Study on interaction of alpha-amylase from Bacillus subtilis with cetyl trimethylammonium bromide

The interaction of cetyl trimethylammonium bromide (CTAB) with alpha-amylase from Bacillus subtilis was investigated at 25 degrees C and various experimental conditions, such as pH, ionic strength and urea concentration. The binding data were measured using CTAB-membrane selective electrodes as a simple, fast, cheap and accurate method. The obtained binding isotherms were analyzed using Wyman binding potential concept. The results represent the highest binding affinity at 10(-3) M of NaBr respect to other salt concentrations. The less binding affinity at pH 9.7 with respect to pH 6.5 is related to increasing of protein self aggregation with pH. The binding data analysis at various urea concentrations also shows that the predominate unfolding of alpha-amylase occurred in the urea concentration range of 3-5 M.     

Determination of the binding parameters for antithrombin-heparin fragment systems by affinity and frontal analysis continuous capillary electrophoresis

The suitability of affinity capillary electrophoresis (ACE) and frontal analysis continuous capillary electrophoresis (FACCE) for binding constant determination was investigated for complexes between heparin fragments and antithrombin III, one of the main target proteins in the coagulation cascade. In a 100 mM ionic strength phosphate buffer (pH 7.4), ACE was suitable to determine weak to medium interactions developed by short oligomeric heparin fragments, but it failed for decasaccharide, which presents a more complex irreversible interaction. However FACCE allowed evaluating the binding constant for these longer oligomeric fragments. Both experimental approaches were complementary for a wide variety of heparinic fragments.     

Influence of a soluble anionic polymer on the electrophoresis of proteins

The influence of a soluble anionic polymer on electrophoresis of proteins was studied in relation to the nonspecific ionic effect of an affinophore on application to affinophoresis. Zone electrophoresis of proteins was carried out in agarose gel in the presence of succinyl-poly-L-lysine (degree of polymerization, 120) by using three electrophoresis buffers differing in ionic strength (0.06, 0.12 and 0.18) and pH (7.0 and 7.9). Proteins migrated as distinct single bands even in the presence of the polymer. The mobility of cationic proteins towards the cathode was first decreased and then increased towards the anode as the polymer concentration increased, while that of anionic proteins was not affected. The dependence of the apparent mobility changes of the proteins on the concentration of the polymer was treated quantitatively in the same way as affinity electrophoresis. The extent of the ionic interaction between a cationic protein and the polymer could be estimated as an apparent dissociation constant. It greatly depended on the ionic strength of the electrophoresis buffer. Except for the extremely cationic proteins such as lysozyme, the ionic interaction with up to 0.1 mM of the polymer could be practically suppressed by the use of 0.1 M sodium phosphate buffer (pH 7.0).     

Aptamer–Target Interaction: A Comprehensive Study by Microchip Electrophoresis in Frontal Mode

An original methodology based on microchip electrophoresis in a continuous frontal analysis mode (FACMCE) was employed to provide new insights into the interaction between an aptamer and its target (lysozyme), i.e., the influence of various experimental conditions on possible conformation change of the aptamer. The parameters evaluated were: background electrolyte (BGE) nature and ionic strength, nature and concentration of an added divalent cation, use of an aptamer thermal treatment, conditions classically used when employing aptamers. Increasing the BGE ionic strength led to a decrease in the dissociation constant highlighting the role played by the non-ionic interactions, and a decrease in the number of binding sites due to a change of binding mode and/or an amplification of selectivity. Divalent cation addition in the BGE improved the binding affinity. We demonstrated that this is not exclusively related to an increase in ionic strength but also certainly to an aptamer conformational change. Furthermore, changing the BGE nature permitted to modulate the binding parameters. Finally, we showed that an initial heating of the aptamer solution has been proved critical to stabilize the optimal conformation and thus to get a high binding affinity as well as a smaller standard deviation on the binding parameters values. This study has evidenced the influence of a wide range of parameters so as to better grasp the target/aptamer interaction, and thus highlight some phenomena involved in such an interacting system. This work will therefore help for further applications of this binding system for selectivity improvement in bioanalytical development.     

Hindered diffusion of synthetic polyelectrolytes in charged microporous membranes

To examine electrostatic effects on the diffusion of macromolecules in membranes, diffusivities of narrow molecular-size fractions of the polyelectrolytes ficoll sulfate and dextran sulfate were measured in polycarbonate track-etch membranes. Radius, number density, and surface charge density of membrane pores were determined from a combination of hydraulic permeability, glucose diffusion, and streaming potential measurements. Molecular charge and Stokes—Einstein radius for each macromolecule fraction were determined from free-solution electrophoretic mobility and diffusivity in a large pore radius membrane, D∞, respectively. As ionic strength was increased from 0.005 to 0.1 M, D∞ for ficoll sulfate remained constant while D∞ for dextran sulfate increased slightly (15-18%). Macromolecule diffusivities in small pore membranes, D, were much more sensitive to ionic strength. For membranes where the ratio of Stokes—Einstein radius to pore radius ranged from 0.08 to 0.29, D/D∞ for ficoll sulfate and dextran sulfate increased by factors ranging from 2.5 to 14 for the same increase in ionic strength. Recent theoretical results for electrostatic double layer interactions in hindered diffusion are in good quantitative agreement with these findings.     

Interaction of cationic surfactants with carboxymethylcellulose in aqueous media

We have examined the polymer-surfactant interaction in mixed solutions of the cationic surfactants, i.e., dodecyltrimethylammonium chloride, dodecyltrimethylammonium bromide, tetradecyltrimethylammonium bromide, hexadecyltrimethylammonium bromide, tetradecyltriphenylphosphonium bromide, and tetradecylpyridinium bromide and a semiflexible anionic polyelectrolyte carboxymethylcellulose in water and aqueous salt solutions by various techniques: tensiometry, viscosimetry or ion-selective electrode method, and dynamic light scattering. We have investigated the effect of varying surfactant chain length, head group size, counterion, and ionic strength on the critical aggregation concentration (CAC) of mixed polymer surfactant systems and the collapse of the polymer molecule under different solution conditions. The CAC decreases with increasing alkyl chain length. Above a certain surfactant concentration, mixed aggregates start growing until their macroscopic phase separation. The growth is more rapid with greater surfactant tail length and with increasing head group size. This is attributed in both cases to the increasing hydrophobic interaction between polymer and surfactant. Among surfactants with monovalent halide counterions, iodide induces the strongest binding, reflected by the onset of growth of the mixed aggregates at low surfactant concentration. This is perhaps related to the decreasing hydration of the counterion from chloride to iodide. The surfactant concentration at which the viscosity of the solution starts to decrease sharply is smaller than the CAC, and probably reflects polymer chain shrinkage due to noncooperative binding.     

Polymer-surfactant interactions: binding mechanism of sodium dodecyl sulfate to poly(diallyldimethylammonium chloride)

The binding mechanism of poly(diallyldimethylammonium chloride), PDAC, and sodium dodecyl sulfate, SDS, has been comprehensively studied by combining binding isotherms data with microcalorimetry, zeta potential, and conductivity measurements, as well as ab initio quantum mechanical calculations. The obtained results demonstrate that surfactant-polymer interaction is governed by both electrostatic and hydrophobic interactions, and is cooperative in the presence of salt. This binding results in the formation of nanoparticles, which are positively or negatively charged depending on the molar ratio of surfactant to PDAC monomeric units. From microcalorimetry data it was concluded that the exothermic character of the interaction diminishes with the increase in the surfactant/polymer ratio as well as with an increase in electrolyte concentration.     

Blood compatibility of particulate carriers investigated by cell electrophoresis and particle electrophoresis: a preliminary report

Polyethylene glycol (PEG) and dextran were covalently coupled, or only adsorbed, to the surface of three kinds of inorganic particles in order to shield their surface and reduce their nonspecific binding to red blood cells. Surface modification as well as interaction of particles with red blood cells was followed up by particle electrophoresis. This allowed a quick evaluation of the efficiency of polymer coupling. Moreover, the nonspecific binding of particles to red blood cells was easily investigated with cell electrophoresis, showing the inhibitory effect of immobilized PEG-5000 or dextran. The electrophoretic mobility analysis presented here may be used for screening blood compatibility of particulate drug carriers and could be helpful in formulating long-living circulating particles.     

Interactions of dextran sulfates with granulocyte colony-stimulating factor and their effects on leukemia cells

The interactions between granulocyte colony-stimulating factor (G-CSF) and dextran sulfate (DS) with different chain lengths and sulfate contents were studied by capillary zone electrophoresis. It was found that DS with a molecular mass of 500 kDa (DS500) could bind to G-CSF and the binding constant and binding sites were determined using Scatchard plot to be 1.17 x 10(6) M(-1) and 3, respectively. DS with a molecular mass of 40 kDa also had the affinity to G-CSF and the binding constant and binding sites were 1.01 x 10(6) M(-1) and 8, respectively. However, DS with a molecular mass of 8 kDa and the non-sulfated saccharide, dextran, had no affinity to G-CSF. The results indicate that the interactions between G-CSF and DS are dependent on the chain lengths and sulfate contents of the saccharides. In addition, the effects of G-CSF-binding DS on a G-CSF-dependent leukemia cell line were investigated using biological methods. Results show that DS500 plus G-CSF has potential therapeutic effect on cancers because their combination could inhibit the growth and induce the differentiation of the leukemia cells.     

亲和毛细管电泳法和荧光法研究氟喹诺酮类药物与牛血清白蛋白的相互作用

分别采用亲和毛细管电泳法和荧光法对6种氟喹诺酮类药物(司帕沙星、洛美沙星、左氧氟沙星、诺氟沙星、培氟沙星和氟罗沙星)与牛血清白蛋白的相互作用进行考察. 结合比均为1∶1, 结合常数在104 L/mol量级, 热力学参数表明体系间的相互作用力以范德华作用力和氢键力为主. 另外, 亲和毛细管电泳实验结果表明, 缓冲溶液pH值和离子强度增大会造成结合常数在一定程度上的减小, 使相互作用减弱. 同时, 荧光猝灭实验结合紫外光谱扫描说明体系间为静态猝灭. 所得到的数据对进一步研究氟喹诺酮类药物的作用机理、提高药效和开发新一代氟喹诺酮类药物具有一定的参考意义.     

Investigation of ion binding in ionic polysaccharide solutions using Tb(III) as a luminescent probe

The luminescence properties of a series of lanthanide-substituted ionic polysaccharides have been examined in an attempt to learn about the nature of interactions between the metalions and the polymers. Emission and excitation spectra were obtained for Tb(III) complexes with carboxymethyl cellulose, Sclerox S-1.0, alginate, polygalacturonic acid, amylose sulfate, dextran sulfate, and i-carrageenan. Studies of the chirality associated with the metal-ion binding sites were performed through the use of circularly polarized luminescence spectroscopy. It was learned that the lanthanide ions could form complexes with polysaccharides in the electrostatic manner of polyelectrolytes, and that specific ligating groups could further influence the metal-ion binding characteristics.     

Partitioning behavior of silica in the Triton X-100/dextran/water aqueous biphasic system

The partitioning behavior of silica particles was investigated in the Triton X-100/dextran/water system. It was found that both electrostatic effects and interactions between phase-component species and the solid surface played important roles in determining the distribution of solids. Silica partition was highly pH-dependent, which was interpreted in terms of the pH dependence of the Triton X-100/SiO(2) interaction and the weak acidity of dextran. The presence of sodium dodecyl sulfate (SDS) moved the particles from the top surfactant-rich phase to the interface and the bottom phase, while dodecyltrimethylammonium bromide (DTAB) had the opposite effect. These trends are attributable to the electrostatic interaction between the charged mixed micelles in the top phase and the particles and to the fact that the ionic surfactants modified the adsorption density of the nonionic surfactant on silica.     

Synthetic polymer nanoparticle-polysaccharide interactions: a systematic study

The interaction between synthetic polymer nanoparticles (NPs) and biomacromolecules (e.g., proteins, lipids, and polysaccharides) can profoundly influence the NPs fate and function. Polysaccharides (e.g., heparin/heparin sulfate) are a key component of cell surfaces and the extracelluar matrix and play critical roles in many biological processes. We report a systematic investigation of the interaction between synthetic polymer nanoparticles and polysaccharides by ITC, SPR, and an anticoagulant assay to provide guidelines to engineer nanoparticles for biomedical applications. The interaction between acrylamide nanoparticles (~30 nm) and heparin is mainly enthalpy driven with submicromolar affinity. Hydrogen bonding, ionic interactions, and dehydration of polar groups are identified to be key contributions to the affinity. It has been found that high charge density and cross-linking of the NP can contribute to high affinity. The affinity and binding capacity of heparin can be significantly diminished by an increase in salt concentration while only slightly decreased with an increase of temperature. A striking difference in binding thermodynamics has been observed when the main component of a polymer nanoparticle is changed from acrylamide (enthalpy driven) to N-isopropylacryalmide (entropy driven). This change in thermodynamics leads to different responses of these two types of polymer NPs to salt concentration and temperature. Select synthetic polymer nanoparticles have also been shown to inhibit protein-heparin interactions and thus offer the potential for therapeutic applications.     

Estimation of degree of counterion binding and thermodynamic parameters of ionic surfactants from cloud point measurements by using triblock polymer as probe

Cloud point (C(P)) was measured for ternary mixtures of different ionic surfactants such as sodium dodecyl sulfate (SDS), dodecyltrimethylammonium bromide (DTAB), and dimethylene bis(dodecyldimethylammonium bromide) (12-2-12) plus triblock polymer (TBP) ((PEO)(2)(PPO)(15.5)(PEO)(2)) plus water, keeping the concentration of TBP constant and varying the surfactant concentration from pre- to postmicellar regions. These experiments were also performed in the presence of different fixed amounts of NaBr to evaluate the salt effect on the clouding behavior of these ternary mixtures. The C(P) value of TBP exhibits a drastic change at the cmc of each surfactant. The cmc values thus obtained both in the absence and in the presence of NaBr were used to evaluate counterion binding (beta) with the Corrin-Harkins method. beta values were also used to evaluate the thermodynamic parameters of these ionic surfactants. The results suggest that the beta values evaluated using this method, especially at low [TBP], are in good agreement with those reported in the literature.     

Separation of enantiomers by capillary electrophoresis using pentosan polysulfate

Pentosan polysulfate, a semisynthetic polysaccharide, was employed as a chiral run buffer additive in capillary electrophoresis. Twenty-eight racemic analytes were resolved. The separations were successful only at low pH when the analytes were significantly protonated. This suggests that ionic interactions were the dominant associative interactions between the anionic pentosan polysulfate and the positively charged analytes. Compared to other linear, carbohydrate-based chiral selectors (i.e., chondroitin sulfates, heparin and dextran sulfate) pentosan polysulfate has some characteristics common of anionic polysaccharides; yet it has several differences in its structure and properties which account for its unusual enantioselectivity. The effects of pH, concentration of phosphate buffer, concentration of pentosan polysulfate and the type and concentration of organic modifier on the enantiomeric separations were investigated. The optimization of these separations were dependent on the nature of the analytes and could be achieved by the proper choice of experimental conditions.     

Microcalorimetric evidence of hydrophobic interactions between hydrophobically modified cationic polysaccharides and surfactants of the same charge

We synthesized and characterized a series of new polymers-hydrophobically modified cationic polysaccharides-based on dextran having pendant N-(2-hydroxypropyl)-N,N-dimethyl-N-alkylammonium chloride groups randomly distributed along the polymer backbone. These polymers are good candidates for studying the hydrophobic effect on polymer/surfactant association. In previous papers we reported their interactions with oppositely charged surfactants. For further insight into the relative importance of the hydrophobic interaction in the association process now we studied the thermodynamics of the interaction of these hydrophobically modified polymers with surfactants of the same charge (DMRX/CnTAC) by isothermal titration calorimetry (ITC). In order to try to discriminate the solution behavior of these polymer/surfactant systems, we analyzed separately the interaction of unmodified dextran with ionic surfactants and the interactions between the corresponding cationic surfactants. The interaction enthalpies for DMRX/CnTAC systems were derived from a proposed thermodynamic model with equations that describe the polymer-surfactant interactions. The thermodynamic parameters for the DMRX/CnTAC aggregation process as well as surfactant micellization in the presence of the polymer were also calculated. From all the results we were able to ascertain the effect on the interactions of changing the alkyl chain length of the polyelectrolyte pendant groups or the surfactant. The importance of the polymer aggregation state on the mechanism of interaction was also addressed.     

Affinity capillary electrophoresis method for investigation of bile salts complexation with sulfobutyl ether‐β‐cyclodextrin

Sulfobutyl ether‐β‐cyclodextrin (SBEβCD) is utilized in preformulation and drug formulation as an excipient for solubilization of drugs with poor aqueous solubility. Approximately seven negative charges of SBEβCD play a role with respect to solubilization and complexation, but also have an influence on the ionic strength of the background electrolyte when the cyclodextrin is used in capillary electrophoresis. Mobility‐shift affinity capillary methods for investigation of the complexation of taurocholate and taurochenodeoxycholate with the negatively charged cyclodextrin derivative applying constant power and ionic strength conditions as well as constant voltage and varying ionic strength were investigated. A new approach for the correction of background electrolyte ionic strength was developed. Mobility‐shift affinity capillary electrophoresis experiments obtained at constant voltage and constant power settings were compared and found to provide binding parameters that were in good agreement upon correction. The complexation of taurochenodeoxycholate with SBEβCD was significantly stronger than the corresponding interaction involving taurocholate. The obtained stability constants for the bile salts were in the same range as those previously reported for the interaction with neutral β‐cyclodextrins derivatives, i.e. the positions of the negative charges on SBEβCD and the bile salts within the complex did not lead to significant electrostatic repulsion.     

Interaction of Amino Acid and Dipeptide β-Naphthylamide Derivatives with Hyaluronic Acid and Human Serum Albumin Studied by Capillary Electrophoresis Frontal Analysis

Interactions of drug candidates with the biomacromolecules of the synovial fluid affect drug targeting to the articular cartilage as well as clearance from the synovial space upon intra-articular administration. Hyaluronic acid (HA) and human serum albumin (HSA) are two main components existing in the synovial fluid. To this end, we investigated the affinity of seven cationic amino acid and dipeptide β-naphthylamide derivatives towards HA and HSA in order to shed light on possible relationships between physicochemical properties, in particular charge state, and biomacromolecular interactions to increase the joint residence time. Capillary electrophoresis frontal analysis was used for characterization of the binding of the derivatives to hyaluronic acid and HSA at 25 °C in acetate buffer (pH 4.65) and phosphate buffer (pH 7.40), respectively. Linear binding isotherms were observed for the ligand–hyaluronic acid interactions and the obtained binding constants ranged from 43 to 133 M^?1. The average fraction of bound ligand towards hyaluronic acid increased with increasing the net charge of the ligands but was less than 67 % for all investigated ligands. The obtained binding constants of the ligands with HSA varied in the range of 10³–10⁶ M^?1. The interactions of low-molecular weight derivatives with hyaluronic acid were highly dependent on the ligand charge state. This trend was not observed for the interactions with HSA. The obtained affinity data may provide useful information in the design of cartilage adhesive prodrugs with extended residence time in the synovial cavity.     

Capillary electrophoresis frontal analysis: principles and applications for the study of drug-plasma protein binding

Capillary electrophoresis is a well-established technique for the study of noncovalent interactions. Various approaches exist and capillary electrophoresis-frontal analysis provides an interesting alternative to the migration shift affinity capillary electrophoresis methods and conventional methods. The present work reviews the principles on which the frontal analysis method is founded. Advantages and limitations of capillary electrophoresis frontal analysis in comparison with both conventional and other capillary electrophoresis based methods for quantification of binding interactions are discussed. Investigations utilizing capillary electrophoresis-frontal analysis have focused on the interaction of drugs with plasma proteins. These studies, primarily addressing the binding of drugs to human serum albumin, alpha1-acid glycoprotein, and lipoproteins are reviewed together with some recent developments in capillary electrophoresis-frontal analysis methodology.     

Consequences of the nanoporosity of cellulosic fibers on their streaming potential and their interactions with cationic polyelectrolytes

Electrokinetic tests, based on the streaming potential method, were used to elucidate interactions between cationic polyelectrolytes and cellulosic fibers and to reveal aspects of fibers’ nanoporosity. The fibrillated and nanoporous nature of bleached kraft fibers gave rise to time-dependent changes in streaming potential, following treatment of the wetted fibers with poly-diallyldimethylammonium chloride. Electrokinetic test results were consistent with an expected longer time required for higher-mass polyelectrolytes to diffuse into pore spaces, compared to lower-mass polyelectrolytes. Further evidence of the relative inability of polyelectrolyte molecules to diffuse into the pores of cellulose was obtained by switching back and forth between high and low ionic strength conditions during repeated measurement of streaming potential, after the fibers had been treated with a moderate amount of cationic polymer. By changing the concentration of sodium sulfate it was possible to switch the sign of streaming potential repeatedly from positive to negative and back again. Such results imply that a continuous path for liquid flow exists either in a fibrillar layer or within the cell walls. The same concepts also helped to explain the dosages of high-charge cationic polymer needed to achieve maximum dewatering rates, as well as the results of retention experiments using positively and negatively charged microcrystalline cellulose particles.