Effects of conversion of the zinc-binding motif sequence of thermolysin, HEXXH, to that of dipeptidyl peptidase III, HEXXXH, on the activity and stability of thermolysin.

Most zinc metalloproteinases have the consensus zinc-binding motif sequence HEXXH, in which two histidine residues chelate a catalytic zinc ion. The zinc-binding motif sequence of thermolysin, H(142)ELTH(146), belongs to this motif sequence, while that of dipeptidyl peptidase III (DPP III), H(450)ELLGH(455), belongs to the motif sequence HEXXXH. In this study, we examined effects of conversion of HEXXH to HEXXXH in thermolysin on its activity and stability. Thermolysin variants bearing H(142)ELLGH(146) or H(142)ELTGH(146) (designated T145LG and T145TG respectively) were constructed by site-directed mutagenesis and were produced in Escherichia coli cells by co-expressing the mature and pro domains separately. They did not exhibit hydrolyzing activity for casein or N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide, but exhibited binding ability to a substrate analog glycyl-D-phenylalanine (Gly-D-Phe). The apparent denaturing temperatures based on the ellipticity at 222 nm of T145LG and T145TG were 85 ± 1 °C and 86 ± 1 °C respectively, almost the same as that of wild-type thermolysin (85 ± 1 °C). These results indicate that conversion of HEXXH to HEXXXH abolishes thermolysin activity, but does not affect its binding ability to Gly-D-Phe or its stability. Our results are in contrast to ones reported previously, that DPP III variants bearing H(450)ELGH(455) exhibit activity.

Effects of mutations of thermolysin, as N116 to asp and asp150 to glu, on salt-induced activation and stabilization.

Neutral salts activate and stabilize thermolysin. We previously found that two single mutations, Asn116→Asp and Asp150→Glu, increase the activity of thermolysin. In the present study, we examined their effects on NaCl-induced activation and stabilization. In the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide, the relative activities (the ratios of the specificity constant, kcat/Km, at x M NaCl to that at 0 M NaCl) at 0.5-4.0 M NaCl of D150E and N116D/D150E were lower than those of wild-type thermolysin (WT) and N116D, respectively. In thermal inactivation at 70 °C, the relative stabilities (the ratios of the first-order rate constant, kobs, at 0 M NaCl to that at x M NaCl) at 0.5-4.0 M NaCl of D150E and N116D/D150E were lower than those of WT and N116D, respectively. These results indicate that unlike Asn116→Asp, Asp150→Glu reduced NaCl-induced activation and stabilization, suggesting that the binding of ions with certain residues of thermolysin is involved in the activation and stabilization.

Effects of site-directed mutagenesis of Asn116 in the ß-hairpin of the N-terminal domain of thermolysin on its activity and stability.

In the N-terminal domain of thermolysin, two anti-parallel ß-strands, Asn112-Ala113-Phe114-Trp115 and Ser118-Gln119-Met120-Val121-Tyr122 are connected by an Asn116-Gly117 turn to form a ß-hairpin structure. In this study, we examined the role of Asn116 in the activity and stability of thermolysin by site-directed mutagenesis. Of the 19 Asn116 variants, four (N116A, N116D, N116T and N116Q) were produced in Escherichia coli, by co-expressing the mature and pro domains separately, while the other 15 were not. In the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide (FAGLA) at 25°C, the intrinsic k(cat)/K(m) value of N116D was 320% of that of the wild-type thermolysin (WT), and in the hydrolysis of N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester (ZDFM) at pH 7.5 at 25°C, the k(cat)/K(m) value of N116D was 140% of that of WT, indicating that N116D exhibited higher activity than WT. N116Q exhibited similar activity as WT, and N116A and N116T exhibited reduced activities. The first-order rate constants, k(obs), of the thermal inactivation at 80°C were in the order N116A, N116D, N116T > N116Q > WT at all CaCl(2) concentrations examined (1-100 mM), indicating that all variants exhibited reduced stabilities. These results suggest that Asn116 plays an important role in the activity and stability of thermolysin presumably by stabilizing this ß-hairpin structure.

Effects of site-directed mutagenesis of the loop residue of the N-terminal domain Gly117 of thermolysin on its catalytic activity.

In the N-terminal domain of thermolysin, two polypeptide strands, Asn112-Ala113-Phe114-Trp115 and Ser118-Gln119-Met120-Val121-Tyr122, are connected by a short loop, Asn116-Gly117, to form an anti-parallel ß-sheet. The Asn112-Trp115 strand is located in the active site, while the Ser118-Tyr122 strand and the Asn116-Gly117 loop are located outside the active site. In this study, we explored the catalytic role of Gly117 by site-directed mutagenesis. Five variants, G117A (Gly117 is replaced by Ala), G117D, G117E, G117K, and G117R, were produced by co-expressing in Escherichia coli the mature and pro domains as independent polypeptides. The production levels were in the order G117E > wild type > G117K, G117R > G117D. G117A was hardly produced. This result is in contrast to our previous one that all 72 active-site thermolysin variants were produced at the similar levels whether they retained activity or not (M. Kusano et al. J. Biochem., 145, 103-113 (2009)). G117E exhibited lower activity in the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide and higher activity in the hydrolysis of N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester than the wild-type thermolysin. G117K and G117R exhibited considerably reduced activities. This suggests that Gly117 plays an important role in the activity and stability of thermolysin, presumably by affecting the geometries of the Asn112-Trp115 and Ser118-Tyr122 strands.