A hyperstable (hs) variant of chicken egg-white lysozyme with enhanced thermal (AT, = + 10.5 "C) and chemical (AC,n for guanidine hydrochloride denaturation = + 1.3 M) stabilities relative to wild-type (WT) was constructed by combining several individual stabilizing substitutions. The free energy difference between the native and denatured states of the hs variant is 3.1 (GdnHCl, 25 "C) to 4.0 (differential scanning calorimetry, 74 "C) kcal mol" greater than that of WT. The specific activity of the hs variant is 2.5-fold greater than that of WT. The choice of mutations came from diverse sources: (1) The 155L/S91T core construct with AT, = 3.3 "C from WT was available from the accompanying study (Shih P, Holland DR, Kirsch JF, 1995, Protein Sci 4:2050-2062. (2) The A31V mutation was suggested by the better atomic packing in the human lysozyme structure where the Ala 3 1 equivalent is Leu. (3) The H15L and R114H substitutions were selected on the basis of sequence comparisons with pheasant lysozymes that are more stable than the chicken enzyme. (4) The DlOlS variant was identified from a screen of mutants previously prepared in this laboratory. The effects of the individual mutations on stability are cumulative and nearly additive.Keywords: a-helix propensity; avian lysozyme sequences; chicken lysozyme; human lysozyme; interior packing; protein design; structures; thermodynamic stability A challenging goal of protein engineering is the design of proteins with significantly enhanced thermo-and chemical stabilities. A variety of successful routes to this objective has been undertaken. These include: (1) introducing disulfide bridges (Matsumura et al., 1989b); (2) increasing internal hydrophobic packing (Malcolm et al., 1990); (3) reducing solvent-exposed nonpolar surface area (Pakula & Sauer, 1990); (4) incorporating a metal association site (Kuroki et al., 1989); and (5) adding charged side chains to interact with the a-helix dipoles (Nicholson et al., 1988). However, the above strategies are not always successful and their pursuit has often yielded proteins that are less stable than the WT progenitors for reasons that are not fully understood (e.g., Karpusas et al., 1989;Matsumura et al., 1989a;Eijsink et al., 1992;Leontiev et al., 1993 Abbreviations: hs, a hyperstable variant of chicken lysozyme; GdnHCI, guanidine hydrochloride; T,, the midpoint temperature of the thermal denaturation transition; C,, the midpoint concentration of the GdnHCl denaturation profile; DSC, differential scanning calorimetry; AH,,,, calorimetrically determined enthalpy of denaturation; AC,, the difference between the heat capacities of the native and the denatured states; WT or wt, wild type.
