Studies of specificity and catalysis in trypsin by structural analysis of site-directed mutants

We are probing the determinants of catalytic function and substrate specificity in serine proteases by kinetic and crystallographic characterization of genetically engineered site-directed mutants of rat trypsin. The role of the aspartyl residue at position 102, common to all members of the serine protease family, has been tested by substitution with asparagine. In the native enzyme, Asp102 accepts a hydrogen bond from the catalytic base His57, which facilitates the transfer of a proton from the enzyme nucleophile Ser195 to the substrate leaving group. At neutral pH, the mutant is four orders of magnitude less active than the naturally occurring enzyme, but its binding affinity for model substrates is virtually undiminished. Crystallographic analysis reveals that Asn102 donates a hydrogen bond to His57, forcing it to act as donor to Ser195. Below pH 6, His57 becomes statistically disordered. Presumably, the di-protonated population of histidyl side chains are unable to hydrogen bond to Asn102. Steric conflict may cause His57 to rotate away from the catalytic site. These results suggest that Asp102 not only provides inductive and orientation effects, but also stabilizes the productive tautomer of His57. Three experiments were carried out to alter the substrate specificity of trypsin. Glycine residues at positions 216 and 226 in the substrate-binding cavity were replaced by alanine residues in order to differentially affect lysine and arginine substrate binding. While the rate of catalysis by the mutant enzymes was reduced in the mutant enzymes, their substrate specificity was enhanced relative to trypsin. The increased specificity was caused by differential effects on the catalytic activity towards arginine and lysine substrates. The Gly----Ala substitution at 226 resulted in an altered conformation of the enzyme which is converted to an active trypsin-like conformation upon binding of a substrate analog. In a third experiment, Lys189, at the bottom of the specificity pocket, was replaced with an aspartate with the expectation that specificity of the enzyme might shift to aspartate. The mutant enzyme is not capable of cleaving at Arg and Lys or Asp, but shows an enhanced chymotrypsin-like specificity. Structural investigations of these mutants are in progress.     

The 2.8 A resolution structure of Streptomyces griseus protease B and its homology with alpha-chymotrypsin and Streptomyces griseus protease A.

The 2.8 A (1 A = 0.1 nm) resolution structure of the crystalline orthorhombic form of the microbial serine protease Streptomyces griseus protease B (SGPB) has been solved by the method of multiple isomorphous replacement using five heavy-atom derivatives. The geometrical arrangement of the active site quartet, Ser-214, Asp-102, His-57, and Ser-195, is similar to that found for pancreatic alpha-chymotrypsin. SGPB and alpha-chymotrypsin have only 18% identity of primary structure but their tertiary structures are 63% topologically equivalent within a root mean square deviation of 2.07 A. The major tertiary structural differences between the bacterial enzyme SGPB and the pancreatic enzymes is due to the zymogen requirement of the multicellular organisms in order to protect themselves against autolytic degradation. The two pronase enzymes, SGPB and Streptomyces griseus protease A (SGPA), have 61% identity of sequence and their tertiary structures are 85% topologically equivalent within a root mean square deviation of 1.46 A. The active site regions of SGPA and SGPB are similar and their tertiary structures differ only in three minor regions of surface loops.     

The effects of chemical modification on the refolding transition of alpha-chymotrypsin.

The role of several active site residues of alpha-chymotrypsin in the prototypical refolding transition between active and inactive forms of this enzyme is examined using chemical modification. Oxidation of Met-192 to the sulfoxide results in a derivative which remains entirely in an active state from pH 6 to 9. The derivative becomes inactive only at high pH with pKa = 10.3, delta H0 = 9.5 kcal and delta S0 = -15 eu., indicating the sulfoxide group supplies about 2.1 kcal of active state stabilization relative to the unoxidized methionine side chain. The refolding transition of N-methyl-His-57-alpha-chymotrypsin, in which a nitrogen of the "charge relay" histidine is methylated, displays one ionization process with an apparent pKa of 9.45. The absence of an additional ionization process with a pKa near 7 provides evidence that one of the ionizations in the six state mechanism which describes this transition in alpha-chymotrypsin is linked to the charge relay system. We also demonstrate, using alpha-chymotrypsin, Met-192-sulfoxide-alpha-chymotrypsin and N-methyl-His-57-alpha-chymotrypsin, that the 230 nm circular dichroism band is a quantitative probe of the active-inactive equilibrium, although the chromophore or chromophores responsible for this and another very large negative band at 202 nm have not been identified. Circular dichroism was used to observe the active-inactive equilibrium in methan sulfonyl-alpha-chymotrypsin and phenylmethane sulfonyl-alpha-chymotrypsin. The enhanced stability of the active state of these derivatives relative to alpha-chymotrypsin can be rationalized in terms of steric effects in the substrate side chain binding site.     

Structure of human pro-chymase: a model for the activating transition of granule-associated proteases

Human chymase is a protease involved in physiological processes ranging from inflammation to hypertension. As are all proteases of the trypsin fold, chymase is synthesized as an inactive "zymogen" with an N-terminal pro region that prevents the transition of the zymogen to an activated conformation. The 1.8 A structure of pro-chymase, reported here, is the first zymogen with a dipeptide pro region (glycine-glutamate) to be characterized at atomic resolution. Three segments of the pro-chymase structure differ from that of the activated enzyme: the N-terminus (Gly14-Gly19), the autolysis loop (Gly142-Thr154), and the 180s loop (Pro185A-Asp194). The four N-terminal residues (Gly14-Glu15-Ile16-Ile17) are disordered. The autolysis loop occupies a position up to 10 A closer to the active site than is seen in the activated enzyme, thereby forming a hydrogen bond with the catalytic residue Ser195 and occluding the S1' binding pocket. Nevertheless, the catalytic triad (Asp102-His57-Ser195) is arrayed in a geometry close to that seen in activated chymase (all atom rmsd of 0.52 A). The 180s loop of pro-chymase is, on average, 4 A removed from its conformation in the activated enzyme. This conformation disconnects the oxyanion hole (the amides of Gly193 and Ser195) from the active site and positions only approximately 35% of the S1-S3 binding pockets in the active conformation. The backbone of residue Asp194 is rotated 180 degrees when compared to its conformation in the activated enzyme, allowing a hydrogen bond between the main-chain amide of residue Trp141 and the carboxylate of Asp194. The side chains of residues Phe191 and Lys192 of pro-chymase fill the Ile16 binding pocket and the base of the S1 binding pocket, respectively. The zymogen positioning of both the 180s and autolysis loops are synergistic structural elements that appear to prevent premature proteolysis by chymase and, quite possibly, by other dipeptide zymogens.     

Ultrasonic studies of proton-transfer reactions at the catalytic site of alpha-chymotrypsin

Ultrasonic relaxation measurements for alpha-chymotrypsin in phosphate, sulfite and arsenate buffers exhibit a high peak of absorption at neutral pH. The analysis is based on: comparison of the relaxation measurements for the enzyme and for the zymogen and inhibited enzyme; X-ray and neutron diffraction data, and high-resolution NMR data. The ultrasonic relaxation is shown to result mainly from a proton-transfer reaction that involves the histidine at the catalytic site (His-57). The question is raised of whether the enhanced ultrasonic effect observed in the enzyme is indicative of a property that plays a part in the catalytic activity.     

Detection of native peptides as potent inhibitors of enzymes. Crystal structure of the complex formed between treated bovine alpha-chymotrypsin and an autocatalytically produced fragment, IIe-Val-Asn-Gly-Glu-Glu-Ala-Val-Pro-Gly-Ser-Trp-Pro-Trp, at 2.2 angstroms resolution

Chymotrypsin is a prominent member of the family of serine proteases. The present studies demonstrate the presence of a native fragment containing 14 residues from Ile16 to Trp29 in alpha-chymotrypsin that binds to chymotrypsin at the active site with an exceptionally high affinity of 2.7 +/- 0.3 x 10(-11) M and thus works as a highly potent competitive inhibitor. The commercially available alpha-chymotrypsin was processed through a three phase partitioning system (TPP). The treated enzyme showed considerably enhanced activity. The 14 residue fragment was produced by autodigestion of a TPP-treated alpha-chymotrypsin during a long crystallization process that lasted more than four months. The treated enzyme was purified and kept for crystallization using vapour the diffusion method at 295 K. Twenty milligrams of lyophilized protein were dissolved in 1 mL of 25 mM sodium acetate buffer, pH 4.8. It was equilibrated against the same buffer containing 1.2 M ammonium sulfate. The rectangular crystals of small dimensions of 0.24 x 0.15 x 0.10 mm(3) were obtained. The X-ray intensity data were collected at 2.2 angstroms resolution and the structure was refined to an R-factor of 0.192. An extra electron density was observed at the binding site of alpha-chymotrypsin, which was readily interpreted as a 14 residue fragment of alpha-chymotrypsin corresponding to Ile-Val-Asn-Gly-Glu-Glu-Ala-Val-Pro-Gly-Ser-Trp-Pro-Trp(16-29). The electron density for the eight residues of the C-terminus, i.e. Ala22-Trp29, which were completely buried in the binding cleft of the enzyme, was of excellent quality and all the side chains of these eight residues were clearly modeled into it. However, the remaining six residues from the N-terminus, Ile16-Glu21 were poorly defined although the backbone density was good. There was a continuous electron density at 3.0 sigma between the active site Ser195 Ogamma and the carbonyl carbon atom of Trp29 of the fragment. The final refined coordinates showed a distance of 1.35 angstroms between Ser195 Ogamma and Trp29 C indicating the presence of a covalent linkage between the enzyme and the native fragment. This meant that the enzyme formed an acyl intermediate with the autodigested fragment Ile16-Trp29. In addition to the O-C covalent bond, there were several hydrogen bonds and hydrophobic interactions between the enzyme and the native fragment. The fragment showed a high complementarity with the binding site of alpha-chymotrypsin and the buried part of the fragment matched excellently with the corresponding buried part of Turkey ovomucoid inhibitor of alpha-chymotrypsin.     

Role of catalytic residues in the formation of a tetrahedral adduct in the acylation reaction of bovine β-trypsin: A molecular orbital study

In the acylation reaction of serine proteases the effect of amino acid residues on the geometrical change of the catalytic site from Michaelis to tetrahedral state was studied by using ab initio molecular orbital calculations. Amino acid residues in the catalytic site and the peptide substrate were calculated as a quantum mechanical region, and all the other amino acid residues and the calcium ion were included in the calculation as the electrostatic effects. The effects of Asp102, Asp194, N-terminus and the oxyanion binding site are large. The oxyanion binding site directly stabilizes the tetrahedral substrate. Asp102 stabilizes the enzyme intermediate, interacting with the protonated His57 residue. In order to elucidate the roles of Asp102 and the oxyanion binding site, energy decomposition analyses were done for the intermolecular interactions. The contribution of Asp102 and the oxyanion binding site to the decrease of energy in the geometrical change is due to the electrostatic effect. The energies of the proton shuttle from Ser195 O^γ to the leaving group of the substrate were calculated for amide and ester substrate models.     

High resolution nuclear magnetic resonance studies of the active site of chymotrypsin. I. The hydrogen bonded protons of the "charge relay" system

High resolution proton nuclear magnetic resonance has been used to observe protons at the active site of chymotrypsin A_δ and at the same region of chymotrypsinogen A. A single resonance with the intensity of one proton is located in the low field region of the nuclear magnetic resonance spectrum. This resonance is observed in H₂O solutions but not in ²H₂O. On going from low to high pH the resonance titrates upfield 3 parts per million in both proteins and has a pK of 7.5. The titration can be prevented by alkylating His57 with either of two active site directed chloromethyl ketones. Using these data the proton resonance has been assigned to a proton in a hydrogen bond between His57 and Asp102. Further confirmation of this assignment lies in the observation of a similar resonance in this same low field region of the nuclear magnetic resonance spectrum of trypsin, trypsinogen, subtilisin BPN′ and α-lytic protease all of which have the Asp-His-Ser triad at their active sites.This proton resonance in chymotrypsin A_δ was used as a probe to monitor the charge state of the active site upon formation of a stable acyl-enzyme analogue N²(N-acetylalanyl)-N¹benzoylcarbazoyl-chymotrypsin A_δ. In this derivative the His-Asp proton resonance titrates from the same low pH end point as in the native enzyme, ?18 parts per million, to a new high pH end point of ?14.4 parts per million (versus ?15.0 parts per million in the native enzyme). The difference of 0.6 parts per million in the high pH end points between the native and acyl enzyme is interpreted as supporting the suggestion that a hydrogen bond exists between Ser195 and His57 in the native enzyme and zymogen.We conclude from these studies that the charge relay system from Asp102 across His57 to Ser195 is intact in chymotrypsin A_δ and chymotrypsinogen A, and that, in the native enzyme, it slightly polarizes Ser195.     

The structure and function of ribonuclease T1. XXI. Modification of histidine residues in ribonuclease T1 with iodoacetamide.

1. When ribonuclease T1 [EC 3.1.4.8] (0.125% solution) was treated with a 760-fold molar excess of iodoacetamide at pH 8.0 and 37 degrees, about 90% of the original activity was lost in 24 hr. The half-life of the activity was about 8 hr. The binding ability for 3'-GMP was lost simultaneously. Changes were detected only in histidine and the amino-terminal alanine residues upon amino acid analyses of the inactivated protein and its chymotryptic peptides. The inactivation occurred almost in parallel with the loss of two histidine residues in the enzyme. The pH dependences of the rate of inactivation and that of loss of histidine residues were similar and indicated the implication of a histidine residue or residues with pKa 7.5 to 8 in this reaction. 3'-GMP and guanosine showed some protective effect against loss of activity and of histidine residues. The reactivity of histidine residues was also reduced by prior modification of glutamic acid-58 with iodoacetate, of lysine-41 with maleic or cis-aconitic anhydride or 2,4,6-trinitrobenzenesulfonate or of arginine-77 with ninhydrin. 2. Analyses of the chymotryptic peptides from oxidized samples of the iodoacetamide-inactivated enzyme showed that histidine-92 and histidine-40 reacted with iodoacetamide most rapidly and at similar rates, whereas histidine-27 was least reactive. Alkylation of histidine-92 was markedly slowed down when the Glu58-carboxymethylated enzyme was treated with iodoacetamide. On the other hand, alkylation of histidine-40 was slowed down most in the presence of 3'-GMP. These results suggest that histidine-92 and histidine-40 are involved in the catalytic action, probably forming part of the catalytic site and part of the binding site, respectively, and that histidine-27 is partially buried in the enzyme molecule or interacts strongly with some other residue, thus becoming relatively unreactive.     

Catalytic activity of the serine proteases alpha-chymotrypsin and alpha-lytic protease tagged at the active site with a (terpyridine)platinum(II) chromophore

Incubation of alpha-chymotrypsin and alpha-lytic protease with chloro(2,2':6',2'-terpyridine)platinum(II), [Pt(trpy)Cl]+, results in attachment of Pt(trpy)2+ tags at both His 57 and His 40 in the former and His 57 in the latter. The [Pt(trpy)His]2+ chromophores are readily detected and quantitated owing to their characteristic, strong UV absorption. Although the tagging of His 57 modifies the catalytic triad (Ser 195, His 57, and Asp 102) and disrupts the charge relay, the platinated enzymes retain significant esterase and amidase activity for both specific and nonspecific substrates. Unlike suicide inhibitors, which inactivate the enzymes by filling the active site and imitating the tetrahedral intermediate, [Pt(trpy)Cl]+ reacts with a particular amino acid and permits binding of substrates. The kinetic constants for the following are reported: two esters and two amides with alpha-chymotrypsin and an amide with alpha-lytic protease. The kcat values are between 1 and 25% of, and the Km values are a little higher than, the corresponding values for the native enzymes. The catalytic activity is not due to the native enzymes, trypsin, or some zinc-containing protease. Activities of the native and of the platinated alpha-chymotrypsin depend similarly on pH although the pKa of His 57 is raised to 9.7 upon platination. The platinated enzymes undergo autodigestion slower than do the native enzymes. Because the Pt(trpy)2+ tags are noninvasive, stable, and yet easily removable by thiourea, [Pt(trpy)Cl]+ may be used to retard autodigestion of stored proteolytic enzymes.     

An investigation of the contribution made by the carboxylate group of an active site histidine-aspartate couple to binding and catalysis in lactate dehydrogenase

The influence of aspartate-168 on the proton-donating and -accepting properties of histidine-195 (the active site acid/base catalyst in lactate dehydrogenase) was evaluated by use of site-directed mutagenesis to change the residue to asparagine and to alanine. Despite the fact that asparagine could form a hydrogen bond to histidine while alanine could not, the two mutant enzymes have closely similar catalytic and ligand-binding properties. Both bind pyruvate and its analogue (oxamate) 200 times more weakly than the wild-type enzyme but show little disruption in their binding of lactate and its unreactive analogue, trifluorolactate. Neither mutation alters the binding of coenzymes (NADH and NAD+) or the pK of the histidine-195 residue in the enzyme-coenzyme complex. We conclude that a strong histidine-aspartate interaction is only formed when both coenzyme and substrate are bound. Deletion of the negative charge of aspartate shifts the equilibrium between enzyme-NADH-pyruvate (protonated histidine) and enzyme-NAD+-lactate (unprotonated histidine) toward the latter. In contrast to the wild-type enzyme, the rate of catalysis in both directions in the mutants is limited by a slow hydride ion transfer step.     

The pKa value of His 57-Asp 102 couple in the active site of bovine pancreatic beta-trypsin: a molecular orbital study

The charge relay hypothesis generated a large number of theoretical and experimental studies that tested the ideas involved. Opinion based upon theoretical and experimental studies is divided on the prediction, although there are many experimental data which do not support the hypothesis. The essential feature is the proton transfer from the histidine imidazole to the aspartate. Thus, we have performed the detailed calculations of the proton transfer from His 57 to Asp 102 including the environment of the couple in protonated bovine pancreatic β-trypsin. The charge state of the His 57-Asp 102 couple is greatly influenced by the environment of the enzyme around it. In this paper, it is shown that the proton between His 57 and Asp 102 is covalently bonded to the His 57 imidazole in the protonated β-trypsin. Our MO calculations, which support the neutral-pK-histidine theory as the results, do not support the charge relay mechanism.     

Expression of functionality of alpha-chymotrypsin. An alternate binding mode in the substrate specificity site

Three-dimensional 2.8 A resolution x-ray crystallographic studies show that toluenesulfonamide and pipsylamide bind isomorphously in the aromatic specificity binding site of alpha-chymotrypsin. However, their orientation differs by about 90 degrees from that usually associated with substrate-like molecules, suggesting a nonproductive binding mode. A secondary binding site is also operative in one molecule of the dimer of the pipsylamide derivative and it is located some 22 A from the active site; however, this site is not operative in the toluenesulfonamide derivative. Binding of toluenesulfonamide and pipsylamide in the specificity site occurs without inducing any significant changes in the native enzyme structure, in contrast to the behavior observed upon tosylation or upon transition state analogue binding of phenylethaneboronic acid. The structural changes accompanying the formation of the latter derivatives are generally asymmetric with respect to the dimeric structure of alpha-chymotrypsin and are generally confined to the binding domain or cylinder 2 of the enzyme (sequence greater than 122). These changes are displayed in a new way via diagonal distance map representation.     

Zymogen activation in serine proteinases. Proton magnetic resonance pH titration studies of the two histidines of bovine chymotrypsinogen A and chymotrypsin Aalpha.

Reversible unfolding of bovine chymotrypsinogen A in 2H2O either by heating at low pH or by exposure to 6 M guanidinium chloride results in the exchange of virtually all the nitrogen-bound hydrogens that give rise to low-field 1H NMR peaks, without significant exchange of the histidyl ring Cepsilon1 hydrogens. These preexchange procedures have enabled the resolution of two peaks, using 250-MHz correlation 1H NMR spectroscopy, that are attributed to the two histidyl residues of chymotrypsinogen A. Assignments of the Cepsilon1 hydrogen peaks to histidine-40 and -57 were based on comparison of the NMR titration curves of the native zymogen with those of the diisopropylphosphoryl derivative. Two histidyl Cepsilon1 H peaks were also resolved with solutions of preexchanged chymotrypsin Aalpha. The histidyl peaks of chymotrypsin Aalpha were assigned by comparison of NMR titration curves of the free enzyme with those of its complex with bovine pancreatic trypsin inhibitor (Kunitz). The NMR titration curves of histidine-57 in the zymogen and enzyme and histidine-40 in the zymogen exhibit two inflections; the additional inflections were assigned to interactions with neighboring carboxyl groups: aspartate-102 in the case of histidine-57 and aspartate-194 in the case of histidine-40 of the zymogen. In bovine chymotrypsinogen A in 2H2O at 31 degrees C, histidine-57 has a pK' of 7.3 and aspartate-102 a pK' of 1.4, and the histidine-40-aspartate-194 system exhibits inflections at pH 4.6 and 2.3. In bovine chymotrypsin Aalpha under the same conditions, the histidine-57-aspartate-102 system has pK' values of 6.1 and 2.8, and histidine-40 has a pK' of 7.2. The results suggest that the pK' of histidine-57 is higher than the pK' of aspartate-102 in both zymogen and enzyme. A significant difference exists in the structure and properties of the catalytic center between the zymogen and activated enzyme. In addition to the difference in pK' values, the chemical shift of histidine-57, which is highly abnormal in the zymogen (deshielded by 0.6 ppm), becomes normalized upon activation. These changes may explain part of the increase in the catalytic activity upon activation. The 1H NMR chemical shift of the Cepsilon1 H of histidine-57 in the chymotrypsin Aalpha-pancreatic trypsin inhibitor (Kunitz) complex is constant between pH 3 and 9 at a value similar to that of histidine-57 in the porcine trypsin-pancreatic trypsin inhibitor complex [Markley, J.L., and Porubcan, M. A. (1976), J. Mol. Biol. 102, 487--509], suggesting that the mechanisms of interaction are similar in the two complexes.     

Electron paramagnetic resonance probing of macromolecules: a comparison of structure-function relationships in chymotrypsinogen, -chymotrypsin and anhydrochymotrypsin

Chymotrypsinogen, chymotrypsin and anhydrochymotrypsin have been covalently spin-labeled by an analog of bromoacetamide, and the latter two proteins have been labeled by an analog of 1-chloro-3-tosylamido-4-phenyl butanone. The electron paramagnetic resonance spectra of the labeled proteins indicate protein conformational changes accompanying (1) activation of the zymogen and (2) the binding of protons and substrates by the native and anhydro enzymes, and tertiary structural differences between these protein forms which are at once informative and predictable. A spin-label linked to the thioether side-chain of methionine 192 in Chymotrypsinogen may be in contact with a hydrophobic surface. This interaction is lost upon zymogen activation with little change in the isotropic rotational freedom of the nitroxide group. The rotational freedom of the group increases sigmoidally with pH; a spectral dependence upon an ionizing group (pK_a = 8.9) is demonstrated. The binding of indole to the labeled enzyme raises the pK_a of the ionizing group to 10.2. A spin-label linked to histidine 57 in chymotrypsin senses both indole binding and pH changes directly; the same label in anhydrochymotrypsin responds directly only to changes in pH. Neither histidine-labeled derivative exhibits enzymic activity. The electron paramagnetic resonance spectra of these two labeled proteins at high pH indicate a decrease in the motional freedom of the spin label. The spectral data show that the conformational state of the labeled zymogen is not similar to the high-pH conformational state of the labeled enzyme. Furthermore, the pH-dependent conformational transition of labeled chymotrypsin requires neither the serine 195 hydroxyl nor the histidine 57 imidazole, since the transition occurs normally in derivatized and chemically modified protein forms. The chemical reactivity of histidine 57 in anhydrochymotrypsin is evaluated and the catalytic activities of two histidine alkylated enzymes are compared.     

The role of the environment around the catalytic triad in β-trypsin: A molecular orbital study

In the enzymatic reaction of β-trypsin the role of environment around the catalytic triad is studied by means of ab initio molecular orbital calculations. The triple ion form of the catalytic triad (Asp 102(?)-His 57(+)-Ser 195(?)) is considerably more stable than the double proton-transferred form (Asp 102(neutral)-His 57(neutral)-Ser 195(?)), due to the environment around it, rather than its nature. The “electrostatic mechanism” is more favorable than the “charge relay mechanism” owing to the nature of the enzyme as a biopolymer.     

13C and 1H NMR studies of ionizations and hydrogen bonding in chymotrypsin-glyoxal inhibitor complexes

Benzyloxycarbonyl (Z)-Ala-Pro-Phe-glyoxal and Z-Ala-Ala-Phe-glyoxal have both been shown to be inhibitors of alpha-chymotrypsin with minimal Ki values of 19 and 344 nM, respectively, at neutral pH. These Ki values increased at low and high pH with pKa values of approximately 4.0 and approximately 10.5, respectively. By using surface plasmon resonance, we show that the apparent association rate constant for Z-Ala-Pro-Phe-glyoxal is much lower than the value expected for a diffusion-controlled reaction. 13C NMR has been used to show that at low pH the glyoxal keto carbon is sp3-hybridized with a chemical shift of approximately 100.7 ppm and that the aldehyde carbon is hydrated with a chemical shift of approximately 91.6 ppm. The signal at approximately 100.7 ppm is assigned to the hemiketal formed between the hydroxy group of serine 195 and the keto carbon of the glyoxal. In a slow exchange process controlled by a pKa of approximately 4.5, the aldehyde carbon dehydrates to give a signal at approximately 205.5 ppm and the hemiketal forms an oxyanion at approximately 107.0 ppm. At higher pH, the re-hydration of the glyoxal aldehyde carbon leads to the signal at 107 ppm being replaced by a signal at 104 ppm (pKa approximately 9.2). On binding either Z-Ala-Pro-Phe-glyoxal or Z-Ala-Ala-Phe-glyoxal to alpha-chymotrypsin at 4 and 25 degrees C, 1H NMR is used to show that the binding of these glyoxal inhibitors raises the pKa value of the imidazolium ion of histidine 57 to a value of >11 at both 4 and 25 degrees C. We discuss the mechanistic significance of these results, and we propose that it is ligand binding that raises the pKa value of the imidazolium ring of histidine 57 allowing it to enhance the nucleophilicity of the hydroxy group of the active site serine 195 and lower the pKa value of the oxyanion forming a zwitterionic tetrahedral intermediate during catalysis.     

Amino acid sequence of bovine protein Z: a vitamin K-dependent serine protease homolog

The amino acid sequence of protein Z has been determined from sequence analysis performed on fragments obtained by chemical and enzymatic degradations. The polypeptide consists of a single chain containing 396 amino acid residues (Mr 43 677). Comparison with the vitamin K-dependent plasma proteins reveals an extensive homology. The N-terminal part, containing 13 gamma-carboxyglutamic acid and one beta-hydroxyaspartic acid residue, is extensively homologous to and of similar length to the light chain of factor X. The remainder of protein Z is homologous to the serine proteases and of similar size to the heavy chain of factor Xa, but of the active site residues only aspartic acid-102 is present. Histidine-57 and serine-195 are replaced in protein Z by threonine and alanine, respectively. The physiological function of protein Z is still uncertain.     

Crystal structures of two engineered thiol trypsins

We have determined the three-dimensional structures of engineered rat trypsins which mimic the active sites of two classes of cysteine proteases. The catalytic serine was replaced with cysteine (S195C) to test the ability of sulfur to function as a nucleophile in a serine protease environment. This variant mimics the cysteine trypsin class of thiol proteases. An additional mutation of the active site aspartate to an asparagine (D102N) created the catalytic triad of the papain-type cysteine proteases. Rat trypsins S195C and D102N,S195C were solved to 2.5 and 2.0 A, respectively. The refined structures were analyzed to determine the structural basis for the 10(6)-fold loss of activity of trypsin S195C and the 10(8)-fold loss of activity of trypsin D102N,S195C, relative to rat trypsin. The active site thiols were found in a reduced state in contrast to the oxidized thiols found in previous thiol protease structures. These are the first reported structures of serine proteases with the catalytic centers of sulfhydryl proteases. Structure analysis revealed only subtle global changes in enzyme conformation. The substrate binding pocket is unaltered, and active site amino acid 102 forms hydrogen bonds to H57 and S214 as well as to the backbone amides of A56 and H57. In trypsin S195C, D102 is a hydrogen-bond acceptor for H57 which allows the other imidazole nitrogen to function as a base during catalysis. In trypsin D102N,S195C, the asparagine at position 102 is a hydrogen-bond donor to H57 which places a proton on the imidazole nitrogen proximal to the nucleophile. This tautomer of H57 is unable to act as a base in catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)