidylcholine (PC) vesicles (SBV) (pH 3.5) gives rise to readily visible transient turbidity. Studies of this system, employing a series of techniques, including time-dependent turbidity changes, membrane filtration, centrifugation, Sepharose chromatography and freeze fracture electron microscopy demonstrated that the process involves aggregation and fusion of the vesicles. At least three distinct time-dependent steps have been characterized: (1) the rapid initial formation (in approx. 5 min) of large aggregates (responsible for the visible turbidity) composed of SBV interconnected by BSA in its F form. The formation of these aggregates may be reversed by raising the pH or adding excess BSA to the system at this stage; (2) spontaneous collapse of these large aggregates, in an irreversible step, to form a heterogeneous population of vesicles; (3) fusion produces as the final product of the process, a relatively homogeneous population of larger (50 ± 10 nm diameter) vesicles. This system serves as a convenient and simple model system for the detailed study of protein-mediated aggregation and fusion of membranes at the molecular level.