Comparison of inactivation and conformational changes of aminoacylase during denaturation in lithium dodecylsulphate solutions

Catalytic Performance of a Recombinant Organophosphate-Hydrolyzing Phosphotriesterase from Brevundimonas diminuta in the Presence of Surfactants

Phosphotriestease (PTE), also known as parathion hydrolase, has the ability to hydrolyze the triester linkage of organophosphate (OP) pesticides and chemical warfare nerve agents, making it highly suitable for environment remediation. Here, we studied the effects of various surfactants and commercial detergents on the esterase activity of a recombinant PTE (His6-tagged BdPTE) from Brevundimonas diminuta. Enzymatic assays indicated that His6-tagged BdPTE was severely inactivated by SDS even at lower concentrations and, conversely, the other three surfactants (Triton X-100, Tween 20, and Tween 80) had a stimulatory effect on the activity, especially at a pre-incubating temperature of 40 °C. The enzyme exhibited a good compatibility with several commercial detergents, such as Dr. Formula® and Sugar Bubble®. The evolution results of pyrene fluorescence spectroscopy showed that the enzyme molecules participated in the formation of SDS micelles but did not alter the property of SDS micelles above the critical micelle concentration (CMC). Structural analyses revealed a significant change in the enzyme’s secondary structure in the presence of SDS. Through the use of the intentionally fenthion-contaminated Chinese cabbage leaves as the model experiment, enzyme–Joy® washer solution could remove the pesticide from the contaminated sample more efficiently than detergent alone. Overall, our data promote a better understanding of the links between the esterase activity of His6-tagged BdPTE and surfactants, and they offer valuable information about its potential applications in liquid detergent formulations.

Assisting the reactivation of guanidine hydrochloride-denatured aminoacylase by hydroxypropyl cyclodextrins

Cyclodextrin is a water-soluble circular oligosaccharide with a cylinder shape characterized by exterior hydrophilic rims and an interior hydrophobic cavity, which makes it an ideal additive to prevent proteins from aggregating during refolding. In this research, three hydroxypropyl cyclodextrins (HPCDs), HP-alpha-, beta-, and gamma-CD, were used to investigate the molecular mechanism of their effects on assisting aminoacylase refolding. The aggregation and reactivation experiments suggested that at moderate concentrations, HPCDs could suppress aggregation and assist aminoacylase refolding in a concentration-dependent manner, and HP-beta-CD was the most efficient of the three HPCDs. Low concentrations of HP-alpha-CD and high concentrations of HP-gamma-CD promoted off-pathway aggregation. Spectroscopic studies indicated that the hydrophobic exposure of the unstructured species in the refolded solutions was gradually reduced by the three HPCDs with the efficiency HP-beta-CD > HP-gamma-CD > HP-alpha-CD. Furthermore, the fast phase of aminoacylase reactivation was slowed down by the addition of 75 mM HP-beta- and gamma-CD, but no significant effect was observed for HP-alpha-CD. The dissimilarity in the effects of the three HPCDs suggested that the internal cavity size played a crucial role in their antiaggregation ability. Further analysis suggested that the observations might be much more complicated than expected because of the various types of interactions between cyclodextrins and proteins in addition to their ability to bind to protein aromatic residues.

Role of osmolytes as chemical chaperones during the refolding of aminoacylase

The refolding and reactivation of aminoacylase is particularly difficult because of serious off-pathway aggregation. The effects of 4 osmolytes--dimethylsulphoxide, glycerol, proline, and sucrose--on the refolding and reactivation of guanidine-denatured aminoacylase were studied by measuring aggregation, enzyme activity, intrinsic fluorescence spectra, 1-anilino-8-naphthalenesulfonate (ANS) fluorescence spectra, and circular dichroism (CD) spectra. The results show that all the osmolytes not only inhibit aggregation but also recover the activity of aminoacylase during refolding in a concentration-dependent manner. In particularly, a 40% glycerol concentration and a 1.5 mol/L sucrose concentration almost completely suppressed the aminoacylase aggregation. The enzyme activity measurements revealed that the influence of glycerol is more significant than that of any other osmolyte. The intrinsic fluorescence results showed that glycerol, proline, and sucrose stabilized the aminoacylase conformation effectively, with glycerol being the most effective. All 4 kinds of osmolytes reduced the exposure of the hydrophobic surface, indicating that osmolytes facilitate the formation of protein hydrophobic collapse. The CD results indicate that glycerol and sucrose facilitate the return of aminoacylase to its native secondary structure. The results of this study suggest that the ability of the various osmolytes to facilitate the refolding and renaturation of aminoacylase is not the same. A survey of the results in the literature, as well as those presented here, suggests that although the protective effect of osmolytes on protein activity and structure is equal for different osmolytes, the ability of osmolytes to facilitate the refolding of various proteins differs from case to case. In all cases, glycerol was found to be the best stabilizer and a folding aid.

Refolding intermediate of guanidine hydrochloride denatured aminoacylase

The refolding of aminoacylase denatured in 6M guanidine hydrochloride (GdnHCl) has been studied by measuring enzyme activity, fluorescence emission spectra, ANS fluorescence spectra and far-UV circular dichroism spectra. The results showed that GdnHCl-denatured aminoacylase could be refolded and reactivated by dilution. A refolding intermediate was observed for low concentrations of GdnHCl (between 0.5 and 1.2M). This refolding intermediate was characterized by an increased fluorescence emission intensity, a blue-shifted emission maximum, and by increased binding of the fluorescence probe 8-anilino-1-naphthalenesulfonate (ANS). The secondary structure of the intermediate was similar to that of the native enzyme, and was therefore quite similar to the molten globule state often found in the protein folding pathway. Combined with the previous evidence of existence of an intermediate during unfolding process, we therefore proposed that the unfolding and refolding of aminoacylase might share the same pathway. A comparison of the Apo-enzyme and Holo-enzyme showed that there was little effect of the zinc ion on the refolding of the aminoacylase. Our study, the first successful report of the refolding of this metalloenzyme, also showed that lowering the concentration and the temperature of the enzyme improved the refolding rate of aminoacylase. The system therefore provides a useful model to study the refolding of proteins with prosthetic groups.

Aspartate-induced aminoacylase folding and forming of molten globule

Aspartate is an osmolyte found in some marine invertebrates and cyclostome fish. The aspartate-induced unfolding of N-acylamino acid amido hydrolase (aminoacylase) has been studied by measuring enzyme activity, fluorescence emission spectra, 8-anilino-1-naphthalenesulfonate (ANS) fluorescence spectra and far-UV circular dichroism (CD) spectra. The results showed that aspartate caused the inactivation and unfolding of aminoacylase. Surprisingly, increasing concentration of aspartate showed the "acid-induced folding", which used to be seen only in strong acids or salts at much lower pH. Although aspartate has the pI of 2.77 that is the lowest among all the free amino acids, it is actually a weak acid. It is thus of great interest why it causes this phenomenon to happen. The relative change of intrinsic fluorescence and ANS binding spectra have shown that there existed a stable molten globule state of aminoacylase with slightly disrupted tertiary structure and more hydrophobic surface. The molten globule state indicates that intermediates existed during aminoacylase refolding process. Unlike the other acids, such as trichloroacetic acid, there is no precipitation observed as the aspartate concentrations increased. It suggests the aspartate anions have an osmotic effect for the molten globule formed during unfolding process. Binding of aspartate anion to the protonated protein, which minimizes the intramolecular repulsion, might explain the osmotic effect of this amino acid in the nature. The results also showed the Apo-aminoacylase followed similar rules as Holo-enzyme, which suggested the zinc ion may play more important roles on activity other than structure.

Conformational changes and inactivation of calf intestinal alkaline phosphatase in trifluoroethanol solutions

The changes in activity and unfolding of calf intestinal alkaline phosphatase (CIP) during denaturation in different concentrations of trifluoroethanol (TFE) have been investigated by far-ultraviolet circular dichroism and fluorescence emission spectra. Unfolding and activation rate constants were measured and compared, the activation and inactivation courses were much faster than that of unfolding, which suggests that the active site of CIP containing two zinc ions and one magnesium ion is situated in a limited and flexible region of the enzyme molecule that is more fragile to the denaturant than the protein as a whole. However, compared to other metalloenzymes, CIP is inactivated at higher concentrations of TFE as denaturant.