Modulation of global stability, ligand binding and catalytic properties of trypsin by anions.

Specific salts effect is well-known on stability and solubility of proteins, however, relatively limited knowledge is known regarding the effect on catalytic properties of enzymes. Here, we examined the effect of four sodium anions on thermal stability and catalytic properties of trypsin and binding of the fluorescent probe, p-aminobenzamidine (PAB), to the enzyme. We show that the specific anions effect on trypsin properties agrees with the localization of the anions in the Hofmeister series. Thermal stability of trypsin, Tm, the affinity of the fluorescent probe to the binding site, Kd, and the rate constant, kcat, of trypsin-catalyzed hydrolysis of the substrate N-benzoyl-L-arginine ethyl ester (BAEE) increase with increasing kosmotropic character of anions in the order: perchlorate

Destabilization effect of imidazolium cation-Hofmeister anion salts on cytochrome c.

We have analyzed an effect of imidazolium cation-Hofmeister anion salts on stability of basic horse heart cytochrome c (cyt c) at pH4.5 (net charge +17). The effect of salts consisting of imidazolium cations, 1-ethyl-3-methylimidazolium (EMIm+) and 1-butyl-3-methylimidazolium (BMIm+), and five anions: chloride, bromide, iodide, nitrate, and thiocyanate on thermal and pH stability of cyt c was compared with the effect of corresponding sodium salts. Correlation between parameter of dTtrs/d [ion] (Ttrs; thermal midpoints) with surface tension changes of solvent in the presence of both imidazolium and sodium salts implies direct interaction between ions and proteins. Surprisingly, the imidazolium salts have more pronounced destabilization effect on highly positively charged cyt c than the corresponding sodium counterparts. Our analysis suggests the direct interaction of imidazolium cations with polypeptide chain, in analogy to guanidium cation, but the destabilization effect is significantly strengthened by decreased surface tension of imidazolium salt solvents. Comparison of an effect of imidazolium and sodium salts on acidic and alkaline transitions and to thermal transition of cyt c implies a role of hydrophobic interaction between imidazolium cation and polypeptide chain.

Ion-Specific Protein/Water Interface Determines the Hofmeister Effect on the Kinetic Stability of Glucose Oxidase.

Homodimeric glucose oxidase (GOX) from Aspergillus niger is a prominent enzyme used for a number of applications in biotechnology and clinical diagnostics. For robust and long-term functional applications of GOX, the stability of the protein is of utmost importance. In vitro, GOX is irreversibly inactivated over time by a mechanism that is poorly understood, and hence, it presents a significant drawback for the development of strategies to stabilize the enzyme. We show that the nonequilibrium stability of GOX is fully described by a one-step conformational unfolding kinetics. To explore the strategies for improving GOX nonequilibrium stability, the effect of salts of the Hofmeister series is examined using microcalorimetry. We obtain activation energies Ea and inactivation temperatures Tk (at which the irreversible step is 1.0 min-1) as a function of the salt types and concentrations. Based on the analysis by the extended Langmuir model, we find that at high salt concentrations (>1 M) the Hofmeister effect on inactivation temperature is determined by the universal ion-specific effect on the protein/water interface, which apparently does not depend significantly on a particular amino-acid sequence and 3D protein structure. Our findings identify protein/water interfacial tension as a critical physicochemical attribute of excipients that is crucial for increasing enzyme kinetic stability.

Hofmeister effect on catalytic properties of chymotrypsin is substrate-dependent.

Effect of Hofmeister sodium salts, sulfate, chloride, bromide and perchlorate, on catalytic properties and stability of chymotrypsin has been studied by absorbance and circular dichroism spectroscopies. To address Hofmeister effect on activity of chymotrypsin, two different substrates, N-benzoyl-L-tyrosine ethyl ester and amide N-succinyl-L-phenylalanine-p-nitroanilide, were used. Catalytic activity of chymotrypsin is dependent on salt concentration and position of anion in Hofmeister series. The enzyme activity for both substrates is only slightly affected by chaotropic anions and increases with kosmotropic nature of anions. While the trend of Hofmeister effect on chymotrypsin catalysis is similar for both substrates, the amplitude of the effect significantly differs. In the presence of 1 M sulfate, catalytic efficiency increased by ~2-fold for the ester but ~20-fold for the amide substrate. Positive correlation between stability and activity of chymotrypsin indicates the interdependence of these enzyme properties and is in agreement with recently developed macromolecular rate theory suggesting an important role of protein dynamics in enzyme catalysis. Linear dependencies of catalytic properties of chymotrypsin with partitioning of anions at bulk water/air as well as at hydrocarbon surface strongly indicate that the modulated enzyme properties are results of direct interaction of anions with protein surface.

The molten-globule residual structure is critical for reflavination of glucose oxidase.

Glucose oxidase (GOX) is a homodimeric glycoprotein with tightly bound one molecule of FAD cofactor per monomer of the protein. GOX has numerous applications, but the preparation of biotechnologically interesting GOX sensors requires a removal of the native FAD cofactor. This process often leads to unwanted irreversible deflavination and, as a consequence, to the low enzyme recovery. Molecular mechanisms of reversible reflavination are poorly understood; our current knowledge is based only on empiric rules, which is clearly insufficient for further development. To develop conceptual understanding of flavin-binding competent states, we studied the effect of deflavination protocols on conformational properties of GOX. After deflavination, the apoform assembles into soluble oligomers with nearly native-like holoform secondary structure but largely destabilized tertiary structure presumambly due to the packing density defects around the vacant flavin binding site. The reflavination is cooperative but not fully efficient; after the binding the flavin cofactor, the protein directly disassembles into native homodimers while the fraction of oligomers remains irreversibly inactivated. Importantly, the effect of Hofmeister salts on the conformational properties of GOX and reflavination efficiency indicates that the native-like residual tertiary structure in the molten-globule states favorably supports the reflavination and minimizes the inactivated oligomers. We interpret our results by combining the ligand-induced changes in quaternary structure with salt-sensitive, non-equilibrated conformational selection model. In summary, our work provides the very first steps toward molecular understanding the complexity of the GOX reflavination mechanism.

Correlation of lysozyme activity and stability in the presence of Hofmeister series anions.

Enzymatic activity and stability of lysozyme in the presence of salts have been studied by fluorescence spectroscopy and differential scanning calorimetry, respectively. The effect of sodium salts of sulfate, acetate, chloride, bromide, thiocyanate, and perchlorate on lysozyme properties depends on anion concentration as well as on position of anion in the Hofmeister series. Kosmotropic anions (sulfate and acetate) increase stability and activate the enzyme while chaotropic anions (bromide, thiocyanate and perchlorate) including chloride decrease stability and inhibits the enzyme activity. Strong correlation between stability and activity of lysozyme suggest the interdependence of these enzyme properties in the presence of salts. The fact that the properties of lysozyme correlate with partition coefficients of anions at hydrocarbon surface clearly indicates that Hofmeister effect of anions is mediated by their interactions with nonpolar parts of the enzyme surface despite its high positive net charge at studied conditions. The efficiency of the anions in affecting both activity and stability of lysozyme also correlates with other anion-related parameters most notably with polarizability of monovalent anions. The presented work points to a critical role of interaction of anions with nonpolar protein surface for the Hofmeister effect. Moreover, the simultaneous investigation of protein stability and activity, in the relation with the Hofmeister effect, provides important information regarding stability/rigidity of enzyme structure for its catalytic activity.