Polyelectrolyte layer interpenetration and swelling of alginate–chitosan multilayers studied by dual wavelength reflection interference contrast microscopy

Polyelectrolyte multilayers of alginate and either poly-l-lysine or chitosan have been studied with dual wavelength reflection interference contrast microscopy (DW-RICM). Alginates with different ratios of the two monomer residues, β-d-mannuronic acid (M) and -l-guluronic acid (G) were included to study possible effects of specific divalent ions selected from their ability to influence gelation of alginate. Measurements of multilayer thickness revealed the importance of the preparation conditions. The multilayer thickness was reduced with increasing ionic strength following preparation, suggesting a dominance of an ordinary screening of the alginate component. The results indicate that the interaction between alginate and chitosan are different from that between alginate and poly-l-lysine, with the latter appearing to be more of a “hit-and-stick” reaction while rearrangements during the adsorption process is occurring to a larger extent in the preparation of the chitosan–alginate multilayers.     

Adhesion patterns of cell interactions revealed by reflection contrast microscopy

Reflection contrast in combination with phase contrast microscopy was utilized for the study of adhesion patterns of locomotive L5222 rat leukemia cells. It was found that for cells moving in a spherical shape on the glass surface, adhesions were very faint. This inconspicuous pattern, however, became very distinct, as soon as the cells changed to a flattened configuration. Such a change took place when leukemia cells came into contact with other spread cells and started to move under these cells. Reflection contrast further showed that in the pathway of the locomoting L5222 cells the adhesions of the overlying spread cells were momentarily detached from the substrate. It is concluded that the combination of reflection contrast and phase contrast represents a good tool for gaining new information on the interaction of motility and formation of adhesions.     

New sensitive light microscopical detection of colloidal gold on ultrathin sections by reflection contrast microscopy. Combination of reflection contrast and electron microscopy in post-embedding immunogold histochemistry.

One simple post-embedding method for combined light- and electron microscopy is presented. Different types of antigens in normal rat and mouse kidneys as well as in tissues from cases of experimental induced nephritis were stained after Lowicryl K4M embedding by an immunogold (silver) method. The (silver-enhanced) gold particles were visualized by light microscopy, e.g. bright-field (BFM)- and reflection contrast (RCM) microscopy, as well as by electron microscopy. The potentials of RCM visualization in this field were investigated, resulting in the successful detection of colloidal gold (15 nm) particles, or silver enhanced gold particles, on ultrathin sections. Furthermore, an increased detection sensitivity of RCM compared with BFM together with an increase in the sensitivity of the immunostaining by RCM visualization was found. The different ways to use RCM, alone or in combination with bright-field- or phase contrast microscopy for visualization of plastic sections varying in thickness, type of plastic and staining, are discussed.     

Cell-to-substrate adhesions during spreading and locomotion of carcinoma cells : A study by microcinematography and reflection contrast microscopy

Motility and patterns of adhesion were determined by time-lapse cinematography and reflection contrast microscopy for two types of carcinoma cells, selected for their different motile behavior and not for their malignancy. Cells from the V2 rabbit carcinoma become locomotory soon after having established the necessary contact to the substratum. In contrast, cells from a human epidermoid carcinoma (LICR-OC-1) first attain a fully spread configuration before some cells slightly round up again for a slow locomotory activity of short range and duration. Reflection contrast showed that during spreading and locomotion, the cells from both carcinomas displayed a predominance of grey, the color associated with close contacts. Fully spread cells, on the other hand, presented a multitude of focal contacts in individually different arrangements of black streaks and dots, randomly distributed over the entire cell area. The functional meaning of this heterogeneity in the arrangement of focal contacts in fully spread cells is not yet understood. The importance of close contacts for spreading and locomotion, however, seems to be established and is in agreement with findings reported for other cell types engaged in the same activities. It is therefore suggested that the formation of substrate contacts depends on cellular activity rather than on the cell type.     

Distribution of injected MRI contrast agents in mouse livers studied by confocal and SIMS microscopy

OBJECTIVE: To localize magnetic resonance imaging (MRI) contrast agents injected intravenously into mouse livers. STUDY DESIGN: Parallel studies were performed on fluorescent europium and nonfluorescent, paramagnetic gadolinium and on a product combining nanoparticles of Fe and Texas Red to obtain combined information on the distribution of these molecules inside the liver. The distribution of different superparamagnetic iron oxides was also studied because the size of these new compounds is not always convenientfor microcirculation studies. RESULTS: Europium and Texas Red can be detected by confocal microscopy. Europium, iron and gadolinium can be detected by secondary ion mass spectrometry (SIMS) microscopy. Studies confirmed the complementarity of both microscopies. They also confirmed the possibility of using europium as a model of gadolinium to analyze thefate of MRI contrast agents. CONCLUSION: The methodology can be used on mice injected intravenously and analyzed by confocal and SIMS microscopy to localize MRI contrast agents inside cellular and tissue specimens of mice.     

The process of epithelial cell attachment to glass surfaces studied by reflexion contrast microscopy

The process of attachment was studied in primary mouse kidney epithelial cell cultures by means of reflexion contrast microscopy, a method developed for studying the cell membrane-substrate relationship. The first in a series of events is simple adherence to the substrate, called close contact. This phenomenon is associated with the greatest extension of lamellar cytoplasm and the fewest number of cell nuclei/unit area. The nuclei of such cells are in close contact with the bottom portion of the cell membrane. Approx. 24 h after planting, as the cultures become more crowded, cells develop a different kind of attachment to the substrate—focal contacts—that are correlated with a decrease in lamellar cytoplasm. Cells detached from the substrate after close contact formation readily reattach, while cells detached after formation of focal contacts do not reattach. After incubation for periods greater than 5 days, the dense cultures degenerate and cells lose their attachment to the glass surface.     

Structural organization of interphase 3T3 fibroblasts studied by total internal reflection fluorescence microscopy

We studied the laminar organization of 3T3 fibroblast cells growing on glass slides by use of total internal reflection illumination to excite fluorescence emission (TIRF) from labeled molecules and stained cellular compartments that are very close to the cell-substrate contact region. Mitochondria, distant from the contact regions and stained with the water-soluble cationic dye, dil-C3-(3), fluoresced only as the glass/cytoplasm critical angle was approached. A similar result was obtained when the nuclei were stained with Hoechst dye 33342. From this measured angle a cytoplasmic refractive index in the range 1.358-1.374 was computed. The plasma membrane of 3T3 cells was stained with dil-C18-(3), and the cytoplasmic compartment was stained with fluoresceinyl-dextran (FTC-dextran) or with carboxyfluorescein. We have demonstrated a high degree of correspondence between the low-reflectance zones in the reflection interference image of a live cell and the TIRF images of both the plasma membrane and cytoplasmic compartment. TIRF photometry of selected contact regions of cells provided data from which the absolute separation of cell and substrate was computed. From a population of 3T3 cells microinjected with fluorescein-labeled actin, motile and adherent interphase cells were selected for study. For adherent cells, which displayed fluorescent stress fibers, the TIRF image was composed of intense patches and less intense regions that corresponded, respectively, to the focal contact and close-contact zones of the reflection-interference image. The intense patches corresponded to the endpoints of the stress fibers. Cells of motile morphology, which formed some focal contacts and extensive close-contact zones, gave AF-actin TIRF images of relatively even intensity. Thin lamellar regions of the cytoplasm were found to contain concentrations of actin not significantly different from other close-contact regions of the cell. The major analytical problem of TIRF microscopy is separation of the effects of proximity to substrate, refractive index, and fluorescent probe concentration on the local brightness of the TIRF image. From our results, it appears possible to use TIRF microscopy to measure the proximity of different components of substrate contact regions of cells.     

Locomotion and adhesion of polymorphonuclear leukocytes. Effects of the supporting substratum

Contact angle measurements have been used to correlate surface hydrophobicity of a supporting substratum with adhesion and locomotion of polymorphonuclear leukocytes. The binding of human serum albumin, a well-known chemokinetic substance, to hydrophilic glass slides gave rise to hydrophobic surfaces with adhesive properties conductive to cell polarization, thus allowing cell locomotion. Parallel contact angle and cell adhesion measurements suggested that albumin modified the cell-substratum interaction by increasing the van der Waals forces of attraction and reducing the electrostatic forces. By allowing cells to adhere to a hydrophobic surface (siliconized glass), it was found that protein could be omitted from in vitro test systems for leukocyte locomotion. It is suggested that quantitatively equal cell adhesion values may, depending on the type of attraction forces working in adhesion to the substratum, result in different locomotion patterns.     

Imaging of immunogold labelled antigens on capping thymocytes by confocal reflection contrast scanning optical microscopy

Confocal laser scanning optical microscopy (CLSM) in the reflection contrast mode has been used to image single 40 nm gold particles, and to study changes in the distribution of gold label associated with capping of the leukocyte sialoglycoprotein (LSGP) antigen on the surface of fixed rat thymocytes, labelled with the mouse monoclonal antibody W3/13 and a goat anti-mouse IgG immunogold conjugate. This imaging method has also been applied to live thymocytes labelled with gold-conjugated antibodies, to study the dynamics of the capping process.     

Immobilized thylakoids in a cross-linked albumin matrix: effects of cations studied by electron microscopy, fluorescence emission, photoacoustic spectroscopy, and kinetic measurements

Immobilization of lettuce (Lactuca sativa) thylakoids has been performed by using glutaraldehyde and bovine serum albumin. Confirming previous reports, a stabilization of the O₂ evolution activity of the photosystem II (PSII) under storage and functional conditions has been observed. The present work is devoted to the role played by mono-and divalent cations, during the immobilization process itself, on the O₂ production. Four types of measurements have been employed: kinetic measurements, low temperature (77 K) fluorescence emission, photoacoustic (PA) spectroscopy, and electron microscopy observations. We show that the effect of glutaraldehyde is complex because it acts as an inhibitor, a stabilizing agent, and a cross-linking reactive. In the present studies, the thylakoids are immobilized within a polymeric insoluble albumin matrix. The highest activity yield and the best storage conditions are obtained when 0.15 mm Na⁺ (or K⁺), 1 mm Mg²⁺, and 0.1 mm Mn²⁺ are present in the resuspending media before the immobilization. Due to modifications of the ionic content during such a process, structural differences are observed on the stacking degree of thylakoids. No modification of the fluorescence and PA spectra after the immobilization are found. Furthermore, a correlation between activities and spectral changes have been shown: when the activities increase, the F₇₃₅ to F₆₉₅ ratio increases and the PA₆₇₆ to PA₄₄₀ ratio decreases.     

New sensitive light microscopical detection of colloidal gold on ultrathin sections by reflection contrast microscopy

Summary One simple post-embedding method for combined light- and electron microscopy is presented. Different types of antigens in normal rat and mouse kidneys as well as in tissues from cases of experimental induced nephritis were stained after Lowicryl K4M embedding by an immunogold (silver) method. The (silver-enhanced) gold particles were visualized by light microscopy, e.g. bright-field (BFM)- and reflection contrast (RCM) microscopy, as well as by electron microscopy. The potentials of RCM visualization in this field were investigated, resulting in the successful detection of colloidal gold (15 nm) particles, or silver enhanced gold particles, on ultrathin sections. Furthermore, an increased detection sensitivity of RCM compared with BFM together with an increase in the sensitivity of the immunostaining by RCM visualization was found. The different ways to use RCM, alone or in combination with bright-field- or phase contrast microscopy for visualization of plastic sections varying in thickness, type of plastic and staining, are discussed.     

Reversible and irreversible adhesion of motile Escherichia coli cells analyzed by total internal reflection aqueous fluorescence microscopy

The initial events in bacterial adhesion are often explained as resulting from electrostatic and van der Waals forces between the cell and the surface, as described by DLVO theory (developed by Derjaguin, Landau, Verwey, and Overbeek). Such a theory predicts that negatively charged bacteria will experience greater attraction toward a negatively charged surface as the ionic strength of the medium is increased. In the present study we observed both smooth-swimming and nonmotile Escherichia coli bacteria close to plain, positively, and hydrophobically coated quartz surfaces in high- and low-ionic-strength media by using total internal reflection aqueous fluorescence microscopy. We found that reversibly adhering cells (cells which continue to swim along the surface for extended periods) are too distant from the surface for this behavior to be explained by DLVO-type forces. However, cells which had become immobilized on the surface did seem to be affected by electrostatic interactions. We propose that the "force" holding swimming cells near the surface is actually the result of a hydrodynamic effect, causing the cells to swim at an angle along the glass, and that DLVO-type forces are responsible only for the observed immobilization of irreversibly adhering cells. We explain our observations within the context of a conceptual model in which bacteria that are interacting with the surface may be thought of as occupying one of three compartments: bulk fluid, near-surface bulk, and near-surface constrained. A cell in these compartments feels either no effect of the surface, only the hydrodynamic effect of the surface, or both the hydrodynamic and the physicochemical effects of the surface, respectively.     

Influence of polylysine on adhesion of fibroblasts to glass substrates visualized by total internal reflection microscopy

The cell adhesion topography of mouse fibroblasts growing on glass substrates has been investigated. In order to compare cell adhesion on covered and uncovered glass, substrates were partly exposed to a solution with 0.1 mg/ml polylysine (300 kDa) for 15 min before incubation with cell suspension. After cultivation for 1, 3, 6, and 24 h their adhesion was visualised by total internal reflection microscopy. In the presence of polylysine, cells incubated for 1 h were strongly attracted to the substrate, leading to a typical cell adhesion topography characterised by round concavities under the ventral cell membrane with an approximate diameter of 1 μm. The cavity-surrounding rims were tightly bound to the glass surface. During further cell cultivation, the topography changed into a well-organised adhesion pattern with focal contact areas on the periphery of the cells. In contrast to the polylysine-mediated adhesion, cells growing on untreated surfaces did not exhibit the cavity-like topography at any stage of cultivation, but a more point spread adhesion with a dense clustering of contact-forming areas.     

Effects of endothelial basement membrane on neutrophil adhesion and migration

The influence of the sub-endothelial basement membrane (BM) on the adhesion and migration of leukocytes is not well-defined. We therefore investigated the behaviour of human neutrophils on purified BM proteins and on BM deposited by short- or long-term cultures of endothelial cells (EC). The adhesion, but not migration velocities, of neutrophils activated with interleukin-8 was dependent on the coating concentrations of purified collagen, laminin or fibronectin. In contrast, adhesion was similar on matrices deposited by 3-day or 20-day cultures of EC, but neutrophils migrated more slowly on the distinct BM that formed over 20 days. In addition, while adhesion on all surfaces was greatly reduced when neutrophils were treated with antibody against β₂-integrins, antibody against β₁-integrins only inhibited adhesion to the 20-day BM. Thus, the native BM has distinct effects on integrin usage and migration by neutrophils, which are not reproduced by purified proteins or matrix deposited early during endothelial culture.     

A new type of substratum adhesion structure in NRK cells revealed by correlated interference reflection and electron microscopy

The substratum adherent membrane of NRK cells in vitro has been studied using correlated interference reflection and surface replica electron microscopy. Structures visualized by interference reflection microscopy were identified in the subsequently prepared platinum-carbon replicas of the adherent membranes. Substratum adherent membranes were prepared using a hypotonic shock/cell shearing technique (lysis-squirting). Typically 20% of the original ventral membrane surface area and 50% of the original focal adhesion number were retained. Microfilament bundle termini, clathrin-coated sheets and pits, cytotic vesicles having a ridged surface and groups of membrane associated particles were well preserved in the replicas. Two types of isolated adhesion structures were found after lysis-squirting. In addition to typical elongate focal adhesions containing actin and vinculin, we report the existence of adherent membrane patches lacking microfilament bundles and negative for vinculin labelling, but coated with clathrin and identifiable in interference reflection microscopy as less dark than focal adhesions and having dot, U- or sinusoidal shapes.     

Effects of C-reactive protein on human neutrophil granulocytes challenged with N-formyl-methionyl-leucyl-phenylalanine and platelet-activating factor

The effects of C-reactive protein (CRP), the prototypical acute-phase reactant were studied on human polymorphonuclear leukocytes (PMNL) challenged with N-formyl-methionyl-leucyl-phenylalanine (fMLP) and platelet-activating factor (PAF). CRP at 8-64 micrograms/ml concentrations inhibited degranulation and superoxide production by PMNL in time-, and dose-dependent manner and stabilized PMNL membranes against the lytic effect of lysophosphatidylcholine. CRP was also capable of binding PAF and in lesser extent fMLP. Furthermore, CRP, 32 micrograms/ml, diminished specific binding of [3H]-fMLP and [3H]-PAF to PMNL. These findings imply that CRP may play an important protective role during the early phase of acute inflammatory reactions.     

Synthesis and secretion of fibrinogen and albumin by isolated rat hepatocytes

In order to investigate the regulation of synthesis of some of the plasma proteins, especially fibrinogen, at the cellular level, we have chosen to work with suspensions of hepatocytes isolated by the perfusion of rat liver with crude bacterial collagenase. By adding soybean trypsin inhibitor to the collagenase and by avoiding mechanical damage, we have prepared cell suspensions that synthesize and secrete fibrinogen and albumin and that survive for longer than twenty hours. The fibrinogen secreted is clottable and shows the same pattern in acrylamide gel electrophoresis as fibrinogen purified from rat plasma. After a three hour lag, the rate of synthesis of fibrinogen, as measured by a solid-phase radioimmunoassay, continually accelerates, so that rates several fold greater than the $\text{in vivo}$ rate have been observed after twenty hours incubation. Cycloheximide (0.1 mM) completely abolished the appearance of fibrinogen in the medium; whereas colchicine (0.3 mM) reduced the rate by 85%. Insulin and cortisol succinate enhanced fibrinogen synthesis and secretion. The albumin secretion profile differs in several respects from that of fibrinogen, reflecting differences in intracellular pool levels and probably distinct regulatory mechanisms.