Purification and characterization of two serine carboxypeptidases from Aspergillus niger and their use in C-terminal sequencing of proteins and peptide synthesis.

A procedure was developed to prepare in large amounts two carboxypeptidases, CPD-I and CPD-II, from Aspergillus niger. They were each shown to be serine proteases and single-chain monomers with molecular masses of ca. 81 kDa and containing 22% carbohydrates. Amino acid analysis, carbohydrate determination, and N-terminal sequencing (20 to 25 residues) were performed on each enzyme. CPD-I showed sequence homologies with malt carboxypeptidase II, while the N terminus of CPD-II was different from that of any known serine carboxypeptidase. Like carboxypeptidase Y from Saccharomyces cerevisiae and carboxypeptidase III from malt, CPD-II contained a free sulfhydryl group that could play a role in catalysis. Both A. niger enzymes had pH optima of about 4 and were unstable above pH 7. Their specificities for substrate positions P1 and P'1 were characterized by use of, as substrates, a series of N-blocked amino acid esters and dipeptides. Both enzymes were specific for Arg, Lys, and Phe in P1. CPD-I preferred hydrophobic residues in P'1, while CPD-II was highly specific for Arg and Lys in this position. Each displayed an original specificity when P1 and P'1 were considered together. The specificities were also studied by analyzing the time course of the release of amino acids from eight different peptides of various lengths. CPD-I and CPD-II appeared to be quite suitable for C-terminal sequence studies as well as for the synthesis of peptide bonds. The latter was studied with two peptide esters as aminolysis substrates and a series of amino acid amides as nucleophiles.(ABSTRACT TRUNCATED AT 250 WORDS)     

The specificity of carboxypeptidase Y may be altered by changing the hydrophobicity of the S'1 binding pocket.

The S'1 binding pocket of carboxypeptidase Y is hydrophobic, spacious, and open to solvent, and the enzyme exhibits a preference for hydrophobic P'1 amino acid residues. Leu272 and Ser297, situated at the rim of the pocket, and Leu267, slightly further away, have been substituted by site-directed mutagenesis. The mutant enzymes have been characterized kinetically with respect to their P'1 substrate preferences using the substrate series FA-Ala-Xaa-OH (Xaa = Leu, Glu, Lys, or Arg) and FA-Phe-Xaa-OH (Xaa = Ala, Val, or Leu). The results reveal that hydrophobic P'1 residues bind in the vicinity of residue 272 while positively charged P'1 residues interact with Ser297. Introduction of Asp or Glu at position 267 greatly reduced the activity toward hydrophobic P'1 residues (Leu) and increased the activity two- to three-fold for the hydrolysis of substrates with Lys or Arg in P'1. Negatively charged substituents at position 272 reduced the activity toward hydrophobic P'1 residues even more, but without increasing the activity toward positively charged P'1 residues. The mutant enzyme L267D + L272D was found to have a preference for substrates with C-terminal basic amino acid residues. The opposite situation, where the positively charged Lys or Arg were introduced at one of the positions 267, 272, or 297, did not increase the rather low activity toward substrates with Glu in the P'1 position but greatly reduced the activity toward substrates with C-terminal Lys or Arg due to electrostatic repulsion. The characterized mutant enzymes exhibit various specificities, which may be useful in C-terminal amino acid sequence determinations.     

Mapping of human plasma kallikrein active site by design of peptides based on modifications of a Kazal-type inhibitor reactive site

Human plasma kallikrein (huPK) is a proteinase that participates in several biological processes. Although various inhibitors control its activity, members of the Kazal family have not been identified as huPK inhibitors. In order to map the enzyme active site, we synthesized peptides based on the reactive site (PRILSPV) of a natural Kazal-type inhibitor found in Cayman plasma, which is not an huPK inhibitor. As expected, the leader peptide (Abz-SAPRILSPVQ-EDDnp) was not cleaved by huPK. Modifications to the leader peptide at P'1, P'3 and P'4 positions were made according to the sequence of a phage display-generated recombinant Kazal inhibitor (PYTLKWV) that presented huPK-binding ability. Novel peptides were identified as substrates for huPK and related enzymes. Both porcine pancreatic and human plasma kallikreins cleaved peptides at Arg or Lys bonds, whereas human pancreatic kallikrein cleaved bonds involving Arg or a pair of hydrophobic amino acid residues. Peptide hydrolysis by pancreatic kallikrein was not significantly altered by amino acid replacements. The peptide Abz-SAPRILSWVQ-EDDnp was the best substrate and a competitive inhibitor for huPK, indicating that Trp residue at the P'4 position is important for enzyme action.     

Thrombin Glu-39 restricts the P'3 specificity to nonacidic residues

Residue 39 of serine proteases neighbors positions P'2 to P'4 of the substrate. When Glu-39 of thrombin is replaced with Lys, the resultant enzyme (E39K) retains similar P1, P2, and P3 specificities but has altered P'3 and/or P'4 specificities. These conclusions are based on analysis of both p-nitroanilide and synthetic peptide hydrolysis. The activity of E39K is nearly normal toward 17 p-nitroanilide substrates. In peptide substrates, an acidic residue at either the P3 or P'3 position reduces the rate of cleavage by thrombin. A single substitution of Asp with Gly in either the P3 or P'3 position of a peptide corresponding to the P7-P'5 residues of protein C increases the rate of cleavage by thrombin 2-3-fold. Replacement of both Asp residues with Gly increases the rate of cleavage 30-fold. With E39K, the inhibitory effect of Asp in P3 remains unchanged, but Asp in the P'3 site is no longer inhibitory. Significant differences in the catalytic activity of E39K are also seen with respect to protein C activation. In the absence of thrombomodulin, E39K activates protein C 2.2 times faster than thrombin. In the presence of thrombomodulin, the rate of protein C activation is similar for E39K and thrombin. The second order rate constant of inhibition by antithrombin III, where P'4 is a Glu, is slightly increased (1.4-fold). The clotting activity is reduced 2.4-fold due to a lower rate of fibrinopeptides A and B release where P'3 is Arg. These data show that the P'3 position is a determinant of thrombin specificity and suggest that thrombomodulin may function in part by alleviating the inhibitory effects that may arise from the proximity of the Asp in P'3 of protein C with Glu-39 of thrombin.     

Substrate specificities of tissue kallikrein and T-kininogenase: their possible role in kininogen processing.

The present studies demonstrate the importance of subsite interactions in determining the cleavage specificities of kallikrein gene family proteinases. The effect of substrate amino acid residues in positions P3-P'3 on the catalytic efficiency of tissue kallikreins (rat, pig, and horse) and T-kininogenase was studied using peptidyl-pNA and intramolecularly quenched fluorogenic peptides as substrates. Kinetic analyses show the different effects of D-amino acid residues at P3, Pro at P'2, and Arg at either P'1 or P'3 on the hydrolysis of substrates by tissue kallikreins from rat and from horse or pig. T-Kininogenase was shown to differ from tissue kallikrein in its interactions at subsites S2, S'1, and S'2. As a result of these differences, Abz-FRSR-EDDnp with Arg at P'2 is a good substrate for tissue kallikreins from horse, pig, and rat but not for T-kininogenase. Abz-FRRP-EDDnp and Abz-FRAPR-EDDnp with Pro at P'2 (rat high molecular weight kininogen sequence) are susceptible to rat tissue kallikrein but not to tissue kallikreins from horse and pig. Arg at P'3 increased the susceptibility of the Arg-Ala bond to rat tissue kallikrein. These data explain the release of bradykinin by rat tissue kallikrein and of kallidin by tissue kallikreins from other animal species. Abz-FRLV-EDDnp and Abz-FRLVR-EDDnp (T-kininogen sequence) are good substrates for T-kininogenase but not for tissue kallikrein. Arg at the leaving group (at either P'1, P'2, or P'3) lowers the Km values of T-kininogenase while Val at P'2 increases its kcat values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate specificity of the Escherichia coli outer membrane protease OmpP

Escherichia coli OmpP is an F episome-encoded outer membrane protease that exhibits 71% amino acid sequence identity with OmpT. These two enzymes cleave substrate polypeptides primarily between pairs of basic amino acids. We found that, like OmpT, purified OmpP is active only in the presence of lipopolysaccharide. With optimal peptide substrates, OmpP exhibits high catalytic efficiency (k(cat)/K(m) = 3.0 x 10(6) M(-1)s(-1)). Analysis of the extended amino acid specificity of OmpP by substrate phage revealed that both Arg and Lys are strongly preferred at the P1 and P1' sites of the enzyme. In addition, Thr, Arg, or Ala is preferred at P2; Leu, Ala, or Glu is preferred at P4; and Arg is preferred at P3'. Notable differences in OmpP and OmpT specificities include the greater ability of OmpP to accept Lys at the P1 or P1', site as well as the prominence of Ser at P3 in OmpP substrates. Likewise, the OmpP P1 site could better accommodate Ser; as a result, OmpP was able to cleave a peptide substrate between Ser-Arg about 120 times more efficiently than was OmpT. Interestingly, OmpP and OmpT cleave peptides with three consecutive Arg residues at different sites, a difference in specificity that might be important in the inactivation of cationic antimicrobial peptides. Accordingly, we show that the presence of an F' episome results in increased resistance to the antimicrobial peptide protamine both in ompT mutants and in wild-type E. coli cells.     

Tetrapeptide substrates for the discrimination among kallikreins and other trypsin-like serine proteinases

The three tetrapeptides Ac-Phe-Arg-Arg-Val-NH2 (I), Ac-Phe-Arg-Arg-Pro-NH2 (II) and Ac-Phe-Lys-Arg-Val-NH2 (III) were shown to form a most convenient substrate system for the discrimination of the serine proteinases listed below. Tissue kallikreins (porcine pancreatic, horse and human urinary) have the unique feature of cleaving well the Arg-Arg bond in peptide I (P'2 = Val), hardly splitting it in peptide II (P'2 = Pro). The kcat/Km for the hydrolysis of peptide II by horse urinary kallikrein was 600-fold lower than that for peptide I. Trypsin, plasma kallikreins (human and rat), tonin and rat urinary kallikrein were distinguished from each other by the sequence of the N-terminal fragments formed in the hydrolysis of peptides I and/or II. Differences in the cleavage sites in these peptides are explained by differences in the specificities of the proteinase subsite S2 and/or in their preference for Arg or Lys residues. The three tetrapeptides were not substrates for plasmin.     

Determination of enzyme specificity in a complex mixture of peptide substrates by N-terminal sequence analysis.

A method has been developed to determine preferred residue substitutions in the P' position of peptide substrates for proteolytic enzymes. The method has been validated with four different enzymes; the angiotensin I-converting enzyme, atrial dipeptidyl carboxyhydrolase, bacterial dipeptidyl carboxyhydrolase, and meprin A. A mixture of N-acylated potential peptide-substrates for each of the enzymes was prepared in a single synthesis procedure on the same solid-phase synthesis resin. The peptides were identical in all residue positions except the P' position to be studied, into which numerous amino acid residues were incorporated on a theoretical equimolar basis. After cleavage and extraction of the peptides from the resin, no attempt was made to purify them individually; the exact concentration of each peptide in the mixture was determined by quantitative amino acid analysis. Incubation of an enzyme with its peptide-substrate mixture at [S] much less than Km yielded peptide hydrolytic products with newly exposed N-termini. The identity and amount of each hydrolysis product was determined by automated N-terminal sequence analysis. One cycle of sequencing revealed preferred amino acid substitutions in the P'1 position, two cycles the P'2 position, and so forth. Comparison of the rates of production of the various products indicates the preferred substitution in that particular P' position. New information on the substrate specificities of each of the enzymes tested was obtained and it is clear that this approach can be applied to any protease with a defined (or suspected) point of cleavage in a peptide substrate.     

Novel serine penicillocarboxypeptidase CPD-S3 from Penicillium janthinellum IBT 3991: Purification, characterization, and uses in peptide synthesis and modification

A novel carboxypeptidase (CPD-S3) from Penicillium janthinellum IBT 3991 has been isolated in a two-step purification procedure by cation exchange and affinity chromatography. The enzyme is a serine carboxypeptidase with a denatured molecular mass determined by SDS of 62 kDa of which 32% is carbohydrate. The isoelectric point is 5.1. CPD-S3 exhibits a high stability towards organic solvents and elevated temperatures. Besides the carboxypeptidase activity, CPD-S3 exhibits esterase, amidase, and carboxamidohydrolase activities. CPD-S3 favors substrates of -configuration with basic amino acid residues in either P₁ or P_1', and particularly dibasic substrates and medium-sized straight-chain alkyl esters for hydrolysis. In aminolysis of esters, amino acid amides and hydrazines coupled in good yield, but methyl esters poorly, and unlike other carboxypeptidases, free amino acids could not be coupled or transpeptidation effected to form amides. In ester semisynthesis, peptides with neutral, but not basic, residues in P₁ could be esterified. The scope of applicability for enzymatic peptide synthesis is limited.     

Sequence specificities of human fibroblast and neutrophil collagenases.

The sequence specificities of human fibroblast and neutrophil collagenases have been investigated by measuring the rate of hydrolysis of 60 synthetic oligopeptides covering the P4 through P'5 subsites of the substrate. The choice of peptides was patterned after both known cleavage sites in noncollagenous proteins and potential cleavage sites (those containing Gly-Ile-Ala, Gly-Leu-Ala, or Gly-Ile-Leu sequences) found in types I, II, III, and IV collagens. The initial rate of hydrolysis of the P1-P'1 bond of each peptide has been measured under first-order conditions ([SO] much less than KM), and kcat/KM values have been calculated from the initial rates. The amino acids in subsites P4 through P'4 all influence the hydrolysis rates for both collagenases. However, the effects of substitutions at each site are distinctive and are consistent with the view that human fibroblast and neutrophil collagenases are homologous but nonidentical enzymes. For peptides with unblocked NH2 and COOH termini, occupancy of subsites P3 through P'3 is necessary for rapid hydrolysis. Compared with the alpha 1(I) cleavage sequence, none of the substitutions investigated at subsites P3, P2, and P'4 produces markedly improved substrates. In contrast, many substitutions at subsites P1, P'1, and P'2 improve specificity. The preferences of both collagenases for alanine in subsite P1 and tryptophan or phenylalanine in subsite P'2, is noteworthy. Human neutrophil collagenase accommodates aromatic residues in subsite P'1 much better than human fibroblast collagenase. The subsite preferences observed for human fibroblast collagenase in these studies agree well with the residues found at cleavage sites in noncollagenous substrates. However, the sequence specificities of these collagenases cannot explain the failure of these enzymes to hydrolyze many potentially cleavable but apparently protected sites in intact collagens. This represents additional support for the notion that the local structure of collagen is important in determining the location of collagenase cleavage sites.     

New serine carboxypeptidase in mung bean seedling cotyledons

Two serine carboxypeptidases (EC 3.4.16.5) were purified from mung bean seedling cotyledons. Sequences of tryptic peptides derived from the 42.5 kD enzyme corresponded to the derived amino acid sequence of a sequenced cDNA (GenBank U49382 and U49741). This enzyme exhibited the substrate specificity pattern previously published for mung bean carboxypeptidase I. In comparison, the sequence and substrate specificity data obtained for the 43 kD enzyme were similar but not identical. Both enzymes showed preference for peptide substrates with a large hydrophobic residue at the C-terminus. With regard to the penultimate residue of peptide substrates, the mung bean carboxypeptidase I preferred small aliphatic amino acid residues, while the 43 kD enzyme preferred large hydrophobic ones.     

Mapping the active site of endothelin-converting enzyme-1 through subsite specificity and mutagenesis studies: a comparison with neprilysin

Endothelin-converting enzyme-1 (ECE-1) is a membrane-bound zinc metallopeptidase that is homologous to neprilysin in amino acid sequence. A major in vivo function of ECE-1 is the generation of endothelin-1, a potent vasoconstrictor, from big endothelin-1. ECE-1 is also potentially involved in the processing or degradation of other peptide hormones. In this study we have used substrates based on the sequence of the COOH-terminal half of big endothelin-1 to examine the subsite specificity of recombinant ECE-1. The big endothelin-1 [16-38] peptides were systematically varied at either position 21 (P(1)) or position 22 (P'(1)) and used in steady-state kinetic analyses of ECE-1. The results indicate that the S(1) pocket of ECE-1 is relatively nonselective, but that the S'(1) subsite of ECE-1 has a preference for large hydrophobic side chains. The peptidyl carboxydipeptidase activity of ECE-1 was also characterized, revealing that substrates with COOH-terminal carboxylates are highly preferred over the cognate amides and esters. A site-directed mutagenesis study was carried out to identify the active-site amino acid residues specifically involved in binding to the COOH-terminal carboxylate of substrates. The data indicate that Arg(133) of ECE-1, which corresponds to Arg(102) of neprilysin that has been identified as an active-site residue of neprilysin involved in binding to the free carboxylate of some substrate peptides, may not play the same role. However, the low activity observed for an ECE-1 Arg(726) mutant is consistent with a role for this arginine residue in the binding of substrates, a role which has been ascribed to arginine residues in both thermolysin (Arg(203)) and neprilysin (Arg(717)).     

Enzyme-substrate interactions in the hydrolysis of peptide substrates by thermitase, subtilisin BPN', and proteinase K

Peptide substrates of the general structure acetyl-Alan (n = 2-5), acetyl-Pro-Ala-Pro-Phe-Alan-NH2 (n = 0-3), and acetyl-Pro-Ala-Pro-Phe-AA-NH2 (AA = various amino acids) were synthesized and used to investigate the enzyme-substrate interactions of the microbial serine proteases thermitase, subtilisin BPN', and proteinase K on the C-terminal side of the scissile bond. The elongation of the substrate peptide chain up to the second amino acid on the C-terminal side (P'2) enhances the hydrolysis rate of thermitase and subtilisin BPN', whereas for proteinase K an additional interaction with the third amino acid (P'3) is possible. The enzyme subsite S'1 specificity of the proteases investigated is very similar. With respect to kcat/Km values small amino acid residues such as Ala and Gly are favored in this position. Bulky residues such as Phe and Leu were hydrolyzed to a lower extent. Proline in P'1 abolishes the hydrolysis of the substrates. Enzyme-substrate interactions on the C-terminal side of the scissile bond appear to affect kcat more than Km for all three enzymes.     

Degradation of a signal peptide by protease IV and oligopeptidase A.

The degradation of the prolipoprotein signal peptide in vitro by membranes, cytoplasmic fraction, and two purified major signal peptide peptidases from Escherichia coli was followed by reverse-phase liquid chromatography (RPLC). The cytoplasmic fraction hydrolyzed the signal peptide completely into amino acids. In contrast, many peptide fragments accumulated as final products during the cleavage by a membrane fraction. Most of the peptides were similar to the peptides formed during the cleavage of the signal peptide by the purified membrane-bound signal peptide peptidase, protease IV. Peptide fragments generated during the cleavage of the signal peptide by protease IV and a cytoplasmic enzyme, oligopeptidase A, were identified from their amino acid compositions, their retention times during RPLC, and knowledge of the amino acid sequence of the signal peptide. Both enzymes were endopeptidases, as neither dipeptides nor free amino acids were formed during the cleavage reactions. Protease IV cleaved the signal peptide predominantly in the hydrophobic segment (residues 7 to 14). Protease IV required substrates with hydrophobic amino acids at the primary and the adjacent substrate-binding sites, with a minimum of three amino acids on either side of the scissile bond. Oligopeptidase A cleaved peptides (minimally five residues) that had either alanine or glycine at the P'1 (primary binding site) or at the P1 (preceding P'1) site of the substrate. These results support the hypothesis that protease IV is the major signal peptide peptidase in membranes that initiates the degradation of the signal peptide by making endoproteolytic cuts; oligopeptidase A and other cytoplasmic enzymes further degrade the partially degraded portions of the signal peptide that may be diffused or transported back into the cytoplasm from the membranes.     

Isolation and molecular cloning of mast cell carboxypeptidase A. A novel member of the carboxypeptidase gene family

Mast cell carboxypeptidase A has been isolated from the secretory granules of mouse peritoneal connective tissue mast cells (CTMC) and from a mouse Kirsten sarcoma virus-immortalized mast cell line (KiSV-MC), and a cDNA that encodes this exopeptidase has been cloned from a KiSV-MC-derived cDNA library. KiSV-MC-derived mast cell carboxypeptidase A was purified with a potato-derived carboxypeptidase-inhibitor affinity column and was found by analytical sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be a Mr 36,000 protein. Secretory granule proteins from KiSV-MC and from mouse peritoneal CTMC were then resolved by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transblotted to polyvinylidine difluoride membranes. Identical aminoterminal amino acid sequences were obtained for the prominent Mr 36,000 protein present in the granules of both cell types. Based on the amino-terminal sequence, an oligonucleotide probe was synthesized and used to isolate a 1,470-base pair cDNA that encodes this mouse exopeptidase. The deduced amino acid sequence revealed that, after cleavage of a 15-amino acid hydrophobic signal peptide and a 94-amino acid activation peptide from a 417-amino acid preproenzyme, the mature mast cell carboxypeptidase A protein core has a predicted Mr of 35,780 and a high positive charge [Lys + Arg) - (Asp + Glu) = 17) at neutral pH. Although critical zinc-binding amino acids (His67, Glu70, His195), substrate-binding amino acids (Arg69, Asn142, Arg143, Tyr197, Asp255, Phe278), and cysteine residues that participate in intrachain disulfide bonds (Cys64-Cys77, Cys136-Cys159) of pancreatic carboxypeptidases were also present in mast cell carboxypeptidase A, the overall amino acid sequence identities for mouse mast cell carboxypeptidase A relative to rat pancreatic carboxypeptidases A1, A2, and B were only 43, 41, and 53%, respectively. RNA and DNA blot analyses revealed that mouse peritoneal CTMC, KiSV-MC, and bone marrow-derived mast cells all express a prominent 1.5-kilobase mast cell carboxypeptidase A mRNA which is transcribed from a single gene. We conclude that mouse mast cell carboxypeptidase A is a prominent secretory granule enzyme of mast cells of the CTMC subclass and represents a novel addition to the carboxypeptidase gene family.     

Role of S'1 loop residues in the substrate specificities of pepsin A and chymosin

Proteolytic specificities of human pepsin A and monkey chymosin were investigated with a variety of oligopeptides as substrates. Human pepsin A had a strict preference for hydrophobic/aromatic residues at P'1, while monkey chymosin showed a diversified preferences accommodating charged residues as well as hydrophobic/aromatic ones. A comparison of residues forming the S'1 subsite between mammalian pepsins A and chymosins demonstrated the presence of conservative residues including Tyr(189), Ile(213), and Ile(300) and group-specific residues in the 289-299 loop region near the C terminus. The group-specific residues consisted of hydrophobic residues in pepsin A (Met(289), Leu/Ile/Val(291), and Leu(298)) and charged or polar residues in chymosins (Asp/Glu(289) and Gln/His/Lys(298)). Because the residues in the loop appeared to be involved in the unique specificities of respective types of enzymes, site-directed mutagenesis was undertaken to replace pepsin-A-specific residues by chymosin-specific ones and vice versa. A yeast expression vector for glutathione-S-transferase fusion protein was newly developed for expression of mutant proteins. The specificities of pepsin-A mutants could be successfully altered to the chymosin-like preference and those of chymosin mutants, to pepsin-like specificities, confirming residues in the S'1 loop to be essential for unique proteolytic properties of the enzymes. An increase in preference for charged residues at P'1 in pepsin-A mutants might have been due to an increase in the hydrogen-bonding interactions. In chymosin mutants, the reverse is possible. The changes in the catalytic efficiency for peptides having charged residues at P'1 were dominated by k(cat) rather than K(m) values.     

Molecular analysis of dibasic endoproteolytic cleavage signals.

Biologically active peptide hormones are synthesized from larger precursor proteins by a variety of post-translational processing reactions. To characterize these processing reactions further we have expressed preprogastrin in two endocrine cell lines and examined the molecular determinants involved in endoproteolysis at dibasic cleavage sites. The Gly93-Arg94-Arg95 carboxyl-terminal processing site of progastrin must be processed sequentially by an endoprotease, a carboxypeptidase, and an amidating enzyme to produce bioactive gastrin. For these studies the dibasic Arg94-Arg95 residues that serve as signals for the initiation of this processing cascade were mutated to Lys94-Arg95, Arg94-Lys95, and Lys94-Lys95. In the GH3 cells the Lys94-Arg95 mutation slightly diminished synthesis of carboxyl-terminally amidated gastrin, whereas in the MTC 6-23 cells this mutation had no effect on amidated gastrin synthesis. In contrast, both Arg94-Lys95 and Lys94-Lys95 mutations resulted in significantly diminished production of amidated gastrin in both cell lines. A specific hierarchy of preferred cleavage signals at this progastrin processing site was demonstrated in both cell lines, indicating that cellular dibasic endoproteases have stringent substrate specificities. Progastrins with the Lys94-Arg95 mutation in GH3 cells also demonstrated diminished processing at the Lys74-Lys75 dibasic site, thus single amino acid changes at one processing site may alter cleavage at distant sites. These studies provide insight into the post-translational processing and biological activation of not only gastrin but other peptide hormones as well.     

Identification of the amino acid residues essential for proteolytic activity in an archaeal signal peptide peptidase

Signal peptide peptidases (SPPs) are enzymes involved in the initial degradation of signal peptides after they are released from the precursor proteins by signal peptidases. In contrast to the eukaryotic enzymes that are aspartate peptidases, the catalytic mechanisms of prokaryotic SPPs had not been known. In this study on the SPP from the hyperthermophilic archaeon Thermococcus kodakaraensis (SppA(Tk)), we have identified amino acid residues that are essential for the peptidase activity of the enzyme. DeltaN54SppA(Tk), a truncated protein without the N-terminal 54 residues and putative transmembrane domain, exhibits high peptidase activity, and was used as the wild-type protein. Sixteen residues, highly conserved among archaeal SPP homologue sequences, were selected and replaced by alanine residues. The mutations S162A and K214A were found to abolish peptidase activity of the protein, whereas all other mutant proteins displayed activity to various extents. The results indicated the function of Ser(162) as the nucleophilic serine and that of Lys(214) as the general base, comprising a Ser/Lys catalytic dyad in SppA(Tk). Kinetic analyses indicated that Ser(184), His(191) Lys(209), Asp(215), and Arg(221) supported peptidase activity. Intriguingly, a large number of mutations led to an increase in activity levels of the enzyme. In particular, mutations in Ser(128) and Tyr(165) not only increased activity levels but also broadened the substrate specificity of SppA(Tk), suggesting that these residues may be present to prevent the enzyme from cleaving unintended peptide/protein substrates in the cell. A detailed alignment of prokaryotic SPP sequences strongly suggested that the majority of archaeal enzymes, along with the bacterial enzyme from Bacillus subtilis, adopt the same catalytic mechanism for peptide hydrolysis.     

Substrate specificity at the P1' site of Escherichia coli OmpT under denaturing conditions

Though OmpT has been reported to mainly cleave the peptide bond between consecutive basic amino acids, we identified more precise substrate specificity by using a series of modified substrates, termed PRX fusion proteins, consisting of 184 residues. The cleavage site of the substrate PRR was Arg140-Arg141 and the modified substrates PRX substituted all 19 natural amino acids at the P1' site instead of Arg141. OmpT under denaturing conditions (in the presence of 4 M urea) cleaved not only between two consecutive basic amino acids but also at the carboxyl side of Arg140 except for the Arg140-Asp141, -Glu141, and -Pro141 pairs. In addition to Arg140 at the P1 site, similar results were obtained when Lys140 was substituted into the P1 site. In the absence of urea, an aspartic acid residue at the P1' site was unfavorable for OmpT cleavage of synthetic decapeptides, the enzyme showed a preference for a dibasic site.     

Barley serine proteinase inhibitor 2-derived cyclic peptides as potent and selective inhibitors of convertases PC1/3 and furin

Proprotein convertases (PCs) are serine proteases containing a subtilisin-like catalytic domain that are involved in the conversion of hormone precursors into their active form. This study aims at designing small cyclic peptides that would specifically inhibit two members of this family of enzymes, namely, the neuroendocrine PC1/3 and the ubiquitously expressed furin. We studied peptide sequences related to the 18-residue loop identified as the active site of the 83 amino acid barley serine protease inhibitor 2 (BSPI-2). Peptides incorporating mutations at various positions in the sequence were synthesized on solid phase and purified by HPLC. Cyclization was achieved by the introduction of a disulfide bridge between the two Cys residues located at both the N- and C-terminal extremities. Peptides VIIA and VIIB incorporating P4Arg, P2Lys, P1Arg, and P2'Lys were the most potent inhibitors with K(i) around 4 microM for furin and around 0.5 microM for PC1/3. Whereas peptide VIIB behaved as a competitive inhibitor of furin, peptide VIIA acted as a noncompetitive one. However, all peptides were eventually cleaved after variable incubation times by PC1/3 or furin. To avoid this problem, we incorporated at the identified cleavage site a nonscissile aminomethylene bond (psi[CH(2)-NH]). Those pseudopeptides, in particular peptide VIID, were shown not to be cleaved and to inhibit potently furin. Conversely, they were not able to inhibit PC1/3 at all. Those results show the validity of this approach in designing new effective PC inhibitors showing a certain level of discrimination between PC1/3 and furin.