Ultrastructural characteristics of the external surfaces of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits

The surface structures of the cells of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits were examined by transmission electron microscopy after ruthenium red staining and polycationic ferritin labelling. P. pneumotropica strains ATCC 35149 and K 79114 had slight extracellular fibrous materials associated with cell walls with ruthenium red staining. Ferritin labelling method revealed thick strands or sparsely ferritin-labelled materials on the cell surface of the strains. P. multocida strains Pm-78 and P-2440 had ferritin-labelled capsules surrounded with the cell wall. Strain Pm-78, which was serotyped as A:12, had a thick capsule, whereas serotype -:3 strain P-2440 had a thin and irregular capsule.     

Polysaccharide capsule of Escherichia coli: microscope study of its size, structure, and sites of synthesis.

This report describes the structure, size, and shape of the uncollapsed polysaccharide capsule of Escherichia coli strain Bi 161/42 [O9:K29(A):H-], its ultrastructural preservation as well as the filamentous components of the isolated capsular material. In a temperature-sensitive mutant, sites were localized at which capsular polysaccharide is "exported" to the cell surface. The highly hydrated capsule of the wild-type cells was visible in the uncollapsed state after freeze-etching, whereas dehydration in greater than or equal to 50% acetone or alcohol caused the capsule to collapse into thick bundles. This was prevented by pretreatment of the cell with capsule-specific immunoglobulin G; the capsule appeared as a homogeneous layer of 250- to 300-nm thickness. The structural preservation depended on the concentration of the anti-capsular immunoglobulin G. Temperature-sensitive mutants, unable to produce capsular antigen at elevated temperatures, showed, 10 to 15 min after shift down to permissive temperature, polysaccharide strands with K29 specificity appearing at the cell surface at roughly 20 sites per cell; concomitantly, capsule-directed antibody started to agglutinate the bacteria. The sites at which the new antigen emerged were found in random distribution over the entire surface of the organism. Spreading of purified polysaccharide was achieved on air-water interfaces; after subsequent shadow casting with heavy metal, filamentous elements were observed with a smallest class of filaments measuring 250 nm in length and 3 to 6 nm in width. At one end these fibers revealed a knoblike structure of about 10-nm diameter. The slimelike polysaccharides from mutants produced filamentous bundles of greater than 100-microns length, with antigenic and phage-receptor properties indistinguishable from those of the wild-type K29 capsule antigen.     

The Fine Structure of Muscle Spindles in the Lumbrical Muscles of the Rat

Lumbrical muscles of young rats were fixed with OsO₄ and embedded in methacrylate for electron microscopy. The spindle capsule was found to be continuous with and similar in structure to the sheath of Henle surrounding the nerves supplying the spindle. The capsule consists of several closely applied concentric cytoplasmic sheets. Each sheet is about 1,000 A thick and has no fenestrations. Many caveolae and vesicles in the cytoplasm suggest active transport through the sheets. The periaxial space fluid contains much solid material. It is suggested that the capsule and periaxial space regulate internal chemical environment. The interfibrillar structures are less evident in the polar regions of intrafusal fibres than in extrafusal fibres. Simple motor end-plates occur on the polar regions of intrafusal fibres. In the myotube region of the intrafusal fibre a peripheral zone of myofibrils surrounds a cytoplasmic core containing nuclei, mitochondria, Golgi bodies, reticulum, and a few lipid-like granules. Naked sensory endings lie on the myotube "in parallel" with the underlying myofilaments. Naked processes of the primary sensory ending deeply indent the muscle plasma membrane and the underlying wisps of myofilament in the nuclear bag region. The plasma membranes of sensory nerve ending and intrafusal muscle fibre are about 200 A apart.     

Fine surface structure of enterotoxemic Escherichia coli O139:K12 strains associated with swine edema disease

The fine structure of the cell surface of seven enterotoxemic Escherichia coli (ETEEC) O139:K12 strains isolated from piglets with edema disease were examined electron microscopically using both the negative-staining method and the freeze-substitution fixation method. Densely packed, fine fibers were observed; they consisted of a capsule layer approximately 25 nm thick around the cell surfaces of strains 107/86, IW-2, ED-3, ED-43, and ED-61, all of which have a capacity to adhere strongly to HEp-2 cells. In contrast, no such structure was observed on the surface of strains RK-O139 or ED-1, both of which adhere only weakly to HEp-2 cells. These results suggest that the capsule structure might be associated with the ability to adhere to HEp-2 cells and, as a result, also potentially play some role in ETEEC infection. Received: 29 April 1996 / Accepted: 13 August 1996     

Structural analysis of viral replicative intermediates isolated from adenovirus type 2-infected HeLa cell nuclei.

Deoxyribonucleoprotein complexes released 17 h postinfection from adenovirus type 1 (Ad2)-infected HeLa cell nuclei were shown by electron microscopy to contain filaments much thicker (about 200 A [20 nm]) than double-stranded DNA (about 20 A [2 nm]). The complexes were partially purified through a linear sucrose gradient, concentrated, and further purified in a metrizamide gradient. The major protein present in the complexes was identified as the 72,000-dalton (72K), adenovirus-coded single-stranded DNA-binding protein (72K DBP). Three types of complexes have been visualized by electron microscopy. Some linear complexes were uniformly thick, and their length corresponded roughly to that of the adenovirus genome. Other linear genome-length complexes appeared to consist of a thick filament connected to a thinner filament with the diameter of double-stranded DNA. Forked complexes consisting of one thick filament connected to a genome-length, thinner double-stranded DNA filament were also visualized. Both thick and thin filaments were sensitive to DNase and not to RNase, but only the thick filaments were digested by the single-strand-specific Neurospora crassa nuclease, indicating that they correspond to a complex of 72K DBP and Ad2 single-stranded DNA. Experiments with anti-72K DBP immunoglobulins indicated that these nucleoprotein complexes, containing the 72K DBP, correspond to replicative intermediates. Both strands of the Ad2 genome were found associated to the 72K DBP. Altogether, our results establish the in vivo association of the 72K DBP with adenovirus single-stranded DNA, as previously suggested from in vitro studies, and support a strand displacement mechanism for Ad2 DNA replication, in which both strands can be displaced. In addition, our results indicate that, late in infection, histones are not bound to adenovirus DNA in the form of a nucleosomal chromatine-like structure.     

Functional organization of the nucleus in the oogenesis of Chrysopa perla L. (Insecta,Neuroptera)

On the basis of light, autoradiographic (uridine-³H incorporation) and electron microscopic investigation changes of nuclear structures were examined during the oogenesis in Chrysopa perla L. — In early meiotic prophase the oocyte nuclei were found to contain a large body of extrachromosomal DNA. In certain cases the latter splits up into several DNA clumps giving rise to a few (4–7) primary nucleoli, 3–5 in diameter. The primary nucleoli consist of densely packed fibrils 50–100 Å thick. They contain no granular component and are inactive in RNA synthesis. — At the beginning of large growth the extrachromosomal DNA bodies disappear and numerous electron-dense clumps, 0,5–1 in diameter, appear in the nucleus. Instead of the primary nucleoli, the nucleus now contains a great number of ring nucleoli about 0,5–1 in diameter with a granular component (granules are 150 Å). The space between them is filled up with nucleolar strands running from the surface of the ring nucleoli. — At the stage ring nucleoli of uridine^–3 H incorporation into the oocyte nucleus begins. — During later previtellogenesis and at the beginning of vitellogenesis the ring nucleoli disappear and the nucleus is filled with the network of nucleolar strands. Among them there are specific complexes. These consist of electron dense masses, of granular clusters (granules 500 Å in diameter) and large fibrillar electron light bodies. At this stage the nucleus takes the most active part in RNA synthesis. — The process of karyosphere capsule formation was studied by electron microscopy. The capsule was found to be of fibrillar nature; its structure is very peculiar and unlike any known membrane components of the cell. On the basis of cytochemical evidences the characteristics of the capsule are given. — The development of a powerful nucleolar apparatus based on the extrachromosomal DNA and a possible role of the synaptonemal complex and extrachromosomal DNA in formation of the karyosphere capsule is discussed.     

The electron microscopy of the human hair follicle. I. Introduction and the hair cortex

1. The presumptive cortical cells of hair in the undifferentiated matrix of the bulb contain mitochondria, agranular vesicles, and many small dense R.N.P. particles, but no keratin, pigment granules, or endoplasmic reticulum. 2. In the mid-bulb region intercellular adhesion is limited to small localised areas. Intercellular gaps are common and the cell surfaces are irregularly convoluted. The melanocyte processes penetrate the cell gaps. The relation between their pigment-bearing tips and the involutions of the cell membranes suggests an active phagocytosis of the tips. 3. Fibrous keratin first appears in loose parallel strands of fine filaments (ca. 60 A diameter) in the mid-bulb. The filaments, the long mitochondria, and elongated nucleus are all parallel to the long axis of the cell and the axis of the follicle. 4. At the level of the constriction of the bulb and above, a dense amorphous substance appears between the fine filaments and apparently acts as adhesive cement. The bundles of filaments now form well defined fibrils. The packing of the filaments within the fibrils is in places hexagonal and elsewhere in the form of "whorls." 5. At higher levels further filaments and interfilamentous cement are added together and the whole cytoplasmic space becomes packed with fibrils which finally condense to massive blocks of keratin. The residual cellular material occupies the interstices. 6. The addition of the interfilamentous substance is regarded as an essential factor in keratinisation. Keratin is considered to be a complex made of fine filaments (alpha-filaments) embedded in an amorphous substance (gamma-keratin) which has the higher cystine content. 7. The wide-angle fibre-type x-ray pattern is thought to be due to scattering by the fine alpha-filaments and some low angle lateral spacings to the filament-plus-cement structure.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Summary Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0° C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37° C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.33 m thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 2001,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0° C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37° C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stercomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Histologic changes in tissue components of the hyperplastic thyroid gland during its involution in the rat

Male Fischer rats were fed a low-iodine diet containing thiouracil for 21 days to produce hyperplastic thyroid glands, and then fed a high-iodine diet for various time intervals, from 5 hr to 180 days, in order to study the morphological changes that occur during involution. Thyroids were fixed by perfusion fixation and embedded in Epon. Sections were examined by light microscopy. Initially at 0 days of involution (at the time of the change to the high-iodine diet), follicular lumens were very narrow and capillary lumens were very wide. The capsule was thick and infiltrated with mononuclear leukocytes. No obvious changes occurred for 1 day after the change in diet, but shortly thereafter capillary lumens began to narrow. By 4 days, most capillary lumens were close to normal size; capillaries formed a more or less normal bed except that many were embedded in a relatively thick or wide interfollicular matrix. This matrix was largely gone by 21 days. Between 1 and 21 days, follicular lumens dilated progressively as colloid accumulated. The density of staining of the accumulated colloid varied from follicle to follicle, and this variation was also observed in older controls. Inflammatory cells gradually disappeared from the capsule and most were gone by 15 days. Starting at approximately 15 days and continuing to 180 days, one or more disintegrating cells were found in some lumen profiles. Colloid goiters were not observed in these rats even after several months of involution. Some lumens were rather large, however, and small fractions of the follicles, both small and large, were bounded by flat cells and resembled "cold" follicles morphologically.     

Immunoelectron microscopic localization of alpha-actinin and actin in embryonic hamster heart cells

Myofibrillogenesis in developing cardiac cells of the Syrian hamster from early embryonic stages through newborn was studied by electron microscopy, immunofluorescence microscopy and immunoelectron microscopy. alpha-Actinin and actin were localized at light and electron microscopic levels in embryonic heart cells which had been fixed in a periodate-lysine-paraformaldehyde or a glutaraldehyde-formaldehyde mixture, and embedded in Lowicryl K4M. Indirect staining methods were used for immunofluorescence staining of thick sections and immunoferritin staining of thin sections. The earliest evidence of myofibrillogenesis in embryonic myocardial cells was the presence of many randomly arranged thin (6 nm) filaments and a few scattered thick filaments (15 nm) near the plasma membrane. alpha-Actinin was detected in a semi-continuous, diffuse layer in some portions of the cell just beneath the plasma membrane in association with the filamentous collections. Later in development, alpha-actinin coalesced into Z-plaques at the membrane as the filaments arranged into parallel arrays. Actin was localized in the thin filaments as expected. In later stages of development, alpha-actinin was observed at the Z-lines and intercalated discs of the mature myofibrils while actin was localized at both the I-band and Z-line. Our results suggest that myofibrillogenesis is initiated at the plasma membrane and that Z-plaques are precursors of myofibrillar Z-bands and may serve as organizing centers for myofibrillogenesis in developing cardiomyocytes.     

A Glycosaminoglycan Based,Modular Tissue Scaffold System for Rapid Assembly of Perfusable,High Cell Density,Engineered Tissues

The limited ability to vascularize and perfuse thick, cell-laden tissue constructs has hindered efforts to engineer complex tissues and organs, including liver, heart and kidney. The emerging field of modular tissue engineering aims to address this limitation by fabricating constructs from the bottom up, with the objective of recreating native tissue architecture and promoting extensive vascularization. In this paper, we report the elements of a simple yet efficient method for fabricating vascularized tissue constructs by fusing biodegradable microcapsules with tunable interior environments. Parenchymal cells of various types, (i.e. trophoblasts, vascular smooth muscle cells, hepatocytes) were suspended in glycosaminoglycan (GAG) solutions (4%/1.5% chondroitin sulfate/carboxymethyl cellulose, or 1.5 wt% hyaluronan) and encapsulated by forming chitosan-GAG polyelectrolyte complex membranes around droplets of the cell suspension. The interior capsule environment could be further tuned by blending collagen with or suspending microcarriers in the GAG solution These capsule modules were seeded externally with vascular endothelial cells (VEC), and subsequently fused into tissue constructs possessing VEC-lined, inter-capsule channels. The microcapsules supported high density growth achieving clinically significant cell densities. Fusion of the endothelialized, capsules generated three dimensional constructs with an embedded network of interconnected channels that enabled long-term perfusion culture of the construct. A prototype, engineered liver tissue, formed by fusion of hepatocyte-containing capsules exhibited urea synthesis rates and albumin synthesis rates comparable to standard collagen sandwich hepatocyte cultures. The capsule based, modular approach described here has the potential to allow rapid assembly of tissue constructs with clinically significant cell densities, uniform cell distribution, and endothelialized, perfusable channels.     

Ion transport in Nitellopsis obtusa

The distribution and rates of exchange of the ions sodium, potassium, and chloride in single internodal cells of the ecorticate characean, Nitellopsis obtusa, have been studied. In tracer experiments three kinetic compartments were found, the outermost "free space" of the cell, a compartment we have called "protoplasmic non-free space", and the cell sap. The concentrations in the vacuole were 54 mM Na(+), 113 mM K(+), and 206 mM Cl(-). The steady state fluxes across the vacuolar membrane were 0.4 pmole Na(+)/cm.(2) sec., 0.25 pmole K(+)/cm.(2) sec., and 0.5 pmole Cl(-)/cm.(2) sec. The protoplasmic Na/K ratio is equal to that in the vacuole but protoplasmic chloride is relatively much lower. Osmotic considerations suggest a layer 4 to 6 micro thick with sodium and potassium concentrations close to those in the vacuole. The fluxes between protoplasm and external solution were of the order of 8 pmoles Na(+)/cm.(2) sec. and 4 pmoles K(+)/cm.(2) sec. We suggest that the protoplasm is separated from the cell wall by an outer protoplasmic membrane at which an outward sodium transport maintains the high K/Na ratio of the cell interior, and from the vacuole by the tonoplast at which an inward chloride transport maintains the high vacuolar chloride. The tonoplast appears to be the site of the principal diffusion resistance of the cell, but the outer protoplasmic membrane probably of the main part of the potential.     

Membrane–wall attachments in plasmolysed plant cells

Summary. Field emission scanning electron microscopy of plasmolysed Tradescantia virginiana leaf epidermal cells gave novel insights into the three-dimensional architecture of Hechtian strands, Hechtian reticulum, and the inner surface of the cell wall without the need for extraction. At high magnification, we observed fibres that pin the plasma membrane to the cell wall after plasmolysis. Treatment with cellulase caused these connecting fibres to be lost and the pinned out plasma membrane of the Hechtian reticulum to disintegrate into vesicles with diameters of 100–250nm. This suggests that the fibres may be cellulose. After 4h of plasmolysis, a fibrous meshwork that labelled with anti-callose antibodies was observed within the space between the plasmolysed protoplast and the cell wall by field emission scanning electron microscopy. Interestingly, macerase-pectinase treatment resulted in the loss of this meshwork, suggesting that it was stabilised by pectins. We suggest that cellulose microfibrils extending from strands of the Hechtian reticulum and entwining into the cell wall matrix act as anchors for the plasma membrane as it moves away from the wall during plasmolysis.Correspondence and reprints: Institute of Ecology and Conservation Biology, University of Vienna, Althanstrasse 14, 1090 Vienna, Austria.     

A morphologic and cytochemical study on the great alveolar cell.

Lungs from marsupials, bats and rodents were studied by light and electron microscopy. In all three groups, the great alveolar cells exhibit similar morphologic and cytochemical characteristics. Cytoplasmic vacuoles seen in these cells by light microscopy correspond to cytosomes that are demonstrable in them by electron microscopy. Such cytosomes are osmiophilic, periodic acid-Schiff-positive and stainable with Sudan black after acetone extraction. After fixation in a mixture of aldehydes, followed by extraction in chloroform-methanol and postfixation in osmium tetroxide, cytosomes lose their osmiophilia. The cytoplasm of the great alveolar cell is notable for a loosely ordered granular endoplasmic reticulum, an extensive Golgi apparatus and numerous multivesicular bodies. Many forms transitional in appearance between multivesicular bodies and cytosomes are present. In these, osmiophilic matter occupies the intervesicular space. It is proposed that these bodies are the precursors of cytosomes. The cytosomes are interpreted to be products of the "lysosomal" system in this cell. Ultimately they are secreted onto the alveolar surface.     

THE ELECTRON MICROSCOPY OF THE HUMAN HAIR FOLLICLE : PART 1. INTRODUCTION AND THE HAIR CORTEX

1. The presumptive cortical cells of hair in the undifferentiated matrix of the bulb contain mitochondria, agranular vesicles, and many small dense R.N.P. particles, but no keratin, pigment granules, or endoplasmic reticulum. 2. In the mid-bulb region intercellular adhesion is limited to small localised areas. Intercellular gaps are common and the cell surfaces are irregularly convoluted. The melanocyte processes penetrate the cell gaps. The relation between their pigment-bearing tips and the involutions of the cell membranes suggests an active phagocytosis of the tips. 3. Fibrous keratin first appears in loose parallel strands of fine filaments (ca. 60 A diameter) in the mid-bulb. The filaments, the long mitochondria, and elongated nucleus are all parallel to the long axis of the cell and the axis of the follicle. 4. At the level of the constriction of the bulb and above, a dense amorphous substance appears between the fine filaments and apparently acts as adhesive cement. The bundles of filaments now form well defined fibrils. The packing of the filaments within the fibrils is in places hexagonal and elsewhere in the form of "whorls." 5. At higher levels further filaments and interfilamentous cement are added together and the whole cytoplasmic space becomes packed with fibrils which finally condense to massive blocks of keratin. The residual cellular material occupies the interstices. 6. The addition of the interfilamentous substance is regarded as an essential factor in keratinisation. Keratin is considered to be a complex made of fine filaments (α-filaments) embedded in an amorphous substance (γ-keratin) which has the higher cystine content. 7. The wide-angle fibre-type x-ray pattern is thought to be due to scattering by the fine α-filaments and some low angle lateral spacings to the filament-plus-cement structure.     

Wafer embedding: Specimen selection in electron microscopic cytochemistry with osmiophilic polymers

Synopsis A new wafer embedding procedure is described that permits light microscopic screening of embedded tissue prior to ultrathin sectioning. It is particularly valuable when used on specimens obtained with an automatic sectioner and treated cytochemically to obtain visible intermediate or visible and electron opaque final reaction products. Aldehyde-fixed tissues are cut into sections with an automatic sectioner, incubated cytochemically including osmication if required, then embedded in epoxy resin between fluorocarbon-coated coverglasses which are supported by a platform specially designed for this purpose. The resultant wafer, less than 0.2 mm thick, is examined by light microscopy for optimal areas of cytochemical reaction and desirable structural features. Such areas are cut out and glued to blank blocks with fast curing cyanoacrylate cement for subsequent ultrathin sectioning. The usefulness of this technique is demonstrated by the location of: (1) esterase-positive lysosomes in kidney and trigeminal ganglia; (2) palatal sensory endings stained for acetylcholinesterase; and (3) phagosomes arising from the resorption of horseradish peroxidase tracer by the cuboidal parietal epithelial cells of Bowman's capsule in the male mouse.     

DEVELOPMENT OF MUCILAGINOUS SURFACES IN EUGLENOIDS. I. STALK MORPHOLOGY OF COLACIUM MUCRONATUM1

The envelope and stalk of Colacium mucronatum Bourr. & Chad, were examined in living cells with light microscopy and in fixed preparations with scanning electron microscopy using critically point dried (CPD) and freeze dried (FD) preparations. The envelope of palmelloid cells is formed over the entire cell surface by many individual strands attached at right angles to areas of articulation of the pellicular strips. Strands were observed to anastomose on the posterior tip of otherwise naked cells. Stalks of living cells in India ink preparations had an optically dark inner core with a lighter outer sheath. In FD stalks a definite inner core was not evident, whereas CPD stalks had an outer surface composed of thick strands which may be the collapsed and aggregated strands of the FD stalks. In both there was also an amorphous matrix. The stalk forms from the aggregation of many strands from the anterior cell tip back to a point encompassing the cell surface anterior to a cross section of the tip 9 μm diam. The outer surface of the stalk comes from the pellicular surface joining that area and the core from the cell tip in the area of the canal opening. Any possible participation of the inner canal surface in stalk formation could not be determined because of the great density of the mucilage at the cell-tip/stalk junction.