Solubilization and refolding of inclusion body proteins in reverse micelles

Today, many valuable proteins can be obtained in sufficient amounts using recombinant DNA techniques. However, frequently the expression of recombinant proteins results in the accumulation of the product in dense amorphous deposits inside the cells, called inclusion bodies. The challenge then is to transform these inactive and misfolded protein aggregates into soluble bioactive forms. Although a number of general guidelines have been proposed, the search for proper reconstitution conditions can be very laborious and time consuming. Hare, we suggest a new versatile approach for solubilization and refolding of inclusion body proteins using a water-sodium bis-2-ethylhexyl sulfosuccinate-isooctane reverse micellar system. Instead of amorphous aggregates, a transparent solution is obtained, where refolded protein is entrapped inside the micelles. The entrapped enzyme has native-like secondary structure and catalytic activity. This approach has been implemented with Fusarium galactose oxidase and Stigmatella aurantiaca putative galactose oxidase. (C) 2003 Elsevier Science (USA). All rights reserved

A new strategy for the study of oligomeric enzymes: γ-glutamyltransferase in reversed micelles of surfactants in organic solvents

A heterodimeric enzyme (γ-glutamyltransferase) was studied in the reversed micellar medium of Aerosol OT (AOT) in octane. As was shown earlier, the size (radius) of inner cavity of the AOT-reversed micelles is determined by their hydration degree, i.e., [H2O]/[AOT] molar ratio, in the system. Owing to this, the dependence of hydrolytic, transpeptidation and autotranspeptidation activities of the enzyme on the hydration degree was investigated using l- and d-isomers of γ-glutamyl(3-carboxy-4-nitro)anilide and glycylglycine as substrates. For all of the reaction types, the observed dependences are curves with three optima. The optima are found at the hydration degrees, [H2O]/[AOT] = 11, 17 and 26 when the inner cavity radii of reversed micelles are equal to the size of light (Mr 21 000) and heavy (Mr 54 000) subunits of γ-glutamyltransferase, and to their dimer (Mr 75 000), respectively. Ultracentrifugation experiments showed that a change of the hydration degree resulted in a reversible dissociation of the enzyme to light and heavy subunits. The separation of light and heavy subunits of γ-glutamyltransferase formed in reversed micelles was carried out and their catalytic properties were studied. The two subunits catalyze hydrolysis and transpeptidation reactions; autotranspeptidation reaction is detected only in the case of the heavy subunit. These findings imply that the reversed micelles of surfactants in organic solvents function as the matrices with adjustable size permitting to regulate the supramolecular structure and the catalytic activity of oligomeric enzymes. © 1989

THE PRINCIPAL DIFFERENCE IN REGULATION OF THE CATALYTIC ACTIVITY OF WATER-SOLUBLE AND MEMBRANE FORMS OF ENZYMES IN REVERSED MICELLES - GAMMA-GLUTAMYL-TRANSFERASE AND AMINOPEPTIDASE

The regulations of functioning of water soluble and membrane forms of enzymes in the systems of reversed micelles of surfactants in organic solvents are compared. By an examples of gamma-glutamyltransferase (in AOT reversed micelles in octane) and amino-peptidase (in Brij 96 reversed micelles in cyclohexane) the principal difference in the catalytic activity regulation of water soluble and membrane forms is demonstrated. The catalytic activity of the membrane form depends largely on the surfactant concentration at the constant hydration degree, whereas the activity of the water soluble form is constant under these conditions. The catalytic activity dependence on the surfactant concentration is regarded as a >

A new strategy for the study of oligomeric enzymes: γ-glutamyltransferase in reversed micelles of surfactants in organic solvents

A heterodimeric enzyme (γ-glutamyltransferase) was studied in the reversed micellar medium of Aerosol OT (AOT) in octane. As was shown earlier, the size (radius) of inner cavity of the AOT-reversed micelles is determined by their hydration degree, i.e., [H2O]/[AOT] molar ratio, in the system. Owing to this, the dependence of hydrolytic, transpeptidation and autotranspeptidation activities of the enzyme on the hydration degree was investigated using l- and d-isomers of γ-glutamyl(3-carboxy-4-nitro)anilide and glycylglycine as substrates. For all of the reaction types, the observed dependences are curves with three optima. The optima are found at the hydration degrees, [H2O]/[AOT] = 11, 17 and 26 when the inner cavity radii of reversed micelles are equal to the size of light (Mr 21 000) and heavy (Mr 54 000) subunits of γ-glutamyltransferase, and to their dimer (Mr 75 000), respectively. Ultracentrifugation experiments showed that a change of the hydration degree resulted in a reversible dissociation of the enzyme to light and heavy subunits. The separation of light and heavy subunits of γ-glutamyltransferase formed in reversed micelles was carried out and their catalytic properties were studied. The two subunits catalyze hydrolysis and transpeptidation reactions; autotranspeptidation reaction is detected only in the case of the heavy subunit. These findings imply that the reversed micelles of surfactants in organic solvents function as the matrices with adjustable size permitting to regulate the supramolecular structure and the catalytic activity of oligomeric enzymes. © 1989

THE PRINCIPAL DIFFERENCE IN REGULATION OF THE CATALYTIC ACTIVITY OF WATER-SOLUBLE AND MEMBRANE FORMS OF ENZYMES IN REVERSED MICELLES - GAMMA-GLUTAMYL-TRANSFERASE AND AMINOPEPTIDASE

The regulations of functioning of water soluble and membrane forms of enzymes in the systems of reversed micelles of surfactants in organic solvents are compared. By an examples of gamma-glutamyltransferase (in AOT reversed micelles in octane) and amino-peptidase (in Brij 96 reversed micelles in cyclohexane) the principal difference in the catalytic activity regulation of water soluble and membrane forms is demonstrated. The catalytic activity of the membrane form depends largely on the surfactant concentration at the constant hydration degree, whereas the activity of the water soluble form is constant under these conditions. The catalytic activity dependence on the surfactant concentration is regarded as a >

Formation of quasi-regular compact structures of poly(methacrylic acid) upon interaction with a-chymotrypsin

Structure and dynamic properties of free poly(methacrylic acid) (PMA) and PMA complexed with -chymotrypsin (CT) were studied using the time resolved fluorescence anisotropy technique. We have found that the interaction of PMA with CT induces the formation of a quasi-regular structure of PMA. At a CT/PMA weight ratio of 4:1 the interaction with CT leads to formation of approximately four equal segments of polyelectrolyte, each binding one CT molecule and characterized by an independent rotational mobility. Increase of the CT/PMA weight ratio above 8:1 gives rise to the overall rotation of the whole enzyme–polyelectrolyte complex. In water–ethanol mixtures the mobility of PMA segments containing CT decreases and the structure of the complex becomes even more rigid due to enhancement of the electrostatic interaction between CT and PMA. Formation of the compact and quasi-regular structure of the complex is perhaps the main reason behind the enhancement of enzyme stability and suppression of enzyme aggregation in water–organic cosolvent mixture