Important role of the cys-191 cys-220 disulfide bond in thrombin function and allostery

Little is known on the role of disulfide bonds in the catalytic domain of serine proteases. The Cys-191-Cys-220 disulfide bond is located between the 190 strand leading to the oxyanion hole and the 220-loop that contributes to the architecture of the primary specificity pocket and the Na+ binding site in allosteric proteases. Removal of this bond in thrombin produces an approximately 100-fold loss of activity toward several chromogenic and natural substrates carrying Arg or Lys at P1. Na+ activation is compromised, and no fluorescence change can be detected in response to Na+ binding. A 1.54-A resolution structure of the C191A/C220A mutant in the free form reveals a conformation similar to the Na+-free slow form of wild type. The lack of disulfide bond exposes the side chain of Asp-189 to solvent, flips the backbone O atom of Gly-219, and generates disorder in portions of the 186 and 220 loops defining the Na+ site. This conformation, featuring perturbation of the Na+ site but with the active site accessible to substrate, offers a possible representation of the recently identified E* form of thrombin. Disorder in the 186 and 220 loops and the flip of Gly-219 are corrected by the active site inhibitor H-D-Phe-Pro-Arg-CH(2)Cl, as revealed by the 1.8-A resolution structure of the complex. We conclude that the Cys-191-Cys-220 disulfide bond confers stability to the primary specificity pocket by shielding Asp-189 from the solvent and orients the backbone O atom of Gly-219 for optimal substrate binding. In addition, the disulfide bond stabilizes the 186 and 220 loops that are critical for Na+ binding and activation.     

Thrombomodulin changes the molecular surface of interaction and the rate of complex formation between thrombin and protein C

The interaction of thrombin with protein C triggers a key down-regulatory process of the coagulation cascade. Using a panel of 77 Ala mutants, we have mapped the epitope of thrombin recognizing protein C in the absence or presence of the cofactor thrombomodulin. Residues around the Na(+) site (Thr-172, Lys-224, Tyr-225, and Gly-226), the aryl binding site (Tyr-60a), the primary specificity pocket (Asp-189), and the oxyanion hole (Gly-193) hold most of the favorable contributions to protein C recognition by thrombin, whereas a patch of residues in the 30-loop (Arg-35 and Pro-37) and 60-loop (Phe-60h) regions produces unfavorable contributions to binding. The shape of the epitope changes drastically in the presence of thrombomodulin. The unfavorable contributions to binding disappear and the number of residues promoting the thrombin-protein C interaction is reduced to Tyr-60a and Asp-189. Kinetic studies of protein C activation as a function of temperature reveal that thrombomodulin increases >1,000-fold the rate of diffusion of protein C into the thrombin active site and lowers the activation barrier for this process by 4 kcal/mol. We propose that the mechanism of thrombomodulin action is to kinetically facilitate the productive encounter of thrombin and protein C and to allosterically change the conformation of the activation peptide of protein C for optimal presentation to the thrombin active site.     

Mutant N143P Reveals How Na+ Activates Thrombin

The molecular mechanism of thrombin activation by Na⁺ remains elusive. Its kinetic formulation requires extension of the classical Botts-Morales theory for the action of a modifier on an enzyme to correctly account for the contribution of the E*, E, and E:Na⁺ forms. The extended scheme establishes that analysis of k_cat unequivocally identifies allosteric transduction of Na⁺ binding into enhanced catalytic activity. The thrombin mutant N143P features no Na⁺-dependent enhancement of k_cat yet binds Na⁺ with an affinity comparable to that of wild type. Crystal structures of the mutant in the presence and absence of Na⁺ confirm that Pro¹⁴³ abrogates the important H-bond between the backbone N atom of residue 143 and the carbonyl O atom of Glu¹⁹², which in turn controls the orientation of the Glu¹⁹²-Gly¹⁹³ peptide bond and the correct architecture of the oxyanion hole. We conclude that Na⁺ activates thrombin by securing the correct orientation of the Glu¹⁹²-Gly¹⁹³ peptide bond, which is likely flipped in the absence of cation. Absolute conservation of the 143–192 H-bond in trypsin-like proteases and the importance of the oxyanion hole in protease function suggest that this mechanism of Na⁺ activation is present in all Na⁺-activated trypsin-like proteases.     

Structural role of Gly(193) in serine proteases: investigations of a G555E (GLY193 in chymotrypsin) mutant of blood coagulation factor XI

In serine proteases, Gly(193) is highly conserved with few exceptions. A patient with inherited deficiency of the coagulation serine protease factor XI (FXI) was reported to be homozygous for a Gly(555) --> Glu substitution. Gly(555) in FXI corresponds to Gly(193) in chymotrypsin, which is the numbering system used subsequently. To investigate the abnormality in FXI(G193E), we expressed and purified recombinant FXIa(G193E), activated it to FXIa(G193E), and compared its activity to wild type-activated FXI (FXIa(WT)). FXIa(G193E) activated FIX with approximately 300-fold reduced k(cat) and similar K(m), and hydrolyzed synthetic substrate with approximately 10-fold reduced K(m) and modestly reduced k(cat). Binding of antithrombin and the amyloid beta-precursor protein Kunitz domain inhibitor (APPI) to FXIa(G193E) was impaired approximately 8000- and approximately 100000-fold, respectively. FXIa(G193E) inhibition by diisopropyl fluoro-phosphate was approximately 30-fold slower and affinity for p-aminobenzamidine (S1 site probe) was 6-fold weaker than for FXIa(WT). The rate of carbamylation of NH(2)-Ile(16), which forms a salt bridge with Asp(194) in active serine proteases, was 4-fold faster for FXIa(G193E). These data indicate that the unoccupied active site of FXIa(G193E) is incompletely formed, and the amide N of Glu(193) may not point toward the oxyanion hole. Inclusion of saturating amounts of p-aminobenzamidine resulted in comparable rates of carbamylation for FXIa(WT) and FXIa(G193E), suggesting that the occupied active site has near normal conformation. Thus, binding of small synthetic substrates or inhibitors provides sufficient energy to allow the amide N of Glu(193) to point correctly toward the oxyanion hole. Homology modeling also indicates that the inability of FXIa(G193E) to bind antithrombin/APPI or activate FIX is caused, in part, by impaired accessibility of the S2' site because of a steric clash with Glu(193). Such arguments will apply to other serine proteases with substitutions of Gly(193) with a non-glycine residue.     

Crystal structure of enteropeptidase light chain complexed with an analog of the trypsinogen activation peptide.

Enteropeptidase is a membrane-bound serine protease that initiates the activation of pancreatic hydrolases by cleaving and activating trypsinogen. The enzyme is remarkably specific and cleaves after lysine residues of peptidyl substrates that resemble trypsinogen activation peptides such as Val-(Asp)4-Lys. To characterize the determinants of substrate specificity, we solved the crystal structure of the bovine enteropeptidase catalytic domain to 2.3 A resolution in complex with the inhibitor Val-(Asp)4-Lys-chloromethane. The catalytic mechanism and contacts with lysine at substrate position P1 are conserved with other trypsin-like serine proteases. However, the aspartyl residues at positions P2-P4 of the inhibitor interact with the enzyme surface mainly through salt bridges with the Nzeta atom of Lys99. Mutation of Lys99 to Ala, or acetylation with acetic anhydride, specifically prevented the cleavage of trypsinogen or Gly-(Asp)4-Lys-beta-naphthylamide and reduced the rate of inhibition by Val-(Asp)4-Lys-chloromethane 22 to 90-fold. For these reactions, Lys99 was calculated to account for 1.8 to 2.5 kcal mol(-1) of the free energy of transition state binding. Thus, a unique basic exosite on the enteropeptidase surface has evolved to facilitate the cleavage of its physiological substrate, trypsinogen.     

The importance of a distal hydrogen bonding group in stabilizing the transition state in subtilisin BPN'

Stabilization of an oxyanion transition state is important to catalysis of peptide bond hydrolysis in all proteases. For subtilisin BPN', a bacterial serine protease, structural data suggest that two hydrogen bonds stabilize the tetrahedral-like oxyanion intermediate: one from the main chain NH of Ser221 and another from the side chain NH2 of Asn155. Molecular dynamic studies (Rao, S., N., Singh, U., C. Bush, P. A., and Kollman, P. A. (1987) Nature 328, 551-554) have indicated the gamma-hydroxyl of Thr220 may be a third hydrogen bond donor even though it is 4A away in the static x-ray structure. We have probed the role of Thr220 by replacing it with serine, cysteine, valine, or alanine by site-directed mutagenesis. These substitutions were intended to alter the size and hydrogen bonding ability of residue 220. Removal of the gamma-hydroxyl group reduced the transition state stabilization energy (delta delta GT) by 1.8-2.1 kcal/mol depending upon the substitution. By comparison, removal of the gamma-methyl group in the Thr220 to serine mutation only decreased delta GT by 0.5 kcal/mol. The gamma-hydroxyl of Thr220 is most important for catalysis, not substrate binding, because virtually all of the effects were on kcat and not KM. The role of the Thr220 hydroxyl is functionally independent from the amide NH2 of Asn155 because the free energy effects of double alanine mutants at these two positions are additive. These data indicate that a distal hydrogen bond donor, namely the hydroxyl of Thr220, plays a functionally important role in stabilizing the oxyanion transition state in subtilisin which is independent of Asn155.     

Contribution of the glutamine 19 side chain to transition-state stabilization in the oxyanion hole of papain

The existence of an oxyanion hole in cysteine proteases able to stabilize a transition-state complex in a manner analogous to that found with serine proteases has been the object of controversy for many years. In papain, the side chain of Gln19 forms one of the hydrogen-bond donors in the putative oxyanion hole, and its contribution to transition-state stabilization has been evaluated by site-directed mutagenesis. Mutation of Gln19 to Ala caused a decrease in kcat/KM for hydrolysis of CBZ-Phe-Arg-MCA, which is 7700 M-1 s-1 in the mutant enzyme as compared to 464,000 M-1 s-1 in wild-type papain. With a Gln19Ser variant, the activity is even lower, with a kcat/KM value of 760 M-1 s-1. The 60- and 600-fold decreases in kcat/KM correspond to changes in free energy of catalysis of 2.4 and 3.8 kcal/mol for Gln19Ala and Gln19Ser, respectively. In both cases, the decrease in activity is in large part attributable to a decrease in kcat, while KM values are only slightly affected. These results indicate that the oxyanion hole is operational in the papain-catalyzed hydrolysis of CBZ-Phe-Arg-MCA and constitute the first direct evidence of a mechanistic requirement for oxyanion stabilization in the transition state of reactions catalyzed by cysteine proteases. The equilibrium constants Ki for inhibition of the papain mutants by the aldehyde Ac-Phe-Gly-CHO have also been determined. Contrary to the results with the substrate, mutation at position 19 of papain has a very small effect on binding of the inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)     

New structural motifs on the chymotrypsin fold and their potential roles in complement factor B

Factor B and C2 are two central enzymes for complement activation. They are multidomain serine proteases and require cofactor binding for full expression of proteolytic activities. We present a 2.1 A crystal structure of the serine protease domain of factor B. It shows a number of structural motifs novel to the chymotrypsin fold, which by sequence homology are probably present in C2 as well. These motifs distribute characteristically on the protein surface. Six loops surround the active site, four of which shape substrate-binding pockets. Three loops next to the oxyanion hole, which typically mediate zymogen activation, are much shorter or absent. Three insertions including the linker to the preceding domain bulge from the side opposite to the active site. The catalytic triad and non-specific substrate-binding site display active conformations, but the oxyanion hole displays a zymogen-like conformation. The bottom of the S1 pocket has a negative charge at residue 226 instead of the typical 189 position. These unique structural features may play different roles in domain-domain interaction, cofactor binding and substrate binding.     

Substitution of valine for glycine-558 in the congenital dysthrombin thrombin Quick II alters primary substrate specificity

Thrombin Quick II is one of two dysfunctional forms of thrombin derived from the previously described congenital dysprothrombin prothrombin Quick. Thrombin Quick II does not clot fibrinogen, hydrolyze p-nitroanilide substrates of thrombin, or bind N2-[5-(dimethylamino)naphthalene-1-sulfonyl]arginine N,N-(3-ethyl-1,5-pentanediyl)amide, a high-affinity competitive inhibitor of thrombin. To determine the structural alteration in thrombin Quick II, the reduced, carboxymethylated protein was hydrolyzed by a lysyl endopeptidase. A peptide not present in a parallel thrombin hydrolysate was identified by reverse-phase chromatography. The peptide was purified by rechromatography and subjected to Edman degradation which showed that Gly-558 of human prothrombin had been replaced by Val. This corresponds to a point mutation of the Gly codon GGC to GUC. This Gly residue, which is highly conserved in the chymotrypsin family of serine proteases, forms part of the substrate binding pocket for bulky aromatic and basic side chains in chymotrypsin and trypsin, respectively. However, in porcine elastase 1, the corresponding residue is threonine. Consistent with the identified structural alteration, thrombin Quick II incorporates [3H]diisopropyl fluorophosphate stoichiometrically and hydrolyzes the elastase substrate succinyl-Ala-Ala-Pro-Leu-p-nitroanilide with a relative kcat/KM of 0.14 when compared to thrombin. This results from a 3-fold increase in KM and a 2.5-fold decrease in kcat for thrombin Quick II when compared to thrombin acting on the same substrate. These results and those of other investigators studying mutant trypsins support the conclusion that the catalytic activity of serine proteases is very sensitive to structural alterations in the primary substrate binding pocket.     

Cleavage of peptidic inhibitors by target protease is caused by peptide conformational transition

Some peptide sequences can behave as either substrates or inhibitors of serine proteases. Working with a cyclic peptidic inhibitor of the serine protease urokinase-type plasminogen activator (uPA), we have now demonstrated a new mechanism for an inhibitor-to-substrate switch. The peptide, CSWRGLENHAAC (upain-2), is a competitive inhibitor of human uPA, but is also slowly converted to a substrate in which the bond between Arg⁴ and Gly⁵ (the P1-P1′ bond) is cleaved. Substituting the P2 residue Trp³ to an Ala or substituting the P1 Arg⁴ residue with 4-guanidino-phenylalanine strongly increased the substrate cleavage rate. We studied the structural basis for the inhibitor-to-substrate switch by determining the crystal structures of the various peptide variants in complex with the catalytic domain of uPA. While the slowly cleaved peptides bound clearly in inhibitory mode, with the oxyanion hole blocked by the side chain of the P3′ residue Glu⁷, peptides behaving essentially as substrates with a much accelerated rate of cleavage was observed to be bound to the enzyme in substrate mode. Our analysis reveals that the inhibitor-to-substrate switch was associated with a 7?Å translocation of the P2 residue, and we conclude that the inhibitor-to-substrate switch of upain-2 is a result of a major conformational change in the enzyme-bound state of the peptide. This conclusion is in contrast to findings with so-called standard mechanism inhibitors in which the inhibitor-to-substrate switch is linked to minor conformational changes in the backbone of the inhibitory peptide stretch.     

Roles of catalytic residues in alpha-amylases as evidenced by the structures of the product-complexed mutants of a maltotetraose-forming amylase.

The crystal structures of the four product-complexed single mutants of the catalytic residues of Pseudomonas stutzeri maltotetraose-forming alpha-amylase, E219G, D193N, D193G and D294N, have been determined. Possible roles of the catalytic residues Glu219, Asp193 and Asp294 have been discussed by comparing the structures among the previously determined complexed mutant E219Q and the present mutant enzymes. The results suggested that Asp193 predominantly works as the base catalyst (nucleophile), whose side chain atom lies in close proximity to the C1-atom of Glc4, being involved in the intermediate formation in the hydrolysis reaction. While Asp294 works for tightly binding the substrate to give a twisted and a deformed conformation of the glucose ring at position -1 (Glc4). The hydrogen bond between the side chain atom of Glu219 and the O1-atom of Glc4, that implies the possibility of interaction via hydrogen, consistently present throughout these analyses, supports the generally accepted role of this residue as the acid catalyst (proton donor).     

Cooperativity of papain-substrate interaction energies in the S2 to S2' subsites

Enzyme-substrate contacts in the hydrolysis of ester substrates by the cysteine protease papain were investigated by systematically altering backbone hydrogen-bonding and side-chain hydrophobic contacts in the substrate and determining each substrate's kinetic constants. The observed specificity energies [defined as delta delta G obs = -RT ln [(kcat/KM)first/(kcat/KM)second)]] of the substrate backbone hydrogen bonds were -2.7 kcal/mol for the P2 NH and -2.6 kcal/mol for the P1 NH when compared against substrates containing esters at those sites. The observed binding energies were -4.0 kcal/mol for the P2 Phe side chain, -1.0 kcal/mol for the P1' C=O, and -2.3 kcal/mol for the P2' NH. The latter three values probably all significantly underestimate the incremental binding energies. The P2 NH, P2 Phe side-chain, and P1 NH contacts display a strong interdependence, or cooperativity, of interaction energies that is characteristic of enzyme-substrate interactions. This interdependence arises largely from the entropic cost of forming the enzyme-substrate transition state. As favorable contacts are added successively to a substrate, the entropic penalty associated with each decreases and the free energy expressed approaches the incremental interaction energy. This is the first report of a graded cooperative effect. Elucidation of favorable enzyme-substrate contacts remote from the catalytic site will assist in the design of highly specific cysteine protease inhibitors.     

Hirudin binding reveals key determinants of thrombin allostery

Thrombin exists in two allosteric forms, slow (S) and fast (F), that recognize natural substrates and inhibitors with significantly different affinities. Because under physiologic conditions the two forms are almost equally populated, investigation of thrombin function must address the contribution from the S and F forms and the molecular origin of their differential recognition of ligands. Using a panel of 79 Ala mutants, we have mapped for the first time the epitopes of thrombin recognizing a macromolecular ligand, hirudin, in the S and F forms. Hirudin binding is a relevant model for the interaction of thrombin with fibrinogen and PAR1 and is likewise influenced by the allosteric S-->F transition. The epitopes are nearly identical and encompass two hot spots, one in exosite I and the other in the Na+ site at the opposite end of the protein. The higher affinity of the F form is due to the preferential interaction of hirudin with Lys-36, Leu-65, Thr-74, and Arg-75 in exosite I; Gly-193 in the oxyanion hole; and Asp-221 and Asp-222 in the Na+ site. Remarkably, no correlation is found between the energetic and structural involvements of thrombin residues in hirudin recognition, which invites caution in the analysis of protein-protein interactions in general.     

Contribution of peptide bonds to inhibitor-protease binding: crystal structures of the turkey ovomucoid third domain backbone variants OMTKY3-Pro18I and OMTKY3-psi[COO]-Leu18I in complex with Streptomyces griseus proteinase B (SGPB) and the structure of the free inhibitor, OMTKY-3-psi[CH2NH2+]-Asp19I

X-ray crystallography has been used to determine the 3D structures of two complexes between Streptomyces griseus proteinase B (SGPB), a bacterial serine proteinase, and backbone variants of turkey ovomucoid third domain (OMTKY3). The natural P1 residue (Leu18I) has been substituted by a proline residue (OMTKY3-Pro18I) and in the second variant, the peptide bond between Thr17I and Leu18I was replaced by an ester bond (OMTKY3-psi[COO]-Leu18I). Both variants lack the P1 NH group that donates a bifurcated hydrogen bond to the carbonyl O of Ser214 and O(gamma) of the catalytic Ser195, one of the common interactions between serine proteinases and their canonical inhibitors. The SGPB:OMTKY3-Pro18I complex has many structural differences in the vicinity of the S1 pocket when compared with the previously determined structure of SGPB:OMTKY3-Leu18I. The result is a huge difference in the DeltaG degrees of binding (8.3 kcal/mol), only part of which can be attributed to the missing hydrogen bond. In contrast, very little structural difference exists between the complexes of SGPB:OMTKY3-psi[COO]-Leu18I and SGPB:OMTKY3-Leu18I, aside from an ester O replacing the P1 NH group. Therefore, the difference in DeltaG degrees, 1.5 kcal/mol as calculated from the measured equilibrium association constants, can be attributed to the contribution of the P1 NH hydrogen bond toward binding. A crystal structure of OMTKY3 having a reduced peptide bond between P1 Leu18I and P'1 Asp19I, (OMTKY3-psi[CH2NH2+]-Asp19I) has also been determined by X-ray crystallography. This variant has very weak association equilibrium constants with SGPB and with chymotrypsin. The structure of the free inhibitor suggests that the reduced peptide bond has not introduced any major structural changes in the inhibitor. Therefore, its poor ability to inhibit serine proteinases is likely due to the disruptions of the canonical interactions at the oxyanion hole.     

Testing electrostatic complementarity in enzyme catalysis: hydrogen bonding in the ketosteroid isomerase oxyanion hole

A longstanding proposal in enzymology is that enzymes are electrostatically and geometrically complementary to the transition states of the reactions they catalyze and that this complementarity contributes to catalysis. Experimental evaluation of this contribution, however, has been difficult. We have systematically dissected the potential contribution to catalysis from electrostatic complementarity in ketosteroid isomerase. Phenolates, analogs of the transition state and reaction intermediate, bind and accept two hydrogen bonds in an active site oxyanion hole. The binding of substituted phenolates of constant molecular shape but increasing p K _a models the charge accumulation in the oxyanion hole during the enzymatic reaction. As charge localization increases, the NMR chemical shifts of protons involved in oxyanion hole hydrogen bonds increase by 0.50–0.76 ppm/p K _a unit, suggesting a bond shortening of ˜0.02 Å/p K _a unit. Nevertheless, there is little change in binding affinity across a series of substituted phenolates (ΔΔG = −0.2 kcal/mol/p K _a unit). The small effect of increased charge localization on affinity occurs despite the shortening of the hydrogen bonds and a large favorable change in binding enthalpy (ΔΔH = −2.0 kcal/mol/p K _a unit). This shallow dependence of binding affinity suggests that electrostatic complementarity in the oxyanion hole makes at most a modest contribution to catalysis of ˜300-fold. We propose that geometrical complementarity between the oxyanion hole hydrogen-bond donors and the transition state oxyanion provides a significant catalytic contribution, and suggest that KSI, like other enzymes, achieves its catalytic prowess through a combination of modest contributions from several mechanisms rather than from a single dominant contribution.     

Role of P225 and the C136-C201 disulfide bond in tissue plasminogen activator

The protease domain of tissue plasminogen activator (tPA), a key fibrinolytic enzyme, was expressed in Escherichia coli with a yield of 1 mg per liter of media. The recombinant protein was titrated with the Erythrina caraffa trypsin inhibitor (ETI) and characterized in its interaction with plasminogen and the natural inhibitor plasminogen activator inhibitor-1 (PAI-1). Analysis of the catalytic properties of tPA using a library of chromogenic substrates carrying substitutions at P1, P2, and P3 reveals a strong preference for Arg over Lys at P1, unmatched by other serine proteases like thrombin or trypsin. In contrast to these proteases and plasmin, tPA shows little or no preference for Pro over Gly at P2. A specific inhibition of tPA by Cu2+ was discovered. The divalent cation presumably binds to H188 near D189 in the primary specificity pocket and inhibits substrate binding in a competitive manner with a Kd = 19 microM. In an attempt to engineer Na+ binding and enhanced catalytic activity in tPA, P225 was replaced with Tyr, the residue present in Na+-dependent allosteric serine proteases. The P225Y mutation did not result in cation binding, but caused a significant loss of specificity (up to 100-fold) toward chromogenic substrates and plasminogen and considerably reduced the inhibition by PAI-1 and ETI. Interestingly, the P225Y substitution enhanced the ability of Cu2+ to inhibit the enzyme. Elimination of the C136-C201 disulfide bond, that is absent in all Na+-dependent allosteric serine proteases, significantly enhanced the yield (5 mg per liter of media) of expression in E. coli, but caused no changes in the properties of the enzyme whether residue 225 was Pro or Tyr. These findings point out an unanticipated crucial role for residue 225 in controlling the catalytic activity of tPA, and suggest that engineering of a Na+-dependent allosteric enhancement of catalytic activity in this enzyme, must involve substantial changes in the region homologous to the Na+ binding site of allosteric serine proteases.     

Enzymatic activity of the Staphylococcus aureus SplB serine protease is induced by substrates containing the sequence Trp-Glu-Leu-Gln

Proteases are of significant importance for the virulence of Staphylococcus aureus. Nevertheless, their subset, the serine protease-like proteins, remains poorly characterized. Here presented is an investigation of SplB protease catalytic activity revealing that the enzyme possesses exquisite specificity and only cleaves efficiently after the sequence Trp-Glu-Leu-Gln. To understand the molecular basis for such selectivity, we solved the three-dimensional structure of SplB to 1.8 Å. Modeling of substrate binding to the protease demonstrated that selectivity relies in part on a canonical specificity pockets-based mechanism. Significantly, the conformation of residues that ordinarily form the oxyanion hole, an essential structural element of the catalytic machinery of serine proteases, is not canonical in the SplB structure. We postulate that within SplB, the oxyanion hole is only formed upon docking of a substrate containing the consensus sequence motif. It is suggested that this unusual activation mechanism is used in parallel with classical determinants to further limit enzyme specificity. Finally, to guide future development, we attempt to point at likely physiological substrates and thus the role of SplB in staphylococcal physiology.     

Mutational evidence of transition state stabilization by serine 88 in Escherichia coli type I signal peptidase

Type I signal peptidase (SPase I) catalyzes the hydrolytic cleavage of the N-terminal signal peptide from translocated preproteins. SPase I belongs to a novel class of Ser proteases that utilize a Ser/Lys dyad catalytic mechanism instead of the classical Ser/His/Asp triad found in most Ser proteases. Recent X-ray crystallographic studies indicate that the backbone amide nitrogen of the catalytic Ser 90 and the hydroxyl side chain of Ser 88 might participate as H-bond donors in the transition-state oxyanion hole. In this work, contribution of the side-chain Ser 88 in Escherichia coli SPase I to the stabilization of the transition state was investigated through in vivo and in vitro characterizations of Ala-, Cys-, and Thr-substituted mutants. The S88T mutant maintains near-wild-type activity with the substrate pro-OmpA nuclease A. In contrast, substitution with Cys at position 88 results in more than a 740-fold reduction in activity (k(cat)) whereas S88A retains much less activity (>2440-fold decrease). Measurements of the kinetic constants of the individual mutant enzymes indicate that these decreases in activity are attributed mainly to decreases in k(cat) while effects on K(m) are minimal. Thermal inactivation and CD spectroscopic analyses indicate no global conformational perturbations of the Ser 88 mutants relative to the wild-type E. coli SPase I enzyme. These results provide strong evidence for the stabilization by Ser 88 of the oxyanion intermediate during catalysis by E. coli SPase I.     

Enzyme:substrate hydrogen bond shortening during the acylation phase of serine protease catalysis

Atomic resolution (相似文献   

Elucidation of the role of arginine-244 in the turnover processes of class A beta-lactamases.

The highly conserved arginine-244 of beta-lactamases has been postulated to play a role in their initial recognition of substrates, presumably through ion pairing interactions [Moews, P. C., Knox, J. R., Dideberg, O., Charlier, P., & Frère, J. M. (1990) Proteins: Struct., Funct., Genet. 7, 156-171]. However, in the Michaelis enzyme-substrate complex, no direct function has been attributed to this residue. Two mutants with substitutions of this residue in the TEM-1 beta-lactamase (lysine-244 and serine-244) have been prepared to explore whether the guanidinium group of arginine-244 plays a critical role in the turnover processes. The mutant enzymes are effective catalysts for the hydrolysis of both penicillins and cephalosporins, and the lysine mutant enzyme behaves virtually identically to the wild-type beta-lactamase. Comparative kinetic characterization of the serine mutant and wild-type enzymes attributed apparent binding energies of 1.3-2.3 kcal/mol for the penicillins and 0.3-1.0 kcal/mol for the cephalosporins to the transition-state species by arginine-244. Furthermore, it was shown that arginine-244 also contributes equally well to ground-state binding stabilization. These results were interpreted to indicate the involvement of a long hydrogen bond between arginine-244 and the substrate carboxylate, both in the ground and transition states. A reassessed picture for substrate anchoring involving interactions of the substrate carboxylate with the side chains of Ser-130, Ser-235, and Arg-244 is proposed to accommodate these observations.