Number Of Charged Groups Research Articles

Structural Properties Dictating Selective Optotracer Detection of Staphylococcus aureus.

Optotracers are conformation‐sensitive fluorescent tracer molecules that detect peptide‐ and carbohydrate‐based biopolymers. Their binding to bacterial cell walls allows selective detection and visualisation of Staphylococcus aureus (S. aureus). Here, we investigated the structural properties providing optimal detection of S. aureus. We quantified spectral shifts and fluorescence intensity in mixes of bacteria and optotracers, using automatic peak analysis, cross‐correlation, and area‐under‐curve analysis. We found that the length of the conjugated backbone and the number of charged groups, but not their distribution, are important factors for selective detection of S. aureus. The photophysical properties of optotracers were greatly improved by incorporating a donor‐acceptor‐donor (D‐A‐D)‐type motif in the conjugated backbone. With significantly reduced background and binding‐induced on‐switch of fluorescence, these optotracers enabled real‐time recordings of S. aureus growth. Collectively, this demonstrates that chemical structure and photophysics are key tunable characteristics in the development of optotracers for selective detection of bacterial species.

Phase Behavior of Melts of Diblock-Copolymers with One Charged Block.

In this work, we investigated the phase behavior of melts of block-copolymers with one charged block by means of dissipative particle dynamics with explicit electrostatic interactions. We assumed that all the Flory–Huggins χ parameters were equal to 0. We showed that the charge- correlation attraction solely can cause microphase separation with a long-range order; a phase diagram was constructed by varying the volume fraction of the uncharged block and the electrostatic interaction parameter λ (dimensionless Bjerrum length). The obtained phase diagram was compared to the phase diagram of “equivalent” neutral diblock-copolymers with the non-zero χ-parameter between the beads of different blocks. The neutral copolymers were constructed by grafting the counterions to the corresponding co-ions of the charged block with further switching off the electrostatic interactions. Surprisingly, the differences between these phase diagrams are rather subtle; the same phases in the same order are observed, and the positions of the order-disorder transition ODT points are similar if the λ-parameter is considered as an “effective” χ-parameter. Next, we studied the position of the ODT for lamellar structure depending on the chain length N. It turned out that while for the uncharged diblock copolymer the product χcrN was almost independent of N, for the diblock copolymers with one charged block we observed a significant increase in λcrN upon increasing N. This can be attributed to the fact that the counterion entropy prevents the formation of ordered structures, and its influence is more pronounced for longer chains since they undergo the transition to ordered structures at smaller values of λ, when the electrostatic energy becomes comparable to kbT. This was supported by studying the ODT in diblock-copolymers with charged blocks and counterions cross-linked to the charged monomer units. The ODT for such systems was observed at significantly lower values of λ, with the difference being more pronounced at longer chain lengths N. The fact that the microphase separation is observed even at zero Flory–Huggins parameter can be used for the creation of “high-χ” copolymers: The incorporation of charged groups (for example, ionic liquids) can significantly increase the segregation strength. The diffusion of counterions in the obtained ordered structures was studied and compared to the case of a system with the same number of charged groups but a homogeneous structure; the diffusion coefficient along the lamellar plane was found to be higher than in any direction in the homogeneous structure.

Rheological characterization of yield stress gels formed via electrostatic heteroaggregation of metal oxide nanoparticles.

Mixtures of fumed fractal metal oxide nanoparticles (np's) dispersed in water, at a solution pH where one species is positively charged and the other is negatively charged, form yield stress gels at volume fractions as low as 1.5%, due to electrostatic heteroaggregation into networks as confirmed by small-angle neutron scattering. These gels exhibit a measurable yield stress and an apparent viscosity that follows a power law relationship with shear rate. Rotational and oscillatory shear rheology is presented for binary mixtures of fumed silica, fumed alumina, and fumed titania in aqueous dispersions. Gels were characterized at various particle concentrations, solution pHs, mixture ratios, and salt concentrations. The strength of the gel network, as evaluated by the storage modulus and yield stress, is maximized when the mixture contains a mixture of particles with an approximately equal, but opposite, number of charged groups.

Persistence Length of Wormlike Micelles Composed of Ionic Surfactants: Self-Consistent-Field Predictions

The persistence length of a wormlike micelle composed of ionic surfactants C(n)E(m)X(k) in an aqueous solvent is predicted by means of the self-consistent-field theory where C(n)E(m) is the conventional nonionic surfactant and X(k) is an additional sequence of k weakly charged (pH-dependent) segments. By considering a toroidal micelle at infinitesimal curvature, we evaluate the bending modulus of the wormlike micelle that corresponds to the total persistence length, consisting of an elastic/intrinsic and an electrostatic contribution. The total persistence length increases with pH and decreases with increasing background salt concentration. We estimate that the electrostatic persistence length l(p,e)(0) scales with respect to the Debye length kappa(-1) as l(p,e)(0) approximately kappa(-p) where p approximately 1.98 for wormlike micelles consisting of C(20)E(10)X(1) surfactants and p approximately 1.54 for wormlike micelles consisting of C(20)E(10)X(2) surfactants. The total persistence length l(p,t)(0) is a weak function of the head group length m but scales with the tail length n as l(p,t)(0) approximately n(x) where x approximately 2-2.6, depending on the corresponding head group length. Interestingly, l(p,t)(0) varies nonmonotonically with the number of charged groups k due to the opposing trends in the electrostatic and elastic bending rigidities upon variation of k.

Cholic Acid-Derived Facial Amphiphiles with Different Ionic Characteristics

A cholate derivative with three epoxide groups was synthesized from cholic acid by allylation followed by epoxidation. Ring opening of the epoxides by various nucleophiles yielded facial amphiphiles with anionic, cationic, or nonionic functional groups. The critical micelle concentrations of these amphiphiles largely depend on the number of charged groups on the molecule. A facial amphiphile with pH-tunable micellization was prepared. Its aggregation behavior changes abruptly at pH = 7.6-6.6 as a result of protonation of its amino groups.

Electrophoresis of Protein Charge Ladders: A Comparison of Experiment with Various Continuum Primitive Models

Detailed modeling of the free solution electrophoresis of five proteins (bovine R-lactalbumin, hen egg white lysozyme, bovine superoxide dismutase, human carbonic anhydrase II, and hen ovalbumin) is carried out within the framework of the continuum primitive model. Protein crystal structures and translational diffusion constants are used to design and parametrize the models. The modeling results are compared with experimental mobilities of protein charge ladders, collections of protein derivatives where the number of charge groups is varied by partial acylation of lysine residues or by amidation of glutamic and aspartic acid residues. The simplest model considered is the Yoon and Kim model of a prolate/oblate ellipsoid with uniform surface potential, electrostatics treated at the level of the linear Poisson -Boltzmann equation, and distortion of the ion atmosphere from equilibrium (ion relaxation) ignored (Yoon, B. J.; Kim, S. J. Colloid Interface Sci. 1989, 128, 275). This model provides good agreement with experiment but only if the net absolute protein charge is low or the average absolute surface, or œ, potential is less than 25 mV. Boundary element (BE) modeling is also carried out in which detailed surface models are employed and the electrostatics are solved at the level of the nonlinear Poisson-Boltzmann equation. Ion relaxation is also included in some of the BE studies. All of the experimental mobilities are in good (human carbonic anhydrase II and hen ovalbumin) to excellent (bovine R-lactalbumin, hen egg white lysozyme, and bovine superoxide dismutase) agreement with BE modeling that includes ion relaxation. We believe that these results taken as a whole serve to confirm the ability of the continuum primitive model to predict, with quantitative accuracy, the free solution electrophoretic mobilities of proteins, provided the underlying models are sufficiently realistic. When a discrepancy occurs, it may be due to error in modeling either the protein charge or the solution conformation. The models described in this work also provide a useful approach for determining values of ¢Z, the change in net charge of proteins due to the chemical modification of charged groups. Knowledge of ¢Z is essential for the use of protein charge ladders in the quantitative description of the electrostatic properties and interactions of proteins. This paper supports the view that the continuum primitive model may be more appropriate for the modeling of electrokinetics than for electrostatics. The main challenge to the accurate predictions of electrophoretic mobilities may lie primarily in the modeling of electrostatics, not electrokinetics. I. Introduction The prediction of electrophoretic mobilities of proteins from their sequences and structures is challenging because such predictions require accurate models of both the electrostatic and the electrokinetic properties of proteins. Electrostatic models are used to predict the distribution of charges on the protein due to the reversible binding of protons to ionizable groups and also the electrostatic potential in the vicinity of the model protein. Electrokinetic models take as input a particular distribution of charge and electrostatic potential and predict the electrophoretic mobility. Both types of models are generally based on the continuum primitive model. The combination of capillary electrophoresis (CE) and protein charge ladders is a useful experimental system for addressing this challenge, as it provides values of electrophoretic mobilities for a collection of

Self-Assembling Microspheres from Charged Functional Polyelectrolytes and Small-Molecule Counterions

AbstractMicrometer-sized spheres have been found to assemble from homopolymer electrolytes and small, multivalent counterions in water. In contrast to previous efforts, these vesicles do not use preformed templates, do not require block copolymers, and do not necessarily employ nanoparticles. We have investigated the requirements for vesicle formation with regards to both components of the assembly. Self-assembly occurs with a variety of poly-amino acids and counterions, all of which require a minimum number of charged groups to promote non-covalent crosslinking. We show how the assembly process is controlled by pH and how, in consequence, the pKa's of the reactants can be used to reliably predict sphere formation. By varying the nature of the small counterions, we have determined the requirements for assemblies. The assemblies have been further investigated using confocal microscopy and fluorescent labeling of the different components.

Measurement of electrostatic interactions in protein folding with the use of protein charge ladders.

This paper describes a new method for the measurement of the role of interactions between charged groups on the energetics of protein folding. This method uses capillary electrophoresis (CE) and protein charge ladders (mixtures of protein derivatives that differ incrementally in number of charged groups) to measure, in a single set of electrophoresis experiments, the free energy of unfolding (DeltaG(D-N)) of alpha-lactalbumin (alpha-LA) as a function of net charge. These same data also yield the hydrodynamic radius, R(H), and net charge measured by CE, Z(CE), of the folded and denatured proteins. Alpha-LA unfolds to a compact denatured state under mildly alkaline conditions; a small increase in R(H) (11%, 2 A) coincides with a large increase in Z(CE) (71%, -4 charge units), relative to the folded state. The increase in Z(CE), in turn, predicts a large pH dependence of free energy of unfolding (-22 kJ/mol per unit increase in pH), due to differences in proton binding in the folded and denatured states. The free energy of unfolding correlates with the square of net charge of the members of the charge ladder. The differential dependence of DeltaG(D-N) on net charge for holo-alpha-LA, (partial differential) DeltaG(D-N)/(partial differential)Z = -0.14Z kJ/mol per unit of charge. This dependence of DeltaG(D-N) on net charge is a result of a net electrostatic repulsion among charge groups on the protein. These results, together with data from pH titrations, show that both the effects of electrostatic repulsion and differences in proton binding in the folded and denatured states can play an important role in the pH dependence of this protein; the relative magnitude of these effects varies with pH. The combination of charge ladders and CE is a rapid and efficient tool that measures the contributions of electrostatics to the energetics of protein folding, and the size and charge of proteins as they unfold. All this information is obtained from a single set of electrophoresis experiments.

Polyelectrolyte Complexes Formed by Calf Thymus DNA and Aliphatic Ionenes: Unexpected Change in Stability upon Variation of Chain Length of Ionenes of Different Charge Density

The formation of polyelectrolyte complexes (PECs) between aliphatic 2,4- and 2,8-ionenes and calf thymus DNA in water–salt solutions is monitored by a fluorescence-quenching technique using an ethidium bromide probe. As expected, the tolerance of PEC to dissociation in water–salt solutions increased with an increase in both the number of charged groups, i. e., degree of polymerization of the ionenes (DP), and in the charge density of their chains. However, the latter tendency weakened markedly upon the lengthening of the ionenes chains and ceased to hold at DP ≈ 25. Comparison of the stability of PECs formed by DNA and poly(methacrylate) anion, respectively, with the ionenes, disclosed that relatively short ionene chains formed noticeably less stable DNA-containing PECs, whereas upon lengthening of the ionenes the difference in the stability of the PEC successively decreased and evened out at DP ≈ 25, in the case of 2,8-ionene. All these findings imply that in such systems the role of charge–charge conformity of the partners in DNA-containing PECs is evident only for rather short ionenes. The unexpected changes in PEC stability revealed suggest that the short chains of the ionenes are of special interest for the design of self-assembling polyelectrolyte systems with controllable stability attractive for biomedical applications and bioseparation.

Poly- l-glutamic acid derivatives as vectors for gene therapy

This paper describes the synthesis and evaluation of biodegradable derivatives of poly- l-glutamic acid as suitable vectors for gene therapy. When mixed with DNA the new polymers self assemble and form polyelectrolyte complexes. The formation of the complexes and determination of their stability towards disruption by serum albumin was monitored by Ethidium bromide (EtBr) fluorescence spectroscopy. All polymers were able to form complexes and their size, determined by photon correlation spectroscopy, was between 84.5±2 nm and 96.7±1.6 nm, depending on the type of polymer and the charge ratio. All complexes were stable towards serum albumin. The results from the biodegradability tests, using tritosomes, show that the polymers are biodegradable and the rate of degradation is influenced by the number of charged groups in the side chains. Haemolysis and red blood cell (RBC) agglutination were assessed and compared to poly( l-lysine) (pLL) and polyethyleneimine (pEI). RBC agglutination was monitored with optical microscopy. Results show that the new polymers are less toxic than pLL and pEI. Preliminary transfection studies show that the polymers are suitable vectors for gene delivery.

Correlations Between the Charge of Proteins and the Number of Ionizable Groups They Incorporate: Studies Using Protein Charge Ladders, Capillary Electrophoresis, and Debye−Hückel Theory

The values of electrophoretic mobility, μelectro, of bovine carbonic anhydrase II, human carbonic anhydrase II, cytochrome c, lysozyme, superoxide dismutase, ovalbumin, and derivatives of these proteins produced by partial neutralization of Lys e-NH3+ and/or Asp and Glu carboxyl groups were measured using capillary electrophoresis (CE). For derivatives of these proteins with the lowest overall values of net charge (either positive or negative), the values of μelectro and the values of charge measured by CE, ZCE, demonstrate a linear correlation with the number of charged groups, n, converted to neutral derivatives. For derivatives of these proteins with larger values of net charge, the values of μelectro and ZCE demonstrate a nonlinear correlation with n. Several observations made in this work suggest that shifts in the values of pka of the ionizable groups on these proteins likely contribute to the observed nonlinear correlation. Debye−Huckel theory was used to calculate values of electrostatic potential...

Spatial sign-alternating charge clusters in globular proteins.

Large sign-alternating charge clusters formed by the charged side groups of amino acid residues and N- and C-terminal groups were found in the majority of considered globular proteins, namely 235 in a total of 274 protein structures, i.e. 85.8%. The clusters were determined by the criteria proposed earlier: charged groups were included in the cluster if their charged N and O atoms were located at distances between 2.4 and 7.0 A. The set of selected proteins consisted of known non-homologous protein structures from the Protein Data Bank with a resolution less than or equal to 2.5 A and pair sequence similarity less than 25%. Molecular masses of the proteins were from 5.5 to 91.5 kDa and protein chain length from 50 to 830 residues. The distribution of charged groups on the protein surface between isolated charged groups, small clusters with two and three groups, and large clusters with four or more groups were found to be approximately similar making 33, 35 and 32% of the total amount of protein charged groups, respectively. The large sign-alternating charge clusters with four or more charged groups were studied in greater detail. The amount of such clusters depends on the protein chain length. The small proteins contain 1-3 clusters while the large proteins display 4-6 or more clusters. On average, 1.5 clusters per each 100 residues were observed. In contrast with this, the size of a cluster, i.e. the number of charged groups inside a cluster, does not depend on the protein molecular mass, and large clusters are observed for proteins from a range of molecular masses. Clusters consisting of four to six charged groups occur most frequently, although extra large clusters are also often revealed. We can conclude that sign-alternating charge clusters are a common feature of the protein surface of globular protein. They are suggested to play a general functional role as a local polar factor of protein surface.

High-frequency alternating-crossed-field gel electrophoresis with neutral or slightly charged interpenetrating networks to improve DNA separation.

Toward improving DNA separations, this work reports the effects of high-frequency square-wave AC fields superimposed perpendicular to the direct current (DC) separation field on DNA migration in both polyacrylamide-based interpenetrating networks (IPNs) and in agarose networks. Compared to standard polyacrylamide gels, IPNs allow the separation of larger DNA (9000 bp vs. 5000 bp at 5 V/cm). In novel polyacrylamide-based IPNs, an alternating current (AC) field of 5 Hz increased the maximum DNA size separable. This effect was extended to larger DNA sizes with increasing electric-field strength up to and apparently beyond the power supply-limited maximum electric-field strength of 48 V/cm. The orthogonal AC field also increased mobility. These two results combine to yield a reduction in separation time of up to a factor of 20 in novel polyacrylamide-based IPNs. When negatively charged acrylic-acid groups were incorporated into the IPNs, the use of the AC field changed the DNA-network interaction, which altered the size dependence of DNA mobility. In agarose gels, an AC field of 50 Hz increased the size range separable; however, there was no increase in DNA mobility. There was no change in size dependence of mobility in an AC field when the number of charged groups in the agarose network was increased. Based on results in the literature, possible mechanisms were examined for the effects of the AC field on DNA separation.

Controlled delivery of antibacterial proteins from biodegradable matrices

Prosthetic valve endocarditis is an infrequent, but serious complication of cardiac valve replacement. The infection is caused by the adherence of bacteria to the prosthetic valve or to tissue at the site of implantation. Recently it was shown that antibacterial peptides from blood platelets are involved in clearance and killing of bacteria adhering to vegetations induced in a model for prosthetic valve endocarditis using rabbits. The application of these antibacterial proteins in a release system, incorporated in the Dacron sewing ring of the prosthetic heart valve would diminish the incidence of endocarditis. In this study a release system for small cationic proteins based on cross-linked gelatin was developed and characterised. Furthermore, the system was evaluated with respect to the uptake and in vitro release of lysozyme, a small cationic protein that was chosen as a model protein for small cationic antibacterial proteins. Variation of gelatin type (A and B), and cross-link density resulted in differences in swelling, thermal behaviour, and number of charged groups. Lysozyme uptake was proportional to swelling, but was governed by the number of anionic groups. The latter was also observed for the release profiles: when the amount of free carboxylic acids is higher (gelatin B compared to gelatin A), the lysozyme release lasts for a longer time period. The release into solidified agarose medium, as a model for heart muscle tissue, was measured. After 50 h, 40–100% of the lysozyme was released, which is in accordance with the aimed release period of 24–48 h. The adsorption experiments in vitro suggest an influence of the electrostatic interactions between lysozyme and gelatin. This hypothesis was validated with a mathematical model which takes both diffusion and adsorption interactions into account.

The polyelectrolyte properties of elastin.

The charge structure and ionic interactions of elastin prepared from the pig thoracic aorta by acid, alkali, or CNBr extraction have been investigated by potentiometric titration and radiotracer techniques. The number of charged groups was consistent with the amino acid composition, comparable to elastin from other sources and insensitive to the method of preparation. The enthalpies of ionization of the basic groups were comparable for those previously found for proteins but those of the acidic groups were higher. Ionic interactions were predominantly electrostatic although a strong affinity for chloride ions was noted. Changes in ionic interactions as the elastin was stretched had a similar effect to an increase in the apparent fixed charge density of the tissue. Mechanical strain altered the protonation of the elastin and the pK of the carboxyl groups. Conversely, the conformation of the elastin network varied with ionic strength and pH, being particularly sensitive to the degree of ionization of the more basic groups and with the ionic strength and anion composition of the medium. We speculate that strain induced changes in the conformation of elastin altering its reactivity towards lipids, ions or matrix macromolecules or changes in its mechanical properties resulting from changes in its ionic environment may be of physiological or pathological importance.

High-performance liquid chromatography of amino acids, peptides and proteins : CI. Identification and characterisation of coulombic interactive regions on sperm whale myoglobin by high-performance anion-exchange chromatography and computer-graphic analysis

A combination of high-performance liquid chromatographic and computer-graphic analysis of the electrostatic interactive surface of sperm whale myoglobin has allowed the putative anion-exchange binding domains to be identified and characterised. These studies have established the existence of four regions of high electrostatic potential in terms of negativity charged amino acid side chain groups. These binding sites are comprised of seven glutamic acid residues, two aspartic acid residues and two propionic acid groups located on the heme moiety which are arranged in a continuous topographic band around on section of the myoglobin surface. The number of charged groups in these interactive patches correlated with the range of experimentally determined Z c values under different elution conditions of varying gradient time, flow-rate and displacer salt. The changes in Z c values observed under some chromatographic conditions have been interpreted in terms of the conformational reorientation of the myoglobin molecule as it interacts with the charged stationary phase surface.

Surface, subunit interfaces and interior of oligomeric proteins.

The solvent-accessible surface area (As) of 23 oligomeric proteins is calculated using atomic co-ordinates from high-resolution and well-refined crystal structures. As is correlated with the protein molecular weight, and a power law predicts its value to within 5% on average. The accessible surface of the average oligomer is similar to that of monomeric proteins in its hydropathy and amino acid composition. The distribution of the 20 amino acid types between the protein surface and its interior is also the same as in monomers. Interfaces, i.e. surfaces involved in subunit contacts, differ from the rest of the subunit surface. They are enriched in hydrophobic side-chains, yet they contain a number of charged groups, especially from Arg residues, which are the most abundant residues at interfaces except for Leu. Buried Arg residues are involved in H-bonds between subunits. We counted H-bonds at interfaces and found that several have none, others have one H-bond per 200 A2 of interface area on average (1 A = 0.1 nm). A majority of interface H-bonds involve charged donor or acceptor groups, which should make their contribution to the free energy of dissociation significant, even when they are few. The smaller interfaces cover about 700 A2 of the subunit surface. The larger ones cover 3000 to 10,000 A2, up to 40% of the subunit surface area in catalase. The lower value corresponds to an estimate of the accessible surface area loss required for stabilizing subunit association through the hydrophobic effect alone. Oligomers with small interfaces have globular subunits with accessible surface areas similar to those of monomeric proteins. We suggest that these oligomers assemble from preformed monomers with little change in conformation. In oligomers with large interfaces, isolated subunits should be unstable given their excessively large accessible surface, and assembly is expected to require major structural changes.

Non-specific precipitin reactions of IgG at low ionic strength

Precipitin reactions apparently not involving specific antibodies were obtained in immunodiffusion experiments performed at low salt concentration between IgG and the muscle proteins, actin and tropomyosin. The precipitates, which dissolved at physiologic ionic strength, may result from electrostatic interaction of molecules of different net charge and different distribution and number of charged groups.

Mixtures of gangliosides and phosphatidylcholine in aqueous dispersions

The interaction of ox brain gangliosides and pure egg phosphatidylcholine has been studied by taking aqueous dispersions of the two lipids in all proportions and centrifugating the dispersion at 100 000 × g for half an hour and measuring the amount and composition of the pellet and supernatant. The first way of making the mixtures was to mix measured amounts of the lipids in organic solvent, dry them and then suspend them in buffer. The second way was to put measured amounts of each pure lipid into two separate tubes and dry each down and suspend each one in buffer. The two pure suspensions were then mixed. To investigate what charge effects the gangliosides would have on membranes, monolayer layers were studied at low (5 %) ganglioside concentrations. The centrifugation studies show that when the lipids are suspended concurrently in 10 mM buffer, pH 6.5, below a lipid composition of 30% ganglioside, 95% of the lipid could be sedimented, while above 65% the lipid composition of the supernatant was identical to that of the initial suspension although the total amount of the lipid in the supernatant varied with the composition. Thus it can be concluded that when the lipids are suspended in this way, they can exist in either a lamellar structure or in micellar solution, depending on the concentration. When, on the other hand the lipids are suspended separately all the lecithin is sedimented out whereas most of the ganglioside remains in suspension, indicating that the ganglioside could adsorb into the outer monolayer of the lamellar structures but not penetrate further and destroy them. Detailed studies of the surface potential of 5% mixtures of the mono- and disialogangliosides, showed that the gangliosides were stable in the monolayer and produced a charge that was concordant with the number of charged groups in the surface. The results were in agreement with those obtained with phosphatidic acid and with the Gouy-Chapman theory, it is also indicated on energetic considerations that it is most probable that the head groups of the gangliosides are not fixed in the plane of the air-water interface.

Fluorescence change of auramine O bound to chromatophores of Rhodospirillum rubrum--analysis in connection to ionic environment and ion transport.

Auramine O [bis(p-dimethylaminophenyl)-methylenimine hydrochloride] had a very low fluorescence yield in water but the yield was markedly enhanced when bound to chromatophores of a photosynthetic bacterium, Rhodospirillum rubrum (blue-green mutant). This binding was sensitive to pH, and type and concentration of cations in the suspending medium. Fluorescence intensity of membrane-bound auramine O decreased moderately in the presence of monovalent cations (Na+, K+ or NH4+) and more significantly in the presence of divalent cations (Mg2+, Ca2+ or Mn2+) The fluorescence intensity of bound auramine O decreased reversibly by illumination of chromatophores. The time-course of the illumination-induced fluorescence change was separated into rapid and slow phases. The extent of the rapid phase was increased by addition of tetraphenylboron−; or valinomycin plus K+. The relationship between the rapid phase of the fluorescence change and the light-induced H+ transport of chromatophores was suggested. The appearance of the rapid phase was also dependent on the redox level of chromatophores. Auramine O fluorescence can be used as a probe for the survey of the physical parameters of chromatophore membranes (distribution and number of charged groups and ionic environment) and energetical level of membranes in energy transduction.