Kinetic peculiarities of human tissue kallikrein: 1--substrate activation in the catalyzed hydrolysis of H-D-valyl-L-leucyl-L-arginine 4-nitroanilide and H-D-valyl-L-leucyl-L-lysine 4-nitroanilide; 2--substrate inhibition in the catalyzed hydrolysis of N alpha-p-tosyl-L-arginine methyl ester

Hydrolysis of D-valyl-L-leucyl-L-lysine 4-nitroanilide (1), D-valyl-L-leucyl-L-arginine 4-nitroanilide (2), and N alpha-p-tosyl-L-arginine methyl ester (3) by human tissue kallikrein was studied throughout a wide range of substrate concentrations. At low substrate concentrations, the hydrolysis followed Michaelis-Menten kinetics but, at higher substrate concentrations, a deviation from Michaelis-Menten behavior was observed. With the nitroanilides, a significant increase in hydrolysis rates was observed, while with the ester, a significant decrease in hydrolysis rates was observed. The results for substrates (1) and (3) can be accounted for by a model based on the hypothesis that a second substrate molecule binds to the ES complex to produce a more active or an inactive SES complex. The deviation observed for substrate (2) can be explained as a bimolecular reaction between the enzyme-substrate complex and a free substrate molecule.     

Substrate specificities of growth factor associated kallikreins of the mouse submandibular gland

The kinetic constants for the hydrolysis of a series of tripeptide p-nitroanilide substrates by mouse epidermal growth factor binding protein (EGF-BP), the gamma-subunit of mouse nerve growth factor (gamma-NGF), bovine pancreatic trypsin (BPT), and porcine pancreatic kallikrein (PPK) have been evaluated. These substrates correspond to the carboxyl-terminal three amino acids of the mature forms of epidermal growth factor (EGF) and beta-nerve growth factor (beta-NGF), as well as various substitutions in the penultimate and antepenultimate positions, and, as such, represent potential recognition sites for precursor processing. The mouse kallikreins (EGF-BP and gamma-NGF) preferentially hydrolyze the substrates with the sequences of their specifically associated growth factors; however, the constants derived from these reactions do not account for the association constants observed with the mature growth factors, and additional significant binding interactions between EGF-BP and EGF and between gamma-NGF and beta-NGF are predicted to exist outside of the catalytic binding site, i.e., the P3 to P1 positions. A comparison of the kinetic constants of BPT, PPK, and the mouse kallikreins indicates that EGF-BP and gamma-NGF display a hybrid catalytic character. A favorable substrate P1 arginine guanidinium group interaction exists for the mouse kallikreins, similar to that of BPT, but a preference for a hydrophobic side chain in the substrate P2 position makes the mouse kallikreins, especially EGF-BP, more closely resemble PPK than BPT. These findings have significant implications with regard to molecular modeling of the mouse kallikreins.     

Horse urinary kallikrein, I. Complete purification and characterization

The isolation procedure for horse urinary kallikrein was considerably improved by the introduction of two new purification steps: a) removal of mucoproteins and concentration of the urine by ultrafiltration and b) affinity chromatography on benzamidine-Sepharose conjugate. The homogeneity of the enzyme preparations, regarding their protein moiety, was demonstrated by: 1) a single symmetric peak on DEAE-Sephadex chromatography, with constant values for A280/A260 ratios, esterolytic and amidolytic specific activities; 2) a single band, although dispersed, on gel-electrophoresis at pH 8.3, also in the presence of sodium dodecyl sulfate, and 3) a unique sequence for the six amino-terminal residues. The isolated enzyme was shown to be a single chain glycoprotein (alpha-kallikrein), similar to human urinary and porcine-pancreatic kallikreins regarding the protein moiety molecular mass, amino-acid composition, and partial amino-terminal sequence; differences were found in their total sugar content and even more conspicuously in their carbohydrate composition. In contrast to porcine pancreatic beta-kallikrein, horse urinary kallikrein was not substrate-activated and unlike other alpha-kallikreins, did not present the biphasic time-course in benzoyl-L-arginine ethyl ester hydrolysis. The specificity constants (kcat/Km) for ester and 4-nitroanilide substrates were lower for horse urinary than for pancreatic beta-kallikrein and as observed with the latter enzyme, were affected by NaCl.     

Catalytic Ca2+-binding site of pancreatic phospholipase A2: laser-induced Eu3+ luminescence study

7F0----5D0 excitation spectroscopy of Eu3+ has been used to study the catalytic Ca2+-binding site of pancreatic phospholipases A2. Eu3+ binds competitively with Ca2+ to the enzyme with retention of about 5% of the activity found with Ca2+. The dissociation constants for the Eu3+-enzyme complexes of bovine phospholipase A2 and porcine isophospholipase A2 are 0.22 mM and 0.16 mM, respectively. Results obtained with the porcine phospholipase A2 at neutral pH indicate aggregation of this enzyme at protein concentrations above 0.18 mM. The Eu3+ bound at the catalytic site of pancreatic phospholipase A2 is coordinated to four or five water molecules, which, in conjunction with binding constant data, suggests the involvement of two or three protein ligands. Addition of a monomeric substrate analogue to the enzyme-Eu3+ complex results in the loss of an additional water molecule from the first coordination sphere of the bound Eu3+. This result suggests an interaction between the negative charge of the polar head group of the substrate analogue and the Eu3+. Binding of the enzyme-Eu3+ complex to micelles results in a nearly complete dehydration of the Eu3+ bound to the catalytic center. In the phospholipase A2-Eu3+-micelle complex, only one H2O molecule is coordinated to Eu3+. This dehydration at the active site of phospholipase A2 in the protein-lipid complex can be an important reason for the enhanced activity of this enzyme at lipid-water interfaces.     

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.     

Substrate specificity of human pancreatic elastase 2

The substrate specificity of human pancreatic elastase 2 was investigated by using a series of peptide p-nitroanilides. The kinetic constants, kcat and Km, for the hydrolysis of these peptides revealed that this serine protease preferentially hydrolyzes peptides containing P1 amino acids which have medium to large hydrophobic side chains, except for those which are disubstituted on the first carbon of the side chain. Thus, human pancreatic elastase 2 appears to be similar in peptide bond specificity to the recently described porcine pancreatic elastase 2 [Gertler, A., Weiss, Y., & Burstein, Y. (1977) Biochemistry 16, 2709] but differs significantly in specificity from porcine elastase 1. The best substrates for human pancreatic elastase 2 were glutaryl-Ala-Ala-Pro-Leu-p nitroanilide and succinyl-Ala-Ala-Pro-Met-p-nitroanilide. However, there was little difference among substrates with leucine, methionine, phenylalanine, tyrosine, norvaline, or norleucine in the P1 position. Changes in the hydrolysis rate of peptides with differing P5 residues indicate that this enzyme has an extended binding site which interacts with at least five residues of peptide substrates. The overall catalytic efficiency of human pancreatic elastase 2 is significantly lower than that of porcine elastase 1 or bovine chymotrypsin with the compounds studied.     

Effects of secondary interactions on the kinetics of peptide and peptide ester hydrolysis by tissue kallikrein and trypsin

Kinetic constants for the hydrolysis by porcine tissue beta-kallikrein B and by bovine trypsin of a number of peptides related to the sequence of kininogen (also one containing a P2 glycine residue instead of phenylalanine) and of a series of corresponding arginyl peptide esters with various apolar P2 residues have been determined under strictly comparative conditions. kcat and kcat/Km values for the hydrolysis of the Arg-Ser bonds of the peptides by trypsin are conspicuously high. kcat for the best of the peptide substrates, Ac-Phe-Arg-Ser-Val-NH2, even reaches kcat for the corresponding methyl ester, indicating rate-limiting deacylation also in the hydrolysis of a peptide bond by this enzyme. kcat/Km for the hydrolysis of the peptide esters with different nonpolar L-amino acids in P2 is remarkably constant (range 1.7), as it is for the pair of the above pentapeptides with P2 glycine or phenylalanine. kcat for the ester substrates varies fivefold, however, being greatest for the P2 glycine compounds. Obviously, an increased potential of a P2 residue for interactions with the enzyme lowers the rate of deacylation. In contrast to results obtained with chymotrypsin and pancreatic elastase, trypsin is well able to tolerate a P3 proline residue. In the hydrolysis of peptide esters, tissue kallikrein is definitely superior to trypsin. Conversely, peptide bonds are hydrolyzed less efficiently by tissue kallikrein and the acylation reaction is rate-limiting. The influence of the length of peptide substrates is similar in both enzymes and indicates an extension of the substrate recognition site from subsite S3 to at least S'3 of tissue kallikrein and the importance of a hydrogen bond between the P3 carbonyl group and Gly-216 of the enzymes. Tissue kallikrein also tolerates a P3 proline residue well. In sharp contrast to the behaviour of trypsin is the very strong influence of the P2 residue in tissue-kallikrein-catalyzed reactions. kcat/Km varies 75-fold in the series of the dipeptide esters with nonpolar L-amino acid residues in P2, a P2 glycine residue furnishing the worst and phenylalanine the best substrate, whereas this exchange in the pentapeptides changes kcat/Km as much as 730-fold. This behaviour, together with the high value of kcat/Km for Ac-Phe-Arg-OMe of 3.75 X 10(7) M-1 s-1, suggests rate-limiting binding (k1) in the hydrolysis of the best ester substrates.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative specificity of porcine pancreatic kallikrein and bovine pancreatic trypsin. Importance of interactions N-terminal to the scissible bond

Hydrolyses catalyzed by bovine pancreatic trypsin and porcine pancreatic kallikrein were studied using synthetic peptide substrates of the type E chi-L chi 2-L chi 1 decreases Y and E chi-L chi 3-L chi 2-L chi 1 decreases Y with L chi 1 = Arg defining the hydrolysis position (indicated by the arrow). The leaving moiety Y was -OCH3, -NH-C6H4-p-NO2 and -Ala-NH2. Insight into interactions occurring between the active site of the enzymes and the acyl moiety of the substrates was gained by studying the influence on hydrolysis rate of structural variation of residues L chi 2 and L chi 3. Parallel analyses of the hydrolyses of the ester, anilide, and peptide substrates having the same acyl moiety considerably facilitated the interpretation of the kinetic data. Trypsin, but not kallikrein, displayed high reactivity even with relatively short substrates. Ac-Ala-Arg-Ala-NH2, for example, was a better substrate for trypsin than for kallikrein by a factor of 1.3 X 10(4) in terms of kcat and 5.9 X 10(4) in terms of kcat/Km. Reactivity differences of such magnitude were related to two main differences in enzyme-substrate interactions: the interaction of the arginine side chain of the substrate with the specificity pocket of the enzyme is optimal for trypsin but poor for kallikrein and the number of hydrogen bonds formed by the enzyme with the backbone section of the substrate on both sides of the specific residue is larger in the case of trypsin. The latter difference is found to be related to the structure of amino-acid residue 192 which is glutamine in trypsin and methionine in kallikrein.     

Studies on trypsin inhibitors. Part IX. Synthesis and trypsin inhibitory activity of the duopentacontapeptide corresponding to the amino acid sequence of porcine pancreatic secretory trypsin inhibitor II (Kazal).

The synthesis of the protected duopentacontapeptide corresponding to the entire amino acid sequence I-52 of porcine pancreatic secretory trypsin inhibitor II (Kazal type) is described. The benzyloxycarbonyltetradecapeptide tert-butyloxycarbonylhydrazide (sequence 1-14) was selectively deblocked with trifluoroacetic acid and used to acylate, by the azide procedure, the peptide free base corresponding to the sequence 15-52. The isolated material was purified by ion exchange chromatography and the protecting groups were removed by successive treatments with anhydrous hydrogen fluoride, 1 M piperidine and mercuric acetate. F02M phosphate buffer, pH8. Determination of the inhibitory capacity indicated that the synthetic material is about 50% effective, at 30:1 inhibitor:trypsin molar ratio in inhibiting the tryptic hydrolysis of Nalpha-benzoyl-DL-arginine-4-nitroanilide. Full inhibition was achieved at a higher inhibitor:trypsin molar ratio. The stability constants and the standard free energy of binding of the complex between trypsin and the synthetic inhibitor have been determined.     

Peptide thioesters and 4-nitroanilides as substrates for porcine pancreatic kallikrein

A series of 14 4-nitroanilide substrates and 17 thioester substrates have been used to measure kinetic constants with porcine pancreatic kallikrein. All of the substrates have a P1 arginine residue. The 4-nitroanilide substrates consist of seven P2-glycine and seven P2-phenylalanine tripeptides. As expected from previous results, the phenylalanine series substrates were generally 100-fold 'better' than those in the glycine series. The S3 subsite was found to 'prefer' lysine or phenylalanine, whereas glutamic acid in this position was distinctly unfavourable. The thioester substrates consisted of various thioester derivatives of arginine as well as 12 dipeptides. These substrates exhibited kcat./Km values generally 1000 times higher than the P2-phenylalanine 4-nitroanilides. With the thioesters, a P2 phenylalanine or tryptophan residue yielded the best substrates, but some of the simple derivatives of arginine were nearly as good. A comparison of the kinetic constants of the thioester substrates between the porcine enzyme and human plasma kallikrein provides further evidence that these enzymes have a similar preference for bulky P2 residues, but otherwise are quite different enzymes. The thioester substrates are nearly as reactive as oxygen ester substrates such as acetylphenylalanylarginine methyl ester for the porcine enzyme [Levison & Tomalin (1982) Biochem. J. 203, 299-302; Fiedler (1983) Adv. Exp. Med. Biol. 156A, 263-274], and owing to the greater ease in assaying with the thioesters, they should find use in routine assays for the glandular kallikreins.     

Homonyms, synonyms and mutations of the sequence/structure vocabulary

The effect of pH and temperature on the association equilibrium constant (Ka) for bovine basic pancreatic trypsin inhibitor (BPTI, Kunitz inhibitor) binding to human urinary kallikrein and porcine pancreatic beta-kallikreins A and B has been investigated. Ka values decrease with decreasing pH, reflecting the acid-midpoint and pK shifts, upon BPTI binding, of a three-proton co-operative transition, between pH 3 and 5, and of a single ionizable group, between pH 5 and 9. At pH 8, the values of delta H degree (between 7 degrees C and 42 degrees C) and delta S degree (at 21 degrees C) for BPTI binding to the glandular kallikreins considered were determined. In particular, the delta H degree values have been found to be independent of temperature and the following values have been obtained by van't Hoff plots: +1.8 kcal/mol, +2.3 kcal/mol and +2.4 kcal/mol (1 kcal = 4184 J) for the inhibitor binding to human urinary kallikrein and porcine pancreatic beta-kallikreins A and B, respectively. Considering the known molecular structures of free porcine pancreatic beta-kallikrein A and BPTI, and of their complex, the stereochemistry of the enzyme : inhibitor contact regions was analysed for the three serine proteinases, in relation to their respective types of behaviour.     

Activities of anionic and cationic trypsins in the temperature range from 5 to 37 degrees C. Mutant anionic trypsins as a model of cold-adapted (psychrophilic) enzymes

Temperature dependences of kinetic constants (k _cat and K _m) were studied for enzymatic hydrolysis of N-succinyl-L-alanyl-L-alanyl-L-prolyl-L-arginine-p-nitroanilide and N-succinyl-L-alanyl-L-alanyl-L-prolyl-L-lysine-p-nitroanilide by bovine cationic and rat anionic (wild-type and mutant) trypsins. The findings were compared with the corresponding literature data for hydrolysis of N-benzoyl-DL-arginine-p-nitroanilide by bovine cationic trypsin and natural trypsins of coldadapted fishes. The anionic and cationic trypsins were found to differ in organization of the S₁ -substrate-binding pocket. The difference in the binding of lysine and arginine residues to this site (S₁) was also displayed by opposite temperature dependences of hydrolysis constants for the corresponding substrates by the anionic and cationic trypsins. The data suggest that the effect of any factor on the binding of substrates (the K _m value) to the anionic and cationic trypsins and on the catalytic activity k _cat should be compared only with the corresponding data for the natural enzyme of the same type. Mutants of rat anionic trypsin at residues K188 or Y228 were prepared by site-directed mutagenesis as approximate models of natural psychrophilic trypsins. Substitution of the charged lysine residue in position 188 by hydrophobic phenylalanine residue shifted the pH optimum of the resulting mutant trypsin K188F from 8.0 to 9.0-10.0, similarly to the case of some natural psychrophilic trypsins, and also 1.5-fold increased its catalytic activity at low temperatures as compared to the wild-type enzyme.     

Refined 2.5 Å X-ray crystal structure of the complex formed by porcine kallikrein A and the bovine pancreatic trypsin inhibitor: Crystallization,patterson search,structure determination,refinement, structure and comparison with its components and with the bovine trypsin-pancreatic trypsin inhibitor complex

The complex formed by porcine pancreatic kallikrein A with the bovine pancreatic trypsin inhibitor (PTI) has been crystallized at pH 4 in tetragonal crystals of space group P4₁2₁2 with one molecule per asymmetric unit. Its crystal structure has been solved applying Patterson search methods and using a model derived from the bovine trypsin-PTI complex (Huber et al., 1974) and the structure of porcine pancreatic kallikrein A (Bode et al., 1983). The kallikrein-PTI model has been crystallographically refined to an R-value of 0·23 including X-ray data to 2·5 Å.The root-mean-square deviation, including all main-chain atoms, is 0·45 Å and 0·65 Å for the PTI and for the kallikrein component, respectively, compared with the refined models of the free components. The largest differences are observed in external loops of the kallikrein molecule surrounding the binding site, particularly in the C-terminal part of the intermediate helix around His172. Overall, PTI binding to kallikrein is similar to that of the trypsin complex. In particular, the conformation of the groups at the active site is identical within experimental error (in spite of the different pH values of the two structures). Ser195 OG is about 2·5 Å away from the susceptible inhibitor bond Lys15 C and forms an optimal 2·5 Å hydrogen bond with His57 NE.The PTI residues Thr11 to Ile18 and Val34 to Arg39 are in direct contact with kallikrein residues and form nine intermolecular hydrogen bonds. The reactive site Lys15 protrudes into the specificity pocket of kallikrein as in the trypsin complex, but its distal ammonium group is positioned differently to accommodate the side-chain of Ser226. Ser226 OG mediates the ionic interaction between the ammonium group and the carboxylate group of Asp189. Model-building studies indicate that an arginine side-chain could be accommodated in this pocket. The PTI disulfide bridge 14–38 forces the kallikrein residue Tyr99 to swing out of its normal position. Model-building experiments show that large hydrophobic residues such as phenylalanine can be accommodated at this (S2) site in a wedge-shaped hydrophobic cavity, which is formed by the indole ring of Trp215 and by the phenolic side-chain of Tyr99, and which opens towards the bound inhibitor/substrate chain. Arg17 in PTI forms a favorable hydrogen bond and van der Waals' contacts with kallikrein residues, whereas the additional hydrogen bond formed in the trypsin-PTI complex between Tvr39 OEH and Ile19 N is not possible The kallikrein binding site offers a qualitative explanation of the unusual binding and cleavage at the N-terminal Met-Lys site of kininogen. Model-building experiments suggest that the generally restricted capacity of kallikrein to bind protein inhibitors with more extended binding segments might be explained by steric hindrance with some extruding external loops surrounding the kallikrein binding site (Bode et al., 1983).     

Serine proteinase inhibition by the active site titrant N alpha-(N, N-dimethylcarbamoyl)-alpha-azaornithine p-nitrophenyl ester. A comparative study.

Kinetics for the hydrolysis of the chromogenic active-site titrant N alpha-(N,N-dimethylcarbamoyl)-alpha-azaornithine p-nitrophenyl ester (Dmc-azaOrn-ONp) catalysed by bovine beta-trypsin, bovine alpha-thrombin, bovine Factor Xa, human alpha-thrombin, human Factor Xa, human Lys77-plasmin, human urinary kallikrein, Mr 33 000 and Mr 54 000 species of human urokinase, porcine pancreatic beta-kallikrein-A and -B and Ancrod (the coagulating serine proteinase from the Malayan pit viper Agkistrodon rhodostoma venom) have been obtained between pH 6.0 and 8.0, at 21.0 degrees C, and analysed in parallel with those for the enzymatic cleavage of N alpha-(N,N-dimethylcarbamoyl)-alpha-azalysine p-nitrophenyl ester (Dmc-azaLys-ONp). The enzyme kinetics are consistent with the minimum three-step catalytic mechanism of serine proteinases, the rate-limiting step being represented by the deacylation process. Bovine beta-trypsin kinetics are modulated by the acid-base equilibrium of the His57 catalytic residue (pKa approximately 6.9). Dmc-azaOrn-ONp and Dmc-azaLys-ONp bind stoichiometrically to the serine proteinase active site, and allow the reliable determination of the active enzyme concentration between 1.0 x 10-6 M and 3.0 x 10-4 M. The affinity and the reactivity for Dmc-azaOrn-ONp (expressed by Ks and k+2/Ks, respectively) of the serine proteinases considered are much lower than those for Dmc-azaLys-ONp. The very different affinity and reactivity properties for Dmc-azaOrn-ONp and Dmc-azaLys-ONp have been related to the different size of the ornithine/lysine side chains, and to the ensuing different positioning of the active-site titrants upon binding to the enzyme catalytic centre (i.e. to P1-S1 recognition). These data represent the first detailed comparative investigation on the catalytic properties of serine proteinases towards an ornithine derivative (i. e. Dmc-azaOrn-ONp).     

Porcine pancreatic alpha-amylase: a model for structure--function studies of homodepolymerases

The amino acid sequence of the porcine pancreatic alpha-amylase chain (496 residues) contains four regions (96-101, 193-201, 233-236 and 295-300) which are highly homologous in amylases of different origins. These regions all belong to the N-terminal domain of the enzyme. Limited proteolysis by subtilisin allows a cut to be made at bond 369-370. Purified fragments indicate that both N- and C-terminal domains are required for amylolytic activity. Kinetic studies and reaction product analysis using oligomaltosides, their nitrophenylated derivatives and amylose as the substrate allowed us to establish: 1) the energy profile of the 5 subsites and, especially, that subsite number 3 is catalytic; 2) that 2 molecules of either maltotriose or its o-nitrophenylated analog or maltose bind to the active site at high substrate concentration. Such a subsite occupancy was confirmed by fluorescence quenching studies. Finally the hydrolysis of p-nitrophenylmaltoside was studied as a function of pH. In contrast to starch hydrolysis, the initial velocity plots for nitrophenol and p-nitrophenylglucoside liberation both gave a narrow pH-activity peak with a maximum value around pH 5.5. All data provide strong evidence for the participation of 2 carboxylic residues in the catalysis.     

Catalytic activity of MsbA reconstituted in nanodisc particles is modulated by remote interactions with the bilayer

ATP-binding cassette (ABC) transporters couple hydrolysis of ATP with vectorial transport across the cell membrane. We have reconstituted ABC transporter MsbA in nanodiscs of various sizes and lipid compositions to test whether ATPase activity is modulated by the properties of the bilayer. ATP hydrolysis rates, Michaelis-Menten parameters, and dissociation constants of substrate analog ATP-γ-S demonstrated that physicochemical properties of the bilayer modulated binding and ATPase activity. This is remarkable when considering that the catalytic unit is located ~50? from the transmembrane region. Our results validated the use of nanodiscs as an effective tool to reconstitute MsbA in an active catalytic state, and highlighted the close relationship between otherwise distant transmembrane and ATPase modules.     

A simple method for the determination of individual rate constants for substrate hydrolysis by serine proteases

A simple method is presented for the determination of individual rate constants for substrate hydrolysis by serine proteases and other enzymes with similar catalytic mechanism. The method does not require solvent perturbation like viscosity changes, or solvent isotope effects, that often compromise nonspecifically the activity of substrate and enzyme. The rates of substrate diffusion into the active site (k1), substrate dissociation (k-1), acylation (k2), and deacylation (k3) in the accepted mechanism of substrate hydrolysis by serine proteases are derived from the temperature dependence of the Michaelis-Menten parameters kcat/Km and kcat. The method also yields the activation energies for these molecular events. Application to wild-type and mutant thrombins reveals how the various steps of the catalytic mechanism are affected by Na+-binding and site-directed mutations of the important residues Y225 in the Na+ binding environment and L99 in the S2 specificity site. Extension of this method to other proteases should enable the derivation of detailed information on the kinetic and energetic determinants of protease function.     

Action of phospholipase A2 on bilayers. Effect of fatty acid and lysophospholipid additives on the kinetic parameters

Action of pig pancreatic phospholipase A2 on the ternary codispersions of diacylphosphatidylcholine, 1-acyllysophosphatidylcholine and fatty acids is examined. The binding and kinetic constants are found to be the same under a variety of conditions. These parameters and the catalytic turnover number change with the phase-transition temperature of the ternary codispersions, and optimal binding, kinetic and catalytic constants are seen in the phase-transition range where an equilibrium exists between laterally separated phases. The effect of changing the structure of any of the three components is also via a change in the phase-transition temperature of their ternary codispersions. These observations suggest that the binding of pig pancreatic phospholipase A2 to the defect sites on the substrate interface determines the substrate concentration dependence of the initial rate of hydrolysis, and the catalytic turnover by the bound enzyme also depends upon the phase state of the bilayer. An additive-induced stabilization of the defects in the substrate bilayer is postulated to account for the enhanced binding of the enzyme to the bilayer.     

Dimerization and activation of porcine pancreatic phospholipase A2 via substrate level acylation of lysine 56

The porcine pancreatic phospholipase A2-catalyzed hydrolysis of the water-soluble chromogenic substrate 4-nitro-3-octanoyloxybenzoate shows an initial latency phase similar to the one observed in the hydrolysis of aggregated phospholipids by the same enzyme. We report here that during the latency phase the enzyme undergoes a slow, autocatalytic, substrate-level acylation whereby in a few of the catalytic events the scissile octanoyl group of the substrate, normally transferred to water, is transferred to the epsilon-amino group of lysine 56. The N epsilon 56-octanoylphospholipase shows a strong tendency to dimerize in solution and thus may be separated from the monomeric native enzyme by gel filtration. Octanoylation of Lys-56 activates the enzyme some 180-fold toward 4-nitro-3-octanoyloxybenzoate and more than 100-fold toward monolayers of 1,2-didecanoyl-sn-glycero-3-phosphocholine. Acylation also attends the enzymatic hydrolysis of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine with the incorporation of 1 eq of palmitate. Kinetic analysis of the early phase of reaction with 4-nitro-3-octanoyloxybenzoate shows that in this initial step the rate of activation is first order with respect to enzyme and substrate. A much more rapid, autocatalytic activation occurs in the later phases of the reaction where the activation of the enzyme is catalyzed by the activated enzyme itself. These findings with porcine pancreatic phospholipase A2, together with those relative to a snake venom enzyme monomer (Cho, W., Tomasselli, A. G., Heinrikson, R. L., and Kézdy, F. J. (1988) J. Biol. Chem. 263, 11237-11241), strongly support the proposal that interfacial activation of monomeric phospholipases is due to substrate-level autoacylation resulting in fully potentiated dimeric enzymes.     

Detection of a covalent intermediate in the mechanism of action of porcine pancreatic alpha-amylase by using 13C nuclear magnetic resonance

The catalytic mechanism of porcine pancreatic alpha-amylase (1,4-alpha-D-glucan glucanohydrolase, EC 3.2.1.1) has been examined by nuclear magnetic resonance (NMR) at subzero temperatures by using [1-13C]maltotetraose as substrate. Spectral summation and difference techniques revealed a broad resonance peak, whose chemical shift, relative signal intensity and time-course appearance corresponded to a beta-carboxyl-acetal ester covalent enzyme-glycosyl intermediate. This evidence supports a double-displacement covalent mechanism for porcine pancreatic alpha-amylase-catalyzed hydrolysis of glycosidic linkages, based on the presence of catalytic aspartic acid residues within the active site of this enzyme.