Despite having a common P1 Leu, eglin C inhibits alpha-lytic proteinase a million-fold more strongly than does turkey ovomucoid third domain.

Results of the inhibition of alpha-lytic proteinase by two standard mechanism serine proteinase inhibitors, turkey ovomucoid third domain (OMTKY3) and eglin C, and many of their variants are presented. Despite similarities, including an identical P1 residue (Leu) in their primary contact regions, OMTKY3 and eglin C have vastly different association equilibrium constants toward alpha-lytic proteinase, with Ka values of 1.8 x 10(3) and 1.2 x 10(9) M(-1), respectively. Although 12 of the 13 serine proteinases tested in our laboratory for inhibition by OMTKY3 and eglin C are more strongly inhibited by the latter, the million-fold difference observed here with alpha-lytic proteinase is the largest we have seen. The million-fold stronger inhibition by eglin C is retained when the Ka values of the P1 Gly, Ala, Ser, and Ile variants of OMTKY3 and eglin C are compared. Despite the small size of the S1 pocket in alpha-lytic proteinase, interscaffolding additivity for OMTKY3 and eglin C holds well for the four P1 residues tested here. To better understand this difference, we measured Ka values for other OMTKY3 variants, including some that had residues elsewhere in their contact region that corresponded to those of eglin C. Assuming intrascaffolding additivity and using the Ka values obtained for OMTKY3 variants, we designed an OMTKY3-based inhibitor of alpha-lytic proteinase that was predicted to inhibit 10,000-fold more strongly than wild-type OMTKY3. This variant (K13A/P14E/L18A/R21T/N36D OMTKY3) was prepared, and its Ka value was measured against alpha-lytic proteinase. The measured Ka value was in excellent agreement with the predicted one (1.1 x 10(7) and 2.0 x 10(7) M(-1), respectively). Computational protein docking results are consistent with the view that the backbone conformation of eglin C is not significantly altered in the complex with alpha-lytic proteinase. They also show that the strong binding for eglin C correlates well with more favorable atomic contact energy and desolvation energy contributions as compared to OMTKY3.

Isolation of a deet-insensitive mutant of Drosophila melanogaster (Diptera: Drosophilidae).

Despite the widespread use of N,N,-diethyl-3-methylbenzamide (deet) in insect repellent products, nothing is known about the molecular basis for the repellency of deet, we initiated a molecular genetics program to elucidate the molecular mechanism of deet repellency in Drosophila melanogaster (Meigen). Deet repellency was apparently due to airborne vapors, as wild type flies were repelled by a deet-treated surface in the absence of physical contact and in the dark. A mutant was isolated using chemical mutagenesis and at choice assay. In a choice assay, mutant flies entered 82 +/- 1% of deet-containing tubes, whereas wild type flies entered only 6 +/- 2% of deet-containing tubes. The mutant was repelled by other repellents, benzaldehyde and citronellal. The mutation was recessive and located on the X chromosome.

Thermodynamic criterion for the conformation of P1 residues of substrates and of inhibitors in complexes with serine proteinases.

Eglin c, turkey ovomucoid third domain, and bovine pancreatic trypsin inhibitor (Kunitz) are all standard mechanism, canonical protein inhibitors of serine proteinases. Each of the three belongs to a different inhibitor family. Therefore, all three have the same canonical conformation in their combining loops but differ in their scaffoldings. Eglin c (Leu45 at P1) binds to chymotrypsin much better than its Ala45 variant (the difference in standard free energy changes on binding is -5.00 kcal/mol). Similarly, turkey ovomucoid third domain (Leu18 at P1) binds to chymotrypsin much better than its Ala18 variant (the difference in standard free energy changes on binding is -4.70 kcal/mol). As these two differences are within the +/-400 cal/mol bandwidth (expected from the experimental error), one can conclude that the system is additive. On the basis that isoenergetic is isostructural, we expect that within both the P1 Ala pair and the P1 Leu pair, the conformation of the inhibitor's P1 side chain and of the enzyme's specificity pocket will be identical. This is confirmed, within the experimental error, by the available X-ray structures of complexes of bovine chymotrypsin Aalpha with eglin c () and with turkey ovomucoid third domain (). A comparison can also be made between the structures of P1 (Lys+)15 of bovine pancreatic trypsin inhibitor (Kunitz) ( and ) and of the P1 (Lys+)18 variant of turkey ovomucoid third domain (), both interacting with chymotrypsin. In this case, the conformation of the side chains is strikingly different. Bovine pancreatic trypsin inhibitor with (Lys+)15 at P1 binds to chymotrypsin more strongly than its Ala15 variant (the difference in standard free energy changes on binding is -1.90 kcal/mol). In contrast, turkey ovomucoid third domain variant with (Lys+)18 at P1 binds to chymotrypsin less strongly than its Ala18 variant (the difference in standard free energies of association is 0.95 kcal/mol). In this case, P1 Lys+ is neither isostructural nor isoenergetic. Thus, a thermodynamic criterion for whether the conformation of a P1 side chain in the complex matches that of an already determined one is at hand. Such a criterion may be useful in reducing the number of required X-ray crystallographic structure determinations. More importantly, the criterion can be applied to situations where direct determination of the structure is extremely difficult. Here, we apply it to determine the conformation of the Lys+ side chain in the transition state complex of a substrate with chymotrypsin. On the basis of kcat/KM measurements, the difference in free energies of activation for Suc-AAPX-pna when X is Lys+ and X is Ala is 1.29 kcal/mol. This is in good agreement with the corresponding difference for turkey ovomucoid third domain variants but in sharp contrast to the bovine pancreatic trypsin inhibitor (Kunitz) data. Therefore, we expect that in the transition state complex of this substrate with chymotrypsin, the P1 Lys+ side chain is deeply inserted into the enzyme's specificity pocket as it is in the (Lys+)18 turkey ovomucoid third domain complex with chymotrypsin.

Interscaffolding additivity. Association of P1 variants of eglin c and of turkey ovomucoid third domain with serine proteinases.

Standard mechanism protein inhibitors of serine proteinases share a common mechanism of interaction with their cognate enzymes. The P1 residue of the inhibitor interacts with the enzyme in a substrate-like manner. Its side chain becomes imbedded in the S1 cavity of the enzyme. The nature of P1, the primary specificity residue, greatly affects the strength and specificity of the enzyme inhibitor association. In canonical inhibitors, residues P4-P2'(P3'), where P1-P1' is the reactive site, share a common main chain conformation that does not change on complex formation. The remainder of the inhibitor's structure, the scaffolding, is not always common. Instead, there are at least 20 inhibitor families, each with a different scaffolding. In this paper, we ask whether the differences in standard free energy of association of enzyme-inhibitor complexes upon P1 mutations are independent of the nature of the scaffolding. We have already reported on 25 P1 variants of turkey ovomucoid third domain, a member of the Kazal inhibitor family, interacting with six different serine proteinases. Here, we report on seven different P1 variants of eglin c, a potato I family member, interacting with the same six serine proteinases under the same conditions. The differences in standard free energy on P1 mutations in the eglin c system agree very well, when P1 Pro is omitted. Complete agreement indicates that these P1 residues are interscaffolding additive. This is consistent with the superimposition of the high-resolution structures of eglin c and of turkey ovomucoid third domain with chymotrypsin. In both cases, the P1 Leu side chain is similarly oriented in almost indistinguishable specificity pockets of the enzyme.