pH Dependence Thermal Stability of a Chymotrypsin Inhibitor from Schizolobium parahyba Seeds

The thermal stability of a Schizolobium parahyba chymotrypsin inhibitor (SPCI) as a function of pH has been investigated using fluorescence, circular dichroism, and differential scanning calorimetry (DSC). The thermodynamic parameters derived from all methods are remarkably similar and strongly suggest the high stability of SPCI under a wide range of pH. The transition temperature (T(m)) values ranging from 57 to 85.3°C at acidic, neutral, and alkaline pH are in good agreement with proteins from mesophilic and thermophilic organisms and corroborate previous data regarding the thermal stability of SPCI. All methods gave transitions curves adequately fitted to a two-state model of the unfolding process as judged by the cooperative ratio between the van't Hoff and the calorimetric enthalpy energies close to unity in all of the pH conditions analyzed, except at pH 3.0. Thermodynamic analysis using all these methods reveals that SPCI is thermally a highly stable protein, over the wide range of pH from 3.0 to 8.8, exhibiting high stability in the pH region of 5.0–7.0. The corresponding maximum stabilities, ΔG(25), were obtained at pH 7.0 with values of 15.4 kcal mol(−1) (combined fluorescence and circular dichroism data), and 15.1 kcal mol(−1) (DSC), considering a ΔC(p) of 1.72 ± 0.24 kcal mol(−1) K(−1). The low histidine content (∼1.7%) and the high acidic residue content (∼22.5%) suggests a flat pH dependence of thermal stability in the region 2.0–8.8 and that the decrease in thermal stability at low pH can be due to the differences in pK values of the acidic groups

Crystal Structure of the Bowman-Birk Inhibitor from Vigna unguiculata Seeds in Complex with β-Trypsin at 1.55 Å Resolution and Its Structural Properties in Association with Proteinases

The structure of the Bowman-Birk inhibitor from Vigna unguiculata seeds (BTCI) in complex with β-trypsin was solved and refined at 1.55 Å to a crystallographic R(factor) of 0.154 and R(free) of 0.169, and represents the highest resolution for a Bowman-Birk inhibitor structure to date. The BTCI-trypsin interface is stabilized by hydrophobic contacts and hydrogen bonds, involving two waters and a polyethylene glycol molecule. The conformational rigidity of the reactive loop is characteristic of the specificity against trypsin, while hydrophobicity and conformational mobility of the antichymotryptic subdomain confer the self-association tendency, indicated by atomic force microscopy, of BTCI in complex and free form. When BTCI is in binary complexes, no significant differences in inhibition constants for producing a ternary complex with trypsin and chymotrypsin were detected. These results indicate that binary complexes present no conformational change in their reactive site for both enzymes confirming that these sites are structurally independent. The free chymotrypsin observed in the atomic force microscopy assays, when the ternary complex is obtained from BTCI-trypsin binary complex and chymotrypsin, could be related more to the self-association tendency between chymotrypsin molecules and the flexibility of the reactive site for this enzyme than to binding-related conformational changes