Cationic Inhibitors of Serine Proteinases from Buckwheat Seeds

Preparations of low molecular weight protein inhibitors of serine proteinases have been obtained from buckwheat (Fagopyrum esculentum) seeds by chromatography of seed extract on trypsin-Sepharose 4B, Mono-Q, and Mono-S ion exchangers (FPLC regime). Their molecular masses, determined by mass spectrometry, were 5203 (BWI-1c), 5347 (BWI-2c), 7760 (BWI-3c), and 6031 daltons (BWI-4c). All of the inhibitors possess high pH- and thermal stability in the pH range 2-12. In addition to trypsin, BWI-3c and BWI-4c inhibited chymotrypsin and subtilisin-like bacterial proteases. The N-terminal sequences of all of the inhibitors were determined: BWI-1c (23 residues), BWI-2c (33 residues), BWI-3c (18 residues), and BWI-4c (20 residues). In their physicochemical properties and N-terminal amino acid sequences, the buckwheat seed trypsin inhibitors BWI-3c and BWI-4c appear to belong to potato proteinase inhibitor I family.     

Cationic Inhibitors of Serine Proteinases from Buckwheat Seeds: Study of Their Interaction with Exogenous Proteinases

The inhibition of exogenous serine proteinases of different origin by cationic protease inhibitors BWI-1c, -2c, -3c, and -4c from buckwheat (Fagopyrum esculentum Moench) seeds has been studied. High efficiency of the inhibitors in binding bovine trypsin and chymotrypsin as well as their broad antiprotease effect, including inhibition of proteinases secreted by fungi and bacteria, has been demonstrated. According to the data obtained, it is proposed that cationic inhibitors from buckwheat seeds may participate in the defense of plants against fungal and bacterial infection.     

Buckwheat trypsin inhibitor with helical hairpin structure belongs to a new family of plant defence peptides

A new peptide trypsin inhibitor named BWI-2c was obtained from buckwheat (Fagopyrum esculentum) seeds by sequential affinity, ion exchange and reversed-phase chromatography. The peptide was sequenced and found to contain 41 amino acid residues, with four cysteine residues involved in two intramolecular disulfide bonds. Recombinant BWI-2c identical to the natural peptide was produced in Escherichia coli in a form of a cleavable fusion with thioredoxin. The 3D (three-dimensional) structure of the peptide in solution was determined by NMR spectroscopy, revealing two antiparallel α-helices stapled by disulfide bonds. Together with VhTI, a trypsin inhibitor from veronica (Veronica hederifolia), BWI-2c represents a new family of protease inhibitors with an unusual α-helical hairpin fold. The linker sequence between the helices represents the so-called trypsin inhibitory loop responsible for direct binding to the active site of the enzyme that cleaves BWI-2c at the functionally important residue Arg(19). The inhibition constant was determined for BWI-2c against trypsin (1.7×10(-1)0 M), and the peptide was tested on other enzymes, including those from various insect digestive systems, revealing high selectivity to trypsin-like proteases. Structural similarity shared by BWI-2c, VhTI and several other plant defence peptides leads to the acknowledgement of a new widespread family of plant peptides termed α-hairpinins.     

The anionic protease inhibitor BWI-1 from buckwheat seeds. Kinetic properties and possible biological role

Kinetic characteristics and effects on the growth of filamentous fungi of one of the main anionic protease inhibitors, BWI-1, isolated from buckwheat seeds, have been studied. The inhibition constants of bovine trypsin, chymotrypsin and cathepsin G from human granulocytes with BWI-1 were found to be 1.1, 67 and 200 n M , respectively. Analysis of the amino acid sequence of BWI-1 in the vicinity of the reactive site revealed its homology to the potato proteinase inhibitor I family. It is suggested that the inability of BWI-1 to bind elastase of human granulocytes is due to the basic nature of the amino acid residue (Arg) at the P_j position in its reactive site. It was demonstrated that BWI-1 was able to suppress the germination of the spores and the growth of the mycelium of two filamentous fungi.     

Purification and some properties of two proteinase inhibitors (DE-1 and DE-3) from Erythrina latissima (broad-leaved erythrina) seed

Two proteinase inhibitors, DE-1 and DE-3, were purified from Erythrina latissima seeds. Whereas DE-1 inhibits bovine chymotrypsin and not bovine trypsin, DE-3 inhibits trypsin but not chymotrypsin. The molecular weights and the amino acid compositions of the two inhibitors resemble the corresponding properties of the Kunitz-type proteinase inhibitors. The N-terminal primary structure of DE-3 showed homology with soybean trypsin inhibitor (Kunitz) and also with the proteinase inhibitors (A-II and B-II) from Albizzia julibrissin seed.     

Isolation of acid-resistant urinary trypsin inhibitors by high performance liquid chromatography and their characterization by N-terminal amino-acid sequence determination

Two crude fractions of acid-resistant trypsin inhibitors (apparent molecular masses 44 and 20 kDa, respectively) were prepared from human urine by gel permeation chromatography. From both preparations the pure inhibitors were isolated by high performance liquid chromatography (HPLC). Their N-terminal amino-acid sequences were determined and compared with those of HI-30 and HI-14 as isolated by reversible binding to either immobilized trypsin or immobilized chymotrypsin. The N-terminal amino-acid sequence of the high-molecular mass inhibitor UI-I isolated by HPLC was identical with those of HI-30 and UI-C-I isolated via immobilized trypsin or chymotrypsin, respectively. The low-molecular mass inhibitors UI-II and UI-C-II differ from HI-14 by the N-terminal extension Glu-Val-Thr-Lys-when obtained by HPLC or by the extension Thr-Lys-when obtained via immobilized chymotrypsin, respectively. The comparison of these N-termini with the amino-acid sequence of HI-30 (Ala1-...-Val16-Thr-Glu-Val-Thr-Lys-HI-14) defines the low molecular urinary trypsin inhibitors as proteolytic degradation products of the high-molecular urinary inhibitor. Proteolysis may occur at different bonds. The existing discrepancies in molecular architecture and in molecular masses of the urinary trypsin inhibitors are discussed.     

The primary structure of porcine pancreatic elastase: The N-terminus and disulphide bridges

1. The amino acid composition and N-terminal groups of purified elastase show that it is a single peptide chain of 234 residues. 2. The N-terminal sequence is Val-Val-Gly-Gly-Thr-Glu-. 3. The sequences around the four disulphide bridges were determined by using a ;diagonal' electrophoretic technique. 4. These four bridges are homologous with the four common to bovine trypsin and chymotrypsin. 5. Out of 83 residues of the elastase sequence so far determined, 43 are homologous with similar regions of trypsin and chymotrypsin. 6. The evolutionary ancestry of these enzymes is discussed.     

Pancreatic proteolytic enzymes of ostrich purified on immobilized protein inhibitors. Characterization of a new form of chymotrypsin (Chtr1)

Four forms of chymotrypsin (Chtr1, Chtr2, Chtr3, Chtr4), one form of trypsin and one form of elastase were purified from a slightly alkaline extract of ostrich (Struthio camelus) pancreas. The zymogens in the crude extract were activated with immobilized trypsin and then separated by affinity chromatography using immobilized inhibitors and ion exchange chromatography. One of the purified forms of chymotrypsin (Chtr1) exhibited an unusual interaction with the highly selective protein trypsin inhibitor from Cucurbita maxima (CMTI). Interactions with other protein trypsin inhibitors such as basic pancreatic trypsin inhibitor (BPTI), soybean trypsin inhibitor (STI), trypsin inhibitors from Cyclanthera pedata (CyPTI), Cucurbita pepo (CPTI), Cucurbita pepo var. giramontia (CPGTI) and Linum usitatissimum (LUTI) were also investigated. This study demonstrated the affinity of Chtr1 to inhibitors containing Arg at P1 position. Studies of substrate specificity of Chtr1 using oxidized B-chain of insulin revealed four susceptible bonds: Tyr15-Leu16, Phe24-Phe25, Phe25-Tyr26 and, surprisingly, Arg22-Gly23. The amino acid composition, as well as the first 13 residues of the N-terminal amino acid sequence, was determined. Studies of ostrich elastase showed that it can interact with immobilized CMTI in the presence of 5 M NaCl. This unusual characteristic is reported for the first time and suggests that elastase specificity depends on ionic strength. The kinetic constants K(M), k(cat) and k(cat)/K(M) for purified ostrich trypsin, chymotrypsin 4 and elastase were also determined.     

Azuki bean (Vigna angularis) protease inhibitors: isolation and amino acid sequences

Double-headed protease inhibitors I, IIa, and IIc (AB I, AB IIa, and AB IIc) have been purified from azuki beans "Takara" (Vigna angularis) by conventional chromatographic methods and their amino acid sequences have been determined. AB I, AB IIa, and AB IIc had molecular weights of 9,166, 8,661, and 8,756 daltons, consisting of 82, 78, 79 amino acid residues, respectively. The molecular weights of these inhibitors, determined by gel filtration at pH 8.0, were 18,000 for AB I and 17,000 for both AB IIa and AB IIc, indicating that the inhibitors are dimers. The inhibitors had isoelectric points of 4.7 (AB I), 6.8 (AB IIa), and 6.2 (AB IIc). AB I stoichiometrically inhibited both trypsin and chymotrypsin at a molar ratio of 1 : 1. On the other hand, AB IIa and AB IIc both inhibited trypsin at a molar ratio of about 1 : 2 and also inhibited chymotrypsin, though only weakly. Sequence comparison with other double-headed inhibitors indicated the reactive sites of AB IIa and AB IIc for trypsin to be Lys26-Ser27 and Arg53-Ser54, and those of AB I for trypsin and chymotrypsin to be Lys26-Ser27 and Tyr53-Ser54, respectively. The differences between AB IIa and AB IIc were that AB IIa lacked the C-terminal aspartic acid residue, and that Glu10 and Arg60 in AB IIa were replaced by Gln10 and His60 in AB IIc. A comparison between AB IIa and AB I revealed 25 variant amino acids among the 78 residues of AB IIa; further, Ab IIa lacked 4 amino acid residues in the C-terminal region of AB I.     

Selection of low-molecular-mass trypsin and chymotrypsin inhibitors based on the binding loop of CMTI-III using combinatorial chemistry methods

Using a combinatorial chemistry approach, a decapaptide library containing the N-terminal fragment of trypsin inhibitor CMTI-III was synthesized by the solid-phase method. The peptide library was screened for trypsin and chymotrypsin inhibitory activity applying the iterative method in solution. Two decapeptides were selected and resynthesized for each enzyme. The association equilibrium constants ((1.1+/-0.2)x10(8) and (7.3+/-1.6)x10(7)) determined for peptides with trypsin inhibitory activity indicate that they are 3-4-fold less active than the CMTI inhibitors. On the other hand, they are significantly more effective as compared with the starting sequence. Two peptides selected as chymotrypsin inhibitors displayed about 10 times higher activity (1.7+/-0.4)x10(7) and (1.1+/-0.2)x10(7), respectively) than those monosubstituted in position P(1) of the CMTI-III analogue. Considering low molecular weight of peptides selected and the lack of conformational constraints in their structures, the results are promising. They are good templates as starting sequences for further selection of small, peptidomimetic proteinase inhibitors.     

Amino acid sequence and disulfide bridges of affinity purified Kunitz-type chymotrypsin inhibitor from winged bean seed (Psophocarpus tetragonolobus (L.) DC)

The primary sequence of the affinity purified chymotrypsin inhibitor, WBCI, isolated from the albumin fraction of Psophocarpus tetragonolobus (L.) DC cv. UPS-122 seed was determined. The inhibitor consisted of a single polypeptide chain of 183 amino acids (Mr 20285) and the four half-cystine residues in the molecule formed two intramolecular disulfide bridges equivalent to those in other Kunitz-type seed inhibitors. The sequence of this chymotrypsin inhibitor was identical to that of chymotrypsin inhibitor-3 from cultivar UPS-31 and it showed about 50% sequence similarity to the winged bean acidic (WBTI-2, pI 5.1) and basic (WBTI-1, pI 8.9) trypsin inhibitors. Sequence similarities to other Kunitz-type seed inhibitors are discussed.     

Amino acid sequence of the protease inhibitor BWI-4a from buckwheat seeds

The complete amino acid sequence of protease inhibitor BWI-4a from buckwheat (Fagopyrum esculentum Moench) seeds, consisting of 67 amino acid residues with a single disulfide bond, has been established by Edman degradation in combination with matrix-assisted laser desorption ionization time-of-flight mass spectrometry. Its N terminus is blocked by a pyroglutamic acid residue. Mass spectrometric analysis revealed that inhibitor BWI-4a is present in buckwheat seeds in two isoforms with a single amino acid substitution of Ala40 for Gly40. The reactive site of the inhibitor contains an Arg43-Asp44 bond. Analysis of the amino acid sequence suggests that the buckwheat seed protease inhibitor is a member of the potato proteinase inhibitor I family.     

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.     

Primary structure of kunitz-type trypsin inhibitor-2a (pI 5.9) fromPsophocarpus tetragonolobus (L.) DC seed

The primary structure of acidic trypsin inhibitor-2a (WBTI-2a,pI 5.9) fromPsophocarpus tetragonolobus (L.) DC seed was determined. This inhibitor consists of a single polypeptide chain of 180 amino acids including four half-cystine residues and has an N-terminal residue of pyroglutamic acid. The sequence of WBTI-2a,pI 5.9, showed 84% identity to acidic trypsin inhibitor-2 (WBTI-2,pI 5.1) but only 57% identity to the basic trypsin inhibitor (WBTI-1,pI 8.9) and 50% identity to the chymotrypsin inhibitor of winged bean. The data indicate that winged bean seed contains a family of three Kunitz-type inhibitors which have about 50% identity.     

Amino acid sequence of the acidic Kunitz-type trypsin inhibitor from winged-bean seed [Psophocarpus tetragonolobus (L.) DC]

The primary sequence of trypsin inhibitor-2 (WBTI-2) fromPsophocarpus tetragonolobus (L.) DC seeds was determined. This inhibitor consists of a single polypeptide chain of 182 amino acids, including four half-cystine residues, and an N-terminal residue of pyroglutamic acid. The sequence of WBTI-2 showed 57% identity to the basic trypsin inhibitor (WBTI-3) and 50% identity to the chymotrypsin inhibitor (WBCI) of winged bean, and 54% identity to the trypsin inhibitor DE-3 fromErythrina latissima seed. The similarity to the soybean Kunitz trypsin inhibitor (40%) and the other Kunitz-type inhibitors fromAdenanthera pavonina (30%) and wheat (26%) was much lower. Sequence comparisons indicate that thePsophocarpus andErythrina inhibitors are more closely related to each other than to other members of the Kunitz inhibitor family.     

Primary structure of kunitz-type trypsin inhibitor-2a (pI 5.9) fromPsophocarpus tetragonolobus (L.) DC seed

The primary structure of acidic trypsin inhibitor-2a (WBTI-2a,pI 5.9) fromPsophocarpus tetragonolobus (L.) DC seed was determined. This inhibitor consists of a single polypeptide chain of 180 amino acids including four half-cystine residues and has an N-terminal residue of pyroglutamic acid. The sequence of WBTI-2a,pI 5.9, showed 84% identity to acidic trypsin inhibitor-2 (WBTI-2,pI 5.1) but only 57% identity to the basic trypsin inhibitor (WBTI-1,pI 8.9) and 50% identity to the chymotrypsin inhibitor of winged bean. The data indicate that winged bean seed contains a family of three Kunitz-type inhibitors which have about 50% identity.     

Kinetics of interaction of trypsin with an anionic inhibitor of trypsin BWI-1a from buckwheat seeds

The kinetics of binding of bovine trypsin to a proteinaceous inhibitor of trypsin from buckwheat seeds (BWI-1a) has been studied. The association rate constant (k(ass)) was 2.2 x 10(6) M-1 x sec-1 and the dissociation rate constant (k(off)) of the enzyme--inhibitor complex was 3.5 x 10(-3) sec-1; the inhibition constant Ki was 1.5 nM. The inhibitor BWI-1a is of the slow, tightly binding type. The mechanism of the inhibition of bovine trypsin by the trypsin inhibitor BWI-1a was studied. The mechanism of inhibition was found to involve two steps according to the kinetic data.     

The reactive sites of proteinase inhibitors from Erythrina seeds

Although the Kunitz-type proteinase inhibitors from the seeds of various Erythrina species have similar molecular weights (approximately 20,000), and share many other chemical characteristics, they could nevertheless be divided into three groups on the basis of their relative abilities to inhibit chymotrypsin, trypsin and tissue plasminogen activator. Group a inhibitors were relatively specific for chymotrypsin; they were poor inhibitors of trypsin and had no apparent effect upon tissue plasminogen activator. Group b proteins inhibited trypsin strongly and chymotrypsin slightly less effectively. They had no effect upon t-PA. Group c inhibitors inhibited trypsin, chymotrypsin and t-PA. Analysis of the amino acid composition of the three groups of inhibitors revealed major differences in alanine content. Minor differences in the content of most other amino acids were also noticed. Group b and group c inhibitors had, in most cases, the same reactive sites (Arg-Ser). The sequences neighbouring the reactive sites showed a significant degree of homology. Chemical modification of arginine in proteinase inhibitors from the seeds of E. latissima and soybeans using 1-2-cyclohexanedione confirmed the presence or absence of arginine in the reactive sites.     

Purification and Properties of the Trypsin Inhibitors from Buckwheat Seed

The trypsin inhibitors in buckwheat seeds were isolated by affinity chromatography on trypsin-Sepharose 4B, and the components were fractionated by chromatography on DEAE-Sepharose CL-6B. The major components, inhibitors I, II and III, were found to be homogeneous proteins with molecular weight of about 8,000. Trypsin inhibitory activity was more pronounced than the chymotrypsin inhibitory activity in all the inhibitor preparation obtained. The three major inhibitors had similar amino acid compositions and had no detectable amounts of tryptophan and carbohydrate. A high level of acidic and basic amino acid residues and a low level of methionine, tyrosine and phenylalanine residues characterized the inhibitors. Although the inhibitors I and II were particularly thermostable, inhibitor III, the most abundant component, was shown to be relatively heat-labile.     

Conformational changes of rBTI from buckwheat upon binding to trypsin: implications for the role of the P(8)' residue in the potato inhibitor I family

BWI-1 (buckwheat trypsin inhibitor), a member of the potato inhibitor I family, suppresses the growth of T-acute lymphoblastic leukemia cells and induces apoptosis in human solid tumor cell lines. Here, we report the crystal structure of rBTI (recombinant buckwheat trypsin inhibitor), a recombinant protein of BWI-1, at 1.84 ? resolution and the structure of rBTI in complex with bovine trypsin at 2.26 ? resolution. A conformational change of Trp53 at the P(8)' position in rBTI was observed upon its binding to trypsin, which is not seen in other members of the potato inhibitor I family reported previously. The role of the P(8)' residue in the potato inhibitor I family was examined by measuring the association and dissociation rates of four rBTI mutants with different substitutions at the P(2) and P(8)' positions when binding to trypsin. One of the mutants, P44T, was found to be a much stronger inhibitor than wild-type rBTI, with a picomolar (pM) dissociation constant. Our results could provide valuable insights for designing a new rBTI-based antitumor drug in the future.