Fine structure and distribution of extracellular polymer surrounding selected aerobic bacteria.

The structure and distribution of extracellular polymer surrounding Bacillus circulans, Diplococcus (Streptococcus) pneumoniae, Streptococcus salivarius, Staphylococcus aureus, Klebsiella pneumoniae, Pseudomonas aeruginosa, Herella vaginacola (Acinetobacter calcoaceticus), and Agrobacterium tumefaciens were studied by electron microscopy. A modified ruthenium red staining procedure was used to examine the fine structure of capsule and slime. Freeze-etching and critical-point drying were used to examine the quantity of unaltered exocellular material. Comparative data demonstrate that fibrillar extracellular polymer surrounding B. circulans, D. pneumoniae, and K. pneumoniae is capsule (cell wall attached) which is characteristic of the producing organism. Capsular polymer generally appeared fibrillar, although globular polymer consisted of capsular subunits bound to S. salivarius and H. vaginacola. Exocellular slime was present about S. aureus, P. aeruginosa, and A. tumefaciens.     

Extracellular matrix of plant callus tissue visualized by ESEM and SEM

Actinidia deliciosa endosperm-derived callus culture is stable over a long period of culture. This system was used to investigate the ultrastructure of extracellular matrix occurring in morphogenic tissue. Specimens were prepared by different biological techniques (chemical fixation, liquid nitrogen fixation, glycerol substitution, critical-point drying, lyophilization) and observed by scanning electron microscopy (SEM). Fresh and wet samples were analyzed with the use of environmental scanning electron microscopy (ESEM). Extracellular matrix was observed on the surface of cell clusters as a membranous layer or reticulated network, shrunken or wrinkled, depending on the procedure. Generally, shrunken membranous layers with a globular appearance and fibrils were noted after critical-point drying and liquid nitrogen fixation. Smoother surface layers without visible fibrils and showing porosity were typically seen by environmental scanning electron microscopy. Preservation with glycerol substitution caused wrinkled appearance of examined layer. Analysis of fresh samples yielded images closer to their natural state than did critical-point drying or fixation in liquid nitrogen, but it seems best to compare the results of different visualization methods. This is the first report of ESEM observations of plant extracellular matrix and comparison with SEM images from fixed material.     

Ultrastructure and Capsule of Mycoplasma meleagridis

The ultrastructural study of Mycoplasma meleagridis utilized the electron microscope techniques of sectioning, histochemical staining, critical-point drying, and freeze etching. The predominant morphotype was a spherical form ranging in diameter from 200 to 700 nm. The other morphotypes were dumbbell-shaped cells interconnected by membranous tubules, and chains of streptococcal-like cells. These forms suggest replication by binary fission. An extracellular structure in the form of a capsular matrix was observed by staining with ruthenium red and potassium tellurite, and was also seen in specimens prepared by critical-point drying and freeze etching.     

Pure F-actin networks are distorted and branched by steps in the critical-point drying method

Elucidation of the ultrastructural organization of actin networks is crucial for understanding the molecular mechanisms underlying actin-based motility. Results obtained from cytoskeletons and actin comets prepared by the critical-point procedure, followed by rotary shadowing, support recent models incorporating actin filament branching as a main feature of lamellipodia and pathogen propulsion. Since actin branches were not evident in earlier images obtained by negative staining, we explored how these differences arise. Accordingly, we have followed the structural fate of dense networks of pure actin filaments subjected to steps of the critical-point drying protocol. The filament networks have been visualized in parallel by both cryo-electron microscopy and negative staining. Our results demonstrate the selective creation of branches and other artificial structures in pure F-actin networks by the critical-point procedure and challenge the reliability of this method for preserving the detailed organization of actin assemblies that drive motility.     

A method of comparing spermatozoa with light and scanning electron microscopy

A new method of comparing light microscopy and scanning electron microscopy in the study of small cells, such as spermatozoa, that must be examined under oil immersion is described. A grid is etched on the corner of a microscope glass slide, and its inner edges are incised. Its surface area is calculated as a function f the chamber of the critical-point drying apparatus. This method dispenses with the need for any special coverslip and enables the cells to be observed under oil immersion.     

Structural analysis of an extracellular polysaccharide bioflocculant of Klebsiella pneumoniae

The glycoside composition and sequence of an extracellular polysaccharide flocculant of Klebsiella pneumoniae H12 was analyzed. GC and HPLC analysis of the acid-hydrolysate identified its constituent monosaccharides as D-Glc, D-Man, D-Gal, and D-GlcA in an approximate molar ratio of 3.9:1.0:2.3:3.6. To analyze the glycoside sequence, the polysaccharide was partially hydrolyzed by acid and enzyme treatment. GC, HPLC, TLC, MALDI-TOF/MS, and 1H- and 13C- NMR spectroscopy characterized the obtained oligosaccharides. The results clarified the partial structure of H12 polysaccharide as a linear polymer of a unit of pentasaccharide with a side chain of one D-GlcA to D-Glc moiety (see below). Although the existence of other sequences or other constituent glycosides could not be fully excluded, H12 polysaccharide must be a novel types as such a complicated unit for a polymer has not so far been reported. The partial structure of a H12 polysaccharide flocculant is also discussed in this report. [structure: see text]     

Microtrabecular lattice of the cytoplasmic ground substance. Artifact or reality

The cytoplasmic ground substance of cultured cells prepared for high voltage transmission electron microscopy (glutaraldehyde/osmium fixed, alcohol or acetone dehydrated, critical-point dried) consists of slender (3-6 nm Diam) strands--the microtrabeculae (55)--that form an irregular three-dimensional lattice (the microtrabecular lattice). The microtrabeculae interconnect the membranous and nonmembranous organelles and are confluent with the cortices of the cytoplast. The lattice is found in all portions of the cytoplast of all cultured cells examined. The possibility that the lattice structure is an artifact of specimen preparation has been tested by (a) subjecting whole cultured cells (WI-38, NRK, chick embryo fibroblasts) to various chemical (aldehydes, osmium tetroxide) and nonchemical (freezing) fixation schedules, (b) examination of model systems (erythrocytes, protein solutions), (c) substantiating the relaibility of critical-point drying, and (d) comparing images of whole cells with conventionally prepared (plastic-embedded) cells. The lattice structure is preserved by chemical and nonchemical fixation, though alterations in ultrastructure can occur especially after prolonged exposure to osmium tetroxide. The critical-point method for drying specimens appears to be reliable as is the freeze-drying method. The discrepancies between images of plastic-embedded and sectioned cells, and images of whole, critical-point dried cells appear to be related, in part, to the electron-scattering properties of the embedding resin. The described observations indicate that the microtrabecular lattice seen in electron micrographs closely represents the nonrandom structure of the cytoplasmic ground substance of living cultured cells.     

Scanning electron microscopy of heart muscle freeze-dried from dimethylsulfoxide for simultaneous demonstration of cell morphology and microvascular function

Scanning electron microscopy was used to examine cryofracture surfaces of ventricular myocardium from glutaraldehyde fixed rat and rabbit hearts subjected to intravascular injection of polymerizing acrylic resin. This allowed simultaneous observation of morphological features of cardiac muscle cells and the functional state of their associated small blood vessels. Because the resin injected to identify capillaries accessible to flow might be soluble in commonly used tissue dehydrating agents, alternative preparation methods using the cryoprotectants dimethylsulfoxide (DMSO) and glycerol were investigated. Provided a high performance backscattered electron detector and simple environmental cell were used to abolish specimen charging and circumvent potential instrument contamination, immersion in 2.82 M DMSO for 12 hr prior to cryofracture and freeze-drying gave the best results. The SEM appearance of specimens dehydrated in this way differed little from that of specimens prepared by ethanol dehydration and freeze-drying or by acetone dehydration and critical-point drying. Tissue shrinkage was 26.5 +/- 9.4%, comparable to that found after standard methods using solvent dehydration and critical-point drying.     

Scanning Electron Microscopy of Heart Muscle Freeze-Dried from Dimethylsulfoxide for Simultaneous Demonstration of Cell Morphology and Microvascular Function

Scanning electron microscopy was used to examine cryofracture surfaces of ventricular myocardium from glutaraldehyde fixed rat and rabbit hearts subjected to intravascular injection of polymerizing acrylic resin. This allowed simultaneous observation of morphological features of cardiac muscle cells and the functional state of their associated small blood vessels. Because the resin injected to identify capillaries accessible to flow might be soluble in commonly used tissue dehydrating agents, alternative preparation methods using the cryoprotectants dimethylsulfoxide (DMSO) and glycerol were investigated. Provided a high performance backscattered electron detector and simple environmental cell were used to abolish specimen charging and circumvent potential instrument contamination, immersion in 2.82 M DMSO for 12 hr prior to cryofracture and freeze-drying gave the best results. The SEM appearance of specimens dehydrated in this way differed little from that of specimens prepared by ethanol dehydration and freeze-drying or by acetone dehydration and critical-point drying. Tissue shrinkage was 26.5 ± 9.4%, comparable to that found after standard methods using solvent dehydration and critical-point drying.     

Ultrastructure of rumen bacterial attachment to forage cell walls.

The degradation of forage cell walls by rumen bacteria was investigated with critical-point drying/scanning electron microscopy and ruthenium red staining/transmission electron microscopy. Differences were observed in the manner of attachment of different morphological types of rumen bacteria to plant cell walls during degradation. Cocci, constituting about 22% of the attached bacteria, appeared to be attached to degraded plant walls via capsule-like substances averaging 58 nm in width (range, 21 to 84 nm). Many bacilli appeared to adhere to forage substrates without distinct capsule-like material, although unattached bacteria with capsules were observed occasionally. Certain bacili appeared to be attached to degraded tissue via small amounts of extracellular material, but others apparently had no extracellular material. Bacilli with a distinct morphology due to an irregularly folded, electron-dense outer layer or layers (about 15 nm thick) and without fibrous extracellular material consituted about 37% of the attached bacteria and were observed to adhere so closely to degraded plant walls that the bacterial shape conformed to the shape of the degraded zone. In the rumen ecosystem, bacteria appeared to adhere to plant substrates during degradation by capsule-like material and by small amounts of extracellular material, as well as by the other means not observable by electron microscopy.     

Ultrastructure of Pellicular and Ciliary Structures of Euplotes eurystomus

SYNOPSIS. Many of the sub-pellicular and infraciliary structures in protozoa have proved difficult to study with standard thin-sectioning technics. When these structures are viewed in isolated and fragmented form, many of the thin-sectioning difficulties are circumvented. Langmuir-trough isolation followed by critical-point drying, as well as thin sectioning, were used in this study to determine the patterns of sub-pellicular microtubules and fibrils interconnecting kinetosomes of membranelles and cirri of Euplotes eurystomus. The fibrillar network in the bases of these ciliary organelles is presented in some detail and apparent variations in pattern are noted. Functional aspects of some of the structures are discussed. With special preparation nearly whole Euplotes may be obtained for study in the electron microscope. Fused cilia were frequently obtained and their ultrastructure was studied.     

Specimen Holder to Critical-Point Dry Microorganisms for Scanning Electron Microscopy

Critical-point drying of microorganisms for scanning electron microscopy can be rapidly and effectively accomplished by use of a newly described specimen holder. Up to eight different samples of spores or vegetative cells are placed between polycarbonate membrane filters in the holder and processed through solvent dehydration and critical-point drying using carbon dioxide without loss or cross contamination of microorganisms. Yeasts, molds, bacteria, and actinomycetes have been successfully processed.     

High resolution scanning electron microscopy of isolated and in situ cytoskeletal elements

Evidence is presented that cytoskeletal structures (actin filaments, intermediate filaments, and microtubules) can be resolved by scanning electron microscopy after osmium impregnation of biological material, using thiocarbohydrazide as a ligand, followed by critical-point drying. These different classes of filaments or tubules can be identified both as purified protein polymers and as structured organelles within cryofractured or detergent-extracted cells.     

Cryofracturing for Scanning Electron Microscope Observations of Internal Structures of Nematodes

Nematodes were prepared for scanning electron microscopy by cryofracturing in ethanol and then by critical-point drying in carbon dioxide. Cross sections of Caenorhabditis briggsae and Xiphinema americanum showed the arrangement of the intestine, ovaries, muscle cells, and some layers of the cuticle. The technique is complementary to transmission electron microscopy and facilitates the interpretation of results from thin sections.     

Ornamentation types of conidia and conidiogenous structures in fasciculate Penicillium species using scanning electron microscopy

KOZAKIEWICZ, Z., 1988. Ornamentation types of conidia and conidiogenous structures in fasciculate Penicillium species using scanning electron microscopy. As part of a multidisciplinary approach to the taxonomy of the fasciculate Penicillium species, the conidial ornamentation of 320 strains was examined in order to determine the types and range of ornamentation and assess the stability of this feature as a taxonomic character.
Five conidial ornamentation classes were identified: echinulate, tuberculate, reticulate, microtuberculate and microverrucate. The technique of cryoscanning was used for examining the penicillus, and assessing such characters as roughening, shape and orientation of the branches. The method provides a fast means of examining freshly frozen material in the absence of artefacts associated with air-drying, freezing and critical-point drying techniques.
Studies on large numbers of conidia from the same isolate and from isolates referred to the same species showed the scanning electron microscopy results to be reproducible and provide an objective and accurate method for comparing micromorphological features. The ornamentation types can be of particular value in species identification.     

Scanning electron microscopy of Treponema pallidum (Nichols strain) attached to cultured mammalian cells.

This paper describes the attachment of Treponema pallidum (Nichols strain) to cultured mammalian cells as a visualized by scanning electron microscopy. Treponemes were incubated for 3 hr with cultured cells derived from normal rabbit testes or human skin epithelium, then fixed, processed with critical-point drying, and examined with a Cambridge Mark 2A scanning electron microscope. Large numbers of treponemes became attached to the cultured cells without altering the morphological integrity of the cultured cells. Attachment appeared to involve a very close physical proximity of treponemes to the cultured cells; at the site of attachment, no changes such as swelling or indentation of the cultured cell surface were observed. The addition of ruthenium red to the fixatives produced a treponemal-associated surface precipitate. This material, which is probably mucopolysaccharide and/or phospholipid, may be important in protecting the organisms against host defense mechanisms; in addition, it may be involved in the serological unresponsiveness of freshly prepared suspensions of T. pallidum.     

Dimensional changes in cells and tissues during specimen preparation for the electron microscope

Studies on dimensional changes incurred during preparation of tissue specimens for the transmission and scanning electron microscopes are reviewed, with emphasis on quantitative measurements pertinent to morphometry and three-dimensional reconstruction. The scope of the review includes fixation, dehydration, plastic embedment, critical-point drying, and freeze-drying. Recommendations are presented for monitoring dimensional changes; a strategy for the choice of method of specimen preparation is outlined.     

Dimensional changes in cells and tissues during specimen preparation for the electron microscope.

Studies on dimensional changes incurred during preparation of tissue specimens for the transmission and scanning electron microscopes are reviewed, with emphasis on quantitative measurements pertinent to morphometry and three-dimensional reconstruction. The scope of the review includes fixation, dehydration, plastic embedment, critical-point drying, and freeze-drying. Recommendations are presented for monitoring dimensional changes; a strategy for the choice of method of specimen preparation is outlined.     

Effects of Petunia cytoplasmic male sterile (CMS) cytoplasm on the development of sterile and fertility-restored P. parodii anthers

The developmental defects causing cytoplasmic male sterility in Petunia parodii are described in isonuclear fertile, sterile, and fertility-restored plants using both light- and scanning electron microscopy. The aberrant development of the sporogenous tissue and tapetal layer caused by the cytoplasmic male sterile cytoplasm in both Petunia hybrida and P. parodii nuclear backgrounds is similar in onset and progression. The degeneration of the sporogenous tissue and tapetal layer of sterile anthers is first apparent late in meiosis and results in highly abnormal sterile sporogenous tissue by tetrad stage of fertile anthers. The stomium and endothecium do not show major developmental differences between fertile and sterile anthers, but the inner connective tissue of sterile anthers contained calcium crystals not found at high abundance in fertile anthers. Ovoid bodies containing magnesium and phosphorus were seen only in the vascular bundles of fertile anthers. Material prepared for the scanning electron microscope by freeze drying showed better retention of fragile morphological features, while critical-point drying permitted examination of nonvolatile structures, such as cell walls.     

Ultrastructural localization of tubulin and actin in polyethylene glycol-embedded rat seminiferous epithelium by immunogold staining

The polyethylene glycol (PEG) method for immunofluorescence localization of cytoskeletal antigens has been extended to the ultrastructural level using glutaraldehyde-fixed tissues and immunogold staining. Semithin sections of fixed tissue embedded in polyethylene glycol are divested of the PEG, exposed to purified antibodies (e.g., antiactin, antitubulin) and anti-IgG-colloidal gold. The sections may be processed by dehydration and critical-point drying, or reembedment in hydrophilic substances. Tubulin is demonstrated in the mitotic spindles of dividing spermatogonia, manchettes, axonemes and centrioles of developing spermatids, and in the Sertoli cell cytoplasm; actin localization is demonstrated in the myoid cells of the tunica propria, and smooth muscle cells of arterioles in the interstitial tissue. The results demonstrate the applicability and versatility of PEG embedding for immunocytochemistry.