An extreme halophilic enzyme active at low salt in reversed micelles.

Possible biotechnological applications of extreme halophilic enzymes are strongly determined by their high salt requirement of around 4 M NaCl. Consequently, the use of these in organic media seemed to be unlikely. However, we have succeeded in dissolving a halophilic enzyme, p-nitrophenylphosphate phosphatase from the archaeon Halobacterium salinarum, in an organic medium by creating a reverse micellar system with very low salt concentration. The enzyme retained its catalytic properties in reversed micelles made with an anionic surfactant (dioctyl sodium sulphosuccinate) or with a cationic surfactant (hexadecyltrimethylammonium bromide) in cyclohexane plus 1-butanol as co-surfactant. The dependence of the rate of hydrolysis of p-nitrophenylphosphate phosphate on the molar water/surfactant ratio (w(0) value) showed a bell-shaped curve for each surfactant system. Kinetic parameters were determined in each system. The enzymatic reaction appeared to follow Michaelis-Menten kinetics with the anionic surfactant only. The kinetic behaviour was determined at different concentrations of Mn(2+) in reversed micelles of dioctyl sodium sulphosuccinate as surfactant.     

Stability and Enzymatic Studies of Glucose Dehydrogenase from the Archaeon Haloferax mediterranei in reverse micelles

Reverse micelles were used as a cytoplasmic model to study the kinetics of an extreme halophilic enzyme such as the recombinant glucose dehydrogenase from the Archaeon Haloferax mediterranei. This enzyme was solubilized in reverse micelles of hexadecyltrimethylammoniumbromide in cyclohexane, with 1-butanol as co-surfactant. Glucose dehydrogenase retained its catalytic properties in this organic medium, showing good stability at low water content, even at low salt concentration (125 mM NaCl). The dependence of the enzymatic activity on the molar water surfactant ratio (w₀=[H₂O]/[surfactant]) increased with rising water content. Surprisingly, the activity of this extreme halophilic enzyme did not depend on the salt concentration in reverse micelles. The kinetic of the enzymatic oxidation of β-D-glucose to D-glucono-1,5-lactone using NADP⁺ as coenzyme for the glucose dehydrogenase from Haloferax mediterranei was also studied in the reverse micellar system.     

Enzymatic hydrolysis of microcrystalline cellulose in reverse micelles

The activities of cellulases from Trichoderma reesei entrapped in three types of reverse micelles have been investigated using microcrystalline cellulose as the substrate. The reverse micellar systems are formed by nonionic surfactant Triton X-100, anionic surfactant Aerosol OT (AOT), and cationic surfactant cetyltrimethyl ammonium bromide (CTAB) in organic solvent media, respectively. The influences of the molar ratio of water to surfactant omega0, one of characteristic parameters of reverse micelles, and other environmental conditions including pH and temperature, on the enzymatic activity have been studied in these reverse micellar systems. The results obtained indicate that these three reverse micelles are more effective than aqueous systems for microcrystalline cellulose hydrolysis, and cellulases show "superactivity" in these reverse micelles compared with that in aqueous systems under the same pH and temperature conditions. The enzymatic activity decreases with the increase of omega0 in both AOT and Triton X-100 reverse micellar systems, but reaches a maximum at omega0 of 16.7 for CTAB reverse micelles. Temperature and pH also influence the cellulose hydrolysis process. The structural changes of cellulases in AOT reverse micelles have been measured by intrinsic fluorescence method and a possible explanation for the activity changes of cellulases has been proposed.     

Enzymatic redox cofactor regeneration in organic media: functionalization and application of glycerol dehydrogenase and soluble transhydrogenase in reverse micelles

An enzymatic system for the regeneration of redox cofactors NADH and NADPH was investigated in nanostructural reverse micelles using bacterial glycerol dehydrogenase (GLD) and soluble transhydrogenase (STH). Catalytic conversion of NAD+ to NADH was realized in the sodium dioctylsulfosuccinate (AOT)/isooctane reverse micellar system harboring GLD and a sacrificial substrate, glycerol. The initial rate of NADH regeneration was enhanced by exogenous addition of ammonium sulfate into the reverse micelles, suggesting that NH4+ acts as a monovalent cationic activator. STH was successfully entrapped in the AOT/isooctane reverse micelles as well as GLD and was revealed to be capable of catalyzing the stoichiometric hydrogen transfer reaction between NADP+ and NADPH in reverse micelles. These results indicate that GLD and STH have potential for use in redox cofactor recycling in reverse micelles, which allows the use of catalytic quantities of NAD(P)H in organic media.     

Reverse micelles in organic solvents: a medium for the biotechnological use of extreme halophilic enzymes at low salt concentration

Alkaline p-nitrophenylphosphate phosphatase (pNPPase) from the halophilic archaeobacterium Halobacterium salinarum (previously halobium) was solubilized at low salt concentration in reverse micelles of hexadecyltrimethyl-ammoniumbromide in cyclohexane with 1-butanol as co-surfactant. The enzyme maintained its catalytic properties under these conditions. The thermodynamic "solvation-stabilization hypothesis" has been used to explain the bell-shaped dependence of pNPPase activity on the water content of reverse micelles, in terms of protein-solvent interactions. According to this model, the stability of the folded protein depends on a network of hydrated ions associated with acidic residues at the protein surface. At low salt concentration and low water content (the ratio of water concentration to surfactant concentration; w0), the network of hydrated ions within the reverse micelles may involve the cationic heads of the surfactant. The bell-shaped profile of the relationship between enzyme activity and w0 varied depending on the concentrations of NaCl and Mn2+.     

Entrapping of Tyrosinase in a System of Reverse Micelles

The enzymatic activity of tyrosinase was studied both in aqueous and organic media. In the latter case tyrosinase was entrapped in a system of reverse micelles of Aerosol OT in octane. At hydration degree 25, when the inner cavity of the reverse micelles was comparable with the size of a tetrameric tyrosinase form known for aqueous solutions, an optimum level of catalytic activity was observed. Another peak of catalytic activity of tyrosinase was observed at hydration degree 12, when the size of the inner cavity of the reverse micelles was consistent with a monomeric form of tyrosinase. Thus, the system of reverse micelles can be exploited as a medium for the investigation of the monomeric form of tyrosinase, which is unstable in aqueous solution.     

Esterification reactions of lipase in reverse micelles

The activities of lipase from Candida cylindracea and Rhizopus delemar have been investigated in water/AOT/iso-octane reverse micellar media through the use of two esterification reactions: fatty acid-alcohol esterification and glyceride synthesis. Such media promotes the occurrence of these two lipase-catalyzed reactions due to its low water content. The effect of various parameters on the activity of lipase from C. cylindracea in reverse micelles was determined and compared to results where alternate media were employed. It was observed that the structure of the media, as dictated by the type and concentration of the substrates and products and by the water/AOT ratio, w(0), had a strong impact on enzyme activity. Strong deactivation of both typase types occurred in reverse micelles, especially in the absence of substrates and for w(0) values greater than 3.0. Glyceride synthesis was realized with lipase from R. delemar, but not with that from C. cylindracea; the temperature and concentration of substrates and water strongly dictated the reaction rate and the percent conversion.     

Solubilization of enzymes in apolar solvents via reverse micelles

The solubilizing of enzymes via reverse micelles provides a method for the catalytic bioconversion of water-insoluble material, for example, reduction of steroids and enoates, cholesterol oxidation, and inter- and trans-esterification of lipophilic substances. Proteases in reverse micelles have been used for the synthesis of water-insoluble peptides. Whole cells solubilized by micellar solutions remain viable in organic solvents. The solubilization of proteins in reverse micelles or water-in-oil microemulsions also provides a method for extracting and purifying enzymes from biological sources. All these uses of reverse micelles represent potential but, as yet, unproven, applications of the technology. What is needed is a deeper understanding of the fundamental processes involved and the development of appropriate reactor systems.     

Strategies for enzymatic esterification in organic solvents: comparison of microaqueous, biphasic, and micellar systems.

The kinetics of butyl butyrate synthesis by a lipase from Mucor miehei in different types of organic media were investigated. The three systems studied were a microaqueous medium containing enzyme in suspension in hexane, a water-hexane two-phase system, and reverse micelles. The synthesis of butyl butyrate was possible in all cases because of a favorable partition of the ester into the organic solvent. A sufficient stirring rate was necessary to achieve good reaction rates in the case of the liquid-liquid biphasic medium. The effect of water content was different according to the type of system used. The dependence of reaction rate and of conversion yield on enzyme and substrate concentrations was also investigated. From an applied point of view, the best performances were obtained with either microaqueous or liquid-liquid two-phase systems. The use of reverse micelles can be advocated only in particular conditions, such as low enzyme concentration, compatible with the specific constraints it involves.     

Stability of a Pseudomonas Sp. Lipase:Comparison Between Solubilized Enzyme in Reverse Micelles and Suspended Lipase in Dry Solvents

The stability of a relatively hydrophobic lipase from Pseudomonas sp., solubilized in reverse micellar media or suspended in dry solvents, was studied and compared. Factors such as the enzyme-solvent interaction, enzyme environment, hydration degree of the system, interphase quality, droplet size, and water activity were studied. A mixed micellar system which stabilized the lipase is reported. In the case of simple AOT micelles, lipase destabilization with respect to water in small droplet sizes and stabilization in the biggest micelles was observed. These effects resulted from lipase penetration into the interphase of the smaller nanodroplets, and the restriction of its conformational mobility in the region of structured water of the largest micelles, respectively. Mixed micelles increased lipase stability, which was mainly related to increased droplet size. Modification with polyethylene glycol decreased lipase stability in reverse micelles, due to the greater interaction with the micellar interphase. The preparation of nanodroplets, in which native and modified lipases were 5.4 and 9.4 times, respectively, more stable than in water, is reported. In contrast to the micellar media, low water contents (low A_w values) stabilized the solid lipase suspended in organic solvent systems. Under the hydration conditions studied here, lipase stability increased when more polar solvents were used. Two alternatives were necessary to obtain similar stabilities in n-heptane as compared with polar solvents: reduction of the water content or use of a low aquaphilic support.     

A comparison of lipase-catalyzed ester hydrolysis in reverse micelles, organic solvents, and biphasic systems

The performance of lipases from Candida rugosa and wheat germ have been investigated in three reaction media using three acetate hydrolyses as model reactions (ethyl acetate, allyl acetate, and prenyl acetate). The effect of substrate properties and water content were studied for each system (organic solvent, biphasic system, and reverse micelles). Not unexpectedly, the effect of water content is distinct for each system, and the optimal water content for enzyme activity is not always the same as that for productivity. A theoretical model has been used to simulate and predict enzyme performance in reverse micelles, and a proposed partitioning model for biphasic systems agrees well with experimental results. While the highest activities observed were in the micellar system, productivity in microemulsions is limited by low enzyme concentrations. Biphasic systems, however, support relatively good activity and productivity. The addition of water to dry organic solvents, combined with the dispersion of lyophilized enzyme powders in the solvent, resulted in significant enzyme aggregation, which not surprisingly limits the applicability of the "anhydrous" enzyme suspension approach. (c) 1995 John Wiley & Sons, Inc.     

Influence of reverse micellar environments on the fluorescence emission properties of tryptophan octyl ester

A number of recent studies have presented perspectives on the hydrophobic fluorescence probe tryptophan octyl ester (TOE). This molecule has attracted notable attention as a suitable model for the natural fluorophore tryptophan, in case of membrane proteins. We report here, for the first time, the fluorescence emission behaviour of TOE in reverse micelles of aerosol-OT (AOT) in n-heptane, containing different amounts of water. Relevant studies in representative homogeneous solvent media are also included for comparison. The fluorescence emission parameters (especially emission maximum, relative intensity, and anisotropy) of TOE are found to exhibit significant variation upon changes in the water/surfactant molar ratio (w(0)) of the reverse micelles. Fluorescence decay studies on TOE which we have also performed, indicate biexponential decay kinetics in reverse micelles as well as in homogeneous solvent media. The implications of these findings are examined in relation to the potentialities of TOE as a novel fluorescence probe for membrane proteins present in water restricted environments prevailing at the interfaces of biomembranes (for which reverse micelles serve as ideal model systems).     

Decontamination of surfaces by lysozyme encapsulated in reverse micelles

Cells and enzymes can be used to decontaminate soil, water supplies, personal equipment, weapons and hospital equipment that have been exposed to bacteria, toxins or viruses. One of the problems associated with the use of microorganisms and enzymes for decontamination purposes is that the presence of water is not acceptable for some applications such as electronic equipment. One way of circumventing this problem is to allow the enzyme to distribute between a water phase and an organic phase-containing surfactant and then use the encapsulated enzyme in reverse micelles directly into the device to be clean. Reverse micelles were used to deliver the enzyme (lysozyme) to the cell-surface interface. They serve as a way to increase the local concentration of lysozyme and decrease the amount of water delivered. Specifically, we explored the lysis by free lysozyme and lysozyme encapsulated in reverse micelles of Klebsiella pneumoniae and Staphylococcus epidermidis attached to steel, glass, and hydroxyapatite. These two bacteria have been selected because they are known to be pathogenic and because of their differences in cell wall structure. Lysozyme was added to the surfaces in either reverse micelles or as a free solution and was tested under conditions of stirring and no stirring. Stirring was implemented to study the interplay between mass transfer limitations and surface roughness. We have shown that free lysozyme or lysozyme encapsulated in reverse micelles is capable of decontaminating surfaces of different texture. Lysis of the cells is slower when the encapsulated enzyme is used but lysis is more complete.     

Regulation and Prediction of Enzyme Activity in Reversed Micelles

The rate of cholesterol oxidation has been studied in cholesterol oxidase containing reversed micellar media consisting of the surfactant cetyltrimethylammonium bromide (CTAB), the surfactant octanol, a buffered aqueous solution, and a variety of organic solvents. By varying the composition of the medium systematically it could be deduced that the rate of cholesterol oxidation obeys the same rules as described earlier for the conversion of apolar steroids by 20β-hydroxysteroid dehydrogenase in CTAB-hexanol-organic solvent reversed micelles (Hilhorst et al. 1984). The general applicability of these rules in optimizing biocatalysis in reversed micelles is discussed.     

Polarographic measurement of oxygen uptake using lipoxygenase in reverse micelles

Lipoxygenase-catalyzed linoleic acid peroxidation was chosen as a model system to study the applicability of oxygraphy to monitor the oxygen uptake in organic solvents containing reverse micelles. Care was taken to control the oxygen back transfer from the atmosphere to the sample micellar solution, resulting in a significant improvement of electrode response. Under these conditions, lipoxygenase activity was linear up to 100 mug of enzyme. Given the quality of the calibration curve and the good correlation between lipoxygenase and ascorbate oxidase, the described technique is proposed as an alternative method for determining lipoxygenase activity in reverse micelles. The reliability of this technique was confirmed by the good agreement between polarography and classic spectrophotometry in kinetic studies. Preliminary experiments carried out on soybean cells solubilized in a Tween 85-isopropylpalmitate system demonstrated that a light-dependent oxygen uptake can be measured. The authors propose that the Clark-type electrode be employed to study both the activity of oxidasic enzymes in reverse micelles and cell viability and physiology in organic solvents.     

Stability of an extreme halophilic alkaline phosphatase from Halobacterium salinarium in non-conventional medium

Alkaline p-nitrophenylphosphate phosphatase from the halophilic archaeon Halobacterium salinarum (earlier halobium) was solubilised in organic medium using reversed micelles of hexadecyltrimethylammonium bromide in cyclohexane, with 1-butanol as co-surfactant. The stability of alkaline p-nitrophenylphosphate phosphatase in this system was studied at different conditions, w(0) ([H(2)O]/[surfactant]), salt concentration, with and without Mn(+2). At all the conditions assayed, alkaline p-nitrophenylphosphate phosphatase was more stable in reversed micelles than in bulk aqueous solution (at 25 degrees C). The stabilisation effect of the reversed micelles was dramatic when the enzyme was dialysed against Mn(+2)-free buffer since the enzyme lost all the activity within 90 min in aqueous medium, but it retained approximately 72% of the initial enzymatic activity for 90 min in reversed micelles.     

Biotechnological uses of archaeal extremozymes

Archaea have developed a variety of molecular strategies to survive the often harsh environments in which they exist. Although the rules that allow archaeal enzymes to fulfill their catalytic functions under extremes of salinity, temperature or pressure are not completely understood, the stability of these extremophilic enzymes, or extremozymes, in the face of adverse conditions has led to their use in a variety of biotechnological applications in which such tolerances are advantageous. In the following, examples of commercially important archaeal extremozymes are presented, potentially useful archaeal extremozyme sources are identified and solutions to obstacles currently hindering wider use of archaeal extremozymes are discussed.     

Enzymes in Low Water Systems

Water is fundamental for enzyme action and for formation of the three-dimensional structure of proteins. Hence, it may be assumed that studies on the interplay between water and enzymes can yield insight into enzyme function and formation. This has proven correct, because the numerous studies that have been made on the behavior of water-soluble and membrane enzymes in systems with a low water content (reverse micelles or enzymes suspended in nonpolar organic solvents) have revealed properties of enzymes that are not easily appreciated in aqueous solutions. In the low water systems, it has been possible to probe the relation between solvent and enzyme kinetics, as well as some of the factors that affect enzyme thermostability and catalysis. Furthermore, the studies show that low water environments can be used to stabilize conformers that exhibit unsuspected catalytic properties, as well as intermediates of enzyme function and formation that in aqueous media have relatively short life-times. The structure of enzymes in these unnatural conditions is actively being explored.     

FTIR study of horseradish peroxidase in reverse micelles

Fourier transform infrared (FTIR) method was used to study the secondary structures of horseradish peroxidase (HRP) in aqueous solution and in reverse micelles for the first time. Results indicated that the structure of HRP in sodium bis(2-ethylhexy)sulfosuccinate (AOT) reverse micelles was close to that in aqueous solution. In cetyltrimethylammonium bromide (CTAB) and sodium dodecylfate (SDS) reverse micelles the position of some bands changed. Results indicated that the secondary structure had a close relationship with the surfactant species of the reverse micelles. Among the three types of reverse micelles, the system of AOT reverse micelles was probably the most beneficial reaction media to HRP.     

Mechanism of adaptation of an atypical alkaline p-nitrophenyl phosphatase from the archaeon Halobacterium salinarum at low-water environments

Enzymes suspended in organic solvents represent a versatile system for studying the involvement of water in catalytic properties and their flexibility in adapting to different environmental conditions. The extremely halophilic alkaline p-nitrophenylphosphate phosphatase from the archaeon Halobacterium salinarum was solubilized in an organic medium consisting of reversed micelles of hexadecyltrimethylammoniumbromide in cyclohexane, with 1-butanol as cosurfactant. Hydrolysis of p-nitrophenylphosphate was nonlinear with time when the enzyme was microinjected into reversed micelles that contained substrate. These data are consistent with a kinetic model in which the enzyme is irreversibly converted from an initial form to a final stable form during the first seconds of the encapsulation process. The model features a rate constant (k) for that transition and separate hydrolysis rates, v(1) and v(2), for the two forms of the enzyme. The enzyme conversion may be governed by the encapsulation process.