The potency and specificity of the interaction between the IA3 inhibitor and its target aspartic proteinase from Saccharomyces cerevisiae

The yeast IA3 polypeptide consists of only 68 residues, and the free inhibitor has little intrinsic secondary structure. IA3 showed subnanomolar potency toward its target, proteinase A from Saccharomyces cerevisiae, and did not inhibit any of a large number of aspartic proteinases with similar sequences/structures from a wide variety of other species. Systematic truncation and mutagenesis of the IA3 polypeptide revealed that the inhibitory activity is located in the N-terminal half of the sequence. Crystal structures of different forms of IA3 complexed with proteinase A showed that residues in the N-terminal half of the IA3 sequence became ordered and formed an almost perfect alpha-helix in the active site of the enzyme. This potent, specific interaction was directed primarily by hydrophobic interactions made by three key features in the inhibitory sequence. Whereas IA3 was cut as a substrate by the nontarget aspartic proteinases, it was not cleaved by proteinase A. The random coil IA3 polypeptide escapes cleavage by being stabilized in a helical conformation upon interaction with the active site of proteinase A. This results, paradoxically, in potent selective inhibition of the target enzyme.     

Key features determining the specificity of aspartic proteinase inhibition by the helix-forming IA3 polypeptide

The 68-residue IA(3) polypeptide from Saccharomyces cerevisiae is essentially unstructured. It inhibits its target aspartic proteinase through an unprecedented mechanism whereby residues 2-32 of the polypeptide adopt an amphipathic alpha-helical conformation upon contact with the active site of the enzyme. This potent inhibitor (K(i) < 0.1 nm) appears to be specific for a single target proteinase, saccharopepsin. Mutagenesis of IA(3) from S. cerevisiae and its ortholog from Saccharomyces castellii was coupled with quantitation of the interaction for each mutant polypeptide with saccharopepsin and closely related aspartic proteinases from Pichia pastoris and Aspergillus fumigatus. This identified the charged K18/D22 residues on the otherwise hydrophobic face of the amphipathic helix as key selectivity-determining residues within the inhibitor and implicated certain residues within saccharopepsin as being potentially crucial. Mutation of these amino acids established Ala-213 as the dominant specificity-governing feature in the proteinase. The side chain of Ala-213 in conjunction with valine 26 of the inhibitor marshals Tyr-189 of the enzyme precisely into a position in which its side-chain hydroxyl is interconnected via a series of water-mediated contacts to the key K18/D22 residues of the inhibitor. This extensive hydrogen bond network also connects K18/D22 directly to the catalytic Asp-32 and Tyr-75 residues of the enzyme, thus deadlocking the inhibitor in position. In most other aspartic proteinases, the amino acid at position 213 is a larger hydrophobic residue that prohibits this precise juxtaposition of residues and eliminates these enzymes as targets of IA(3). The exquisite specificity exhibited by this inhibitor in its interaction with its cognate folding partner proteinase can thus be readily explained.     

N-terminal extension of the yeast IA3 aspartic proteinase inhibitor relaxes the strict intrinsic selectivity

Yeast IA(3) aspartic proteinase inhibitor operates through an unprecedented mechanism and exhibits a remarkable specificity for one target enzyme, saccharopepsin. Even aspartic proteinases that are very closely similar to saccharopepsin (e.g. the vacuolar enzyme from Pichia pastoris) are not susceptible to significant inhibition. The Pichia proteinase was selected as the target for initial attempts to engineer IA(3) to re-design the specificity. The IA(3) polypeptides from Saccharomyces cerevisiae and Saccharomyces castellii differ considerably in sequence. Alterations made by deletion or exchange of the residues in the C-terminal segment of these polypeptides had only minor effects. By contrast, extension of each of these wild-type and chimaeric polypeptides at its N-terminus by an MK(H)(7)MQ sequence generated inhibitors that displayed subnanomolar potency towards the Pichia enzyme. This gain-in-function was completely reversed upon removal of the extension sequence by exopeptidase trimming. Capture of the potentially positively charged aromatic histidine residues of the extension by remote, negatively charged side-chains, which were identified in the Pichia enzyme by modelling, may increase the local IA(3) concentration and create an anchor that enables the N-terminal segment residues to be harboured in closer proximity to the enzyme active site, thus promoting their interaction. In saccharopepsin, some of the counterpart residues are different and, consistent with this, the N-terminal extension of each IA(3) polypeptide was without major effect on the potency of interaction with saccharopepsin. In this way, it is possible to convert IA(3) polypeptides that display little affinity for the Pichia enzyme into potent inhibitors of this proteinase and thus broaden the target selectivity of this remarkable small protein.     

IA3, an aspartic proteinase inhibitor from Saccharomyces cerevisiae, is intrinsically unstructured in solution

IA(3) is a highly specific and potent 68-amino acid endogenous inhibitor of yeast proteinase A (YprA), and X-ray crystallographic studies have shown that IA(3) binds to YprA as an alpha-helix [Li, M., Phylip, L. H., Lees, W. E., Winther, J. R., Dunn, B. M., Wlodawer, A., Kay, J., and Gustchina, A. (2000) Nat. Struct. Biol. 7, 113-117]. Surprisingly, only residues 2-32 of IA(3) are seen in the X-ray structure, and the remaining residues are believed to be disordered in the complex. We have used circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy to show that IA(3) is unstructured in the absence of YprA. Specifically, IA(3) produced a CD spectrum characteristic of an unstructured peptide, and the (15)N HSQC NMR spectra of IA(3) were characteristic of a polypeptide lacking intrinsic structure. We characterized the unstructured state of IA(3) by using singular-value decomposition (SVD) to analyze the CD data in the presence of TFE, by fully assigning the unbound IA(3) protein by NMR and comparing the chemical shifts to published random-coil values, and by measuring (1)H-(15)N heteronuclear NOEs, which are all consistent with an unfolded protein. The IA(3) samples used for NMR analyses were active and inhibited YprA with an inhibition constant (K(i)) of 1.7 nM, and the addition of YprA led to a large spectral transition in IA(3). Calorimetric (ITC) data also show that the overall enthalpy of the interaction between IA(3) and YprA is exothermic.     

3,4-dichloroisocoumarin-induced activation of the degradation of beta-casein by the bovine pituitary multicatalytic proteinase complex.

The breakdown of beta-casein (caseinolytic activity) by the bovine pituitary multicatalytic proteinase complex (MPC) is initiated by a fourth active site different from the previously described chymotrypsin-like activity (cleavage of Cbz-Gly-Gly-Leu-p-nitroanilide, where Cbz is benzyloxycarbonyl), trypsin-like activity (cleavage of Cbz-D-Ala-Leu-Arg-2-naphthylamide), and peptidylglutamyl peptide bond-hydrolyzing (PGP) activity (cleavage of Cbz-Leu-Leu-Glu-2-naphthylamide) (Yu, B., Pereira, M. E., and Wilk, S. (1991) J. Biol. Chem. 266, 17396-17400). 3,4-Dichloroisocoumarin, a serine proteinase inhibitor, stimulated the caseinolytic activity of bovine pituitary or lens MPC, 3-18-fold under conditions under which the other three catalytic activities were inactivated. Addition of hydroxylamine to the modified enzyme did not reverse the effects of the inhibitor. A form of the proteinase exhibiting only 2-4% of control chymotrypsin-like, trypsin-like, and PGP activities degraded beta-casein with no accumulation of intermediate peptides. 3,4-Dichloroisocoumarin, by reacting with the chymotrypsin-like, trypsin-like, and/or PGP-active sites, may promote a conformational change of MPC, rendering the caseinolytic active site accessible to the substrate. Once bound to the active site, beta-casein is rapidly degraded either by the caseinolytic component itself or by a cooperative interaction with catalytic centers that are not affected by the serine proteinase inhibitor. These results imply that the caseinolytic component does not belong to the class of serine proteinases. Other proteins tested were not degraded by the 3,4-dichloroisocoumarin-treated enzyme, suggesting that the conformation of beta-casein may be more adequate for degradation by the caseinolytic component.     

Adaptation of the behaviour of an aspartic proteinase inhibitor by relocation of a lysine residue by one helical turn

In addition to self-inhibition of aspartic proteinase zymogens by their intrinsic proparts, the activity of certain members of this enzyme family can be modulated through active-site occupation by extrinsic polypeptides such as the small IA3 protein from Saccharomyces cerevisiae. The unprecedented mechanism by which IA3 helicates to inhibit its sole target aspartic proteinase locates an i, i+4 pair of charged residues (Lys18+Asp22) on an otherwise-hydrophobic face of the amphipathic helix. The nature of these residues is not crucial for effective inhibition, but re-location of the lysine residue by one turn (+4 residues) in the helical IA3 positions its side chain in the mutant IA3-proteinase complex in an orientation essentially identical to that of the key lysine residue in zymogen proparts. The binding of the extrinsic mutant IA3 shows pH dependence reminiscent of that required for the release of intrinsic zymogen proparts so that activation can occur.     

Crystal and molecular structure of the serine proteinase inhibitor CI-2 from barley seeds

Chymotrypsin inhibitor 2 (CI-2), a serine proteinase inhibitor from barley seeds, has been crystallized and its three-dimensional structure determined at 2.0-A resolution by the molecular replacement method. The structure has been refined by restrained-parameter least-squares methods to a crystallographic R factor (= sigma parallel Fo magnitude of-Fo parallel/sigma magnitude of Fo) o of 0.198. CI-2 is a member of the potato inhibitor 1 family. It lacks the characteristic stabilizing disulfide bonds of most other members of serine proteinase inhibitor families. The body of CI-2 shows few conformational changes between the free inhibitor and the previously reported structure of CI-2 in complex with subtilisin Novo [McPhalen, C.A., Svendsen, I., Jonassen, I., & James, M.N.G. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 7242-7246]. However, the reactive site loop has some significant conformational differences between the free inhibitor and its complexed form. The residues in this segment of polypeptide exhibit relatively large thermal motion parameters and some disorder in the uncomplexed form of the inhibitor. The reactive site bond is between Met-59I and Glu-60I in the consecutive sequential numbering of CI-2 (Met-60-Glu-61 according to the alignment of Svendsen et al. [Svendsen, I., Hejgaard, J., & Chavan, J.K. (1984) Carlsberg Res. Commun. 49, 493-502]). The network of hydrogen bonds and electrostatic interactions stabilizing the conformation of the reactive site loop is much less extensive in the free than in the complexed inhibitor.     

Amino acid sequence of derivatives of newborn rat epidermal thiol proteinase inhibitor

Three different forms of thiol proteinase inhibitor (TPI) were isolated from newborn rat epidermis, in which two forms, TPI-1 and TPI-2, inhibited a proteinase activity, but another newly detected one (designated as TPI-3), showed no inhibitory effect. The complete amino acid sequence of TPI-2 and the sequence of the first seventeen residues from the NH2-terminus of TPI-3 were determined. The sequence shows that TPI-2 lacks in the first six (or four) residues from the NH2-terminus of intact inhibitor, TPI-1, whereas TPI-3 is devoid of its fifteen amino acid residues. These results indicate a high and specific susceptibility of TPI to proteolysis. Most significantly, the NH2-terminal region of TPI appears to be essential for inhibition of proteinase activity.     

The selectivity of action of the aspartic-proteinase inhibitor IA3 from yeast (Saccharomyces cerevisiae).

The ability of the aspartic-proteinase inhibitor IA3 from yeast (Saccharomyces cerevisiae) to affect the activities of a range of mammalian and microbial aspartic proteinases was examined. The inhibitor appeared to be completely selective in that only the aspartic proteinase A from yeast was inhibited to any significant extent. IA3 thus represents the first example of a totally specific, naturally occurring, aspartic-proteinase inhibitor.     

Molecular cloning and functional expression of cDNA encoding the cysteine proteinase inhibitor with three cystatin domains from sunflower seeds

Two cysteine proteinase inhibitors, cystatins Sca and Scb, were previously isolated from sunflower seeds [Kouzuma et al. J. Biochem. 119 (1996) 1106-1113]. A cDNA clone encoding a novel phytocystatin with three repetitive cystatin domains was isolated from a cDNA library of sunflower seeds using the Sca cDNA fragment as a hybridization probe. The cDNA insert comprises 1,093 bp and encodes 282 amino acid residues. The deduced amino acid sequences of the domains are highly similar to each other (66-81%), sharing 65-90% identical residues with Sca. The cDNA was expressed in Escherichia coli cells, and then the recombinant sunflower multicystatin (SMC) was purified and its inhibitory activity toward papain was examined. SMC exhibited strong inhibitory activity toward papain, with a stoichiometry of 1:3, indicating that each cystatin domain independently functions as a potent cysteine proteinase inhibitor. Proteolysis of SMC with Asn-specific proteinase suggested that post-translational processing by an Asn-specific proteinase may give rise to mature Sca-like phytocystatins.     

The refined 2.0 A X-ray crystal structure of the complex formed between bovine beta-trypsin and CMTI-I, a trypsin inhibitor from squash seeds (Cucurbita maxima). Topological similarity of the squash seed inhibitors with the carboxypeptidase A inhibitor from potatoes

The stoichiometric complex formed between bovine beta-trypsin and the Cucurbita maxima trypsin inhibitor I (CMTI-I) was crystallized and its X-ray crystal structure determined using Patterson search techniques. Its structure has been crystallographically refined to a final R value of 0.152 (6.0-2.0 A). CMTI-I is of ellipsoidal shape; it lacks helices or beta-sheets, but consists of turns and connecting short polypeptide stretches. The disulfide pairing is CYS-3I-20I, Cys-10I-22I and Cys-16I-28I. According to the polypeptide fold and disulfide connectivity its structure resembles that of the carboxypeptidase A inhibitor from potatoes. Thirteen of the 29 inhibitor residues are in direct contact with trypsin; most of them are in the primary binding segment Val-2I (P4)-Glu-9I (P4') which contains the reactive site bond Arg-5I-Ile-6I and is in a conformation observed also for other serine proteinase inhibitors.     

The proteinase yscA-inhibitor, IA3, gene. Studies of cytoplasmic proteinase inhibitor deficiency on yeast physiology

The gene of the proteinase yscA inhibitor IA3, PAI3, of the yeast Saccharomyces cerevisiae was isolated by oligonucleotide screening of a genomic DNA library and sequenced. The gene codes for a single protein of 68 amino acids. The structural PAI3 gene was deleted in vitro by oligonucleotide-site-directed mutagenesis. The mutated allele was introduced via homologous recombination into the genome of wild-type yeast and into the genome of a yeast mutant, which lacks the second cytoplasmic proteinase-inhibitor, IB2. The deficiency of either or of both inhibitors has no effect on the cell viability under various physiological conditions. The inhibitor mutants, however, show an increase in the general in vivo protein degradation rate. The IA3 mutant has a 2-3-fold increased protein degradation rate in the first 6 h after a shift from rich medium onto starvation-medium, whereas the IB2 mutant shows a constantly increased degradation rate of 20-50% under the same conditions. The inhibitor double null mutant has the same protein degradation rate as the IA3 null mutant. These results suggest an in vivo interaction between the vacuolor endopeptidases and their cytoplasmic inhibitors.     

Alkaline proteinase inhibitor of Pseudomonas aeruginosa: a mutational and molecular dynamics study of the role of N-terminal residues in the inhibition of Pseudomonas alkaline proteinase

Alkaline proteinase inhibitor of Pseudomonas aeruginosa is a 11.5-kDa, high affinity inhibitor of the serralysin class of zinc-dependent proteinases secreted by several Gram-negative bacteria. X-ray crystallography of the proteinase-inhibitor complex reveals that five N-terminal inhibitor residues occupy the extended substrate binding site of the enzyme and that the catalytic zinc is chelated by the alpha-amino and carbonyl groups of the N-terminal residue of the inhibitor. In this study, we assessed the effect of alteration of inhibitor residues 2-5 on its affinity for Pseudomonas alkaline proteinase (APR) as derived from the ratio of the dissociation and associate rate constants for formation of the enzyme-inhibitor complex. The largest effect was observed at position Ser-2, which occupies the S1' pocket of the enzyme and donates a hydrogen bond to the carboxyl group of the catalytic Glu-177 of the proteinase. Substitution of Asp, Arg, or Trp at this position increased the dissociation constant KD by 35-, 180-, and 13-fold, respectively. Mutation at positions 3-5 of the trunk also resulted in a reduction in enzyme-inhibitor affinity, with the exception of an I4W mutant, which exhibited a 3-fold increase in affinity. Molecular dynamics simulation of the complex formation between the catalytic domain of APR and the S2D mutant showed that the carboxyl of Asp-2 interacts with the catalytic zinc, thereby partially neutralizing the negative charge that otherwise would clash with the carboxyl group of Glu-177 of APR. Simulation of the interaction between the alkaline proteinase and the I4W mutant revealed a major shift in the loop comprised of residues 189-200 of the enzyme that allowed formation of a stacking interaction between the aromatic rings of Ile-4 of the inhibitor and Tyr-158 of the proteinase. This new interaction could account for the observed increase in enzyme-inhibitor affinity.     

Candida albicans produces a cystatin-type cysteine proteinase inhibitor.

A cysteine proteinase inhibitor was found in culture media of Candida albicans. Purification to homogeneity of the inhibitor was performed by carboxymethyl-papain-Sepharose affinity, DE-52 ion-exchange, and reverse-phase high performance liquid chromatographies. The purified inhibitor had an M(r) of 15 kDa and a pI of 4.9. It was more stable to heat and pH than most proteins. The N-terminal sequence of the first 30 residues demonstrated high similarity with that of human cystatin A. Thus, C. albicans cysteine proteinase inhibitor seems to belong to the cystatin superfamily. The inhibitor activity of the yeast cellular form was 4.0 times higher than that of the hyphal cellular form in 7-day culture media. It is suggested that the inhibitor has regulatory functions similar to those of its counterpart proteinases in the invasion of host cells.     

Cysteine proteinase activity in various developmental stages of Clonorchis sinensis: a comparative analysis

1. Cysteine proteinase activity in acidic extracts of various developmental stages of Clonorchis sinensis (metacercariae, 1-, 2-, and 3-month old worms) was examined. All the activities were maximum at acidic pH and showed inhibitor susceptibilities similar to the vertebrate cysteine proteinases. 2. Specific activity of cysteine proteinase(s) was highest in metacercariae with either CBZ-phe-arg-AFC or Azocoll as the substrate. The immature and mature worms had similar (but less than metacercariae) levels of activity. 3. A soluble cysteine proteinase with a native molecular weight of approximately 20,000 +/- 1414 was partially purified from 1-, 2-, and 3-month worms. The molecular weight of similar activity in metacercariae was approximately 32,000. 4. Results suggest developmental regulation of cysteine proteinase activity in the life cycle of C. sinensis.     

alpha2-Macroglobulin from hemolymph of the freshwater crayfish Astacus astacus.

1. A high mol. wt proteinase inhibitor has been purified from the haemolymph of the freshwater crayfish Astacus astacus. 2. The protein is a disulphide-bonded dimer (Mr 390,000) of two identical polypeptide chains (Mr 185,000). 3. The inhibitor displays a broad specificity and protects trypsin from inhibition by soybean trypsin inhibitor and thus is similar to vertebrate alpha 2-macroglobulin. 4. The alpha 2-macroglobulin-like inhibitor from Astacus interacts with bovine trypsin in an equimolar stoichiometry thereby decreasing tryptic hydrolysis of N-benzoyl-L-arginine-ethylester to 50% residual activity. In contrast, the activity of Astacus protease, a digestive zinc proteinase from crayfish toward succinyl-alanyl-alanyl-alanyl-4-nitroanilide is inhibited almost completely. 5. Sensitivity of the inhibitor to methylamine and autolytic cleavage suggests the presence of an internal thioester bond. 6. The N-terminal amino acid sequence of Astacus alpha 2-macroglobulin is strongly related to the alpha 2-macroglobulins from Pacifastacus leniusculus (91% identity) and from the lobster Homarus americanus (72% identity). In contrast, only 25% of the residues are identical with the alpha 2-macroglobulin from the horseshoe crab Limulus polyphemus. There is also a faint similarity to human complement protein C3 and human alpha 2-macroglobulin.     

Subtilisin Protein Inhibitor from Potato Tubers

A protein with molecular weight of 21 kD denoted as PKSI has been isolated from potato tubers (Solanum tuberosum L., cv. Istrinskii). The isolation procedure includes precipitation with (NH4)2SO4, gel chromatography on Sephadex G-75, and ion-exchange chromatography on CM-Sepharose CL-6B. The protein effectively inhibits the activity of subtilisin Carlsberg (Ki = 1.67 +/- 0.2 nM) by stoichiometric complexing with the enzyme at the molar ratio of 1 : 1. The inhibitor has no effect on trypsin, chymotrypsin, and the cysteine proteinase papain. The N-terminal sequence of the protein consists of 19 amino acid residues and is highly homologous to sequences of the known inhibitors from group C of the subfamily of potato Kunitz-type proteinase inhibitors (PKPIs-C). By cloning PCR products from the genomic DNA of potato, a gene denoted as PKPI-C2 was isolated and sequenced. The N-terminal sequence (residues from 15 to 33) of the protein encoded by the PKPI-C2 gene is identical to the N-terminal sequence (residues from 1 to 19) of the isolated protein PKSI. Thus, the inhibitor PKSI is very likely encoded by this gene.     

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.     

Biosynthesis, purification, and substrate specificity of severe acute respiratory syndrome coronavirus 3C-like proteinase

The 3C-like proteinase of severe acute respiratory syndrome (SARS) coronavirus has been proposed to be a key target for structural-based drug design against SARS. In order to understand the active form and the substrate specificity of the enzyme, we have cloned, expressed, and purified SARS 3C-like proteinase. Analytic gel filtration shows a mixture of monomer and dimer at a protein concentration of 4 mg/ml and mostly monomer at 0.2 mg/ml, which correspond to the concentration used in the enzyme assays. The linear decrease of the enzymatic-specific activity with the decrease of enzyme concentration revealed that only the dimeric form is active and the dimeric interface could be targeted for structural-based drug design against SARS 3C-like proteinase. By using a high pressure liquid chromatography assay, SARS 3C-like proteinase was shown to cut the 11 peptides covering all of the 11 cleavage sites on the viral polyprotein with different efficiency. The two peptides corresponding to the two self-cleavage sites are the two with highest cleavage efficiency, whereas peptides with non-canonical residues at P2 or P1' positions react slower. The P2 position of the substrates seems to favor large hydrophobic residues. Secondary structure studies for the peptide substrates revealed that substrates with more beta-sheetlike structure tend to react fast. This study provides a basic understanding of the enzyme catalysis and a full substrate specificity spectrum for SARS 3C-like proteinase, which are helpful for structural-based inhibitor design against SARS and other coronavirus.