Crystal structure at 2.6 A resolution of the complex of subtilisin BPN' with streptomyces subtilisin inhibitor

The crystal structure of the complex of a bacterial alkaline serine proteinase, subtilisin BPN', with its proteinaceous inhibitor SSI (Streptomyces subtilisin inhibitor) was solved at 2.6 A resolution. Compared with other similar complexes involving serine proteinases of the trypsin family, the present structure is unique in several respects. (1) In addition to the usual antiparallel beta-sheet involving the P1, P2 and P3 residues of the inhibitor, the P4, P5 and P6 residues form an antiparallel beta-sheet with a previously unnoticed chain segment (residues 102 through 104, which was named the S4-6 site) of subtilisin BPN'. (2) The S4-6 site does not exist in serine proteinases of the trypsin family, whether of mammalian or microbial origin. (3) Global induced-fit movement seems to occur on SSI: a channel-like structure in SSI where hydrophobic side-chains are sandwiched between two lobes becomes about 2 A wider upon complexing with subtilisin. (4) The complex is most probably a Michaelis complex, as in most of the other complexes. (5) The main role of the "secondary contact region" of SSI seems to be to support the reactive site loop ("primary contact region"). Steric homology of the two contact regions between the inhibitors of the SSI family and the pancreatic secretory trypsin inhibitor-ovomucoid inhibitor family is so high that it seems to indicate divergent evolutionary processes and to support the general notion as to the relationship of prokaryotic and eukaryotic genes put forward by Doolittle (1978).     

Comparative molecular model building of two serine proteinases from cytotoxic T lymphocytes

Two genes that are expressed when precursor cytotoxic T lymphocytes are transformed to T killer cells have been cloned and sequenced. The derived amino acid sequences, coding for cytotoxic cell protease 1 (CCP1) and Hannuka factor (HF) are highly homologous to members of the serine proteinase family. Comparative molecular model building using the known three-dimensional structures and the derived amino acid sequences of the lymphocyte enzymes has provided useful structural information, especially in predicting the conformations of the substrate binding sites. In applying this modelling procedure, we used the X-ray structures of four serine proteinases to provide a structurally based sequence alignment: alpha-chymotrypsin (CHT), bovine trypsin (BT), Streptomyces griseus trypsin (SGT), and rat mast cell protease 2 (RMCP2). The root mean square differences in alpha-carbon atom positions among these four structures when compared in a pairwise fashion range from 0.79 to 0.97 A for structurally equivalent residues. The sequences of the two lymphocyte enzymes were then aligned to these proteinases using chemical criteria and the superimposed X-ray structures as guides. The alignment showed that the sequence of CCP1 was most similar to RMCP2, whereas HF has regions of homology with both RMCP2 and BT. With RMCP2 as a template for CCP1 and the two enzymes RMCP2 and BT as templates for HF, the molecular models were constructed. Intramolecular steric clashes that resulted from the replacement of amino acid side chains of the templates by the aligned residues of CCP1 and HF were relieved by adjustment of the side chain conformational angles in an interactive computer graphics device. This process was followed by energy minimization of the enzyme model to optimize the stereochemical geometry and to relieve any remaining unacceptably close nonbonded contacts. The resulting model of CCP1 has an arginine residue at position 226 in the specificity pocket, thereby predicting a substrate preference for P1 aspartate or glutamate residues. The model also predicts favorable binding for a small hydrophobic residue at the P2 position of the substrate. The primary specificity pocket of HF resembles that of BT and therefore predicts a lysine or arginine preference for the P1 residue. The arginine at position 99 in the model of HF suggests a preference for aspartate or glutamate side chains in the P2 position of the substrate. Both CCP1 and HF have a free cysteine in the segment of polypeptide 88 to 93.(ABSTRACT TRUNCATED AT 400 WORDS)     

Crystal structure of subtilisin complexed with its trapped substrateStreptomyces subtilisin inhibitor—Protein-protein interaction and evolution of serine proteinases and their proteinaceous inhibitors

The complex of a bacterial alkaline serine proteinase, subtilisin BPN’, with its proteinaceous inhibitorStreptomyces subtilisin inhibitor is unique in several respects, compared with other similar complexes containing serine proteinases of trypsin family. In addition to the usual antiparallelβ-sheet involving P₁-P₃ residues of the inhibitor, P₄-P₆ residues form antiparallelβ-sheet with a previously unnoticed chain segment (the ‘S4-6 site’) of subtilisin. The ‘S4-6 site’ does not exist in serine proteinases of trypsin family, whether of mammalian or microbial origin. Global induced-fit movement seems to occur on the ‘trapped substrate’Streptomyces subtilisin inhibitor: a channel-like structure in SSI remote from the contact region becomes about 2 Å wider upon complexing with subtilisin. Main role of the secondary contact region ofStreptomyces subtilisin inhibitor seems to support the reactive site loop (primary contact region). Steric homology for the two contact regions is so high between the inhibitors ofStreptomyces subtilisin inhibitor family and those of pancreatic secretory trypsin inhibitor-ovomucoid inhibitor family that it seems to favour a divergent evolution and to support the general notion as to the relationship of prokaryotic and eukaryotic genes put forwarded by Doolittle(Nature (London),272, 581, 1978).     

The first semi-synthetic serine protease made by native chemical ligation

Selective incorporation of non-natural amino acid residues into proteins is a powerful approach to delineate structure-function relationships. Although many methodologies are available for chemistry-based protein engineering, more facile methods are needed to make this approach suitable for routine laboratory practice. Here, we describe a new strategy and provide a proof of concept for engineering semi-synthetic proteins. We chose a serine protease Streptomyces griseus trypsin (SGT) for this study to show that it is possible to efficiently couple a synthetic peptide containing a catalytically critical residue to a recombinant fragment containing the other active site residues. The 223-residue hybrid SGT molecule was prepared by fusing a chemically synthesized N-terminal peptide to a large C-terminal fragment of recombinant origin using native chemical ligation. This C-terminal polypeptide was produced from full-length SGT by cyanogen bromide cleavage at a genetically engineered Met57 position. This semi-synthetic hybrid trypsin is fully active, showing kinetics identical to the wild-type enzyme. Thus, we believe that it is an ideal model enzyme for studying the catalytic mechanisms of serine proteases by providing a straightforward approach to incorporate non-natural amino acids in the N-terminal region of the protein. In particular, this strategy will allow for replacement of the catalytic His57 residue and the buried N-terminus, which is thought to help align the active site, with synthetic analogs. Our approach relies on readily available recombinant proteins and small synthetic peptides, thus having general applications in chemical engineering of large proteins where the N-terminal region is the focal interest.     

Crystallographic refinement of Japanese quail ovomucoid, a Kazal-type inhibitor, and model building studies of complexes with serine proteases

Japanese quail ovomucoid third domain (OMJPQ3), a Kazal-type inhibitor, was crystallographically refined with energy constraints. The final R-value is 0.20 at 1.9 Å resolution. The four molecules in the asymmetric unit are very similar, with deviations of main-chain atoms between 0.2 and 0.3 Å. An analysis of the side-chain hydrogen-bonding pattern and amino acid variability in the Kazal family shows a high correlation between hydrogen-bonding and conservation.The conformation of the reactive site loop (P2-P2′) of OMJPQ3 is similar to those of basic pancreatic trypsin inhibitor, Streptomyces subtilisin inhibitor, and soybean trypsin inhibitor. This suggests a common binding mode and justifies model-building studies of complexes.Complexes of OMJPQ3 with trypsin, chymotrypsin and elastase were modelled on the basis of the trypsin-basic pancreatic trypsin inhibitor complex structure and inspected by use of a computer graphics system. Stereochemically satisfying models were constructed in each case and detailed interactions are proposed. The complex with elastase is of particular interest, showing that leucine and methionine are good P1 residues. A good correlation is observed between functional properties of ovomucoid variants and the position of the exchanged residues with respect to the modelled inhibitor-protease contact.     

Isolation and characterization from potato tubers of two polypeptide inhibitors of serine proteinases

Two polypeptides, isolated to electrophoretic homogeneity from Russet Burbank potato tubers, are powerful inhibitors of pancreatic serine proteinases. One of the inhibitors, called polypeptide trypsin inhibitor, PTI, has a molecular weight of 5100, and inhibits bovine trypsin. The inhibitor is devoid of methionine, histidine, and tryptophan and contains eight half-cystine residues as four disulfide bridges. The second inhibitor, polypeptide chymotrypsin inhibitor II, PCI-II, has a molecular weight of 5700 and powerfully inhibits chymotrypsin. This inhibitor is also devoid of methionine and tryptophan but it contains only six of half-cystines as three disulflde bonds. Both polypeptides strongly inhibit pancreatic elastase. In immunological double diffusion assays, polypeptide trypsin inhibitor and polypeptide chymotrypsin inhibitor II exhibit a high degree of immunological identity (a) with each other, (b) with a polypeptide chymotrypsin inhibitor (PCI-I, M_r 5400) previously isolated from potato tubers, and (c) with inhibitor II, a larger (monomer M_r ~ 12,000) inhibitor of both trypsin and chymotrypsin which has also been previously isolated from potato tubers. The four polypeptide proteinase inhibitors now isolated from Russet Burbank potato tubers cumulatively inhibit all five major intestinal digestive endo- and exoproteinases of animals. The inhibitors are thought to be antinutrients that are present as part of the natural chemical defense mechanisms of potato tubers against attacking pests.     

Hypodermin B, a trypsin-related enzyme from the insect Hypoderma lineatum. Comparison with hypodermin A and Hypoderma collagenase, two serine proteinases from the same source

Hypodermin B, a serine proteinase with a molecular weight of 23000, was purified to homogeneity from the larvae Hypoderma lineatum. It is stoichiometrically inhibited by diisopropylfluorophosphate and fully inactivated by N-tosyllysine chloromethyl ketone and soya bean and bovine pancreatic trypsin inhibitors. N-Tosylphenylalanine chloromethyl ketone and ovomucoid are without effect on its activity. Hypodermin B hydrolyses both amide and ester substrates of trypsin but does not display any chymotryptic activity on synthetic substrates. Its specificity on the B chain of insulin is slightly broader than that of bovine trypsin. Its amino acid composition and N-terminal sequence suggest structural homology with serine proteinases of the trypsin family and with two other serine proteinases, hypodermin A and Hypoderma collagenase, previously isolated from the same larvae. Hypodermins A and B are very similar with respect to their inhibition and specificity, they differ however strongly from Hypoderma collagenase.     

The refined 1.9-A X-ray crystal structure of D-Phe-Pro-Arg chloromethylketone-inhibited human alpha-thrombin: structure analysis, overall structure, electrostatic properties, detailed active-site geometry, and structure-function relationships.

Thrombin is a multifunctional serine proteinase that plays a key role in coagulation while exhibiting several other key cellular bioregulatory functions. The X-ray crystal structure of human alpha-thrombin was determined in its complex with the specific thrombin inhibitor D-Phe-Pro-Arg chloromethylketone (PPACK) using Patterson search methods and a search model derived from trypsinlike proteinases of known spatial structure (Bode, W., Mayr, I., Baumann, U., Huber, R., Stone, S.R., & Hofsteenge, J., 1989, EMBO J. 8, 3467-3475). The crystallographic refinement of the PPACK-thrombin model has now been completed at an R value of 0.156 (8 to 1.92 A); in particular, the amino- and the carboxy-termini of the thrombin A-chain are now defined and all side-chain atoms localized; only proline 37 was found to be in a cis-peptidyl conformation. The thrombin B-chain exhibits the characteristic polypeptide fold of trypsinlike serine proteinases; 195 residues occupy topologically equivalent positions with residues in bovine trypsin and 190 with those in bovine chymotrypsin with a root-mean-square (r.m.s.) deviation of 0.8 A for their alpha-carbon atoms. Most of the inserted residues constitute novel surface loops. A chymotrypsinogen numbering is suggested for thrombin based on the topological equivalences. The thrombin A-chain is arranged in a boomeranglike shape against the B-chain globule opposite to the active site; it resembles somewhat the propeptide of chymotrypsin(ogen) and is similarly not involved in substrate and inhibitor binding. Thrombin possesses an exceptionally large proportion of charged residues. The negatively and positively charged residues are not distributed uniformly over the whole molecule, but are clustered to form a sandwichlike electrostatic potential; in particular, two extended patches of mainly positively charged residues occur close to the carboxy-terminal B-chain helix (forming the presumed heparin-binding site) and on the surface of loop segment 70-80 (the fibrin[ogen] secondary binding exosite), respectively; the negatively charged residues are more clustered in the ringlike region between both poles, particularly around the active site. Several of the charged residues are involved in salt bridges; most are on the surface, but 10 charged protein groups form completely buried salt bridges and clusters. These electrostatic interactions play a particularly important role in the intrachain stabilization of the A-chain, in the coherence between the A- and the B-chain, and in the surface structure of the fibrin(ogen) secondary binding exosite (loop segment 67-80).(ABSTRACT TRUNCATED AT 400 WORDS)     

Crystal structure of cancer chemopreventive Bowman-Birk inhibitor in ternary complex with bovine trypsin at 2.3 A resolution. Structural basis of Janus-faced serine protease inhibitor specificity

Understanding molecular recognition on a structural basis is an objective with broad academic and applied significance. In the complexes of serine proteases and their proteinaceous inhibitors, recognition is governed mainly by residue P1 in accord with primary serine protease specificity. The bifunctional soybean Bowman-Birk inhibitor (sBBI) should, therefore, interact at LysI16 (subdomain 1) with trypsin and at LeuI43 (subdomain 2) with chymotrypsin. In contrast with this prediction, a 2:1 assembly with trypsin was observed in solution and in the crystal structure of sBBI in complex with trypsin, determined at 2.3 A resolution by molecular replacement. Strikingly, P1LeuI43 of sBBI was fully embedded into the S(1) pocket of trypsin in contrast to primary specificity. The triple-stranded beta-hairpin unique to the BBI-family and the surface loops surrounding the active site of the enzyme formed a protein-protein-interface far extended beyond the primary contact region. Polar residues, hydrophilic bridges and weak hydrophobic contacts were predominant in subdomain 1, interacting specifically with trypsin. However, close hydrophobic contacts across the interface were characteristic of subdomain 2 reacting with both trypsin and chymotrypsin. A Met27Ile replacement shifted the ratio with trypsin to the predicted 1:1 ratio. Thus, the buried salt-bridge responsible for trypsin specificity was stabilised in a polar, and destabilized in a hydrophobic, environment. This may be used for adjusting the specificity of protease inhibitors for applications such as insecticides and cancer chemopreventive agents.     

Development of human pancreas

The developmental sequence of human pancreatic secretory proteins has not previously been studied in detail. We applied immunohistochemistry to study 20 fetal and neonatal pancreas' (8th to 39th gestational weeks) using antisera against the following pancreatic secretory proteins: pancreatic secretory trypsin inhibitor (PSTI), serine proteinases (trypsin, chymotrypsin, and elastase I), and amylase. PSTI was first detected in developing buds of the pancreas during the 8th gestational week, and proteinases were observed in acinar cells during the 14th week of gestation. Immunoreactivity for both PSTI and proteinases was found in most acinar cells soon after their appearance. Immunoreactivity for amylase could not be detected in fetal or neonatal pancreas tissue. PSTI was also found in developing islets during the 14th gestational week, but the number of immunoreactive cells had decreased by term. Cells positive for serine proteinases were occasionally in contact with islets in second-trimester fetuses. In discussing these results, we give particular attention to the nonparallel appearance of secretory products in the fetal pancreas, and the significance of cells immunoreactive for secretory proteins in endocrine islets.     

Refined X-ray crystal structures of the reactive site modified ovomucoid inhibitor third domains from silver pheasant (OMSVP3*) and from Japanese quail (OMJPQ3*).

Tetragonal and triclinic crystals of two ovomucoid inhibitor third domains from silver pheasant and Japanese quail, modified at their reactive site bonds Met18-Glu19 (OMSVP3*) and Lys18-Asp19 (OMJPQ3*), respectively, were obtained. Their molecular and crystal structures were solved using X-ray data to 2.5 A and 1.55 A by means of Patterson search methods using truncated models of the intact (virgin) inhibitors as search models. Both structures were crystallographically refined to R-values of 0.185 and 0.192, respectively, applying an energy restraint reciprocal space refinement procedure. Both modified inhibitors show large deviations from the intact derivatives only in the proteinase binding loops (Pro14 to Arg21) and in the amino-terminal segments (Leu1 to Val6). In the modified inhibitors the residues immediately adjacent to the cleavage site (in particular P2, P1, P1') are mobile and able to adapt to varying crystal environments. The charged end-groups, i.e. Met18 COO- and Glu19 NH3+ in OMSVP3*, and Lys18 COO- and Asp19 NH3+ in OMJPQ3*, do not form ion pairs with one another. The hydrogen bond connecting the side-chains of Thr17 and Glu19 (i.e. residues on either side of the scissile peptide bond) in OMSVP3 is broken in the modified form, and the hydrogen-bond interactions observed in the intact molecules between the Asn33 side-chain and the carbonyl groups of loop residues P2 and P1' are absent or weak in the modified inhibitors. The reactive site cleavage, however, has little effect on specific interactions within the protein scaffold such as the side-chain hydrogen bond between Asp27 and Tyr31 or the side-chain stacking of Tyr20 and Pro22. The conformational differences in the amino-terminal segment Leu1 to Val6 are explained by their ability to move freely, either to associate with segments of symmetry-related molecules under formation of a four-stranded beta-barrel (OMSVP3* and OMJPQ3) or to bind to surrounding molecules. Together with the results given in the accompanying paper, these findings probably explain why Khyd of small protein inhibitors of serine proteinases is generally found to be so small.     

A theoretical study of the active sites of papain and S195C rat trypsin: implications for the low reactivity of mutant serine proteinases.

The serine and cysteine proteinases represent two important classes of enzymes that use a catalytic triad to hydrolyze peptides and esters. The active site of the serine proteinases consists of three key residues, Asp...His...Ser. The hydroxyl group of serine functions as a nucleophile and the imidazole ring of histidine functions as a general acid/general base during catalysis. Similarly, the active site of the cysteine proteinases also involves three key residues: Asn, His, and Cys. The active site of the cysteine proteinases is generally believed to exist as a zwitterion (Asn...His+...Cys-) with the thiolate anion of the cysteine functioning as a nucleophile during the initial stages of catalysis. Curiously, the mutant serine proteinases, thiol subtilisin and thiol trypsin, which have the hybrid Asp...His...Cys triad, are almost catalytically inert. In this study, ab initio Hartree-Fock calculations have been performed on the active sites of papain and the mutant serine proteinase S195C rat trypsin. These calculations predict that the active site of papain exists predominately as a zwitterion (Cys-...His+...Asn). However, similar calculations on S195C rat trypsin demonstrate that the thiol mutant is unable to form a reactive thiolate anion prior to catalysis. Furthermore, structural comparisons between native papain and S195C rat trypsin have demonstrated that the spatial juxtapositions of the triad residues have been inverted in the serine and cysteine proteinases and, on this basis, I argue that it is impossible to convert a serine proteinase to a cysteine proteinase by site-directed mutagenesis.     

Crystal structure of a subtilisin-like serine proteinase from a psychrotrophic Vibrio species reveals structural aspects of cold adaptation

The crystal structure of a subtilisin-like serine proteinase from the psychrotrophic marine bacterium, Vibrio sp. PA-44, was solved by means of molecular replacement and refined at 1.84 A. This is the first structure of a cold-adapted subtilase to be determined and its elucidation facilitates examination of the molecular principles underlying temperature adaptation in enzymes. The cold-adapted Vibrio proteinase was compared with known three-dimensional structures of homologous enzymes of meso- and thermophilic origin, proteinase K and thermitase, to which it has high structural resemblance. The main structural features emerging as plausible determinants of temperature adaptation in the enzymes compared involve the character of their exposed and buried surfaces, which may be related to temperature-dependent variation in the physical properties of water. Thus, the hydrophobic effect is found to play a significant role in the structural stability of the meso- and thermophile enzymes, whereas the cold-adapted enzyme has more of its apolar surface exposed. In addition, the cold-adapted Vibrio proteinase is distinguished from the more stable enzymes by its strong anionic character arising from the high occurrence of uncompensated negatively charged residues at its surface. Interestingly, both the cold-adapted and thermophile proteinases differ from the mesophile enzyme in having more extensive hydrogen- and ion pair interactions in their structures; this supports suggestions of a dual role of electrostatic interactions in the adaptation of enzymes to both high and low temperatures. The Vibrio proteinase has three calcium ions associated with its structure, one of which is in a calcium-binding site not described in other subtilases.     

Cold adaption of enzymes: Structural comparison between salmon and bovine trypsins

The crystal structure of an anionic form of salmon trypsin has been determined at 1.82 Å resolution. We report the first structure of a trypsin from a phoikilothermic organism in a detailed comparison to mammalian trypsins in order to look for structural rationalizations for the cold-adaption features of salmon trypsin. This form of salmon trypsin (T II) comprises 222 residues, and is homologous to bovine trypsin (BT) in about 65% of the primary structure. The tertiary structures are similar, with an overall displacement in main chain atomic positions between salmon trypsin and various crystal structures of bovine trypsin of about 0.8 Å. Intramolecular hydrogen bonds and hydrophobic interactions are compared and discussed in order to estimate possible differences in molecular flexibility which might explain the higher catalytic efficiency and lower thermostability of salmon trypsin compared to bovine trypsin. No overall differences in intramolecular interactions are detected between the two structures, but there are differences in certain regions of the structures which may explain some of the observed differences in physical properties. The distribution of charged residues is different in the two trypsins, and the impact this might have on substrate affinity has been discussed. © 1994 Wiley-Liss, Inc.     

Localization of a serine proteinase inhibitor, B-43, in the bovine pancreas

 B-43, a serine proteinase inhibitor belonging to the ovalbumin branch of the serpin superfamily, was purified and cloned from bovine brain. Since [³⁵S]-labeled B-43 forms SDS-stable complexes with pancreatic serine proteinases, trypsin, α-chymotrypsin, and kallikrein, it has been suggested that B-43 is capable of inhibiting these serine proteinases and that B-43 may be present in the pancreas. In the present study, we investigated the localization of B-43 in the bovine pancreas immunohistochemically and examined the effect of B-43 on the amidolytic activities of pancreatic serine proteinases. Strong B-43-like immunoreactivity was localized in acinar cells, especially in the basal sides of the cells where the rough endoplasmic reticulum is located. The nuclei of the subpopulation of acinar cells were also immunoreactive for B-43. The recombinant glutathione S-transferase–B-43 fusion protein inhibited the amidolytic activity of trypsin and, to a lesser extent, α-chymotrypsin and kallikrein, but not elastase. These results suggest a role of B-43 in regulating serine proteinases both in the cytoplasm and the nucleus. Accepted: 13 January 1998     

Toxicity to cotton boll weevil Anthonomus grandis of a trypsin inhibitor from chickpea seeds

Cotton (Gossypium hirsutum L.) is an important agricultural commodity, which is attacked by several pests such as the cotton boll weevil Anthonomus grandis. Adult A. grandis feed on fruits and leaf petioles, reducing drastically the crop production. The predominance of boll weevil digestive serine proteinases has motivated inhibitor screenings in order to discover new ones with the capability to reduce the digestion process. The present study describes a novel proteinase inhibitor from chickpea seeds (Cicer arietinum L.) and its effects against A. grandis. This inhibitor, named CaTI, was purified by using affinity Red-Sepharose Cl-6B chromatography, followed by reversed-phase HPLC (Vydac C18-TP). SDS-PAGE and MALDI-TOF analyses, showed a unique monomeric protein with a mass of 12,877 Da. Purified CaTI showed significant inhibitory activity against larval cotton boll weevil serine proteinases (78%) and against bovine pancreatic trypsin (73%), when analyzed by fluorimetric assays. Although the molecular mass of CaTI corresponded to alpha-amylase/trypsin bifunctional inhibitors masses, no inhibitory activity against insect and mammalian alpha-amylases was observed. In order to observe CaTI in vivo effects, an inhibitor rich fraction was added to an artificial diet at different concentrations. At 1.5% (w/w), CaTI caused severe development delay, several deformities and a mortality rate of approximately 45%. These results suggested that CaTI could be useful in the production of transgenic cotton plants with enhanced resistance toward cotton boll weevil.     

Synthesis and characterization of a pancreatic trypsin inhibitor homologue and a model inhibitor.

The synthesis and characterization of protein proteinase inhibitor homologues with variations in the amino acid composition in the vicinity of the reactive site should aid the understanding of the mechanism by which inhibition of enzymatic activity occurs. A homologue inhibitor in which the reactive-site residue Ala-16 of basic pancreatic trypsin inhibitor (Kunitz) (BPTI) is replaced by Phe has been synthesized to study the effect of this replacement on the dissociation constants of the enzyme-inhibitor complexes. The replacement of Ala-16 by Phe causes a dramatic increase in the K1 value of the trypsin-BPTI complex while that of the chymotrypsin-BPTI complex remains essentially the same. This cannot be explained simply in terms of increased steric crowding. The Phe replacement probably causes a small change in the local conformation of the reactive site of the inhibitor which leads to a large decrease in the stability of the very tight trypsin-BPTI complex. This conformation change apparently can be tolerated in the less tightly bound chymotrypsin-BPTI complex. On the basis of the known structure of BPTI, a cyclic heptadecapeptide containing one disulfide bond was synthesized as a model inhibitor in order to determine if a smaller peptide can be designed to act as a highly efficient inhibitor for trypsin. This heptadecapeptide which contains all of the amino acid residues of BPTI taking part in the interaction of the proteinase inhibitor with trypsin binds 3 X 10(7) time more weakly to the enzyme than native BPTI does. It thus appears that even though only a small part of the inhibitor molecule enters directly into interaction with the enzyme, the remaining portions of the molecule which hold the structure of the inhibitor rigid are essential for the strong interaction.     

Computer aided prediction and evaluation of the tertiary structure for rat elastase II

Predictive methods have been extended to generate a proposed tertiary structure of rat elastase II on the basis of primary amino acid sequence and structural homologies within the family of mammalian serine proteinases. Force field refinement calculations were used to relax the structure. Structurally conserved molecules of solvation were introduced and the structure was again refined by means of force-field calculations. The resulting structure suggests probable substrate cleavage preferences. An independent statistical analysis of the crystallographically refined structures of serine proteinases (0.01-0.13 A, RMS) shows a close similarity to the final predicted model of rat pancreatic elastase II (0.03-0.14 A, RMS).     

Comparative structure analysis of proteinase inhibitors from the desert locust, Schistocerca gregaria.

The solution structure of three small serine proteinase inhibitors, two natural and one engineered protein, SGCI (Schistocerca gregaria chymotrypsin inhibitor), SGCI[L30R, K31M] and SGTI (Schistocerca gregaria trypsin inhibitor), were determined by homonuclear NMR-spectroscopy. The molecules exhibit different specificities towards target proteinases, where SGCI is a good chymotrypsin inhibitor, its mutant is a potent trypsin inhibitor, and SGTI inhibits both proteinases weakly. Interestingly, SGTI is a much better inhibitor of insect proteinases than of the mammalian ones used in common assays. All three molecules have a similar fold composed from three antiparallel beta-pleated sheets with three disulfide bridges. The proteinase binding loop has a somewhat distinct geometry in all three peptides. Moreover, the stabilization of the structure is different in SGCI and SGTI. Proton-deuterium exchange experiments are indicative of a highly rigid core in SGTI but not in SGCI. We suggest that the observed structural properties play a significant role in the specificity of these inhibitors.     

Phage display selection of P1 mutants of BPTI directed against five different serine proteinases

The P1 position of protein inhibitors and oligopeptide substrates determines, to a large extent, association energy with many serine proteinases. To test the agreement of phage display selection with the existing thermodynamic data, a small library of all 20 P1 mutants of basic pancreatic trypsin inhibitor (BPTI) was created, fused to protein III, and displayed on the surface of M13 phage. The wild type of displayed inhibitor monovalently and strongly inhibited trypsin with an association constant of Ka = 3 x 10(11) M(-1). The library was applied to select BPTI variants active against five serine proteinases of different specificity (bovine trypsin and chymotrypsin, human leukocyte and porcine pancreatic elastases, human azurocidin). The results of enrichment with four proteinases agreed well with the available thermodynamic data. In the case of azurocidin, the phage display selection allowed determination of the P1 specificity of this protein with the following frequencies for selected P1 variants: 43% Lys, 36% Leu, 7% Met, 7% Thr, 7% Gln.