Interaction of acridine orange with teichoic acids of Staphylococcus aureus]

Teichoic acids of the cell wall of Staphylococcus aureus 209-P belong to the class of ribitol teichoic acids and can bind actively the molecules or acridine orange, changing its optical properties. The intravital fluorochromy of the cells with acridine orange may be caused by the sorption of its molecules by the teichoic acids of the cell wall.     

Interaction of poly- ,L-glutamic acid with acridine orange

Interaction of poly-α,L -glutamic acid (PGLA) with acridine orange (AO) was studied with circular dichroism and absorption spectra measurements. The following results were observed: (1) the addition of a comparable amount of AO with the glutamyl residue to the PLGA solution at pH of 4.5 reduced the fraction of helix of the polymer; (2) when AO was added to the PGLA solution, the pH range of the helix-coil transition of the polymer shifted toward higher pH regions; and (3) when the mixture of the same amount of AO and the glutamyl residue was brought to the neutral and alkaline pH region, some induced circular dichroism bands were observed. In this case, it was assumed that PLGA in the system takes a helical form due to the neutralization of the anionized side chains by the cationic species of AO. We concluded that AO molecules bound to the carboxylate groups of the side chains of PLGA arrange to from a righthanded super-helix which surrounds the core of the righthanded α-helix of PLGA.     

Interaction between acridine orange and polyriboadenylic acid

The absorption spectra and circular dichroism of aqueous solutions of acridine orange mixed with polY(riboadenylic acid) [poly(rA)] have been measured for different mixing ratios at acid and neutral pH. The binding ratio of dye to poly(rA) has been determined by equilibrium dialysis. At acid pH where poly(rA) is in a double-stranded helix, monomeric dye molecules are intercalated between base pairs, first sparsely and then at neighbouring sites with mutual coupling, as the nucleotide-to-dye mixing ratio decreases. In the presence of excess dye, dimeric dye molecules of antiparallel type are bound to phosphate groups electrostatically and stack together to form linear sequences along a poly(rA) chain. At neutral pH where poly(rA) is single-stranded, isolated intercalation of monomeric dye molecules can occur in the helical parts. At intermediate mixing ratios, half-intercalated dimeric dye molecules are bound to adjacent sites and electronically coupled, inducing characteristic circular dichroism. In the presence of higher amounts of dye, external stacking of dimeric dye molecules of antiparallel type occurs along a poly(rA) chain. The binding of dye cations is suppressed to some degree at acid pH compared to that at neutral pH, owing to the repulsion exerted by protonated adenine bases.     

Interaction of Staphylococcus aureus alpha-toxin with eukaryotic cells and their target

In this review information on S. aureus alpha-toxin is expounded. The data on the targets of the action of the toxin on eukaryotic cells, its activity with respect to different membrane structures, effects established in the interaction of toxin and cell elements, as well as of its biological action on the macroorganism, are presented. Information on the factors inactivating the cytolytic action of the toxin is given.     

Interaction of triosephosphate isomerase from Staphylococcus aureus with plasminogen

Triosephosphate isomerase (TPI; EC 5. 3. 1. 1) displayed on the cell surface of Staphylococcus aureus acts as an adhesion molecule that binds to the capsule of Cryptococcus neoformans, a fungal pathogen. This study investigated the function of TPI on the cell surface of S. aureus and its interactions with biological substances such as fibronectin, fibrinogen, plasminogen, and thrombin were investigated. Binding of TPI to plasminogen was demonstrated by both surface plasmon resonance analysis and Far‐Western blotting. It is suggested that lysine residues contribute to this binding because the interaction was inhibited by ?‐aminocaproic acid. Activation of plasminogen to plasmin by staphylokinase or tissue plasminogen activator decreased in the presence of TPI, whereas TPI was degraded by plasmin. In other experiments, intact S. aureus cells had the ability to both increase and decrease plasminogen activation depending on the number of cells. Several molecules expressed on the surface of S. aureus were predicted to interact with plasminogen, resulting in its increased or decreased activation. These findings indicate that S. aureus sometimes localizes and sometimes disseminates in the host, depending on the molecules expressed under various conditions.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange

Summary Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and mucopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracellular dye contents as low as 5×10^–16 mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Interaction of the alpha-toxin of Staphylococcus aureus with the liposome membrane

When the liposome membrane is exposed to the alpha-toxin of Staphylococcus aureus, fluorescence of the tryptophan residue(s) of the toxin molecule increases concomitantly with the degree of toxin-hexamer formation (Ikigai, H., and Nakae, T. (1985) Biochem. Biophys. Res. Commun. 130, 175-181). In the present study, the toxin-membrane interaction was distinguished from the hexamer formation by the fluorescence energy transfer from the tryptophan residue(s) of the toxin molecule to the dansylated phosphatidylethanolamine in phosphatidylcholine liposome. Measurement of these two parameters yielded the following results. The effect of the toxin concentration and phospholipid concentration on these two parameters showed first order kinetics. The effect of liposome size on the energy transfer and the fluorescence increment of the tryptophan residue(s) was only detectable in small liposomes. Under moderately acidic or basic conditions, the fluorescence energy transfer always preceded the fluorescence increment of the tryptophan residue(s). The fluorescence increment at 336 nm at temperatures below 20 degrees C showed a latent period, whereas the fluorescence energy transfer did not. These results were thought to indicate that when alpha-toxin damages the target membrane, the molecule interacts with the membrane first, and then undergoes oligomerization within the membrane.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange.

Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and muscopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracelluar dye contents as low as 5 X 10(-16) mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Photodynamic inactivation of newcastle disease virus with acridine orange

[This corrects the article on p. 1453 in vol. 15.].