SGCI (Schistocerca gregaria chymotrypsin inhibitor) and SGTI (Sch. gregaria trypsin inhibitor) are small, 35-residue serine protease inhibitors with intriguing taxon specificity: SGTI is specific for arthropod proteases while SGCI is an excellent inhibitor on both mammalian and arthropodal enzymes. Here we report the cloning, expression, and (15)N backbone dynamics investigations of these peptides. Successful expression could be achieved by a "dimeric" construct similar to the natural precursor of the inhibitors. An engineered methionine residue between the two modules served as a unique cyanogen bromide cleavage site to cleave the precursor and physically separate SGCI and SGTI. The overall correlation time of the precursor (5.29 ns) as well as the resulted SGCI (3.14 ns) and SGTI (2.96 ns) are as expected for proteins of this size. General order parameters (S(2)) for the inhibitors are lower than those characteristic of well-folded proteins. Values in the binding loop region are even lower. Interestingly, the distribution of residues for which a chemical exchange (R(ex)) term should be considered is strikingly different in SGCI and SGTI. Together with H-D exchange studies, this indicates that the internal dynamics of the two closely related molecules differ. We suggest that the dynamic properties of these inhibitors is one of the factors that determine their specificity.
The mechanism of serine proteases prominently illustrates how charged amino acid residues and proton transfer events facilitate enzyme catalysis. Here we present an ultrahigh resolution (0.93 Å) x-ray structure of a complex formed between trypsin and a canonical inhibitor acting through a substrate-like mechanism. The electron density indicates the protonation state of all catalytic residues where the catalytic histidine is, as expected, in its neutral state prior to the acylation step by the catalytic serine. The carboxyl group of the catalytic aspartate displays an asymmetric electron density so that the Oδ2–Cγ bond appears to be a double bond, with Oδ2 involved in a hydrogen bond to His-57 and Ser-214. Only when Asp-102 is protonated on Oδ1 atom could a density functional theory simulation reproduce the observed electron density. The presence of a putative hydrogen atom is also confirmed by a residual mFobs − DFcalc density above 2.5 σ next to Oδ1. As a possible functional role for the neutral aspartate in the active site, we propose that in the substrate-bound form, the neutral aspartate residue helps to keep the pKa of the histidine sufficiently low, in the active neutral form. When the histidine receives a proton during the catalytic cycle, the aspartate becomes simultaneously negatively charged, providing additional stabilization for the protonated histidine and indirectly to the tetrahedral intermediate. This novel proposal unifies the seemingly conflicting experimental observations, which were previously seen as either supporting the charge relay mechanism or the neutral pKa histidine theory.
The cDNA for a 73-mer peptide containing two locust serine proteinase inhibitors was cloned, fused to the constitutive CaMV35S promoter and introduced into potato by Agrobacterium-mediated transformation. From 23 independent transgenic lines, three with high mRNA level and proteinase inhibitory activity were propagated in vitro and transferred to pots. The peptide from the leaves was identified by its N-terminal sequence and by K(i) values against chymotrypsin and trypsin. Colorado potato beetle larvae reared on transgenic plants grew slightly but significantly more slowly than those on control plants. This supports the notion that expression of multifunctional proteinase inhibitors of insect origin might be a good strategy to improve insect resistance in plants.
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