Circular dichroic properties and average dimensions of DNA-containing reverse micellar aggregates

With the aim of investigating the compartmentation of nucleic acids and surfactant aggregates, we have studied the circular dichroic properties of DNA solubilized in reverse micelles. DNA incorporated in AOT/isooctane reverse micelles (AOT=bis-2-ethyl-hexyl sodium sulfosuccinate) assumes an anomalous circular dichroism (CD) spectrum with the characteristic features of a psi spectrum. Older literature observations could therefore be confirmed that attribute these spectral changes to the fact that the reverse micelles induce the formation of a condensed form of DNA. A dynamic light scattering (DLS) characterization of the DNA-containing micellar solutions was carried out, and three populations of aggregates in a polar solvent are observed, with an average radius centered at 5, 100 and 1000 nm, respectively, all three containing DNA. Several forms of DNA, including a plasmid, have been investigated. The formation of 1 microm-large aggregates depends on the DNA concentration and such aggregates disappear in the course of a few hours. Conversely, the 100 nm aggregates are stable for at least 1 day and contain DNA in a normal spectral state at low concentration and in a condensed form-it is the characteristic psi spectrum-in a higher concentration range. The solubilization of DNA in reverse micelles brings about unexpected larger structures in hydrocarbon solution, and whereas the very large component can be with all likelihood be attributed to clusters of smaller reverse micelles, the components at 100 nm radius appear to be a quite stable and characteristic feature of DNA-containing reverse micelles.     

Measurements of hydrodynamic diameter of AOT reverse micelles containing lipase in supercritical ethane and its enzymatic reaction

The enzymatic reaction by aerosol-OT (AOT)reverse micelles containing lipase in supercritical ethane was examined and is the focus of this paper. The reverse micelles were formed under various conditions at which their hydrodynamic diameters were measured by using the dynamic light scattering spectrophotometer. The reverse micelles in supercritical ethane were formed in the range of Wo (water/surfactant) less than six. The hydrodynamic diameter of the reverse micelles ranged from 2 to 5 microm. The hydrolysis reaction of triolein by the lipase in reverse micelles was also examined. The observations indicate that lipase in AOT reverse micelles in supercritical ethane showed activity. The conversion of triolein increased with the increase in size of reverse micelles and Wo, and reached its maximum near the critical temperature. Moreover, although the conversion of triolein increased with pressure, it was independent of pressure near the critical temperature.     

Solubilizing water involved in protein extraction using reversed micelles

The extraction of protein using reversed micelles was investigated in relation to the amount of solubilizing water in the reversed micellar organic phase. The minimal concentration of amphiphilic molecule di-2-ethylhexyl sodium sulfosuccinate (C(20)H(37)O(7)Na) (AOT) required for 100% cytochrome c extraction was recognized. This critical AOT concentration increased with protein concentration in the aqueous phase. On this minimal AOT condition, the molar ratio of solubilizing water to extracted protein was found to be a constant of 3500 under C(KCI) = 1.0 x 10(2) mol . m(-3) in this system. This ratio means the hydrophillic surroundings required for extracting one protein molecule into the micellar organic phase under the suitable pH and salt concentration for the forward extraction. In this regard, AOT molecules seemed to take the part of water solubilizing agent in the reversed micellar extraction. This role of AOT is important to extract protein under the suitable pH and salt concentration. The amount of solubilizing water in the protein-containing system was larger than in the protein-free system. This difference shows that the water molecules accompany the extracted protein into the reversed micellar organic phase at constant ratio 2200 under C(KCI) = 1.0 x 10(2) mol . m(-3), i.e., accompanying water molecules per one extracted protein. The minimal AOT concentration increased with ionic strength. On this minimal AOT condition, the molar ratio of solubilizing water to extracted protein also increased with ionic strength, so that in higher ionic strength, more solubilizing water was required. Then more AOT was required to provide the hydrophillic surroundings for protein. The pH affected the minimal AOT concentration required for 100% protein extraction.     

Study of the factors affecting the extraction of soybean protein by reverse micelles

In this work, the forward and back extraction of soybean protein by reverse micelles was studied. The reverse micellar systems were formed by anionic surfactant sodium bis(2-ethyl hexyl) sulfosuccinate (AOT), isooctane and KCl solution. The effects of AOT concentration, aqueous pH, KCl concentration and phase volume ratio on the extraction efficiency of soybean protein were tested. Suitability of reverse micelles of AOT and Triton-X-100/AOT mixture in organic solvent toluene for soybean protein extraction was also investigated. The experimental results lead to complete forward extraction at the AOT concentration 120 mmol l⁻¹, aqueous pH 5.5 and KCl concentration 0.8 mol l⁻¹. The backward extraction with aqueous phase (pH 5.5) resulted in 100% extraction of soybean protein from the organic phase.     

Extraction of bovine serum albumin using nanoparticulate reverse micelles

The extraction of a relatively large molecular weight protein, bovine serum albumin (BSA), using nano-sized reverse micelles of nonionic surfactant polyoxyethylene p-t-octylphenol (Triton-X-100) is attempted for the first time. Suitability of reverse micelles of anionic surfactant sodium bis (2-ethyl hexyl) sulfosuccinate (AOT) and Triton-X-100/AOT mixture in organic solvent toluene for BSA extraction is also investigated. Although, the size of the Triton-X-100 reverse micelle in toluene is large enough to host BSA molecule in the hydraulic core, the overall extraction efficiency is found to be low, which may be due to lack of strong driving force. AOT/toluene system resulted in complete forward extraction at aqueous pH 5.5 and a surfactant concentration of 160 mM. The back extraction with aqueous phase (pH 5.5) resulted in 100% extraction of BSA from the organic phase. The addition of Triton-X-100 to AOT reduced the extraction efficiency of AOT reverse micelles, which may be attributed to reduced hydrophobic interaction. The circular dichroism (CD) spectrum of BSA extracted using AOT/toluene reverse micelles indicated the structural stability of the protein extracted.     

Lipase-catalyzed esterification of fatty acid in DMSO (dimethyl sulfoxide) modified AOT reverse micellar systems

AOT reverse micellar system was modified with DMSO for improved esterification activity of Chromobacterium viscosum lipase (glycerol-ester hydrolase, EC 3.1.1.3). The enzymatic activity was strongly affected by the concentration of DMSO, and maximum activity was obtained at 30-40 mM. The various relevant physical parameters such as w₀ (molar ratio of water to AOT), pH and reaction temperature that influence the activity of lipase were studied in order to obtain the best value and compared with those in simple AOT reverse micelles. The apparent activation energy decreased in the presence of DMSO. The stability of lipase entrapped in modified AOT systems was excellent, and the half-life was about 3.25 times than that observed in simple AOT systems at 25°C. A simple first-order deactivation model was considered to determine the deactivation rate constant. The thermodynamic stability of lipase in reverse micelles was measured by the Gibbs free energy. A fluorescence study was performed to provide information on structural changes in AOT reverse micelles which was accompanied by the addition of DMSO.     

Photodynamic effect in lysozyme: a kinetic study in different micellar media.

The influence of medium heterogeneity on the kinetics of the photodynamic effect on native protein lysozyme (Lyso), as well as the interaction of protein and the medium, anionic (SDS) micelles, neutral (Triton X-100) micelles and reversed micelles of AOT, were investigated at pH 8. The interaction between Lyso, Triton X-100 and SDS micelles was quantified by determining the respective associations constant (K(Lyso)). Values were 37 M(-1) for Triton X-100 and 514 M(-1) for SDS, indicating that the Lyso molecule binds Triton X-100 micelles effectively and SDS micelles even more strongly. Time-resolved phosphorescence detection (TRPD) indicates that the protein interacts with O2 (1deltag), with overall rate constants of the order of 10(8) M(-1)/S in direct micelles and 10(7) M(-1)/S in reverse micelles. Apparent reactive rate constants for eosin-sensitized photo-oxidation (singlet molecular oxygen [O2 (1deltag)]-mediated) of the protein were determined through oxygen uptake experiments for the direct micelles, while the fade in the protein fluorescence spectrum upon sensitized irradiation was used in AOT. The results indicate that the O2 (1deltag) attack on the interior of Lyso on amino acid residues, was more effective in leading to a photo-oxidative reaction in SDS and in Triton X-100 at surfactant concentrations < 1 x 10(-2) M than in a homogeneous solution. However, Lyso reactivity reached a maximum when the concentration of micelles was approximately 1 x 10(-5), the same as the protein concentration In AOT reverse micelles, the quenching rate constants decreased > 75% with respect to water. This effect can be attributed to the decrease in accessibility of the amino acid residues to O2 (1deltag).     

Lipase-catalyzed esterification of fatty acid in DMSO (dimethyl sulfoxide) modified AOT reverse micellar systems

AOT reverse micellar system was modified with DMSO for improved esterification activity of Chromobacteriumviscosum lipase (glycerol–ester hydrolase, EC 3.1.1.3). The enzymatic activity was strongly affected by the concentration of DMSO, and maximum activity was obtained at 30–40 mM. The various relevant physical parameters such as w₀ (molar ratio of water to AOT), pH and reaction temperature that influence the activity of lipase were studied in order to obtain the best value and compared with those in simple AOT reverse micelles. The apparent activation energy decreased in the presence of DMSO. The stability of lipase entrapped in modified AOT systems was excellent, and the half-life was about 3.25 times than that observed in simple AOT systems at 25°C. A simple first-order deactivation model was considered to determine the deactivation rate constant. The thermodynamic stability of lipase in reverse micelles was measured by the Gibbs free energy. A fluorescence study was performed to provide information on structural changes in AOT reverse micelles which was accompanied by the addition of DMSO.     

Micellar catalysis of polyphenol oxidase in AOT/cyclohexane

The catalytic behaviour of mushroom polyphenol oxidase has been studied in dioctylsulphosuccinate (AOT)/cyclohexane reverse micelles. The steady-state conditions were accomplished up to 20 min and 17 μg protein in the assay towards 4-methylcatechol and no loss of specific activity was observed relative to aqueous medium. The pH activity profile of the enzyme was kept in reverse micelles as in water, showing a plateau between 5 and 6.5. The stability of polyphenol oxidase to pH was also studied and about 20% inactivation was found in reverse micelles relative to aqueous medium at neutral pHs. Moreover there was a decrease of stability at acidic pHs. The optimum W_o obtained was 20 and the enzyme was nearly independent of the surfactant concentration at constant W_o.

Kinetic studies of polyphenol oxidase towards several substrates showed that the substrate inhibition by p-cresol and 4-methylcatechol observed in buffer was not kept in AOT/cyclohexane reverse micelles. Moreover, the K_m increased and the catalytic efficiency (V/K_m) of the enzyme decreased as the hydrophobicity of substrates was increased.     

Complexation of trypsin and alcohol dehydrogenase with poly(diallyldimethylammonium chloride)

Complexation of alcohol dehydrogenase (ADH) and trypsin with poly(diallyldimethyl-ammonium chloride) (PDADMAC) in dilute electrolyte solution was studied by turbidimetric titration, quasi-elastic light scattering (QELS), and electrophoretic light scattering (ELS). Both QELS and turbidimetric titration show that PDADMAC forms complexes with ADH and trypsin in 0.01M NaCl solution at pH ≥ 6.8 and pH ≥ 9.2, respectively. These complexes take the form of stable coacervates in 0.01M, pH 11.0, phosphate buffer solution. QELS shows sizes of 400 and 315 nm for the coacervates of ADH-PDMDAAC and trypsin-PDMDAAC, respectively, while ELS reveals that these coacervates carry a net positive charge. Activity measurements show that both ADH and trypsin are enzymatically active in their coacervated states. Complexation of trypsin and PDADMAC was also studied by fluorescence in 0.01M, pH 11.0, phosphate buffer, and the protein emission was found to be quenched by complexation. The fluorescence quenching data show that trypsin retains its three-dimensional structure in the complex. These and other results are consistent with the quenching of the two tryptophans on the protein surface, but not the interior ones.© 1997 John Wiley & Sons, Inc.     

The physicochemical state of protoporphyrin IX in aqueous solution investigated by fluorescence and light scattering

Fluorescence spectros copy and light scattering have been used to investigate the physicochemical behaviour of protoporphyrin IX in aqueous solutions. In the alkaline range large micelles are formed with a hydrodynamic radius of 130 nm and a molecular mass of 5.0 x 10(7) Da. The micelles are fluorescent with an emission maximum at 620 nm. A pH lowering caused quenching of the micelle fluorescence. On a collision encounter these micelles will disintegrate and they are reformed by nucleation of collision fragments. From measurements of the fluorescence intensity of the micelles versus total concentration an equilibrium constant of 4.0 x 10(6) M(-1) was found for this collision-nucleation process. In the pH range between 6 and 3 another micelle type of twice the size of those in the alkaline range was stable with respect to the solute. These micelles have free base porphyrin fluorescence with an emission maximum at 634 nm. A lowering of the pH below unity causes disintegration of these micelles and monomer fluorescence from the protoporphyrin dication was observed.     

The fluorescence and circular dichroism of proteins in reverse micelles: application to the photophysics of human serum albumin and N-acetyl-l-tryptophanamide

Evidence is presented that a compartmentalised protein exists in its native state only within a particular size of aqueous cavity. This behaviour is shown to exist in AOT reverse micelles using fluorescence quenching and circular dichroism (CD) studies of human serum albumin (HSA). In particular, far ultraviolet CD measurements show that a reduction in quencher accessibility to the fluorophore is consistent with the protein being nearest to its native conformation at a waterpool size of around 80 Å diameter. We also show that the biexponential fluorescence decay of N-acetyl-l-tryptophanamide (NATA) in AOT reverse micelles arises from the probe being located in two distinct sites within the interfacial region. The more viscous of these two sites is located on the waterpool side of the interface and the other is located on the oil side of the interface.     

Solubilization and insertion into reverse micelles of the major myelin transmembrane proteolipid

The Folch-Pi proteolipid has been isolated from bovine white matter and characterized with respect to phospholipid and glycolipid composition. The protein-lipid complex has been solubilized in aqueous reverse micelles of di(2-ethylhexyl) sodium sulfosuccinate and isooctane. Solubilization of this otherwise water-insoluble proteolipid requires small amounts of water, the percent of solubility being maximum for a low molar ratio of water to surfactant (Wo = 5.6). Unlike hydrophilic proteins, the extent of incorporation into the micellar system is negligible at 50 mM surfactant and reaches 90Vo only at 300 mM. However, the conformation of the proteolipid in reverse micelles as studied by fluorescence emission spectroscopy and circular dichroism was not affected by variations of the surfactant concentration. These results are consistent with the peculiar properties of the aqueous environment of the proteolipid within the reverse micelles and may reflect the membrane-like character of these bio-assemblies.     

A procedure for the joint evaluation of substrate partitioning and kinetic parameters for reactions catalyzed by enzymes in reverse micellar solutions. I. Hydrolysis of 2-naphthyl acetate catalyzed by lipase in sodium 1,4-bis(2-ethylhexyl) sulphosuccinate (AOT)/buffer/heptane

A simple method useful for the joint evaluation of substrate partitioning and kinetic parameters for reactions catalyzed by enzymes entrapped in reverse micelles is proposed. The method is applied to the hydrolysis of 2-naphthyl acetate (2-NA) catalyzed by lipase in sodium 1,4-bis(2-ethylhexyl) sulfosuccinate (AOT)/buffer/heptane reverse micellar solutions. In the presence of micelles, the relationship between the initial reaction rate and the analytical concentration of 2-NA was dependent on AOT concentration at a constant W ([water]/[AOT]) value. The dependence of the initial reaction rate profiles with [AOT] was analyzed according with the method proposed to obtain the partition constant of 2-NA between the micelles and the external solvent, Kp. A value of Kp = 2.7 L mol(-1) was obtained irrespective of the water content of the micelles (W from 5 to 20). The catalytic rate constant kcat in the micellar solutions was independent of [AOT] but slightly decreased with an increase in W from 2 x 10(-6) mol g(-1) s(-1) at W = 5 to 1.2 x 10(-6) mol g(-1) s(-1) at W = 20. The apparent Michaelis constant determined in terms of the analytical concentration of 2-NA increased with [AOT] at a given W and moderately decreased with W at a fixed [AOT]. The increase with [AOT] is accounted for by considering the partitioning of the substrate. After correction for the partitioning of 2-NA values of (Km)corr were obtained as 3.9 x 10(-3) mol L(-1) (W = 5), 4.6 x 10(-3) mol L(-1) (W = 10), 2.3 x 10(-3) mol L(-1) (W = 15), and 1.7 x 10(-3) mol L(-1) (W = 20). The rate parameters in the aqueous phase in the absence of micelles, were obtained as (kcat)aq = 7.9 x 10(-6) mol g(-1) s(-1) and (Km)aq = 2.5 x 10(-3) mol L(-1). In order to compare the efficiency of the enzyme in the micellar solution with that in aqueous phase, the values of (Km)corr were in turn corrected to take into account differences in the substrate activity, obtaining so a set of (Km)*corr values. The efficiency of the enzyme in the micellar solution, defined as the ratio, kcat/(Km)*corr, was found to be higher than in the aqueous phase, even at high water contents (W = 20). This higher efficiency is due to a significant decrease in (Km)*corr values.     

Ethylene glycol and the thermostability of trypsin in a reverse micelle system

The influence of ethylene glycol (EG) on the kinetics of hydrolysis of N-alpha-benzoyl-L-arginine ethyl ether catalyzed by trypsin encapsulated in sodium bis-(2-ethylhexyl)sulfosuccinate (AOT)-based reverse micelles was studied at different temperatures. Ethylene glycol was shown to shift the range of the trypsin activity in the reverse micelles towards higher temperatures. Infrared spectroscopy showed a stabilizing effect of EG on the secondary structure of the protein in the system of reverse micelles. Electron spin resonance spectroscopy showed that the solubilized protein affected the interactions of EG with the polar head groups of AOT and altered the rigidity of the micellar matrix. The results indicate that EG increases the thermostability of the solubilized enzyme in microemulsion media by two mechanisms.     

Impact of Surface Active Compounds on Iron Catalyzed Oxidation of Methyl Linolenate in AOT–Water–Hexadecane Systems

Edible oils contain minor surface active components that form micro-heterogeneous environments, such as reverse micelles, which can alter the rate and direction of chemical reactions. However, little is known about the role of these micro-heterogeneous environments on lipid oxidation of bulk oil. Our objective was to evaluate the ability of water, cumene hydroperoxide, oleic acid, and phosphatidylcholine to influence the structure of reverse micelles in a model oil system: sodium bis(2-ethylhexyl) sulfosuccinate (aerosol-OT; AOT) in n-hexadecane. The influence of reverse micelle structure on iron catalyzed lipid oxidation was determined using methyl linolenate as an oxidizable substrate. The size and shape of the reverse micelle were investigated by small-angle x-ray scattering, and water contents was determined by Karl Fischer titrations. Lipid hydroperoxides and thiobarbituric acid reactive substances were used to follow lipid oxidation. Our results showed that AOT formed spherical reverse micelles in hexadecane. The size of the reverse micelles increased with increased water or phosphatidylcholine concentration, but decreased upon addition of cumene hydroperoxide or oleic acid. Iron catalyzed oxidation of methyl linolenate in the reverse micelle system decreased with increasing water concentration. Addition of phosphatidylcholine into the reverse micelle systems decreased methyl linolenate oxidation compared to control and reverse micelles with added oleic acid. These results indicate that water, cumene hydroperoxide, oleic acid, and phosphatidylcholine can alter reverse micelle size and lipid oxidation rates. Understanding how these compounds influence reverse micelle structure and lipid oxidation rates could provide information on how to modify bulk oil systems to increase oxidative stability.     

Effect of hydration degree of aerosol OT reversed micelles and surfactant concentration in heptane on spectral and catalytic properties of catalase.

The influence of micelle hydration degree (w0) and AOT concentration on fluorescence, circular dichroism (CD), catalytic activity, and stability of catalase in Aerosol OT (AOT) reversed micelles in heptane was investigated. The quantitative parameters--differential fluorescence of catalase (DeltaI), protein molar ellipticity ([theta]lambda), initial rate of catalytic reaction, catalase efficiency (kcat/Km), and rate constant of enzyme inactivation (kin, sec-1)--decreased with increasing AOT concentration in micellar systems, reflecting the interaction of solubilized catalase with the AOT micellar aggregates in heptane. The dependences of all these parameters on increasing hydration degree of micelles (w0) were characterized by the appearance of maxima at w0 of 8, 15-18, and 26-30. These maxima are suggested to reflect three different states of catalase in the micellar system, distinguished by their conformations and catalytic activity, which is determined by the micellar microenvironment of the enzyme.     

Antimicrobial activity of AOT-isooctane reverse micelle as a bioseparation and biocatalysis tool

Abstract

The antimicrobial activity of different reverse micelles on microorganisms is been compared using the disc diffusion method. The bis (2-ethylhexyl) sodium sulfosuccinate (AOT) reverse micelle showed a more significant inhibitory effect than do other reverse. micelles, and it had an antimicrobial activity against a broad range of microorganisms. Results from an antimicrobial activity test of isooctane and a forward extraction containing soybean protein suggest that the surfactant was chiefly responsible for inhibiting microbes in AOT/isooctane reverse micelle, while isooctane hardly inhibited the microbial growth. The properties of S. aureus, cultured in the TSB with AOT reverse micellar solution, were identified by the SEM and SDS-PAGE fingerprinting of cell-wall proteins. It is concluded that the cell-wall of the S. aureus decreased in the TSB with AOT reverse micellar solution, and some cell protein subunits of the S. aureus did not occurr, especially between 14.4 and 42.7 kDa, while one new protein subunit at near 97.4 kDa occurred     

Light scattering,CD, and ligand binding studies of ferrihemoglobin–polyelectrolyte complexes

Quasi‐elastic light scattering (QELS), electrophoretic light scattering (ELS), CD spectroscopy, and azide binding titrations were used to study the complexation at pH 6.8 between ferrihemoglobin and three polyelectrolytes that varied in charge density and sign. Both QELS and ELS show that the structure of the soluble complex formed between ferrihemoglobin and poly(diallyldimethylammonium chloride) [PDADMAC] varies with protein concentration. At fixed 1.0 mg/mL polyelectrolyte concentration, protein addition increases complex size and decreases complex mobility in a tightly correlated manner. At 1.0 mg/mL or greater protein concentration, a stable complex is formed between one polyelectrolyte chain and many protein molecules (i.e., an intra‐polymer complex) with apparent diameter approximately 2.5 times that of the protein‐free polyelectrolyte. Under conditions of excess polyelectrolyte, each of the three ferrihemoglobin–polyelectrolyte solutions exhibits a single diffusion mode in QELS, which indicates that all protein molecules are complexed. CD spectra suggest little or no structural disruption of ferrihemoglobin upon complexation. Azide binding to the ferrihemoglobin–poly(2‐acrylamide‐2‐methylpropanesulfonate) [PAMPS] complex is substantially altered relative to the polyelectrolyte‐free protein, but minimal change is induced by complexation with an AMPS‐based copolymer of reduced linear charge density. The change in azide binding induced by PDADMAC is intermediate between that of PAMPS and its copolymer. © 1999 John Wiley & Sons, Inc. Biopoly 50: 153–161, 1999