Consequences of breaking the Asp-His hydrogen bond of the catalytic triad: effects on the structure and dynamics of the serine esterase cutinase.

The objective of this study has been to investigate the effects on the structure and dynamics that take place with the breaking of the Asp-His hydrogen bond in the catalytic triad Asp175-His188-Ser120 of the serine esterase cutinase in the ground state. Four molecular dynamics simulations were performed on this enzyme in solution. The starting structures in two simulations had the Asp175-His188 hydrogen bond intact, and in two simulations the Asp175-His188 hydrogen bond was broken. Conformations of the residues comprising the catalytic triad are well behaved during both simulations containing the intact Asp175-His188 hydrogen bond. Short contacts of less than 2.6 A were observed in 1.2% of the sampled distances between the carboxylate oxygens of Asp175 and the NE2 of His188. The simulations showed that the active site residues exhibit a great deal of mobility when the Asp175-His188 hydrogen bond is broken. In the two simulations in which the Asp175-His188 hydrogen bond is not present, the final geometries for the residues in the catalytic triad are not in catalytically productive conformations. In both simulations, Asp175 and His188 are more than 6 A apart in the final structure from dynamics, and the side chains of Ser120 and Asp175 are in closer proximity to the NE2 of His188 than to ND1. Nonlocal effects on the structure of cutinase were observed. A loop formed by residues 26-31, which is on the opposite end of the protein relative to the active site, was greatly affected. Further changes in the dynamics of cutinase were determined from quasiharmonic mode analysis. The frequency of the second lowest mode was greatly reduced when the Asp175-His188 hydrogen bond was broken, and several higher modes showed lower frequencies. All four simulations showed that the oxyanion hole, composed of residues Ser42 and Gln121, is stable. Only one of the hydrogen bonds (Ser42 OG to Gln121 NE2) observed in the crystal structure that stabilize the conformation of Ser42 OG persisted throughout the simulations. This hydrogen bond appears to be enough for the oxyanion hole to retain its structural integrity.     

Quantum chemical study of the "catalytic triad" of serine proteases

Using the semi-empirical MNDO/H method several systems simulating the reaction of tetrahedral intermediate formation in the active site of serine proteases have been studied. The role played by elements of the "catalytic triad" in increasing the reactivity of serine hydroxyl has been discussed. The formation of a strong hydrogen bond between His and Asp was shown to be important in lowering the activation energy in the reaction of Ser with substrate. The change in position of the proton located between Ser and His and between His and Asp was analysed. The influence of substrate distortion on the energy of intermediate formation has been considered.     

Refined atomic model of wheat serine carboxypeptidase II at 2.2-A resolution.

The crystal structure of the homodimeric serine carboxypeptidase II from wheat (CPDW-II, M(r) 120K) has been determined and fully refined at 2.2-A resolution to a standard crystallographic R factor of 16.9% using synchrotron data collected at the Brookhaven National Laboratory. The model has an rms deviation from ideal bond lengths of 0.018 A and from bond angles of 2.8 degrees. The model supports the general conclusions of an earlier study at 3.5-A resolution and will form the basis for investigation into substrate binding and mechanistic studies. The enzyme has an alpha + beta fold, consisting of a central 11-stranded beta-sheet with a total of 15 helices on either side. The enzyme, like other serine proteinases, contains a "catalytic triad" Ser146-His397-Asp338 and a presumed "oxyanion hole" consisting of the backbone amides of Tyr147 and Gly53. The carboxylate of Asp338 and imidazole of His397 are not coplanar in contrast to the other serine proteinases. A comparison of the active site features of the three families of serine proteinases suggests that the "catalytic triad" should actually be regarded as two diads, a His-Asp diad and a His-Ser diad, and that the relative orientation of one diad with respect to the other is not particularly important. Four active site residues (52, 53, 65, and 146) have unfavorable backbone conformations but have well-defined electron density, suggesting that there is some strain in the active site region. The binding of the free amino acid arginine has been analyzed by difference Fourier methods, locating the binding site for the C-terminal carboxylate of the leaving group. The carboxylate makes hydrogen bonds to Glu145, Asn51, and the amide of Gly52. The carboxylate of Glu145 also makes a hydrogen bond with that of Glu65, suggesting that one or both may be protonated. Thus, the loss of peptidase activity at pH > 7 may in part be due to deprotonation of Glu145. The active site does not reveal exposed peptide amides and carbonyl oxygen atoms that could interact with substrate in an extended beta-sheet fashion. The fold of the polypeptide backbone is completely different than that of trypsin or subtilisin, suggesting that this is a third example of convergent molecular evolution to a common enzymatic activity. Furthermore, it is suggested that the active site sequence motif "G-X-S-X-G/A", often considered the hallmark of serine peptidase or esterase activity, is fortuitous and not the result of divergent evolution.(ABSTRACT TRUNCATED AT 400 WORDS)     

X-ray snapshots of serine protease catalysis reveal a tetrahedral intermediate

Studies on the catalytic mechanism and inhibition of serine proteases are widely used as paradigms for teaching enzyme catalysis. Ground-breaking work on the structures of chymotrypsin and subtilisin led to the idea of a conserved catalytic triad formed by the active site Ser, His and Asp residues. An oxyanion hole, consisting of the peptide amide of the active site serine and a neighbouring glycine, was identified, and hydrogen bonding in the oxyanion hole was suggested to stabilize the two proposed tetrahedral intermediates on the catalytic pathway. Here we show electron density changes consistent with the formation of a tetrahedral intermediate during the hydrolysis of an acyl-enzyme complex formed between a natural heptapeptide and elastase. No electron density for an enzyme-product complex was observed. The structures also suggest a mechanism for the synchronization of hydrolysis and peptide release triggered by the conversion of the sp2 hybridized carbonyl carbon to an sp3 carbon in the tetrahedral intermediate. This affects the location of the peptide in the active site cleft, triggering the collapse of a hydrogen bonding network between the peptide and the beta-sheet of the active site.     

Unconventional serine proteases: variations on the catalytic Ser/His/Asp triad configuration

Serine proteases comprise nearly one-third of all known proteases identified to date and play crucial roles in a wide variety of cellular as well as extracellular functions, including the process of blood clotting, protein digestion, cell signaling, inflammation, and protein processing. Their hallmark is that they contain the so-called "classical" catalytic Ser/His/Asp triad. Although the classical serine proteases are the most widespread in nature, there exist a variety of "nonclassical" serine proteases where variations to the catalytic triad are observed. Such variations include the triads Ser/His/Glu, Ser/His/His, and Ser/Glu/Asp, and include the dyads Ser/Lys and Ser/His. Other variations are seen with certain serine and threonine peptidases of the Ntn hydrolase superfamily that carry out catalysis with a single active site residue. This work discusses the structure and function of these novel serine proteases and threonine proteases and how their catalytic machinery differs from the prototypic serine protease class.     

Structure determinants and substrate recognition of serine carboxypeptidase-like acyltransferases from plant secondary metabolism

Structures of the serine carboxypeptidase-like enzymes 1-O-sinapoyl-beta-glucose:L-malate sinapoyltransferase (SMT) and 1-O-sinapoyl-beta-glucose:choline sinapoyltransferase (SCT) were modeled to gain insight into determinants of specificity and substrate recognition. The structures reveal the alpha/beta-hydrolase fold as scaffold for the catalytic triad Ser-His-Asp. The recombinant mutants of SMT Ser173Ala and His411Ala were inactive, whereas Asp358Ala displayed residual activity of 20%. 1-O-sinapoyl-beta-glucose recognition is mediated by a network of hydrogen bonds. The glucose moiety is recognized by a hydrogen bond network including Trp71, Asn73, Glu87 and Asp172. The conserved Asp172 at the sequence position preceding the catalytic serine meets sterical requirements for the glucose moiety. The mutant Asn73Ala with a residual activity of 13% underscores the importance of the intact hydrogen bond network. Arg322 is of key importance by hydrogen bonding of 1-O-sinapoyl-beta-glucose and L-malate. By conformational change, Arg322 transfers L-malate to a position favoring its activation by His411. Accordingly, the mutant Arg322Glu showed 1% residual activity. Glu215 and Arg219 establish hydrogen bonds with the sinapoyl moiety. The backbone amide hydrogens of Gly75 and Tyr174 were shown to form the oxyanion hole, stabilizing the transition state. SCT reveals also the catalytic triad and a hydrogen bond network for 1-O-sinapoyl-beta-glucose recognition, but Glu274, Glu447, Thr445 and Cys281 are crucial for positioning of choline.     

Identification and analysis of a new family of bacterial serine proteinases

A family of hypothetical proteins, identified predominantly from archaeal genomes, has been analyzed in order to understand its functional characteristics. Using extensive sequence similarity searches it is inferred that this family is remotely related (best sequence identity is 19%) to ClpP proteinases that belongs to serine proteinase class. This family of hypothetical proteins is referred to as SDH proteinase family based on conserved sequential order of Ser, Asp and His residues and predicted serine proteinase activity. Results of fold recognition of SDH family sequences confirmed the remote relationship between SDH proteinases and Clp proteinases and revealed similar tertiary location of putative catalytic triad residues critical for serine proteinase function. However, the best sequence alignment we could obtain suggests that while catalytic Ser is conserved across Clp and SDH proteinases the location of the other catalytic triad residues, namely, His and Asp are swapped in their amino acid alignment positions and hence in 3-D structure. The evidence of conserved catalytic triad suggests that SDH could be a new family of serine proteinases with the fold of Clp proteinase, however sharing the catalytic triad order of carboxypeptidase clan. Signal peptide sequence identified at the N-terminus of some of the homologues suggests that these might be secretory serine proteinases involved in cleavage of extracellular proteins while the remote homologues, ClpP proteinases, are known to work in intracellular environment.     

Structure of wheat serine carboxypeptidase II at 3.5-A resolution. A new class of serine proteinase

The structure of serine carboxypeptidase II from wheat bran has been determined to 3.5-A resolution by multiple isomorphous replacement, solvent flattening, and crystallographic refinement. The amino acid sequence has been fit to the electron density map and the model refined to a conventional crystallographic R factor of 20.9%. The molecule is an alpha + beta protein and contains a "catalytic triad" (Asp338, His397, and Ser146) similar in arrangement to those in chymotrypsin and subtilisin. The -fold of the polypeptide backbone is, however, completely different from those enzymes. This suggests that this is a third example of convergent evolution to a common enzymatic mechanism. The -fold is, on the other hand, surprisingly similar to that of the zinc proteinase carboxypeptidase A.     

NMR studies of the hydrogen bonds involving the catalytic triad of Escherichia coli thioesterase/protease I

Escherichia coli thioesterase/protease I (TEP-I) is a lipolytic enzyme of the serine protease superfamily with Ser(10), Asp(154) and His(157) as the catalytic triad residues. Based on comparison of the low-field (1)H nuclear magnetic resonance spectra of two mutants (S10G and S12G) and two transition state analogue complexes we have assigned the exchangeable proton resonances at 16.3 ppm, 14.3 ppm, and 12.8 ppm at pH 3.5 to His(157)-N(delta1)H, Ser(10)-O(gamma)H and His(157)-N(epsilon2)H, respectively. Thus, the presence of a strong Asp(154)-His(157) hydrogen bond in free TEP-I was observed. However, Ser(10)-O(gamma)H was shown to form a H-bond with a residue other than His(157)-N(epsilon2).     

The 1.4 a crystal structure of kumamolysin: a thermostable serine-carboxyl-type proteinase

Kumamolysin is a thermostable endopeptidase from Bacillus novosp. MN-32, exhibiting maximal proteolytic activity around pH 3. It belongs to the newly identified family of serine-carboxyl proteinases, which also includes CLN2, a human lysosomal homolog recently implicated in a fatal neurodegenerative disease. Kumamolysin and its complexes with two aldehyde inhibitors were crystallized, and their three-dimensional structures were solved and refined with X-ray data to 1.4 A resolution. As its Pseudomonas homolog, kumamolysin exhibits a Ser/Glu/Asp catalytic triad with particularly short interconnecting hydrogen bonds and an oxyanion hole enabling the reactive serine to attack substrate peptide bonds at quite acidic pH. An additional Glu/Trp pair, unique to kumamolysin, might further facilitate proton delocalization during nucleophilic attack, in particular at high temperature.     

Design of a serine protease-like catalytic triad on an antibody light chain displayed on the yeast cell surface

Lc-WT, the wild-type light chain of antibody, and Lc-Triad, its double mutant with E1D and T27aS designing for the construction of catalytic triad within Asp1, Ser27a, and original His93 residues, were displayed on the cell surface of the protease-deficient yeast strain BJ2168. When each cell suspension was reacted with BODIPY FL casein and seven kinds of peptide-MCA substrates, respectively, a remarkable difference in hydrolytic activities toward Suc-GPLGP-MCA (succinyl-Gly-Pro-Leu-Gly-Pro-MCA), a substrate toward collagenase-like peptidase, was observed between the constructs: Lc-Triad-displaying cells showed higher catalytic activity than Lc-WT-displaying cells. The difference disappeared in the presence of the serine protease inhibitor diisopropylfluorophosphate, suggesting that the three amino acid residues, Ser27a, His93, and Asp1, functioned as a catalytic triad responsible for the proteolytic activity in a similar way to the anti-vasoactive intestinal peptide (VIP) antibody light chain. A serine protease-like catalytic triad (Ser, His, and Asp) is considered to be directly involved in the catalytic mechanism of the anti-VIP antibody light chain, which moderately catalyzes the hydrolysis of VIP. These results suggest the possibility of new approach for the creation of tailor-made proteases beyond limitations of the traditional immunization approach.     

Chlorophyllase as a serine hydrolase: identification of a putative catalytic triad

Chlorophyllases (Chlases), cloned so far, contain a lipase motif with the active serine residue of the catalytic triad of triglyceride lipases. Inhibitors specific for the catalytic serine residue in serine hydrolases, which include lipases effectively inhibited the activity of the recombinant Chenopodium album Chlase (CaCLH). From this evidence we assumed that the catalytic mechanism of hydrolysis by Chlase might be similar to those of serine hydrolases that have a catalytic triad composed of serine, histidine and aspartic acid in their active site. Thus, we introduced mutations into the putative catalytic residue (Ser162) and conserved amino acid residues (histidine, aspartic acid and cysteine) to generate recombinant CaCLH mutants. The three amino acid residues (Ser162, Asp191 and His262) essential for Chlase activity were identified. These results indicate that Chlase is a serine hydrolase and, by analogy with a plausible catalytic mechanism of serine hydrolases, we proposed a mechanism for hydrolysis catalyzed by Chlase.     

Breaking the low barrier hydrogen bond in a serine protease

The serine protease subtilisin BPN' is a useful catalyst for peptide synthesis when dissolved in high concentrations of a water-miscible organic co-solvent such as N,N-dimethylformamide (DMF). However, in 50% DMF, the k(cat) for amide hydrolysis is two orders of magnitude lower than in aqueous solution. Surprisingly, the k(cat) for ester hydrolysis is unchanged in 50% DMF. To explain this alteration in activity, the structure of subtilisin 8397+1 was determined in 20, 35, and 50% (v/v) DMF to 1.8 A resolution. In 50% DMF, the imidazole ring of His64, the central residue of the catalytic triad, has rotated approximately 180 degrees around the Cbeta-Cgamma bond. Two new water molecules in the active site stabilize the rotated conformation. This rotation places His64 in an unfavorable geometry to interact with the other members of the catalytic triad, Ser221 and Asp32. NMR experiments confirm that the characteristic resonance due to the low barrier hydrogen bond between the His64 and Asp32 is absent in 50% DMF. These experiments provide a clear structural basis for the change in activity of serine proteases in organic co-solvents.     

Multiple conformations of catalytic serine and histidine in acetylxylan esterase at 0.90 A

Acetylxylan esterase (AXEII; 207 amino acids) from Penicillium purpurogenum has substrate specificities toward acetate esters of d-xylopyranose residues in xylan and belongs to a new class of alpha/beta hydrolases. The crystal structure of AXEII has been determined by single isomorphous replacement and anomalous scattering, and refined at 0.90- and 1.10-A resolutions with data collected at 85 K and 295 K, respectively. The tertiary structure consists of a doubly wound alpha/beta sandwich, having a central six-stranded parallel beta-sheet flanked by two parallel alpha-helices on each side. The catalytic residues Ser(90), His(187), and Asp(175) are located at the C-terminal end of the sheet, an exposed region of the molecule. The serine and histidine side chains in the 295 K structure show the frequently observed conformations in which Ser(90) is trans and the hydroxyl group is in the plane of the imidazole ring of His(187). However, the structure at 85 K displays an additional conformation in which Ser(90) side-chain hydroxyl is away from the plane of the imidazole ring of His(187). The His(187) side chain forms a hydrogen bond with a sulfate ion and adopts an altered conformation. The only other known hydrolase that has a similar tertiary structure is Fusarium solani cutinase. The exposed nature of the catalytic triad suggests that AXEII is a pure esterase, i.e. an alpha/beta hydrolase with specificity for nonlipidic polar substrates.     

Structural relationship between lipases and peptidases of the prolyl oligopeptidase family.

In prolyl oligopeptidase and its homologues, which constitute a new serine protease family, the order of the catalytic Ser and His residues in the amino acid sequence is the reverse of what is found in the trypsin and subtilisin families. The exact position of the third member of the catalytic triad, an Asp residue, has not yet been identified in the new family. Recent determination of the three-dimensional structures of pancreatic and microbial lipases has shown that the order of their catalytic residues is Ser, Asp, His, and this fits the order Ser, His of prolyl oligopeptidase. However, there is no sequence homology between lipases and peptidases, except for a 10-residue segment, which encompasses the essential Ser, and for the immediate vicinity of the catalytic Asp and His residues. This comparison identifies the catalytic Asp residue in the prolyl oligopeptidase family. The relative positions of the three catalytic residues in peptidases and microbial lipases were the same and this indicated structural and possibly evolutionary relationship between the two families.     

Structural investigations of the active-site mutant Asn156Ala of outer membrane phospholipase A: function of the Asn-His interaction in the catalytic triad

Outer membrane phospholipase A (OMPLA) from Escherichia coli is an integral-membrane enzyme with a unique His-Ser-Asn catalytic triad. In serine proteases and serine esterases usually an Asp occurs in the catalytic triad; its role has been the subject of much debate. Here the role of the uncharged asparagine in the active site of OMPLA is investigated by structural characterization of the Asn156Ala mutant. Asparagine 156 is not involved in maintaining the overall active-site configuration and does not contribute significantly to the thermal stability of OMPLA. The active-site histidine retains an active conformation in the mutant notwithstanding the loss of the hydrogen bond to the asparagine side chain. Instead, stabilization of the correct tautomeric form of the histidine can account for the observed decrease in activity of the Asn156Ala mutant.     

Identification of the catalytic residues of alpha-amino acid ester hydrolase from Acetobacter turbidans by labeling and site-directed mutagenesis

The alpha-amino acid ester hydrolase from Acetobacter turbidans ATCC 9325 is capable of hydrolyzing and synthesizing the side chain peptide bond in beta-lactam antibiotics. Data base searches revealed that the enzyme contains an active site serine consensus sequence Gly-X-Ser-Tyr-X-Gly that is also found in X-prolyl dipeptidyl aminopeptidase. The serine hydrolase inhibitor p-nitrophenyl-p'-guanidino-benzoate appeared to be an active site titrant and was used to label the alpha-amino acid ester hydrolase. Electrospray mass spectrometry and tandem mass spectrometry analysis of peptides from a CNBr digest of the labeled protein showed that Ser(205), situated in the consensus sequence, becomes covalently modified by reaction with the inhibitor. Extended sequence analysis showed alignment of this Ser(205) with the catalytic nucleophile of some alpha/beta-hydrolase fold enzymes, which posses a catalytic triad composed of a nucleophile, an acid, and a base. Based on the alignments, 10 amino acids were selected for site-directed mutagenesis (Arg(85), Asp(86), Tyr(143), Ser(156), Ser(205), Tyr(206), Asp(338), His(370), Asp(509), and His(610)). Mutation of Ser(205), Asp(338,) or His(370) to an alanine almost fully inactivated the enzyme, whereas mutation of the other residues did not seriously affect the enzyme activity. Circular dichroism measurements showed that the inactivation was not caused by drastic changes in the tertiary structure. Therefore, we conclude that the catalytic domain of the alpha-amino acid ester hydrolase has an alpha/beta-hydrolase fold structure with a catalytic triad of Ser(205), Asp(338), and His(370). This distinguishes the alpha-amino acid ester hydrolase from the Ntn-hydrolase family of beta-lactam antibiotic acylases.     

A catalytic diad involved in substrate-assisted catalysis: NMR study of hydrogen bonding and dynamics at the active site of phosphatidylinositol-specific phospholipase C

Phosphatidylinositol-specific phospholipase Cs (PI-PLCs, EC 3.1.4.10) are ubiquitous enzymes that cleave phosphatidylinositol or phosphorylated derivatives, generating second messengers in eukaryotic cells. A catalytic diad at the active site of Bacillus cereus PI-PLC composed of aspartate-274 and histidine-32 was postulated from the crystal structure to form a catalytic triad with the 2-OH group of the substrate [Heinz, D. W., et al. (1995) EMBO J. 14, 3855-3863]. This catalytic diad has been observed directly by proton NMR. The single low-field line in the 1H NMR spectrum is assigned by site-directed mutagenesis: The peak is present in the wild type but absent in the mutants H32A and D274A, and arises from the histidine Hdelta1 forming the Asp274-His32 hydrogen bond. This hydrogen is solvent-accessible, and exchanges slowly with H2O on the NMR time scale. The position of the low-field peak shifts from 16.3 to 13.8 ppm as the pH is varied from 4 to 9, reflecting a pKa of 8.0 at 6 degrees C, which is identified with the pKa of His32. The Hdelta1 signal is modulated by rapid exchange of the Hepsilon2 with the solvent. Estimates of the exchange rate as a function of pH and protection factors are derived from a line shape analysis. The NMR behavior is remarkably similar to that of the serine proteases. The postulated function of the Asp274-His32 diad is to hydrogen-bond with the 2-OH of phosphatidylinositol (PI) substrate to form a catalytic triad analogous to Asp-His-Ser of serine proteases. This is an example of substrate-assisted catalysis where the substrate provides the catalytic nucleophile of the triad. This hydrogen bond becomes shorter as the imidazole is protonated, suggesting it is stronger in the transition state, contributing further to the catalytic efficiency. The hydrogen bond fits the NMR criteria for a short, strong hydrogen bond, i.e., a highly deshielded proton resonance, bond length of 2.64 +/- 0.04 A at pH 6 measured by NMR, a D/H fractionation factor significantly lower than 1.0, and a protection factor > or = 100.     

Homology modeling and identification of serine 160 as nucleophile of the active site in a thermostable carboxylesterase from the archaeon Archaeoglobus fulgidus

The hyperthermophilic Archaeon Archaeoglobus fulgidus has a gene (AF1763) which encodes a thermostable carboxylesterase belonging to the hormone-sensitive lipase (HSL)-like group of the esterase/lipase family. Based on secondary structure predictions and a secondary structure-driven multiple sequence alignment with remote homologous proteins of known three-dimensional structure, we previously hypothesized for this enzyme the alpha/beta-hydrolase fold typical of several lipases and esterases and identified Ser160, Asp 255 and His285 as the putative members of the catalytic triad. In this paper we report the building of a 3D model for this enzyme based on the structure of the homologous brefeldin A esterase from Bacillus subtilis whose structure has been recently elucidated. The model reveals the topological organization of the fold corroborating our predictions. As regarding the active-site residues, Ser160, Asp255 and His285 are located close each other at hydrogen bond distances. The catalytic role of Ser160 as the nucleophilic member of the triad is demonstrated by the [(3)H]diisopropylphosphofluoridate (DFP) active-site labeling and sequencing of a radioactive peptide containing the signature sequence GDSAGG.     

The crystal and molecular structure of the Rhizomucor miehei triacylglyceride lipase at 1.9 A resolution.

The crystal and molecular structure of a triacylglyceride lipase (EC 3.1.1.3) from the fungus Rhizomucor miehei was analyzed using X-ray single crystal diffraction data to 1.9 A resolution. The structure was refined to an R-factor of 0.169 for all available data. The details of the molecular architecture and the crystal structure of the enzyme are described. A single polypeptide chain of 269 residues is folded into a rather unusual singly wound beta-sheet domain with predominantly parallel strands, connected by a variety of hairpins, loops and helical segments. All the loops are right-handed, creating an uncommon situation in which the central sheet is asymmetric in that all the connecting fragments are located on one side of the sheet. A single N-terminal alpha-helix provides the support for the other, distal, side of the sheet. Three disulfide bonds (residues 29-268, 40-43, 235-244) stabilize the molecule. There are four cis peptide bonds, all of which precede proline residues. In all, 230 ordered water molecules have been identified; 12 of them have a distinct internal character. The catalytic center of the enzyme is made up of a constellation of three residues (His257, Asp203 and Ser144) similar in structure and function to the analogous (but not homologous) triad found in both of the known families of serine proteinases. The fourth residue in this system equivalent to Thr/Ser in proteinases), hydrogen bonded to Asp, is Tyr260. The catalytic site is concealed under a short amphipatic helix (residues 85 to 91), which acts as "lid", opening the active site when the enzyme is adsorbed at the oil-water interface. In the native enzyme the "lid" is held in place by hydrophobic interactions.