Molecular dynamics as a tool to help design mutants

A 200 ps MD trajectory of wild type PCI and a 120 ps one for the Pro36Gly putative mutant are studied and compared with the structure of PCI in its complex with carboxypeptidase A (CPA). It is first established that the structures of PCI from X-ray and from MD simulation are essentially equal. Thereafter, data from the PCI-CPA and average MD structures together with available biochemical information are used to identify possible structural factors that may determine the inhibitory power of PCI. These structural determinants are used to analyze the mutant structure. The fold of the mutant protein shows a large degree of stability. The N-terminal tail in PCIm differs from the X-ray structure as it does in PCIw, while the mutant's C-terminal tail (which is the primary binding site with CPA) and residues 13–17 present deviations. Differences in fluctuation patterns exist between PCIm and PCIw in residues 2–4 (the N-terminal tail), 13–17, 22–23, 28–81 (the secondary contact site with CPA), and 37–38 (the C-terminal tail); the latter region is rigidified in PCIm. Results show that the MD method is able to sense long-range as well as local perturbative effects produced by amino-acid substitutions in flexible regions of this protein. The simulations suggest that the conformation of the C-terminal tail is less favorable for interaction with the target protein in the mutant than it is in the wild type protein. The Pro-36-Gly mutant is predicted to be a less potent inhibitor.Abbreviations CPA carboxypeptidase A - MD molecular dynamics - NIS non-inertial solvent - PCI potato carboxypeptidase A inhibitor - PCIm mutated inhibitor - PCIw wild inhibitor     

On the Entropic and Hydrophobic Properties Involved in the Inhibitory Mechanism of Carboxypeptidase A by its Natural Inhibitor from Potato

The inhibition of carboxypeptidase A (CPA) by its natural inhibitor from potato (PCI) has been widely analysed with theoretical and experimental methods. Several mutants of PCI have been obtained in order to study the physico-chemical properties related to the inhibition. Point mutations were performed in the C-tail of PCI given its fundamental role in the inhibition. The inhibition constant and the dissociation free energy of the complexes PCI-CPA was experimentally obtained for each mutant. The mutants were divided in two sets, those where the mutation was intrinsically affecting the conformation of the PCI C-tail, and those where the mutation affected the interaction between PCI and CPA. The crystallographic structure of PCI, as found in its complex with bovine carboxypeptidase A, was used to model the structure of these mutants. Two theoretical approaches were performed to explain both sets of experimental results: 1) study of the structural features of wt PCI and mutant forms by molecular dynamics (MD) simulation, and 2) modelling of the interaction of the C-tail of PCI with CPA. The first approach provides an explanation of the observed behaviour of the mutants of PCI, if the hypothesis is made of a direct relationship between the entropy of inhibition and the mobility of the C-tail of PCI. For the second set of mutants, the experimentally measured dissociation energies for the complexes PCI- CPA can be related to the theoretically estimated exposure to the solvent of the side chain of the mutated residue in the complex. In the case of the double mutation G35P+P36G, the importance of the main chain hydrogen bond between Gly 35 and Ala26, anchoring the C-tail to the core of PCI, as predicted by the MD simulations, was also supported by the experimental result. The agreement between the theoretical approaches and the experimental results shows the appropriateness of our hypotheses and also the relevance of such a combined effort of experimental and computational molecular biology in protein engineering.     

Structure of a novel leech carboxypeptidase inhibitor determined free in solution and in complex with human carboxypeptidase A2

Leech carboxypeptidase inhibitor (LCI) is a novel protein inhibitor present in the medicinal leech Hirudo medicinalis. The structures of LCI free and bound to carboxypeptidase A2 (CPA2)have been determined by NMR and X-ray crystallography, respectively. The LCI structure defines a new protein motif that comprises a five-stranded antiparallel beta-sheet and one short alpha-helix. This structure is preserved in the complex with human CPA2 in the X-ray structure, where the contact regions between the inhibitor and the protease are defined. The C-terminal tail of LCI becomes rigid upon binding the protease as shown in the NMR relaxation studies, and it interacts with the carboxypeptidase in a substrate-like manner. The homology between the C-terminal tails of LCI and the potato carboxypeptidase inhibitor represents a striking example of convergent evolution dictated by the target protease. These new structures are of biotechnological interest since they could elucidate the control mechanism of metallo-carboxypeptidases and could be used as lead compounds for the search of fibrinolytic drugs.     

Structure and atomic fluctuation patterns of potato carboxypeptidase a inhibitor protein

Molecular dynamics (MD) simulation methods were applied to the study of the structural and dynamic fluctuation properties of the potato carboxypeptidase A inhibitor protein (PCI) immersed in a bath of 1259 water molecules. A trajectory of 200 ps was generated at constant temperature and pressure. The crystallographic structure of PCI, as found in its complex with bovine carboxy-peptidase A (CPA), was used to seed the MD simulation. Analyses show that the structure of the PCI core is fairly rigid and stable in itself, and that little deformation is caused by the protein-protein interactions found in the PCI-CPA complex. The N-terminal tail fluctuates to approach the core structure and appears as a relatively disordered region. In contrast, the conformations of the C-terminal tail, which is involved in the inhibitory mechanism, fluctuates in the neighborhood of the X-ray structure in orientations which facilitate CPA binding. Comparison with the structural entries for PCI in water obtained from both 2D-NMR experiments and X-ray data shows that important features of the MD structural results fluctuates between the initial crystal values and those obtained from the NMR solution structure. This fluctuation is not uniform; minor regions move away from the X-ray conformation while they do not approach the NMR conformation. The results reported suggest that the trajectory is long enough to show a behavior that is consistent with the conformational space available to the protein in solution.Abbreviations CPA Carboxypeptidase - DG Distance Geometry - NMR Nuclear Magnetic Resonance - NIS Non Inertial Solvent - MD Molecular Dynamics - PBC Periodic Boundary Conditions - PCI Potato Carboxypeptidase Inhibitor - RMSD Root Mean Square Deviation - a.m.u. Atomic mass units Correspondence to: O. Tapia     

A molecular dynamics study of a model built Pro-36-Gly mutant derived from the potato carboxypeptidase A inhibitor protein

A 120ps molecular dynamics (MD) trajectory was calculated and analyzed for a putative Pro-36-Gly mutant of the potato carboxypeptidase A (CPA) protein inhibitor (PCIm). The mutant protein's fold shows a large degree of stability, judged from its low alpha-carbon r.m.s. deviation from the X-ray structure of the wild type PCI (PCIw). The N-terminal tail of PCIm differs slightly less from the X-ray structure than it does in PCIw, while the mutant's C-terminal tail (the primary contact site with CPA) and residues 13-17 present deviations as they approach each other. Differences in fluctuation pattern exist between PCIm and PCIw in residues 2-4 (the N-terminal tail), 13-17, 22-23, 28-31 (the secondary contact site with CPA) and 37-38 (the C-terminal tail); the latter region is rigidified in PCIm. Results show that the MD method is able to sense local perturbative effects produced by amino acid substitutions in flexible regions of protein molecules. The simulation suggests that the conformation of the C-terminal tail is less favorable for interaction with the target protein in the mutant than it is in the wild type protein. The Pro-36-Gly mutant is predicted to be a less potent inhibitor.     

Secondary binding site of the potato carboxypeptidase inhibitor. Contribution to its structure, folding, and biological properties

The contribution of each residue of the potato carboxypeptidase inhibitor (PCI) secondary binding site to the overall properties of this protein has been examined using alanine-scanning mutagenesis. Structural and enzymatic studies, performed on a series of PCI mutants, demonstrate that the proper positioning of the primary site for efficient binding and inhibition of carboxypeptidase A is significantly dependent on such a secondary contact region. The aromatic residues in this region play a key role in the stabilization of the PCI-enzyme complex, whereas polar residues contribute little to this task. A comparative study of the oxidative folding of these PCI mutants has been carried out using the disulfide quenching approach. The data, together with the structural characterization of some of these mutants, clearly indicate that noncovalent forces drive the refolding of this small disulfide-rich protein at the reshuffling stage, the rate-limiting step of the process. Moreover, it reveals that by introducing new noncovalent intramolecular contacts in PCI, we may create more stable variants, which also show improved folding efficiency. Taken together, the collected results clarify the folding determinants of the primary and secondary binding sites of PCI and their contribution to the inhibition of the carboxypeptidase, providing clues about PCI evolution and knowledge for its biotechnological redesign.     

Hybrid protease inhibitors for pest and pathogen control – a functional cost for the fusion partners?

Fusion proteins integrating dual pesticidal functions have been devised over the last 10 years to improve the effectiveness and potential durability of pest-resistant transgenic crops, but little attention has been paid to the impact of the fusion partners on the actual activity of the resulting hybrids. Here we assessed the ability of the rice cysteine protease inhibitor, oryzacystatin I (OCI), to retain its protease inhibitory potency when used as a template to devise hybrid inhibitors with dual activity against papain-like proteases and carboxypeptidase A (CPA). C-terminal variants of OCI were generated by fusing to its C-terminal end: (i) the primary inhibitory site of the small CPA inhibitor potato carboxypeptidase inhibitor (PCI, amino acids 35-39); or (ii) the complete sequence of PCI (a.a. 1-39). The hybrid inhibitors were expressed in E. coli and tested for their inhibitory activity against papain, CPA and digestive cysteine proteases of herbivorous and predatory arthropods. In contrast with the primary inhibitory site of PCI, the entire PCI attached to OCI was as active against CPA as free, purified PCI. The OCI-PCI hybrids also showed activity against papain, but the presence of extra amino acids at the C terminus of OCI negatively altered its inhibitory potency against cysteine proteases. This negative effect, although not preventing dual binding to papain and CPA, was correlated with an increased binding affinity for papain presumably due to non-specific interactions with the PCI domain. These results confirm the potential of OCI and PCI for the design of fusion inhibitors with dual protease inhibitory activity, but also point out the possible functional costs associated with protein domain grafting to recipient pesticidal proteins.     

Response of the digestive system of Helicoverpa zea to ingestion of potato carboxypeptidase inhibitor and characterization of an uninhibited carboxypeptidase B

Carboxypeptidase activity participates in the protein digestion process in the gut of lepidopteran insects, supplying free amino-acids to developing larvae. To study the role of different carboxypeptidases in lepidopteran protein digestion, the effect of potato carboxypeptidase inhibitor (PCI) on the digestive system of larvae of the pest insect Helicoverpa zea was investigated, and compared to that of Soybean Kunitz Trypsin Inhibitor. Analysis of carboxypeptidase activity in the guts showed that ingested PCI remained active in the gut, and completely inhibited the activity of carboxypeptidases A and O. Interestingly, carboxypeptidase B activity was not affected by PCI. All previously described enzymes from the same family, both from insect or mammalian origin, have been found to be very sensitive to PCI. Analysis of several lepidopteran species showed the presence of carboxypeptidase B activity resistant to PCI in most of them. The H. zea carboxypeptidase B enzyme (CPBHz) was purified from gut content by affinity chromatography. N-terminal sequence information was used to isolate its corresponding full-length cDNA, and recombinant expression of the zymogen of CPBHz in Pichia pastoris was achieved. The substrate specificity of recombinant CPBHz was tested using peptides. Unlike other CPB enzymes, the enzyme appeared to be highly selective for C-terminal lysine residues. Inhibition by PCI appeared to be pH-dependent.     

Sulfamide derivatives as transition state analogue inhibitors for carboxypeptidase A

3-Phenyl-2-sulfamoyloxypropionic acid (2), 2-benzyl-3-sulfamoylpropionic acid (3), and N-(N-hydroxysulfamoyl)phenylalanine (5) have been synthesized and evaluated as inhibitors for carboxypeptidase A (CPA) to find that they inhibit the enzyme competitively with the Ki values in the microM range, suggesting that their binding modes to CPA are analogous to each other, and resemble the binding mode of N-sulfamoylphenylalanine (1) that has been established by the X-ray crystallographic method to form a complex with CPA in a manner reminiscent of the binding of a transition state in the catalytic pathway. It was concluded thus that they are a new type of transition state analogue inhibitors for CPA. (R)-N-Hydroxy-N-sulfamoyl-beta-phenylalanine (8) was shown to be also a potent CPA inhibitor (Ki = 39 microM), the high potency of which may be ascribed to the involvement of the hydroxyl in the binding of CPA, most likely forming bidentate coordinative bonds to the zinc ion in CPA together with the sulfamoyl oxygen atom.     

Zinc-mediated thermal stabilization of carboxypeptidase A

In this study we investigated the contribution of Zn ions to the catalytic and structural thermostability of carboxypeptidase A (CPA). Structural studies on CPA molecule, performed in the presence of a number of ligands, demonstrated the multiple binding models around Zn ions which may affect the enzyme functions. Zinc was reported to bind at various sites in the CPA molecule at room temperature leading to inhibition of its enzymic activity. In this study we found that binding of Zn to CPA molecule followed by exposure to 50 degrees C did not inhibit the enzymic activity but activates and protects it against heat denaturation. The stabilization effect was found to be dependent on the increasing Zn/CPA ratios. The moderate changes of CPA activity as well as the UV and fluorescence spectra analyses indicate that the main function of the newly introduced zinc atoms is structural rather than catalytical.     

Enzyme immobilization via monoclonal antibodies I. Preparation of a highly active immobilized carboxypeptidase A

A novel method for the preparation of highly active immobilized enzymes is described. It is based on the binding of enzymes to suitable carriers via monoclonal antibodies, which bind to the enzyme with high affinity without affecting its catalytic activity. The applicability of the method forwarded has been illustrated by the preparation of two samples of highly active immobilized carboxypeptidase A (CPA) preparations as follows: A mouse monoclonal antibody (mAb 100)to CPA that binds to the enzyme with a high-affinity constant without affecting its catalytic activity was prepared, purified, and characterized. Covalent binding of this monoclonal antibody to Eupergit C (EC) or noncovalent binding to Sepharose-protein A (SPA)yielded the conjugated carriers EC-mAb and SPA.mAb, respectively, which reacted specifically with CPA to give the immobilized enzyme preparations EC-mAb.CPA and SPA.mAb.CPA displaying full catalytic activity and improved stability. At pH 7.5 and a temperature range of 4-37 degrees C an apparent binding constant of approximately 10(8)M(-1) characterizing the interaction of CPA with EC-mAb and SPA.mAb, was obtained. To compare the properties of EC-mAb.CPA and SPA.mAb.CPA with those of immobilized CPA preparations obtained by some representative techniques of covalent binding of the enzyme with a corresponding carrier, the following immobilized CPA preparations were obtained and their properties investigated: EC-CPA (I), a preparation obtained by direct binding of EC with CPA; EC-NH-GA-CPA (II), a derivative obtained by covalent binding of CPA to aminated EC via glutaraldehyde; EC-NH-Su-CPA (III), a CPA derivative obtained by binding the enzyme to aminated EC via a succinyl residue; and EC-HMD-GA-CPA (IV), obtained by binding the enzyme via glutaraldehyde to a hexamethylene diamine derivative of EC. Full enzymic activity for all of the bound enzyme, such as that recorded for the immobilized CPA preparations EC-mAb.CPA and SPA.mAb.CPA, was not detected in any of the insoluble covalently bound enzyme preparations.     

Analysis of the effect of potato carboxypeptidase inhibitor pro-sequence on the folding of the mature protein.

Protein folding can be modulated in vivo by many factors. While chaperones act as folding catalysts and show broad substrate specificity, some pro-peptides specifically facilitate the folding of the mature protein to which they are bound. Potato carboxypeptidase inhibitor (PCI), a 39-residue protein carboxypeptidase inhibitor, is synthesized in vivo as a precursor protein that includes a 27-residue N-terminal and a seven-residue C-terminal pro-regions. In this work the disulfide-coupled folding of mature PCI in vitro has been compared with that of the same protein extended with either the N-terminal pro-sequence (ProNtPCI) or both N- and C-terminal pro-sequences (ProPCI), and also with the N-terminal pro-sequence in trans (ProNt + PCI). No significant differences can be observed in the folding kinetics or efficiencies of all these molecules. In addition, in vivo folding studies in Escherichia coli have been performed using wild-type PCI and three PCI mutant forms with and without the N-terminal pro-sequence, the mutations had been previously reported to affect folding of the PCI mature form. The extent to which the 'native-like' form was secreted to the media by each construction was not affected by the presence of the N-terminal pro-sequence. These results indicate that PCI does not depend on the N-terminal pro-sequence for its folding in both, in vitro and in vivo in E. coli. However, structural analysis by spectroscopy, hydrogen exchange and limited proteolysis by mass spectrometry, indicate the capability of such N-terminal pro-sequence to fold within the precursor form.     

A potato carboxypeptidase inhibitor gene provides pathogen resistance in transgenic rice

A defensive role against insect attack has been traditionally attributed to plant protease inhibitors. Here, evidence is described of the potential of a plant protease inhibitor, the potato carboxypeptidase inhibitor (PCI), to provide resistance to fungal pathogens when expressed in rice as a heterologous protein. It is shown that rice plants constitutively expressing the pci gene exhibit resistance against the economically important pathogens Magnaporthe oryzae and Fusarium verticillioides . A M. oryzae carboxypeptidase was purified by affinity chromatography and further characterized by mass spectrometry. This fungal carboxypeptidase was found to be a novel carboxypeptidase B which was fully inhibited by PCI. Overall, the results indicate that PCI exerts its antifungal activity through the inhibition of this particular fungal carboxypeptidase B. Although pci confers protection against fungal pathogens in transgenic rice, a significant cost in insect resistance is observed. Thus, the weight gain of larvae of the specialist insect Chilo suppressalis (striped stem borer) and the polyphagous insect Spodoptera littoralis (Egyptian cotton worm) fed on pci rice is significantly larger than that of insects fed on wild-type plants. Homology-based modelling revealed structural similarities between the predicted structure of the M. oryzae carboxypeptidase B and the crystal structure of insect carboxypeptidases, indicating that PCI may function not only as an inhibitor of fungal carboxypeptidases, but also as an inhibitor of insect carboxypeptidases. The potential impact of the pci gene in terms of protection against fungal and insect diseases is discussed.     

Stability and fluctuations of the potato carboxypeptidase A protein inhibitor fold: a molecular dynamics study

A 120ps non-inertial solvent (NIS) molecular dynamics (MD) trajectory of the potato carboxypeptidase A protein inhibitor (PCI) was calculated and analyzed. It is shown that, in spite of a very low content of regular secondary structure, the PCI fold has a large degree of stability, judged from the fairly good agreement between the average MD and X-ray structures. The N-terminal and C-terminal regions behave differently, both in their isoatomic positional shifts with respect to the X-ray structure, and in atomic fluctuation pattern. Positional shifts up to 9A are detected in the exposed N-terminal region as it folds back on the inhibitor's core. This large deviation is most likely caused by the absence of the receptor protein or by the lack of supporting solvent molecules. In contrast, the C-terminal region, which is the primary contact site with the enzyme, has an average structure similar to the X-ray conformation; this feature is probably due to a hydrogen bond network to the central core of PCI. The C-terminal tail shows larger fluctuations than the core. The secondary contact site retains its structure in this simulation. The results evidence an intrinsically stable PCI fold which favors a spatially well defined, fairly flexible, structuration of the primary and secondary contact sites that optimizes PCI's interaction with its target enzyme.     

2-Benzyl-2-methylsuccinic acid as inhibitor for carboxypeptidase A. synthesis and evaluation.

Recently, Asante-Appiah et al. (Asante-Appiah, E.; Seetharaman, J.; Sicheri, F.; Yang, D. S.-C.; Chan, W. W.-C. Biochemistry 1997, 36, 8710 8715) reported that 2-ethyl-2-methylsuccinic acid is a highly potent inhibitor for carboxypeptidase A (CPA), a prototypic zinc protease. The X-ray crystal structure of the complex of the enzyme formed with 2-ethyl-2-methylsuccinic acid revealed that at the active site of CPA there is present a small cavity which accommodates the methyl group of the inhibitor. These investigators postulated that incorporation of a methyl group at the alpha-position to the carboxylate of existing inhibitors of CPA would improve the inhibitory potency. We have synthesized racemic and optically active 2-benzyl-2-methylsuccinic acids and evaluated their inhibitory activities for CPA to find the K(i) values to be 0.28, 0.15, and 17microM for racemic form, (R)-, and (S)-enantiomer, respectively. Contrary to the expectation, the effect on the binding affinity by the incorporation of the methyl group is minimal. The validity of the proposition that the small cavity may be utilized for the improvement of the inhibitory potency appears questionable.     

A novel rat carboxypeptidase, CPA2: characterization, molecular cloning, and evolutionary implications on substrate specificity in the carboxypeptidase gene family

A new member of the carboxypeptidase gene family, carboxypeptidase A2 (CPA2), has been identified from the predicted amino acid sequence of a rat pancreatic cDNA clone. In vivo recombination and in situ hybridization techniques employing the CPA2 cDNA resulted in the isolation of two genomic clones spanning the 25-kilobase pair rat CPA2 gene. Evolutionary trees built from the amino acid sequences of the known pancreatic carboxypeptidases show that CPA2 and carboxypeptidase A1 (CPA1) are the products of genes which duplicated before the mammalian radiation, and that bovine CPA is of the A1 type. The substrate specificities of CPA1 and CPA2 isolated from rat pancreas are similar to bovine CPA in that carboxyl-terminal amino acids with aromatic or branched aliphatic side chains are preferred. However, the substrate preference of rat CPA1 is skewed toward smaller amino acids, while that of rat CPA2 is skewed toward bulkier amino acids as compared to bovine CPA. The differences in the substrate specificities of these three carboxypeptidases are compatible with the nature of the amino acid replacements in their binding pockets for the carboxylterminal amino acid of the substrate.     

Comparison of the structures of three carboxypeptidase A-phosphonate complexes determined by X-ray crystallography

The structures of the complexes of carboxypeptidase A (CPA) with two tight-binding phosphonate inhibitors have been determined by X-ray crystallography. The inhibitors, Cbz-Phe-ValP-(O)-Phe[ZFVP(O)F] and Cbz-Ala-GlyP-(O)-Phe[ZAGP(O)F], bind noncovalently to CPA with dissociation constants (Ki's) of 11 fM and 710 pM, respectively. The CPA-ZFVP(O)F complex crystallizes in the space group P2(1)2(1)2(1) with unit cell parameters a = 65.3 A, b = 63.4 A, and c = 76.0 A, and the CPA-ZAGP(O)F complex crystallizes in the space group P2(1)2(1)2(1) with unit cell parameters a = 63.4 A, b = 65.9 A, and c = 74.4 A. Both structures were determined by molecular replacement to a resolution of 2.0 A. The final crystallographic residuals are 0.189 for the CPA-ZFVP(O)F complex and 0.191 for the CPA-ZAGP(O)F complex. The CPA-ZFVP(O)F complex exhibits the lowest Ki yet determined for an enzyme-inhibitor interaction. Comparison of the CPA-ZFVP(O)F structure with that of the CPA-ZAAP(O)F complex [Kim, H., & Lipscomb, W.N. (1990) Biochemistry 29, 5546-5555] indicates the likely important contributions of hydrophobic and weakly polar enzyme-inhibitor interactions to the exceptional stability of the CPA-ZFVP(O)F complex. Among these interactions is a network of four aromatic rings of CPA and ZFVP(O)F in a configuration that allows stabilizing aromatic-aromatic edge-to-face interactions from one ring to the next. A comparison of the structures of the CPA-ZFVP(O)F, CPA-ZAAP(O)F and CPA-ZAGP(O)F complexes shows that all three phosphonates assume a similar binding mode in the active-site binding groove of CPA. For ZAGP(O)F, the glycyl P1 residue does not lead to an anomalous or a partially disordered binding mode as seen in some previous complexes of CPA involving dipeptide analogue inhibitors with glycyl P1 residues. The additional enzyme-inhibitor interactions for these tripeptide phosphonates secure a binding mode in which a Pi portion of the inhibitor is clearly bound by the corresponding Si binding subsite. These three phosphonates have been implicated as transition-state analogues of the CPA-catalyzed reaction. The phosphinyl groups of these phosphonates coordinate to the active-site zinc in a manner that has been proposed as a characteristic feature of the general-base (Zn-hydroxyl or Zn-water) mechanism for the CPA-catalyzed reaction. Further mechanistic proposals are made for Arg-127, whose probable role in binding substrates is apparent in these CPA-phosphonate complexes.     

Interaction of carboxypeptidases A and B with nitrotyrosyl and aminotyrosyl derivatives of the carboxypeptidase inhibitor from potatoes

The single tyrosine residue of the carboxypeptidase inhibitor from potatoes, which is in contact with carboxypeptidase A in the enzyme-inhibitor complex as determined by X-ray diffraction. was converted to 3-nitrotyrosine by treatment with tetranitromethane in buffers containing 75% ethanol. The nitroinhibitor bound both bovine carboxypeptidase A and porcine carboxypeptidase B with apparent K_i values indistinguishable from those of the unmodified inhibitor. Spectral titration indicated that the nitrotyrosyl residue of the inhibitor ionized with pK_a of 7.25 either in the presence or absence of carboxypeptidase A; however, this pK_a was shifted to (ca 7.7 in the presence of carboxypeptidase B. Reduction of the 3-nitrotyrosine residue to 3-aminotyrosine slightly increased the strength of binding to both carboxypeptidases. These data suggest that the tyrosine residue of the inhibitor, is in a polar environment in the enzyme-inhibitor complex and that it is not involved in hydrogen bonding.     

Study by HPLC-MS of the interaction of platinum antitumor complexes with potato carboxypeptidase inhibitor (PCI)

The interaction of the well-known antitumor drug cisplatin cis-[PtCl(2)(NH(3))(2)] and the compound trans-[PtCl(2)NH(3)(4-hydroxymethylpyridine)] with the small protein potato carboxypeptidase inhibitor (PCI) and a PCI mutant in which glycine-39 was substituted by methionine has been followed by HPLC/mass spectrometry. Our results showed that both Pt drugs were able to bind PCI through Met-39 and histidines in mutated PCI, whereas only the trans complex interacted significantly with wild PCI. In the cytotoxic studies, the monofunctional adduct PCI-Met-cisplatin was neither more active nor more selective than cisplatin itself when tested against three tumor cell lines with different number of EGF receptors. Those results suggested that the poor activity of the adduct could be just due to the small fraction of cisplatin which was decoordinated from the adduct and able to penetrate the tumor cells, as well as to the changes in the structure of the platinum drug after the loss of NH(3) groups upon binding PCI-Met.     

Structural evolution of an enzyme specificity. The structure of rat carboxypeptidase A2 at 1.9-A resolution.

The structure of rat carboxypeptidase A2 (CPA2), which has a unique specificity for tryptophan-containing COOH-terminal peptides, has been determined in an unliganded state at 1.9-A resolution and refined to a crystallographic R-factor of 18.3%. Comparison of the structure of CPA2 with that of bovine carboxypeptidase A (referred to here as CPA1) reveals that the specificity of the former for larger amino acids probably arises from two amino acid replacements within the binding cavity (Thr268----Ala and Leu203----Met), coupled with differences in the positions of conserved residues in a surface loop on one face of the specificity pocket. The position of the reactive-site surface loop may be affected also by a disulfide bridge between Cys210 and Cys244. In this unliganded form of the enzyme, Tyr248 takes up a position interior to the specificity pocket and is distinct from that observed in bovine CPA1. The structural differences between CPA1 and CPA2 correlate strongly with crystallographically determined temperature factors and thus appear to be largest where the enzyme is flexible.