Unstained and in vivo fluorescently stained bacterial nucleoids and plasmolysis observed by a new specimen preparation method for high-power light microscopy of metabolically active cells

Microscope slides were coated with a layer of gelatin, the thickness of the gelatin increasing linearly along the long axis. The bacterial suspension is applied to the dried gelatin and covered by a coverslip. The medium is absorbed by the gelatin and thus the cells applied against the coverslip. By this method, cultures of concentrations below 10⁸ cells/ml provide statistically relevant numbers for observation without prior concentration steps. It is easier to apply than the existing methods for the observation of bacterial nucleoids by phase contrast imaging. Because the cells are maintained in growing conditions the method is useful for the vital fluorescence DAPI-staining of various bacterial species and for observations of plasmolysis and its reversal at different physiological conditions and extracellular osmolalities. The previously generally assumed view that the plasmolytic changes of the cell morphology are immediate upon the hyperosmotic shock and are rapidly repaired when the cell is able to metabolize actively was confirmed; this is in contrast to some recent claims.     

Video microscopy of dynamic plant cell organelles: principles of the technique and practical application

Video microscopy, including video-enhanced contrast, ultraviolet and video-intensified fluorescence microscopy, was applied to the visualization and analysis of organelles and cytoskeletal elements at the border of resolution of the light microscope. We describe the principles of video microscopy and the necessary technical equipment, and discuss the advantages and limitations with the example of three selected plant cells. In characean internodal cells we observed the motility and disappearance of Golgi secretory vesicles during wound wall formation by video-enhanced contrast microscopy. In Byblis gland hairs we investigated the movement of different organelles along bundles of actin microfilaments by ultraviolet microscopy, and in onion inner epidermal cells we visualized the arrangement of actin microfilaments during different stages of plasmolysis with video-intensified fluorescence microscopy.     

Characterization of the near-surface layers of carbon steels modified by interaction with intense pulsed plasma beams: scanning electron microscopy investigations

Modification of materials is a wide area in materials science, especially surface modification. To investigate the results of the modification process, treated and nontreated samples were compared. Intense plasma pulses of argon or nitrogen were used to irradiate the carbon steels. In all samples, the near‐surface layer was melted. Results of scanning electron microscopy investigations of the surface morphology and cross‐sections, as well as the results of tribological tests, are presented. The obtained results allowed us to draw conclusions about changes in material properties and to propose subsequent studies using other investigation techniques.     

Dentinal tubule penetration of endodontic sealers after nonthermal plasma treatment: A confocal laser scanning microscopy study

One of the factors affecting the success of endodontic treatment is to fill the root canal system hermetically. The aim of this in vitro study was to evaluate the effect of nonthermal plasma (NP) on dentinal tubule penetration of root canal sealers using confocal laser scanning microscopy. Forty mandibular premolar teeth were selected and the root canals were prepared with large‐Waveone‐Gold rotary‐files. Specimens were divided into four experimental groups according to sealer and NP treatment (n = 10). G1: AH‐Plus (AH) G2: nonthermal plasma application + AH‐Plus(AH‐P) G3: Endosequence‐BC(BC) G4: nonthermal plasma application + Endosequence‐BC(BC‐P). Cold lateral‐condensation technique was used for the obturation of root canals. The roots were sectioned horizontally and the sections were examined under confocal laser scanning microscopy. The maximum tubule penetration and percentage of penetration values were obtained from the microscopy images and were statistically analyzed with repeated measurements‐ANOVA and the Tukey (HSD) test (p < 0.05). The percentages of dentinal tubule penetration of the groups were not statistically different. The maximum tubule penetration of the AH‐P was statistically lower than that of the BC‐P (p < 0.05). Plasma application had no affect on the percentage of dentinal tubule penetration. Under the conditions of this in vitro Endosequence‐BC sealer showed higher maximum tubule penetration values than AH‐Plus after NP treatment. Percentage of dentinal tubule penetration values of experimental groups was similar.     

Measurement of absolute tracer concentrations in tissue sections by using digital imaging fluorescence microscopy. Application to the study of plasma protein uptake by the arterial wall

Digital imaging fluorescence microscopy (DIFM) of tissue sections was used to quantify uptake of labelled plasma proteins by the arterial wall. Several aspects of the measuring system were investigated so that absolute tracer concentrations and their local variation could be derived from digitized images. These investigations may be relevant to other studies employing DIFM. Nonlinearities were found to arise from offsets in the video digitizers, from background fluorescence and stray light within the microscope and from the transfer characteristics of the intensified CCD camera. Camera gain controls showed complex behaviour. Camera output fell substantially for several hours after switching on and was affected by room temperature. Large spatial variations in response were caused by the geometry of the microscope optics and by the image intensifier. However, the ratios between areas were not affected by light intensity or camera gain settings. Measured intensities were independent of the depthwise location of fluorophores within tissue sections but they were affected by the emission from objects outside the measuring area. Photobleaching of tracer varied significantly over the range of excitation intensities and durations used but was not concentration dependent. Methods used to correct these effects and obtain a uniform, linear and constant relationship between concentration and grey level are described. Using the system and appropriate corrections, in vivo uptake of sulphorhodamine-B-labelled serum albumin by the rabbit aortic wall was investigated. Results obtained for the mean uptake of tracer and its local variation were quantitatively similar to those previously obtained with nonmicroscopic methods.     

Morphological changes induced in erythrocyte membrane by the antiepileptic treatment: An atomic force microscopy study

Atomic force microscopy (AFM), a powerful characterization tool widely applied in problems in a large range of disciplines of the natural sciences, including cellular biology, was used to obtain information about the morphological changes induced in the erythrocyte membrane at the patients with epilepsy that undergo a long time treatment that operates upon one or several neuronal ionic channels, comparative with a healthy donor. This technique allowed non‐invasive imaging of erythrocyte membrane, revealing details and specific characteristics down to the nanometer level with characterization of surface texture parameters, such as average height, average roughness and coefficient of kurtosis at micrometer/nanometer resolution. For the healthy donor the AFM morphology appears to have all the characteristics of a normal red blood cell membrane. Instead, the closer examination of the erythrocytes membrane surface morphology for the samples collected from the patients diagnosed with epilepsy and treated with specific drugs did not reveal similar structures with those obtained for the healthy donor. The nanostructure of the membrane was drastically damaged, depending on the administrated treatment, and probably in time will affect their functionality. Therefore, the anticomital drugs have influence not only at the neuronal level, but also at the red blood cell level.     

Advanced spinning disk‐TIRF microscopy for faster imaging of the cell interior and the plasma membrane

Understanding the cellular processes that occur between the cytosol and the plasma membrane is an important task for biological research. Till now, however, it was not possible to combine fast and high‐resolution imaging of both the isolated plasma membrane and the surrounding intracellular volume. Here, we demonstrate the combination of fast high‐resolution spinning disk (SD) and total internal reflection fluorescence (TIRF) microscopy for specific imaging of the plasma membrane. A customised SD‐TIRF microscope was used with specific design of the light paths that allowed, for the first time, live SD‐TIRF experiments at high acquisition rates. A series of experiments is shown to demonstrate the feasibility and performance of our setup.     

Comparative study of a block copolymer morphology by transmission electron microscopy and scanning force microscopy

Using transmission electron microscopy (TEM) and scanning force microscopy (SFM) together, it was possible to verify important structural features of a nanostructured bulk material such as the kp‐morphology in an ABC triblock copolymer. By applying suitable imaging techniques during the SFM measurements it was possible to determine the morphology without additional manipulation steps in between. In comparison, TEM investigations on this type of material usually require selective staining procedures prior to the measurement. Also electron beam damage is often encountered during TEM measurements especially if components such as poly(methacrylates) are present. In contrast, SFM measurements can be assumed not to significantly change the phase dimensions of the components.     

The response of SiC fibres to vacuum plasma spraying and vacuum hot pressing during the fabrication of titanium matrix composites

Vacuum plasma spraying (VPS) and vacuum hot pressing (VHP) have been used to fabricate Ti-6Al-4V matrix composite material reinforced longitudinally with DERA Sigma C coated SiC 1140+ fibres. VPS of Ti-6Al-4V onto Sigma 1140+ SiC fibres caused no fibre/matrix interfacial reaction. During VHP a fibre/matrix reaction occurred, producing a mixture of fine (< 50 nm) TiC_x (x ≤ 1) adjacent to the fibre coating and coarse-grained (0.3–0.5 μm) equiaxed TiC_x adjacent to the Ti matrix. A decrease in C concentration with increasing distance from the C coating is proposed, and is consistent with the evidence presented. A similar thickness and morphology of reaction product arose from conventional foil–fibre foil processing, but the matrix coated fibre/hot isostatic pressing process led to a slightly thicker reaction layer. The TiC_x reaction product acted as a diffusion barrier, inhibiting further reaction more effectively than in experiments on earlier SiC fibres having a C coating. Surface damage was shown to be a factor in lowering 1140+ SiC fibre failure stress. Surface damage to 1140+ fibres resulted from both VPS and VHP, the former causing a slight reduction in mean ultimate tensile strength (UTS), and a large reduction in the bend strain to failure Weibull modulus. This damage was caused by both fibre winding and by deposition of metal during VPS, giving rise to coating flaws, and is not in itself considered to be a major problem. Surface damage increased after VHP, reducing the mean UTS and tensile Weibull modulus, and the mean bend strain to failure. This damage arose from bending and flattening of the rough monotapes, and from the fibre/matrix reaction caused by thermal exposure. The level of damage to 1140+ SiC fibre from VHP was reduced by modification of the process path. Increasing the VHP temperature and lowering the pressure ramp rate reduced fibre damage sufficiently to enable a macroscopic composite UTS of 95% of the theoretical maximum to be achieved.     

High-resolution scanning electron microscopy of immunogold-labelled cells by the use of thin plasma coating of osmium

The feasibility of plasma coating of a thin osmium layer for high‐resolution immuno‐scanning electron microscopy of cell surfaces was tested, using Drosophila embryonic motor neurones as a model system. The neuro‐muscular preparations were fixed with formaldehyde and labelled with a neurone‐specific antibody and 10 or 5 nm colloidal gold‐conjugated secondary antibodies. The specimens were post‐fixed with osmium tetroxide and freeze‐dried. Then they were coated with a 1–2 nm thick layer of osmium using a hollow cathode plasma coater. The thin and continuous coating of amorphous osmium gave good signals of gold particles and fine surface structures of neurites in backscattered electron images simultaneously. This method makes it possible to visualize the antigen distribution and the three‐dimensionally complex surface structures of cellular processes with a resolution of several nanometres.     

Correlative microscopy: a potent tool for the study of rare or unique cellular and tissue events

Biological studies have relied on two complementary microscope technologies – light (fluorescence) microscopy and electron microscopy. Light microscopy is used to study phenomena at a global scale to look for unique or rare events, and it also provides an opportunity for live imaging, whereas the forte of electron microscopy is the high resolution. Traditionally light and electron microscopy observations are carried out in different populations of cells/tissues and a 'correlative' inference is drawn. The advent of true correlative light-electron microscopy has allowed high-resolution imaging by electron microscopy of the same structure observed by light microscopy, and in advanced cases by video microscopy. Thus a rare event captured by low-resolution imaging of a population or transient events captured by live imaging can now also be studied at high resolution by electron microscopy. Here, the potential and difficulties of this approach, along with the most impressive breakthroughs obtained by these methods, are discussed.     

The interaction of biological molecules with clay minerals: a scanning force microscopy study

We have used the technique of scanning force microscopy (SFM) to investigate the reaction of both amino acids and activated nucleotides in the presence of the clay mineral Cu(II)-exchanged hectorite. Using simulated prebiotic heating and wetting cycles, we have shown that the clay mineral acts to adsorb, concentrate, and subsequently catalyze the polymerization of these biological monomers into short peptides and oligonucleotides. The presence of the Cu(II) cations within the clay intergallery regions, and at surface step edges and cracks, is crucial for the observed reactions to occur. Clay minerals such as hectorite may have thus played an important role in the evolution of biologically viable molecules on the prebiotic earth.     

Cellulose microfibril deposition: coordinated activity at the plant plasma membrane

Plant cell wall production is a membrane-bound process. Cell walls are composed of cellulose microfibrils , embedded inside a matrix of other polysaccharides and glycoproteins. The cell wall matrix is extruded into the existing cell wall by exocytosis. This same process also inserts the cellulose synthase complexes into the plasma membrane. These complexes, the nanomachines that produce the cellulose microfibrils, move inside the plasma membrane leaving the cellulose microfibrils in their wake. Cellulose microfibril angle is an important determinant of cell development and of tissue properties and as such relevant for the industrial use of plant material. Here, we provide an integrated view of the events taking place in the not more than 100 nm deep area in and around the plasma membrane, correlating recent results provided by the distinct field of plant cell biology. We discuss the coordinated activities of exocytosis, endocytosis, and movement of cellulose synthase complexes while producing cellulose microfibrils and the link of these processes to the cortical microtubules.     

The preparation of leaf surfaces for scanning electron microscopy: a comparative study

Cryopreservation is the superior technique for viewing leaf surfaces in the SEM. Epidermal cells become distorted when freeze dried and disrupt the orientation of epicuticular wax structures. The latter are largely lost during critical point drying. Nevertheless, the appearance of surface structures after subjecting them to each drying method is valuable in interpreting the features observed by cryopreservation.     

An integrated approach to the study of living cells by atomic force microscopy

We describe a technique for studying living cells with the atomic force microscope (AFM) in tapping mode using a thermostated, controlled-environment culture system. We also describe the integration of the AFM with bright field, epifluorescence and surface interference microscopy, achieving the highest level of integration for the AFM thus far described. We succeeded in the continuous, long-term imaging of relatively flat but very fragile cytoplasmic regions of COS cells at a lateral resolution of about 70 nm and a vertical resolution of about 3 nm. In addition, we demonstrate the applicability of our technology for continuous force volume imaging of cultured vertebrate cells.
The hybrid instrument we describe can be used to collect simultaneously a diverse variety of physical, chemical and morphological data on living vertebrate cells. The integration of light microscopy with AFM and steady-state culture methods for vertebrate cells represents a new approach for studies in cell biology and physiology.     

Comparisons of the low-resolution structures of ornithine decarboxylase by electron microscopy and X-ray crystallography: The utility of methylamine tungstate stain and butvar support film in the study of macromolecules by transmission electron microscopy

The structure of ornithine decarboxylase (M_r ≈? 1.04 × 10⁶) from Lactobacillus 30a was investigated by electron microscopy and x-ray crystallography. Electron micrographs showed the structure to be well preserved in methylamine tungstate stain. The molecules interacted little with the Butvar support film, yielding three unique projections: a hexagonal ring (front view) and two rod-shaped projections (edge views). Stereo pairs revealed a novel feature of the Butvar film in that some molecules were suspended in the stain in random orientations. Consequently, the relatedness of the hexagonal ring and the rod-shaped particles could be demonstrated since some particle shapes interconverted when the stage was tilted ± 45°. The two edge views were related by a 30° rotation about the sixfold axis. Image averaging of the three primary views suggested a dodecamer (point group symmetry 622) composed of two hexameric rings, apparently in an eclipsed configuration. To investigate the structural organization of the complex, the dissociation of the enzyme was studied by electron microscopy. The dissociation process involved the initial breakage of the ring followed by separation of dimers from the ring (one subunit from each of the two hexamers). Thus, the dodecamer forms as a hexamer of dimers rather than a dimer of hexamers. These structural studies were confirmed and extended by x-ray crystallographic analysis. A 4.0-Å resolution electron density map revealed two hexameric rings, consisting of six closely associated dimers, tilted approximately 10° with respect to the molecular twofold axis. Electron density projections of the three primary views of the molecule derived from the x-ray data corresponded closely to those obtained from image averaging of the electron microscopy data, thereby establishing in a novel way the reliability of the electron microscopy studies. Methylamine tungstate stain and Butvar support film therefore offer unique advantages for investigating protein structures by electron microscopy.     

Surface imaging in near-field optical microscopy by using the fluorescence decay rate: a theoretical study

In this paper, we study the fluorescence decay rate of a molecule above a corrugated interface, and particularly the variations of the decay rate as a function of the lateral position of the molecule. As a first step, one has to determine the field diffracted by a corrugated interface when the incident field is the field emitted by a dipole. For this purpose, we have used a perturbative Rayleigh method, and we show that the decay rate variations can be connected to the surface profile via a transfer function. Some numerical calculations of this transfer function and of decay rate variation images are presented for dielectric and metallic samples. The visibility of the theoretical images is up to 20% and, moreover, resolution of the images is good enough to use the fluorescence lifetime of molecules as signal in a life-time scanning near-field optical microscope. The technical problems are discussed briefly.     

Ultrastructure of activated mouse platelets: a qualitative scanning electron microscopy study

Platelets form an integral part of the coagulation process, and their ultrastructure can provide valuable information regarding diseases associated with hemostasis. During coagulation, platelets aggregate; this aggregation can be achieved in vitro, by adding thrombin to platelet-rich plasma. Previous research showed that human thrombin could be used successfully to activate mouse platelets. When conservative changes are included, the amino acid similarity between human and mouse thrombin is approximately 75%. In this qualitative study, we compare the ultrastructure of mouse platelet aggregates activated by human thrombin as well as two concentrations of mouse thrombin, using the scanning electron microscope. Results show that both human and mouse thrombin activate platelets to form aggregates with typical pseudopodia formation. Magnification up to 250,000x showed membrane morphology with the open canalicular system pores visible in both the mouse- and human-activated platelets. It is therefore concluded that mouse platelets can be successfully aggregated using either mouse or human thrombin.     

Atomic force microscopy study of the antibacterial effects of chitosans on Escherichia coli and Staphylococcus aureus

Chitosan has been reported to be a non-toxic, biodegradable antibacterial agent. The aim of this work was to elucidate the relationship between the molecular weight of chitosan and its antimicrobial activity upon two model microorganisms, one Gram-positive (Staphylococcus aureus) and one Gram-negative (Escherichia coli). Atomic force microscopy (AFM) imaging was used to obtain high-resolution images of the effect of chitosans on the bacterial morphology. The AFM measurements were correlated with viable cell numbers, which show that the two species reacted differently to the high- and low-molecular-weight chitosan derivatives. The images obtained revealed not only the antibacterial effects, but also the response strategies used by the bacteria; cell wall collapse and morphological changes reflected cell death, whereas clustering of bacteria appeared to be associated with cell survival. In addition, nanoindentation experiments with the AFM revealed mechanical changes in the bacterial cell wall induced by the treatment. The nanoindentation results suggested that despite little modification observed in the Gram-positive bacteria in morphological studies, cell wall damage had indeed occurred, since cell wall stiffness was reduced after chitooligosaccharide treatment.