Substrate Specificity of Human Carboxypeptidase A6

Carboxypeptidase A6 (CPA6) is an extracellular matrix-bound metallocarboxypeptidase (CP) that has been implicated in Duane syndrome, a neurodevelopmental disorder in which the lateral rectus extraocular muscle is not properly innervated. Consistent with a role in Duane syndrome, CPA6 is expressed in a number of chondrocytic and nervous tissues during embryogenesis. To better characterize the enzymatic function and specificity of CPA6 and to compare this with other CPs, CPA6 was expressed in HEK293 cells and purified. Kinetic parameters were determined using a panel of synthetic carboxypeptidase substrates, indicating a preference of CPA6 for large hydrophobic C-terminal amino acids and only very weak activity toward small amino acids and histidine. A quantitative peptidomics approach using a mixture of peptides representative of the neuropeptidome allowed the characterization of CPA6 preferences at the P1 substrate position and suggested that small and acidic P1 residues significantly inhibit CPA6 cleavage. Finally, a comparison of available kinetic data for CPA enzymes shows a gradient of specificity across the subfamily, from the very restricted specificity of CPA2 to the very broad activity of CPA4. Structural data and modeling for all CPA/B subfamily members suggests the structural basis for the unique specificities observed for each member of the CPA/B subfamily of metallocarboxypeptidases.     

Substrate requirements of human rhinovirus 3C protease for peptide cleavage in vitro

A series of synthetic peptides representing authentic proteolytic cleavage sites of human rhinovirus type 14 were assayed as substrates for purified 3C protease. Competition cleavage assays were employed to determine the relative specificity constants (Kcat/Km) for substrates with sequences related to the viral 2C-3A cleavage site. Variable length peptides representing the 2C-3A cleavage site were cleaved with comparable efficiency. These studies defined a minimum substrate of 6 amino acids (TLFQ/GP), although retention of the residue at position P5 (ETLFQ/GP) resulted in a better substrate by an order of magnitude. Amino acid substitutions at position P5, P4, P1', or P2' indicated that the identity of the residue at position P5 was not critical, whereas substitutions at position P4, P1' or P2' resulted in substrates with Kcat/Km values varying over 2 orders of magnitude. In contrast to the 2C-3A cleavage site, small peptide derivatives representative of the 3A-3B cleavage site were relatively poor substrates, which suggested that residues flanking the minimum core sequence may influence susceptibility to cleavage. The 3C protease of rhinovirus type 14 was also capable of cleaving peptides representing comparable cleavage sites predicted for coxsackie B virus and poliovirus.     

Specificity studies on retroviral proteinase from myeloblastosis-associated virus.

The specificity of the p15 proteinase of myeloblastosis-associated virus (MAV) was tested with nonviral high molecular weight substrates and with synthetic peptides. Peptides with sequences spanning known cleavage sites in viral polyproteins of Rous sarcoma virus (RSV) and avian leukemia viruses, as well as in BSA and HSA, were synthesized, and the rate of their cleavage by the MAV proteinase was compared. Synthetic peptides require for successful cleavage at least 4 residues at the N-terminal side and 3 residues at the C-terminal side. The proteinase shows a preference for hydrophobic residues with bulky side chains (Met, Tyr, Phe) in P3, although Arg and Gln can also be accepted. Small hydrophobic residues are required in P2 and P2', and large hydrophobic residues (Tyr, Met, Phe/p-nitro-Phe) are preferred in both P1 and P1'. The difference between the specificity of the p15 proteinase and that of the HIV-1 proteinase mostly pertains to position P2' of the substrate, where bulkier side chains are accepted by the HIV-1 proteinase (Richards et al., 1990). A good chromogenic substrate for the MAV and RSV proteinases was developed and used to further characterize the MAV proteinase activity with respect to ionic strength and pH. The activity of the proteinase is strongly dependent on ionic strength and pH. Both the kcat and Km values contribute to a higher cleavage efficiency at higher salt concentrations and show a bell-shaped pH dependence curve with a sharp maximum at pH 5.5 (kcat) and 6.5 (Km).     

Cleavage specificity of the subtilisin-like protease C1 from soybean

The cleavage specificity of protease C1, isolated from soybean (Glycine max (L.) Merrill) seedling cotyledons, was examined using oligopeptide substrates in an HPLC based assay. A series of peptides based on the sequence Ac-KVEKEESEEGE-NH2 was used, mimicking a natural cleavage site of protease C1 in the alpha subunit of the storage protein beta-conglycinin. A study of substrate peptides truncated from either the N- or C-terminus indicates that the minimal requirements for cleavage by protease C2 are three residues N-terminal to the cleaved bond, and two residues C-terminal (i.e. P3-P2'). The maximal rate of cleavage is reached with substrates containing four to five residues N-terminal to the cleaved bond and four residues C-terminal (i.e. P4 or P5 to P4'). The importance of Glu residues at the P1, P1', and P4 positions was examined using a series of substituted nonapeptides (P5-P4') with a base sequence of Ac-KVEKEESEE-NH2. At the P1 position, the relative ranking, based on kcat/Km, was E>Q>K>A>D>F>S. Substitutions at the P1' position yield the ranking E congruent withQ>A>S>D>K>F, while those at P4' had less effect on kcat/Km, yielding the ranking F congruent with S congruent with E congruent withD>K>A congruent withQ. These data show that protease C1 prefers to cleave at Glu-Glu and Glu-Gln bonds, and that the nature of the P4' position is less important. The fact that there is specificity in the cleavage of the oligopeptides suggests that the more limited specific cleavage of the alpha and alpha' subunits of beta-conglycinin by protease C1 is due to a combination of the sequence cleavage specificity of the protease and the accessibility of appropriate scissile peptide bonds on the surface of the substrate protein.     

Identification and characterization of three members of the human metallocarboxypeptidase gene family

Amino acid homology searches of the human genome revealed three members of the metallocarboxypeptidase (metallo-CP) family that had not been described in the literature in addition to the 14 known genes. One of these three, named CPA5, is present in a gene cluster with CPA1, CPA2, and CPA4 on chromosome 7. The cDNA encoding a mouse homolog of human CPA5 was isolated from a testis library and sequenced. The deduced amino acid sequence of human CPA5 has highest amino acid sequence identity (60%) to CPA1. Modeling analysis shows the overall structure to be very similar to that of other members of the A/B subfamily of metallocarboxypeptidases. The active site of CPA5 is predicted to cleave substrates with C-terminal hydrophobic residues, as do CPA1, -2, and -3. Using Northern blot analysis, CPA5 mRNA is detected in testis but not in kidney, liver, brain, or lung. In situ hybridization analysis shows that CPA5 is localized to testis germ cells. Mouse pro-CPA5 protein expressed in Sf9 cells using the baculovirus system was retained in the particulate fraction of the cells and was not secreted into the media. Pro-CPA5 was not enzymatically active toward standard CPA substrates, but after incubation with prohormone convertase 4 the resulting protein was able to cleave furylacryloyl-Gly-Leu, with 3-4-fold greater activity at pH 7.4 than at 5.6. Two additional members of the human CP gene family were also studied. Modeling analysis indicates that both contain the necessary amino acids required for enzymatic activity. The CP on chromosome 8 is predicted to have a CPA-like specificity for C-terminal hydrophobic residues and was named CPA6. The CP on chromosome 2 is predicted to cleave substrates with C-terminal acidic residues and was named CPO.     

Determination of the P1', P2' and P3' subsite-specificity of factor Xa

Factor Xa is a central protease in the coagulation cascade and the target for many anticoagulant compounds currently under development. The preferences of the enzyme for substrates incorporating residues N-terminal to the cleavage site (P1, P2, etc.) have been elucidated, but little is known of its preferences for residues C-terminal to the cleavage site (P1', P2', etc.). The preferences of bovine factor Xa for substrate residues in the P1', P2' and P3' positions were mapped using fluorescence-quenched substrates. Bovine factor Xa, often used as a model for factor Xa, was most selective for the P2' position, less selective at the P1' position and almost completely non-selective at the P3' position. It appears that while the prime side subsites of factor Xa impose some selectivity towards substrates, the influence of these sites on factor Xa cleavage specificity is relatively low in comparison to related enzymes such as thrombin.     

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.     

Specificity of the dynorphin-processing endoprotease: comparison with prohormone convertases

The cleavage specificity of a monobasic processing dynorphin converting endoprotease is examined with a series of quench fluorescent peptide substrates and compared with the cleavage specificity of prohormone convertases. A dynorphin B-29-derived peptide, Abz-Arg-Arg-Gln-Phe-Lys-Val-Val-Thr-Arg-Ser-Glneddnp (where Abz is o-aminobenzoyl and eddnp is ethylenediamine 2,4-dinitrophenyl), that contains both dibasic and monobasic cleavage sites is efficiently cleaved by the dynorphin converting enzyme and not cleaved by two propeptide processing enzymes, furin and prohormone convertase 1. A shorter prorenin-related peptide, Dnp-Arg-Met-Ala-Arg-Leu-Thr-Leu-eddnp, that contains a monobasic cleavage site is cleaved by the dynorphin converting enzyme and prohormone convertase 1 and not by furin. Substitution of the P1' position by Ala moderately affects cleavage by the dynorphin-processing enzyme and prohormone convertase 1. It is interesting that this substitution results in efficient cleavage by furin. The site of cleavage, as determined by matrix-assisted laser desorption/ionization time of flight mass spectrometry, is N-terminal to the Arg at the P1 position for the dynorphin converting enzyme and C-terminal to the Arg at the P1 position for furin and prohormone convertase 1. Peptides with additional basic residues at the P2 and at P4 positions also serve as substrates for the dynorphin converting enzyme. This enzyme cleaves shorter peptide substrates with significantly lower efficiency as compared with the longer peptide substrates, suggesting that the dynorphin converting enzyme prefers longer peptides that contain monobasic processing sites as substrates. Taken together, these results suggest that the cleavage specificity of the dynorphin converting enzyme is distinct but related to the cleavage specificity of the prohormone convertases and that multiple enzymes could be involved in the processing of peptide hormones and neuropeptides at monobasic and dibasic sites.     

Determination of the Substrate Specificity of Protein-tyrosine Phosphatase TULA-2 and Identification of Syk as a TULA-2 Substrate

TULA-1 (UBASH3A/STS-2) and TULA-2 (p70/STS-1) represent a novel class of protein-tyrosine phosphatases. Previous studies suggest that TULA-2 is sequence-selective toward phosphotyrosyl (Tyr(P)) peptides. In this work the substrate specificity of TULA-1 and -2 was systematically evaluated by screening a combinatorial Tyr(P) peptide library. Although TULA-1 showed no detectable activity toward any of the Tyr(P) peptides in the library, TULA-2 recognizes two distinct classes of Tyr(P) substrates. On the N-terminal side of Tyr(P), the class I substrates contain a proline at the Tyr(P)−1 position, a hydrophilic residue at the Tyr(P)−2 position, and aromatic hydrophobic residues at positions Tyr(P)−3 and beyond. The class II substrates typically contain two or more acidic residues, especially at Tyr(P)−1 to Tyr(P)−3 positions, and aromatic hydrophobic residues at other positions. At the C-terminal side of Tyr(P), TULA-2 generally prefers acidic and aromatic residues. The library screening results were confirmed by kinetic analysis of representative peptides selected from the library as well as Tyr(P) peptides derived from various Tyr(P) proteins. TULA-2 is highly active toward peptides corresponding to the Tyr(P)-323 and Tyr(P)-352 sites of Syk, and the Tyr(P)-397 site of focal adhesion kinase and has lower activity toward other Tyr(P) sites in these proteins. In glycoprotein VI-stimulated platelets, knock-out of the TULA-2 gene significantly increased the phosphorylation level of Syk at Tyr-323 and Tyr-352 sites and to a lesser degree at the Tyr-525/526 sites. These results suggest that Syk is a bona fide TULA-2 substrate in platelets.     

Role of P2 glycine in determining the specificity of antithrombin reaction with coagulation proteases

Structural data suggests that bulky hydrophobic residues at the S2-S4 sub-sites of factor Xa (fXa) restrict the preference of this pocket for small and non-polar residues like Gly at the P2 position of substrates and inhibitors. However, kinetic studies monitoring the cleavage specificity of 10-residue peptides by fXa have identified Phe as the most preferred P2 residue and Gln-Phe-Arg-Ser-Leu-Ser as the most preferred P3-P3′ residues for recognition by fXa. To determine whether this mechanism of specificity is also true for fXa reaction with antithrombin (AT), we prepared two AT mutants having either a Phe at the P2 or Gln-Phe-Arg-Ser-Leu-Ser at the P3-P3′ positions of the reactive center loop. Inhibition kinetic studies indicated that the reactivity of P2-Phe with fXa was significantly (∼5-fold) impaired, however, the P3-P3′ mutant exhibited 1.5-fold improved reactivity with the protease, suggesting cooperative effects between P3-P3′ residues influence the P2 specificity of AT. Substitution of Tyr-99 of fXa with a Gly dramatically impaired the reactivity of fXa with wild-type AT, but improved its reactivity with the serpin mutants in the absence, but not in the presence of pentasaccharide. AT with a P2-Phe inhibited thrombin with >150-fold impaired reactivity, however, the defect was restored by either pentasaccharide or by replacing Leu-99 of thrombin with a Gly. The P3-P3′ mutant rapidly inhibited factors VIIa and XIa independent of pentasaccharide. These results indicate that P2-Gly plays a key role in determining the S2 sub-site specificity and target protease selectivity of AT in circulation.     

Substrate specificity characterization of recombinant metallo oligo-peptidases thimet oligopeptidase and neurolysin

We report a systematic and detailed analysis of recombinant neurolysin (EC 3.4.24.16) specificity in parallel with thimet oligopeptidase (TOP, EC 3.4.24.15) using Bk sequence and its C- and N-terminal extensions as in human kininogen as motif for synthesis of internally quenched fluorescent substrates. The influence of the substrate size was investigated, and the longest peptide susceptible to TOP and neurolysin contains 17 amino acids. The specificities of both oligopeptidases to substrate sites P(4) to P(3)' were also characterized in great detail using seven series of peptides based on Abz-GFSPFRQ-EDDnp taken as reference substrate. Most of the peptides were hydrolyzed at the bond corresponding to P(4)-F(5) in the reference substrate and some of them were hydrolyzed at this bond or at F(2)-S(3) bond. No restricted specificity was found for P(1)' as found in thermolysin as well for P(1) substrate position, however the modifications at this position (P(1)) showed to have large influence on the catalytic constant and the best substrates for TOP contained at P(1), Phe, Ala, or Arg and for neurolysin Asn or Arg. Some amino acid residues have large influence on the K(m) constants independently of its position. On the basis of these results, we are hypothesizing that some amino acids of the substrates can bind to different sub-sites of the enzyme fitting P-F or F-S bond, which requires rapid interchange for the different forms of interaction and convenient conformations of the substrate in order to expose and fit the cleavage bonds in correct position for an efficient hydrolysis. Finally, this plasticity of interaction with the substrates can be an essential property for a class of cytosolic oligopeptidases that are candidates to participate in the selection of the peptides to be presented by the MHC class I.     

Cleavage of synthetic peptides by purified poliovirus 3C proteinase

Synthetic peptides, 14-16 residues in length, were used as substrates for purified recombinant poliovirus proteinase 3C. The sequences of the substrates correspond to the sequences of authentic cleavage sites in the poliovirus polyprotein, all of which contain Gln-Gly at the scissile bond. Specificity of cleavages was demonstrated by analysis of 3C digests of synthetic peptides. Relative rate constants for the cleavages were derived by competition experiments. The rate constants roughly correlated with the estimated half-life of the homologous precursor proteins detected in poliovirus-infected cells. The peptide most resistant to cleavage corresponded to the 3C/3D junction, a site known to be cleaved very slowly by 3C in vivo. Substitution of threonine for alanine in P4 position of this peptide, however, resulted in significant cleavage. This observation supports the hypothesis that the residue in P4 position, in addition to the Gln-Gly in P1 and P1', respectively, contributes to substrate recognition. Ac-Gln-Gly-NH2 was not a substrate for 3C.     

Substrate specificities of cathepsin A,L and A,S from pig kidney

The substrate specificities of two different molecular sizes of cathepsin A, A,L (large form) and A,S (small form), for synthetic substrates were examined kinetically. Both enzymes showed a similar broad substrate specificity against various acyl dipeptides, amino acid esters, and amino acid amides. Z-Phe-Ala and Ac-Phe-OEt were good substrates. Peptides containing hydrophobic amino acids were hydrolyzed rapidly. The presence of hydrophobic amino acid residues, not only at the C-terminal position but also at the second position and probably the third position from the C-terminal, resulted in an increase in the rate of hydrolysis. Peptides containing glycine and proline were hydrolyzed slowly. Inhibition studies with Z-D-Phe-D-Ala and Z-Phe suggested that the peptidase and esterase activities of the enzymes are both catalyzed by the same site of the enzyme molecule, but it remains to be elucidated whether or not the binding sites for peptides and esters are the same.     

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.     

Subsite preferences of pepstatin-insensitive carboxyl proteinases from prokaryotes: kumamolysin, a thermostable pepstatin-insensitive carboxyl proteinase

Kumamolysin, a carboxyl proteinase from Bacillus novosp. MN-32, is characterized by its thermostability and insensitivity to aspartic proteinase inhibitors such as pepstatin, diazoacetyl-DL-norleucine methylester, and 1,2-epoxy-3-(p-nitro-phenoxy)propane. Here, its substrate specificity was elucidated using two series of synthetic chromogenic substrates: P(5)-P(4)-P(3)-P(2)-Phe*Nph (p-nitrophenylalanine: *cleavage site)-P(2)'-P(3)', in which the amino acid residues at the P(5)-P(2), P(2)' and P(3)' positions were systematically substituted. Among 74 substrates, kumamolysin was shown to hydrolyze Lys-Pro-Ile-Pro-Phe-Nph-Arg-Leu most effectively. The kinetic parameters of this peptide were K(m) = 41+/-5 microM, k(cat) = 176+/- 10 s(-1), and k(cat)/K(m) = 4.3+/-0.6 mM(-1) x s(-1). These systematic analyses revealed the following features: (i) Kumamolysin had a unique preference for the P(2) position. Kumamolysin preferentially hydrolyzed peptides having an Ala or Pro residue at the P(2) position; this was also observed for the pepstatin-insensitive carboxyl proteinase from Bacillus coagulans J-4 [J-4; Shibata et al. (1998) J. Biochem. 124, 642-647]. Other carboxyl proteinases, including Pseudomonas sp. 101 pepstatin-insensitive carboxyl proteinase (PCP) and Xanthomonas sp. T-22 pepstatin-insensitive carboxyl proteinase (XCP), preferred peptides having hydrophobic and bulky amino acid residue such as Leu at the P(2) position. (ii) Kumamolysin preferred such charged amino acid residues as Glu or Arg at the P(2)' position, suggesting that the S(2)' subsite of kumamolysin is occupied by hydrophilic residues, similar to that of PCP, XCP, and J-4. In general, the S(2)' subsite of pepstatin-sensitive carboxyl proteinases (aspartic proteinases) is hydrophobic in nature. Thus, the hydrophilic nature of the S(2)' subsite was confirmed to be a distinguishing feature of pepstatin-insensitive carboxyl proteinases from prokaryotes.     

Investigating the substrate specificity and oligomerisation of the leader protease of foot and mouth disease virus using NMR

The leader protease (Lbpro) of foot-and-mouth disease virus frees itself during translation from the viral polyprotein by cleavage between its own C terminus and the N terminus of the subsequent protein, VP4. Lbpro also specifically cleaves the host proteins eukaryotic initiation factor (eIF) 4GI and 4GII, thus disabling host cell protein synthesis. We used NMR to study full-length Lbpro as well as a shortened species lacking six C-terminal amino acid residues (sLbpro) to examine the mechanism of self-processing, the quaternary structure and the substrate specificity. Both Lbpro forms have the same structure in solution as in the crystal. In the solution structure of sLbpro, the 12 residue C-terminal extension was flexible and disordered. In contrast, the 18 residue C-terminal extension of full-length Lbpro was bound by the substrate-binding site of a neighbouring molecule, resulting in the formation of a stable dimer in solution. The Lbpro dimer could not be dissociated by increasing the ionic strength or by dilution. Furthermore, titration with model peptides mimicking the substrates destabilised the dimer interface without dissociating the dimer. The peptides were, however, bound by sLbpro in the canonical substrate binding site. Peptide binding gave rise to chemical shifts of residues around the sLbpro substrate binding site. Shifts of Asn146 and Glu147 indicated that these residues might form the enzyme's S1' site and interact with the P1' arginine residue of the eIF4GI cleavage site. Furthermore, differences in substrate specificity between sLbpro and Lbpro observed with an in vitro translated protein indicate some involvement of the C terminus in substrate recognition.     

Substrate recognition of VAMP-2 by botulinum neurotoxin B and tetanus neurotoxin

Botulinum neurotoxin (BoNT; serotypes A-G) and tetanus neurotoxin elicit flaccid and spastic paralysis, respectively. These neurotoxins are zinc proteases that cleave SNARE proteins to inhibit synaptic vesicle fusion to the plasma membrane. Although BoNT/B and tetanus neurotoxin (TeNT) cleave VAMP-2 at the same scissile bond, their mechanism(s) of VAMP-2 recognition is not clear. Mapping experiments showed that residues 60-87 of VAMP-2 were sufficient for efficient cleavage by BoNT/B and that residues 40-87 of VAMP-2 were sufficient for efficient TeNT cleavage. Alanine-scanning mutagenesis and kinetic analysis identified three regions within VAMP-2 that were recognized by BoNT/B and TeNT: residues adjacent to the site of scissile bond cleavage (cleavage region) and residues located within N-terminal and C-terminal regions relative to the cleavage region. Analysis of residues within the cleavage region showed that mutations at the P7, P4, P2, and P1' residues of VAMP-2 had the greatest inhibition of LC/B cleavage (> or =32-fold), whereas mutations at P7, P4, P1', and P2' residues of VAMP-2 had the greatest inhibition of LC/TeNT cleavage (> or =64-fold). Residues within the cleavage region influenced catalysis, whereas residues N-terminal and C-terminal to the cleavage region influenced binding affinity. Thus, BoNT/B and TeNT possess similar organization but have unique residues to recognize and cleave VAMP-2. These studies provide new insights into how the clostridial neurotoxins recognize their substrates.     

Sequences that flank subdominant and cryptic epitopes influence the proteolytic generation of MHC class I-presented peptides

The proteasome has been shown to make the proper C-terminal cleavage for the generation of several immunodominant class I-presented peptides whereas aminopeptidases generate their proper N termini. In this study, we show that these two distinct proteolytic processes are also involved in generating a subdominant OVA peptide KVVRFDKL (K-L). Moreover, proteasome inhibitors did not enhance the presentation of any K-L construct, suggesting that destruction of this peptide by proteasomes, if any, does not limit its presentation. We have further examined in intact cells the influence of residues flanking this epitope on these proteolytic processes. When the N-terminal flanking residues of K-L are fused to an immunodominant OVA peptide SIINFEKL (S-L), the presentation of S-L is reduced as compared with a construct with its natural flanking sequence and was not inhibited (or enhanced) by proteasome inhibitors. Similarly, a reduction in presentation was observed when the C-terminal flanking residues of the subdominant epitope were attached to S-L. A detailed analysis revealed that the Pro at the P1' position of K-L was responsible for this reduction, and presentation of these C-terminally extended constructs was sensitive to proteasome inhibitor. The study suggests that both the N- and C-terminal flanks of the subdominant peptide are suboptimal for Ag presentation. Moreover, three of four C-terminal residues that flank other subdominant or cryptic epitopes in OVA reduced the presentation of S-L. Therefore, the residues that flank the C termini of several subdominant and cryptic epitopes are often suboptimal for cleavage and may contribute to the phenomenon of immunodominance.     

Characterization of carboxypeptidase A6, an extracellular matrix peptidase

Carboxypeptidase A6 (CPA6) is a member of the M14 metallocarboxypeptidase family that is highly expressed in the adult mouse olfactory bulb and broadly expressed in embryonic brain and other tissues. A disruption in the human CPA6 gene is linked to Duane syndrome, a defect in the abducens nerve/lateral rectus muscle connection. In this study the cellular distribution, processing, and substrate specificity of human CPA6 were investigated. The 50-kDa pro-CPA6 is routed through the constitutive secretory pathway, processed by furin or a furin-like enzyme into the 37-kDa active form, and secreted into the extracellular matrix. CPA6 cleaves the C-terminal residue from a range of substrates, including small synthetic substrates, larger peptides, and proteins. CPA6 has a preference for large hydrophobic C-terminal amino acids as well as histidine. Peptides with a penultimate glycine or proline are very poorly cleaved. Several neuropeptides were found to be processed by CPA6, including Met- and Leu-enkephalin, angiotensin I, and neurotensin. Whereas CPA6 converts enkephalin and neurotensin into forms known to be inactive toward their receptors, CPA6 converts inactive angiotensin I into the biologically active angiotensin II. Taken together, these data suggest a role for CPA6 in the regulation of neuropeptides in the extracellular environment within the olfactory bulb and other parts of the brain.     

Actin, troponin C, Alzheimer amyloid precursor protein and pro-interleukin 1 beta as substrates of the protease from human immunodeficiency virus

We show here for the first time that actin, troponin C, Alzheimer amyloid precursor protein (AAP), and pro-interleukin 1 beta (pro-IL-1 beta), are substrates of the protease encoded by the human immunodeficiency virus (HIV) type-1. As has been seen in other non-viral protein substrates of the HIV protease, the presence of Glu residues in the P2' position appears to play an important role in substrate recognition. Three of the four bonds cleaved in actin, two of the three in troponin C, and all of the bonds hydrolyzed in AAP and pro-IL-1 beta have a P2' Glu residue. In fact, Glu residues are accommodated in all positions from P4 to P4' surrounding the scissile bond in substrates of the HIV proteases, and as many as 4 adjacent Glu residues were seen in one of the bonds cleaved in AAP. This study of non-viral protein substrates has also revealed unexpected amino acids such as Gly, Arg, and Glu in the scissile bond itself rather than the more conventional hydrophobic amino acids. The HIV-2 protease hydrolyzed actin in a manner similar to that of the HIV-1 enzyme, but its cleavage of troponin C was distinct in that it split a bond adjacent to a triplet of Glu residues in P2, P3, and P4 that was refractory to the HIV-1 enzyme. Documentation of cleavage sites in the several important cellular proteins noted above has extended our understanding of the features in a substrate that are recognized by these multi sub-site proteases of retroviral maturation. Moreover, the present work adds to an accumulating body of evidence which demonstrates that these enzymes can damage crucial structural and regulatory cellular proteins if ever their activity is expressed outside the viral particle itself.