Fine structure of the mesosome and nucleoid in frozen-etchedBacillus subtilis

Summary An electron microscopical investigation ofBacillus subtilis prepared by freeze-etching revealed the fine structural changes that occur in the cell prior to spore formation. The initiation of growth from lyophilized cells was characterized by the appearance of numerous vesicular structures embedded in and attached to the plasma membrane. As growth continued, the number of vesicular structures decreased and lamellar membrane structures began to appear. Prior to spore formation, a fine, fibrillar material was found in the central portion of the cell and was believed to be the DNA.     

Calcium containing particles in mitochondria of heart muscle cells as shown by cryo-ultramicrotomy and X-ray microanalysis

Summary Mitochondria of normal myocardial cells of the sand rat and the mouse as well as of the left ventricle of man, have been examined for their content of calcium. Ultrahistochemistry and X-ray microanalysis revealed two basically different inclusions: Osmiophilic mitochondrial granules and Spherical mitochondrial particles. Osmiophilic mitochondrial granules were found in conventionally fixed and plastic embedded tissues as well as in cryosections of chemically fixed and sucrose infused tissues. Such granules lacked inert electron density and probably consisted mainly of unsaturated lipids. X-ray spectra obtained from these tissues revealed no peaks for calcium. Spherical mitochondrial particles were present in dry-cut cryo-sections of N₂-frozen tissues not treated by fixatives and/or cryoprotectants. These particles were deeply electron dense in unstained, freeze-dried cryo-sections. They usually measured from 600Å–900Å in diameter in the normal myocardium of the sand rat and the mouse and from 250 Å–400Å in diameter in the left ventricular myocardium of man. Significant calcium peaks could be identified in the X-ray spectra of these particles, whereas none occurred in the analyses of other tissue regions. Potassium was detected with about equal frequency in the particles and in other parts of the tissue. On the basis of the inert electron density of the particles and their absence in chemically fixed tissues as well as of the results of the X-ray analysis, it is concluded that they contain precipitates of extremely labile ions of mitochondrial calcium.We should like to thank Mrs. Trine Jensen for skillful technical assistance. This work was supported by grants from The Norwegian Council on Cardiovascular Disease and from the Norwegian Research Council for Science and the Humanities     

Electron microscopy of the cell envelope of Ferrobacillus ferrooxidans prepared by freeze-etching and chemical fixation techniques

Remsen, C. C. (Swiss Federation Institute of Technology, Zurich, Switzerland), and D. G. Lundgren. Electron microscopy of the cell envelope of Ferrobacillus ferrooxidans prepared by freeze-etching and chemical fixation techniques. J. Bacteriol. 92:1765-1771. 1966.-A comparison was made of the fine structure of the cell envelope of the gram-negative bacterium Ferrobacillus ferrooxidans when cells were prepared for microscopy by freeze-etching and chemical fixation techniques. Cell envelopes of chemically fixed cells appeared as five separate layers distinguishable by their location and electron density. Frozen-etched cells showed a three-layered complex with each layer measuring approximately 100 A in thickness. The latter technique is considered to be "artifact-free" and, as a technique, yields purely morphological information on the natural state. The three layers revealed by freeze-etching are: the outer layer, a lipoprotein-lipopolysaccharide layer; the middle layer, a layer composed of globular protein attached to fibrillar mucopeptide; and the innermost layer, the cytoplasmic membrane. The latter was covered with 100 to 120 A particles. The relationship of the aforementioned layers to those seen in chemically fixed cells is discussed.     

The fine structure of the pellicle ofEuglena gracilis as revealed by freeze-etching

Summary The ultrastructure of the pellicle ofEuglena gracilis (Klebs) Z strain was studied using the freeze-etching technique and the results were correlated with data obtained from thin sections of fixed material.Examination of freeze-etched pellicles reveals an outer particulate layer and an inner striated layer. The particles of the outer layer measure approximately 150 Å in diameter. The striations of the inner layer are about 50 Å wide and are separated from each other by about 35 Å. A broad repeating pattern is also visible with a periodicity of about 450 Å. When deep etching is employed, a smooth outer layer is seen covering the particulate layer. This is probably the outer surface of the plasma membrane. Mucilage is present on the outer surface of the cell and is seen as a substructure of threads superposed on the smooth layer of plasma membrane.Thin sectioning also shows a striated layer interior to the plasma membrane. This appears to be identical to the striated layer seen after freeze-etching.     

FINE STRUCTURE IN FROZEN-ETCHED YEAST CELLS

The freeze-etching technique, which is a special kind of freeze-drying, allows electron microscopic investigation of cells and tissues in the frozen state. In regard to yeast cells (Saccharomyces cerevisiae) a freeze-fixation technique has been developed which does not kill the object. The electron micrographs therefore are considered to impart an image of high fidelity. The cutting of the frozen object, which actually consists of a fine splintering, produces not only cross-sectional views (cross-fractures) of the structures but also surface views of the membranes and organelles. Many surface structures are described which have not been shown by the usual sectioning techniques. The cytoplasmic membrane contains hexagonal arrangements of particles which are apparently involved in the production of the glucan fibrils of the cell wall. Alterations of the distribution of nuclear pores are shown in cells of different ages. Freeze-etching enables a clear distinction of endoplasmic reticulum and vacuoles in yeast cells. The membranes of the vesicular systems are covered by ribosomes arranged in circular patterns. The mitochondrial envelope shows small perforations which could allow the exchange of macromolecules. The storage granules consist of concentric layers of lipid, presumably phosphatide. A Golgi apparatus has been detected which may be involved in the storage of lipid. The structure of the unit membrane and the membrane structures of all organelles as revealed by chemical fixation are confirmed in principle. Glycogen agglomerations are identified in the ground plasm of older cells. Insight into artifacts introduced by common chemical fixation and embedding techniques is obtained and discussed.     

Ultrastructural pathology of the compound eye and optic neuropiles of the retinal degeneration mutant (w rdgB KS222) Drosophila melanogaster

Summary Lanthanum, applied to the outside of the fixed sciatic nerve of Rana pipiens, did not enter the endoneurium, but was halted by functionally tight junctions at the inner layers of the perineurium. This component of the bloodnerve barrier consists of several concentric layers of cells interspersed with an extracellular matrix of amorphous ground substance, collagen fibrils, and fine filaments. Numerous vesicular profiles are closely associated with the surface membranes of all the cells. The application of lanthanum to fixed tissue revealed that these profiles are attached to the cell surface by narrow necks, and open to the extracellular space. The attenuated cells are filled by the vesicular structures, which often appear to overlap. Stereoscopic electron microscopy showed that these vesicles did not fuse with each other or with the apposing cell surface to form transcellular channels. Channel formation does not appear to contribute significantly to the permeability of any of the perineurial layers.     

Periplasmic Structure of Frozen-Etched and Negatively Stained Cells of Bacillus licheniformis as Correlated with Penicillinase Formation

Bacillus licheniformis strain 749/C (constitutive for penicillinase formation) and uninduced cells of strain 749 (penicillinase-inducible) were examined after freezeetching. In the early stationary phase, strain 749/C organisms had clusters of vesicles (30 to 40 nm in diameter) on the outer surface of the plasma membrane. These are randomly distributed on the membrane, including the region of septum formation. The vesicles are not intimately associated with the plasma membrane, and their inner and outer surfaces are devoid of particles. Periplasmic vesicles were not detected by freeze-etching in strain 749 (uninduced) or in young cells of 749/C; however, the membrane of mid-logarithmic phase 749/C cells had a corrugated appearance. Negatively stained 749/C cells (logarithmic phase) also showed many vesicular and tubular bodies in the periplasm as well as septal and cytoplasmic mesosomes of typical morphology. The periplasmic structures appear to be formed either by evagination of plasma membrane or by migration of vesicular bodies from the membranous pockets of the cytoplasm. Stationary phase cells of 749/C still have many periplasmic vesicular bodies; however, the mesosomes are greatly reduced both in number and size. In sharp contrast, strain 749 organisms have very few structures similar to the periplasmic bodies of strain 749/C. These findings support our previous view that penicillinase-producing cells of 749/C have periplasmic membranous structures that are rare in the uninduced strain 749, though there is some lack of correspondence between freeze-etching, negative staining, and thin section data. These structures may be important for the retention or storage of penicillinase in the cell.     

Electron microscopic observations on synapse-like contacts between pituicytes and different types of nerve fibers in the anuran pars nervosa

Summary Pituicytes of Rana pipiens could be classified into two types, pale and dense, according to their relative densities of cytoplasm and the populations of free ribosomes and cell organelles. An intermediate type of pituicyte was also recognized.Lipid droplet such as are typical in the cytoplasm of mammalian pituicytes, are not in the cytoplasm of either types of frog pituicyte. Both types have long cytoplasmic processes which run among the nerve fibers, and some of them end at the pericapillary space.Nerve endings making synapse-like contacts with the cell bodies or the processes of the pituicyte are frequent. According to the structures and sizes of granules and vesicles in the nerve endings, these endings are classified into one of three types: 1) A, which appears to be a peptidergic neuronal ending containing dense granules 1,200–2,000 Å in diameter and small clear vesicles 300–400 Å in diameter; 2) B, which appear to be monoaminergic endings containing cored vesicles 600–1,000 Å in diameter and small clear vesicles 300–500 Å in diameter; 3) C, which appear to be cholinergic endings containing only small clear vesicles. Type C endings are relatively rare. In the synaptic area the axonal membranes appose those of the pituicytes across a gap of about 200 Å and numerous presynaptic vesicles are clustered or accumulated near the presynaptic membranes.The author wish to express his hearty thanks Professor Dr. A. Gorbman, Zoology Department, University of Washington, Seattle, U.S.A. and Professor Dr. H. Fujita for their helpful advices and criticisms. The frog tissues were obtained and fixed in Professor A. Gorbman's laboratory supported by U.S.P.H.S. grant NS 04887.     

The structure and formation of the test ofPyura stolonifera (Tunicata)

Summary Previous X-ray diffraction studies have established the crystallographic identity of tunicin with cellulose from plant cell walls. Enzymatic degradation of the tunicin results in the isolation of microfibrils 120–130 Å in width (which appear to consist of two sub-units). Using staining and freeze-etching techniques it has been demonstrated that the microfibrils occur in the test as aggregates measuring 2000–4000 Å in diameter. In this respect the physical texture of the cellulose ofPyura resembles that of collagen in animal connective tissue and does not resemble the texture of cellulose in either the primary or secondary cell walls of plants.Examination of fixed and frozen etched specimens showed that ferrocytes of the test and vesicles derived from them are closely associated with the cellulose microfibril bundles. However, at the optical level, autoradiographs of animals treated with C¹⁴ glucose showed greatest radioactivity to be in the epidermal cells of the mantle and of the blood vessels, but not in the ferrocytes. These cells also showed a considerable development of rough ER and of Golgi bodies. On the evidence obtained it is considered that the sites of cellulose synthesis are the epidermal cells of the mantle and of the blood vessels. The function of the test cells is unknown. The migration of ferrocytes to areas of wounding in the test suggests that they may have some lytic function associated with wound repair.     

Electron microscopy of the tracheal ciliated mucosa in rat

Summary The structure of the tracheal epithelial cells from rat has been studied by electron microscopy on approximately 200 Å thick sections with a resolution of better than 30 Å.The epithelium is found to be of a simple columnar type composed of ciliated cells, mucus producing (goblet) cells, basal cells and a fourth kind of cell, here called brush cell. A great number of non-ciliated cells has also been encountered. It has been proved that these represent goblet cells in different stages of intracellular synthesis of mucous granules. The ciliated cells have approximately 8–9 cilia per square micron and there are about 270 cilia on each cell, the calculated surface area being 33 square microns. They are covered by a 70 Å thick membrane. The ciliary filaments are arranged in a pattern of 2 separate ones in the center and a ring of 9 peripheral ones, each divided into 2 subfilaments by a wall with same thickness as the filamentous wall itself, this being 60 Å. The peripheral filaments are continuous with the basal corpuscles. The structure of the corpuscles as compared with earlier findings is discussed. A number of 0.05 micron thick and 1 micron long filiform projections emerge from the cell surface. No cuticle is present.The cell membrane facing adjacent cells is 90 Å and separated from their cell membrane by a 105 Å wide space, this space, being expanded towards a level corresponding to the proximal parts of the cell. A structure that represents terminal bar has been encountered. The cytoplasm is loose and composed of 160 Å thick granules. Spaces enclosed by 50 Å thick membranes with attached 160 Å thick granules (-cytomembranes) are rare. The Golgi zone is analyzed and its regular composition of -cytomembranes, granules and vacuoles is confirmed. The mitochondria with a mean width of 0.23 micron differ to their inner structure from the common type in that the triple layered membranes are highly interconnected. Large opaque granules are encountered in the cytoplasm. Ring-shaped, 850 Å wide, structures are present in the nuclear membrane. The goblet cells are not as abundant as the ciliated cells, the ratio being 14. Small filiform projections covered by a 95 Å thick membrane protrude from the cell surface. This membrane is continuous with the cell membrane, the latter with the same dimensions as in the ciliated cells. Terminal bars are present. The cytoplasm is very opaque due to a dense packing of the 165 Å opaque granules, many in clusters of 4–6. The -cytomembranes have the same dimensions as mentioned above for those present in the ciliated cells. The Golgi zone is of regular composition. There is a suggestion that the Golgi vacuoles and the -cytomembranes are involved in the formation of mucus. In the stage of cellular activity with but few mucous granules, there is a great number of large opaque granules, the size varying from 0.4–1 micron. The mitochondria with a mean width of 0.23 micron have an outer triple layered membrane with a total thickness of 180 Å. The central less opaque layer is 70 Å and the opaque layer on either side is 55 Å. The inner membranes are arranged parallel to each other and have a triple layered composition where the central less opaque layer is 65 Å and the opaque layers each 60 Å. The brush cells belong to the non-ciliated cells. They are encountered singly, surrounded by goblet cells. The surface structures are shaped like brushes or clumsy protrusions which emerge from the distal end of the cell, and are covered by a 95 Å thick membrane. There have been no suggestions of the brushes being cilia in a stage of growth, nor is it probable that they represent stereocilia. They most nearly resemble the intestinal brush border extensions and thus might serve as a resorbing structure.The cytoplasm of the brush cells appears of medium opacity between the ciliated cells and goblet cells and is composed of 155 Å opaque granules. The -cytomembranes are very rare. The Golgi zone is diminutive though of regular composition. The mitochondria are abundant and small with a mean width of 0.14 micron. The outer and inner membranes are triple layered with approximately the same dimensions as reported for the mitochondria of the ciliated and goblet cells. The inner membranes are very few, often only one or two are present. Some of the large opaque granules have inside a very regular arrangement of small 60 Å thick opaque granules arranged in a crystallinic pattern. In the cytoplasm 0.5–1 micron long bundles of 30–40 Å wide fibrils are encountered. The nucleolus shows a characteristic structure of concentrically arranged thin membranes. The basal cells are believed to represent lymphocytes or white blood cells. They sometimes rest on the basement membrane, sometimes are encountered in the distal part of the intercellular spaces. They are bordered by a 110 Å thick cell membrane and have a rather opaque cytoplasm characterized by 160 Å thick opaque granules. A very small Golgi zone is present. The mitochondria, the mean width being 0.14 micron, have triple layered outer and inner membranes, where the less opaque central layer is 65–70 Å and the opaque layers 45–50 Å each. The basement membrane has a thickness of 600 Å. No inner structure has been resolved. The basement membrane is separated from adjacent parts of the ciliated, goblet, brush, and basal cells by a 250 Å wide less opaque space. Below the basement membrane is the lamina propria of the trachea, which is composed of collagen and elastin fibers together with fibroblasts, white blood cells and lymphocytes. The relationship between different types of tracheal epithelial cells in rat has been analyzed. There has been found no indication of a transformation of any type of cells observed into a different type of cell. The development of basal cells via supporting cells or intermediate cells to goblet cells or ciliated cells has not been noticed. On the contrary, all cells that in light microscopy could have been considered to be supporting or intermediate cells, we have been able to recognize as brush cells or as goblet cells to a varying degree filled with mucous granules. If the cells did not seem to reach the cell surface it has been found to be due to a diagonal direction of the sectioning. In this connection it should be emphasized that this relationship is valid only in rat where it is known that the epithelium is of a simple columnar type as distinct from the conditions in man, that epithelium being of a pseudostratified columnar type.This paper is based on a report given at the meeting of Deutsche Gesellschaft für Elektronenmikroskopie in Münster, March 28–31, 1955 and at the Scandinavian Electron Microscope Society Meeting in Stockholm, May 13, 1955.     

Ultrastructural analysis of milk fat globule membranes of colostrum and human milk

Lacteous fat globules with their membranes from human milk and calostrum were studied by scanning and transmission electron microscopy. The first appear as spheroidal structures with some irregularities on the surface. Under the transmission electron microscope these irregularities are composed of islets from a material morphologically similar to cytoplasm, and with structures that resemble a fragment of rugose endoplasmic reticulum. The membranes in specimens fixed immediately after secretion are tri-layered, similar in appearance to those of a single membrane, but in samples fixed between two and four hours after secretion the details are unclear. Through freeze-etching, the laminar aspect of the fat globules is observed.     

Gap junctions in spermatocyte cysts of Drosophila hydei testis

Gap junctions between cyst cells and adjacent spermatocytes have been found in Drosophila hydei by means of the freeze-etching technique. The existence of these cellular junctions suggests that these structures could serve to exchange information between the two types of cells.     

Vesicle and granule content of sympathetic ganglion cells during limb regeneration of the newt Triturus

Summary Fine structural observations were made on the vesicle and granule content of ganglion cells in the posterior subclavian ganglion and peripheral nerve fibers of the upper forelimb of the newt Triturus. The populations of vesicles and granules in normal ganglion cells and nerve fibers were compared with those observed after limb transection. In normal neurons, clear vesicles range in size from 250 to 1000 Å in diameter, but are most frequently 400–500 Å. Vesicles with dense contents (granules) also vary greatly in size, but most are 450–550 Å in diameter and correspond to dense-core vesicles. Large granules that contain acid phosphatase activity are thought to be lysosomes. During limb regeneration, in both the ganglion cells and peripheral nerves, the ratio of dense vesicles to clear vesicles increases. There is a large increase in number of dense granules with a diameter over 800 Å, particularly in the peripheral regenerating fibers. This study shows that regenerating neurons differ from normal in their content of vesicular structures, especially large, membrane-bounded granules.This work was supported by grants from the National Science Foundation (GB 7912) and from the National Cancer Institute (TICA-5055), National Institutes of Health, United States Public Health Service.     

Die Feinstruktur der Zellwand und Cytoplasmamembran von Clostridium nigrificans,dargestellt mit Hilfe der Gefrierätz- und Ultradünnschnittechnik

Zusammenfassung Der mit Hilfe der Gefrierätztechnik dargestellte Feinbau der Zellwand und Cytoplasmamembran von Clostridium nigrificans wurde mit den Ergebnissen der chemischen Fixation verglichen. Die Zellwand von chemisch fixierten Zellen zeigt einen Aufbau aus drei stark und zwei schwach elektronenstreuenden Schichten, wobei die innerste, der Cytoplasmamembran angrenzende Schicht nicht immer darstellbar ist. Die Cytoplasmamembran hat eine asymmetrische Elementarmembran-Struktur. Mit Hilfe der Gefrierätztechnik konnte die Zellwand in drei Schichten aufgespalten werden: Einer äußeren aus globulären, rechtwinkelig geordneten, etwa 9 nm messenden Partikeln aufgebauten Schicht und zwei darunter liegenden, 15 und 5 nm dicken Schichten. Die Cytoplasmamembran wird in jungen Kulturen vollkommen, in alten teilweise mit 5–15 nm großen Teilchen bedeckt. An Stellen wo die Teilchen abgespalten wurden oder entsprechend locker angeordnet waren, konnte die Oberfläche der Cytoplasmamembran sichtbar gemacht werden. Sie ist sowohl auf der der Zellwand als auch auf der dem Cytoplasma zugekehrten Seite mit systemlos verteilten, scheinbar verschieden tief eingebetteten Teilchen bedeckt.

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The fine structure of the cell wall and cytoplasmic membrane of Clostridium nigrificans demonstrated by means of freeze-etching and chemical fixation techniques

Summary A comparison was made between the results obtained using the freeze-etching technique in demonstrating the fine structure of the cell wall and the cytoplasmic membrane of Clostridium nigrificans with those using the chemical fixation technique. In chemically fixed cells, the cell wall appears to consist of three dense layers separated by two layers of low electron scattering power, whereby it is not always possible to observe that layer immediately bordering on the cytoplasmic membrane. The cytoplasmic membrane has an asymmetrical unit membrane structure. It was possible, to separate the cell wall in three distinct layers using the freeze-etching technique. The outermost is composed of globular, rectangularly arranged particles, approximataly 9 nm in size, the two inner layers are 15 and 5 nm wide respectively. The cytoplasmic membrane is covered with particles 5 to 15 nm in size, in younger cultures completely, in older cultures partially. On those places where the particles have been split off or where they are loosly arranged, it was possible to observe the surface of the cytoplasmic membrane. It appears to be covered with unsystematically scattered particles imbedded at different depths, not only on that side turned to the cell wall but also on that facing the cytoplasm.

     

Functionality and specific membrane localization of transport GTPases carrying C-terminal membrane anchors of synaptobrevin-like proteins.

Ras-related guanine nucleotide-binding proteins of the Ypt/Rab family fulfill a pivotal role in vesicular protein transport both in yeast and in mammalian cells. Proper functioning of these proteins involves their cycling between a GTP- and a GDP-bound state as well as their reversible association with specific membranes. Here we show that the yeast Ypt1 and Sec4 proteins, essential components of the vesicular transport machinery, allow unimpaired vesicular transport when permanently fixed to membranes by membrane-spanning domains replacing their two C-terminal cysteine residues. Membrane detachment of the GTPases therefore is not obligatory for transport vesicle docking to or fusion with an acceptor membrane. It was also found that the membrane anchors derived from different synaptobrevin-related proteins have targeting information and direct the chimeric GTPases to different cellular compartments, presumably from the endoplasmic reticulum via the secretory pathway.     

Freeze-etch and thin section studies ofNeurospora crassa ascospores

Summary Mature, dormant ascospores derived from crosses of wild type stocks of the fungusNeurospora crassa were studied using both thin section and freeze-etch techniques for electron microscopy. The spore wall is composed of three major layers with, perhaps, a fourth distinct layer covering these layers. The spore contains several nuclei, many discrete mitochondria, lipid bodies, vacuoles and small pieces of endoplasmic reticulum. Freeze-etch fracture faces of several membranes are described in this paper. Included is a diagram illustrating various fracture faces and surfaces seen following freeze-etching. The thin section results are less than satisfactory but serve to generally confirm the freeze-etch observations and suggest that further work could lead to the development of techniques which will result in high quality thin sections of ascospores.     

Substructure of membranes in cultivated chick embryo fibroblasts

Summary Electron microscope examination of the plasma membrane of chick embryo fibroblasts cultured in vitro revealed the presence of a single osmiophilic layer about 90 Å thick and a substructure composed of ovoid sub-units associated with an amorphous component. These ovoid sub-units measured approximately 112 Å along the major axis and 75 Å along the minor axis and were composed of a central core, approximately 30 Å by 60 Å, surrounded by a peripheral component.Examination of other membranous components of these cells revealed a similar ovoid subunit structure in a single layered membrane. Differences in thickness and in the sizes of ovoid sub-units were seen in these membranes. The ergastoplasmic membranes, the outer nuclear membranes, the outer mitochondrial and the Golgi membranes were found to be the thinnest.These varied in thickness from approximately 75 Å to 80 Å. The thickest membranes seen were the inner nuclear membranes. These were approximately 100 Å thick. The dimensions of the ovoid sub-units corresponded with differences in the thickness of the various membranes. These findings support the concept of a particulate substructure of cell membranes.This work was aided by Research Grant PH 5593 from the National Science Foundation. Some of the equipment used was purchased with funds from the National Institutes of Health Grant 2TI GM 326. I wish to thank Dr. Robert M. Dougherty from the Department of Microbiology who grew and supplied me with the chick embryo fibroblast cultures used in these studies, and Mrs. Ursula Feller fer her technical assistance.     

Differences in the surface membranes and water content between the vegetative cells and spores of Bacillus subtilis

Bacillus subtilis forms both vegetative cells and spores. The fluidity of the membranes in these forms was measured by using fluorescent anisotropy of 1,6‐diphenyl‐1,3,5‐hexatriene (DPH). The spores were more rigid than the vegetative cells, suggesting that the structure of the spores and vegetative cells was different. This difference was thought to be due to the structure of the cell membranes. The anisotrophy of DPH in the cell membranes of spores gave higher values at all temperatures. The anisotrophy of DPH in the cell membranes of vegetative cells was lower than that of the spores and the value depended upon the temperature. Time Domain Reflectometry (TDR) was used to measure the quantities of bound and free water in the vegetative cells and spores. The spores were dehydrated, and the amount of bound and free water in the spores was about two‐thirds of the levels in the vegetative cells. The spores have fewer sugars molecules on their cell surface membranes, but contained as much sugars within the cell. Almost 100 per cent of the vegetative cells wee absorbed toward chitin, but the spores were not absorbed toward it at all. It was felt that the surface membrane of the vegetative cell had a high mobility because it was sugar‐rich, while the surface membrane of the spore showed a lower mobility because there are fewer sugars on the outer membrane. The spores survive in high temperatures because the surface membrane of the spore is tight and has relatively few sugars. Dehydration causes the rigidity of the spores. On the other hand, the vegetative cells are sugar‐ and water‐rich, which makes them more fluid. The difference between the vegetative cells and spores is the glycosylation of their surface membranes. Copyright © 1999 John Wiley & Sons, Ltd.     

Observations on the ultrastructure of nerve cells in the brain of the planarian,Dugesia gonocephala

Summary The submicroscopic structure of the nerve cells in the planarian brain was studied. Close similarities with neurons of other invertebrates were noted. In the cytoplasm of the planarian nerve cells there are at least three types of vesicular inclusions: 1) Clear vesicles (200–800 Å in epon embedded tissue) similar in morphological appearance to classical synaptic vesicles. These have generally some content of extremely low density but occasionally a dense core. 2) Dense vesicles (400–1,200 Å in epon embedded tissue) containing highly osmiophilic granules. Between the limiting membrane of the vesicle and the granule there is always a clear rim of variable width. These vesicles closely resemble synaptic vesicles described in vertebrate adrenergic endings. 3) Neurosecretory vesicles (600–1,300 Å in Vestopal embedded tissue) similar to elementary granules observed in neurosecretory systems in vertebrates and invertebrates. All three vesicle types have the same mode of origin from the Golgi membranes. All are present in the nerve cell processes of the neuropil as well as in the perikarya. Any given perikaryon or axon contains only one of the three vesicle types. All of these vesicles are considered to be discharged into the axons from their site of origin within the perikaryon.     

CILIA AND VESICULAR PARTICLES IN THE ENDOCRINE PANCREAS OF THE MONGOLIAN GERBIL

Though the general appearance and the cellular composition of the pancreatic islets of the Mongolian gerbil (Meriones unguiculatus) conformed to those of most other rodent species, some peculiar ultrastructural details were found. Thus there were diversiform, mainly vesicular particles with varying electron opacity in these islets. The vesicular particles showed a clear association to cilia which seemed to possess a basic fiber pattern of 9 + 0. The basal bodies were localized in the cytoplasm of the islet parenchymal cells, most often in the β-cells, and the vesicular particles occurred in the portions of cilia that were protruding into intercellular spaces. The cilia were often swollen, and the vesicular particles were mainly found in the space between the ciliary membranes and the longitudinal fibers. A few vesicular particles could be seen inside and sometimes seemingly in contact with these fibers. Occasionally, there were morphologically similar structures in the cytoplasm of adjacent β-cells. The vesicular particles were differentiated from the vesicles occurring in nerve structures by their larger size, as well as by their heterogeneous shape and electron opacity. The nature of the vesicular particles and the significance of their presence in cilia and in the cytoplasm of some of the islet cells remain unknown. Among other possibilities, it is, however, suggested that the vesicular particles may represent secretory material.