The active site topology of Aspergillus niger endopolygalacturonase II as studied by site-directed mutagenesis

Strictly conserved charged residues among polygalacturonases (Asp-180, Asp-201, Asp-202, His-223, Arg-256, and Lys-258) were subjected to site-directed mutagenesis in Aspergillus niger endopolygalacturonase II. Specific activity, product progression, and kinetic parameters (K(m) and V(max)) were determined on polygalacturonic acid for the purified mutated enzymes, and bond cleavage frequencies on oligogalacturonates were calculated. Depending on their specific activity, the mutated endopolygalacturonases II were grouped into three classes. The mutant enzymes displayed bond cleavage frequencies on penta- and/or hexagalacturonate different from the wild type endopolygalacturonase II. Based on the biochemical characterization of endopolygalacturonase II mutants together with the three-dimensional structure of the wild type enzyme, we suggest that the mutated residues are involved in either primarily substrate binding (Arg-256 and Lys-258) or maintaining the proper ionization state of a catalytic residue (His-223). The individual roles of Asp-180, Asp-201, and Asp-202 in catalysis are discussed. The active site topology is different from the one commonly found in inverting glycosyl hydrolases.     

Structural and mutational characterization of the catalytic A-module of the mannuronan C-5-epimerase AlgE4 from Azotobacter vinelandii

Alginate is a family of linear copolymers of (1-->4)-linked beta-d-mannuronic acid and its C-5 epimer alpha-l-guluronic acid. The polymer is first produced as polymannuronic acid and the guluronic acid residues are then introduced at the polymer level by mannuronan C-5-epimerases. The structure of the catalytic A-module of the Azotobacter vinelandii mannuronan C-5-epimerase AlgE4 has been determined by x-ray crystallography at 2.1-A resolution. AlgE4A folds into a right-handed parallel beta-helix structure originally found in pectate lyase C and subsequently in several polysaccharide lyases and hydrolases. The beta-helix is composed of four parallel beta-sheets, comprising 12 complete turns, and has an amphipathic alpha-helix near the N terminus. The catalytic site is positioned in a positively charged cleft formed by loops extending from the surface encompassing Asp(152), an amino acid previously shown to be important for the reaction. Site-directed mutagenesis further implicates Tyr(149), His(154), and Asp(178) as being essential for activity. Tyr(149) probably acts as the proton acceptor, whereas His(154) is the proton donor in the epimerization reaction.     

Analysis of a catalytic acidic pair in the active center of cellulase from Aspergillus aculeatus

Four acidic amino acid residues, Asp97, Asp101, Glu118, and Glu202, were located in the cleft from the X-ray crystallographic analysis of FI-CMCase, endo-1,4-beta-glucanase (EC: 3.2.1.4) of Aspergillus aculeatus No. F-50. To identify the catalytic residues of the FI-CMCase, these residues were mutated to Glu or Ser from Asp97 and Asp101, and to Asp or Ser from Glu118 and Glu202 by site-directed mutagenesis, and totally 8 single mutant enzymes expressed in Escherichia coli were prepared: D97E, D97S, D101E, D101S, E118D, E118S, E202D, and E202S. Mutant enzymes E118S and E202S were not shown to have any detectable activity. Kinetic parameters of other mutant enzymes were measured after purification. The Km of mutant enzymes were not much different from that of wild type FI-CMCase, while the Vmax of mutant enzymes D97E, D97S, D101E, D101S, E118D, and D202E were much decreased to 1/50, 1/20, 1/4000, 1/2000, 1/800, and 1/1600 of the wild type FI-CMCase, respectively. From these results we concluded that Glu118 and Glu202 were most probable candidates for a catalytic pair of acidic amino acids in FI-CMCase.     

Three-dimensional structure of Erwinia chrysanthemi pectin methylesterase reveals a novel esterase active site

Most structures of neutral lipases and esterases have been found to adopt the common alpha/beta hydrolase fold and contain a catalytic Ser-His-Asp triad. Some variation occurs in both the overall protein fold and in the location of the catalytic triad, and in some enzymes the role of the aspartate residue is replaced by a main-chain carbonyl oxygen atom. Here, we report the crystal structure of pectin methylesterase that has neither the common alpha/beta hydrolase fold nor the common catalytic triad. The structure of the Erwinia chrysanthemi enzyme was solved by multiple isomorphous replacement and refined at 2.4 A to a conventional crystallographic R-factor of 17.9 % (R(free) 21.1 %). This is the first structure of a pectin methylesterase and reveals the enzyme to comprise a right-handed parallel beta-helix as seen in the pectinolytic enzymes pectate lyase, pectin lyase, polygalacturonase and rhamnogalacturonase, and unlike the alpha/beta hydrolase fold of rhamnogalacturonan acetylesterase with which it shares esterase activity. Pectin methylesterase has no significant sequence similarity with any protein of known structure. Sequence conservation among the pectin methylesterases has been mapped onto the structure and reveals that the active site comprises two aspartate residues and an arginine residue. These proposed catalytic residues, located on the solvent-accessible surface of the parallel beta-helix and in a cleft formed by external loops, are at a location similar to that of the active site and substrate-binding cleft of pectate lyase. The structure of pectin methylesterase is an example of a new family of esterases.     

Mutagenesis of two acidic active site residues in human muscle creatine kinase: implications for the catalytic mechanism

Creatine kinase (CK) catalyzes the reversible phosphorylation of the guanidine substrate, creatine, by MgATP. Although several X-ray crystal structures of various isoforms of creatine kinase have been published, the detailed catalytic mechanism remains unresolved. A crystal structure of the CK homologue, arginine kinase (AK), complexed with the transition-state analogue (arginine-nitrate-ADP), has revealed two carboxylate amino acid residues (Glu225 and Glu314) within 2.8 A of the proposed transphosphorylation site. These two residues are the putative catalytic groups that may promote nucleophilic attack by the guanidine amino group on the gamma-phosphate of ATP. From primary sequence alignments of arginine kinases and creatine kinases, we have identified two homologous creatine kinase acidic amino acid residues (Glu232 and Asp326), and these were targeted for examination of their potential roles in the CK mechanism. Using site-directed mutagenesis, we have made several substitutions at these two positions. The results indicate that of these two residues the Glu232 is the likely catalytic residue while Asp326 likely performs a role in properly aligning substrates for catalysis.     

Biochemical characterization of recombinant acetyl xylan esterase from Aspergillus awamori expressed in Pichia pastoris: mutational analysis of catalytic residues

We engineered an acetyl xylan esterase (AwaxeA) gene from Aspergillus awamori into a heterologous expression system in Pichia pastoris. Purified recombinant AwAXEA (rAwAXEA) displayed the greatest hydrolytic activity toward alpha-naphthylacetate (C2), lower activity toward alpha-naphthylpropionate (C3) and no detectable activity toward acyl-chain substrates containing four or more carbon atoms. Putative catalytic residues, Ser(119), Ser(146), Asp(168) and Asp(202), were substituted for alanine by site-directed mutagenesis. The biochemical properties and kinetic parameters of the four mutant enzymes were examined. The S119A and D202A mutant enzymes were catalytically inactive, whereas S146A and D168A mutants displayed significant hydrolytic activity. These observations indicate that Ser(119) and Asp(202) are important for catalysis. The S146A mutant enzyme showed lower specific activity toward the C2 substrate and higher thermal stability than wild-type enzyme. The lower activity of S146A was due to a combination of increased K(m) and decreased k(cat). The catalytic efficiency of S146A was 41% lower than that of wild-type enzyme. The synthesis of ethyl acetate was >10-fold than that of ethyl n-hexanoate synthesis for the wild-type, S146A and D168A mutant enzymes. However, the D202A showed greater synthetic activity of ethyl n-hexanoate as compared with the wild-type and other mutants.     

Computational analyses of JAK1 kinase domain: subtle changes in the catalytic cleft influence inhibitor specificity

The Janus kinases (JAKs) are a family of intracellular non-receptor tyrosine kinases which transmit signals by phosphorylation of downstream substrates. A myriad of cytokines can trigger the JAK-STAT pathway which influences immune response, embryonic development, and cellular transformation. Here, we built a comparative model for Jak1 based on the crystal structure of Jak2 (PDB code:2B7A) and Jak3 (PDB code: 1YVJ) using the InsightII package. 3D-Profile and stereochemical analysis further verified the validity of the proposed structure. Adenosine 5′-triphosphate (ATP) was then docked into its catalytic cleft. Although the shape of Jak1 kinase cleft is fairly similar to that of Jak3, we observed minute changes in the key residues of the binding interface which influenced the docking of a specific Jak3 inhibitor, WHI-P131. Superimposition of the interface residues suggested that substitution of Asp 99 (Jak3) into Glu 101 (Jak1) generated steric hindrance and a Tyr 91 to Phe 93 switch altered the shape of catalytic cleft which collectively prohibited the inhibitor binding. Furthermore, in-silico mutagenesis of these two residues back to Asp and Tyr enabled Jak1 to accommodate WHI-P131. These results may provide clues for the design and optimization of selective kinase inhibitors.     

Structural insights into the processivity of endopolygalacturonase I from Aspergillus niger

Endopolygalacturonase I is a processive enzyme, while the 60% sequence identical endopolygalacturonase II is not. The 1.70 A resolution crystal structure of endopolygalacturonase I reveals a narrowed substrate binding cleft. In addition, Arg96, a residue in this cleft previously shown to be critical for processivity, interacts with the substrate mimics glycerol and sulfate in several well-defined conformations in the six molecules in the asymmetric unit. From this we conclude that both Arg96 and the narrowed substrate binding cleft contribute to retaining the substrate while it moves through the active site after a cleavage event has occurred.     

Elucidating the role of conserved glutamates in H+-pyrophosphatase of Rhodospirillum rubrum

H(+)-pyrophosphatase (H(+)-PPase) catalyzes pyrophosphate-driven proton transport against the electrochemical potential gradient in various biological membranes. All 50 of the known H(+)-PPase amino acid sequences contain four invariant glutamate residues. In this study, we use site-directed mutagenesis in conjunction with functional studies to determine the roles of the glutamate residues Glu(197), Glu(202), Glu(550), and Glu(649) in the H(+)-PPase of Rhodospirillum rubrum (R-PPase). All residues were replaced with Asp and Ala. The resulting eight variant R-PPases were expressed in Escherichia coli and isolated as inner membrane vesicles. All substitutions, except E202A, generated enzymes capable of PP(i) hydrolysis and PP(i)-energized proton translocation, indicating that the negative charge of Glu(202) is essential for R-PPase function. The hydrolytic activities of all other PPase variants were impaired at low Mg(2+) concentrations but were only slightly affected at high Mg(2+) concentrations, signifying that catalysis proceeds through a three-metal pathway in contrast to wild-type R-PPase, which employs both two- and three-metal pathways. Substitution of Glu(197), Glu(202), and Glu(649) resulted in decreased binding affinity for the substrate analogues aminomethylenediphosphonate and methylenediphosphonate, indicating that these residues are involved in substrate binding as ligands for bridging metal ions. Following the substitutions of Glu(550) and Glu(649), R-PPase was more susceptible to inactivation by the sulfhydryl reagent mersalyl, highlighting a role of these residues in maintaining enzyme tertiary structure. None of the substitutions affected the coupling of PP(i) hydrolysis to proton transport.     

X-ray structure of papaya chitinase reveals the substrate binding mode of glycosyl hydrolase family 19 chitinases

The crystal structure of a chitinase from Carica papaya has been solved by the molecular replacement method and is reported to a resolution of 1.5 A. This enzyme belongs to family 19 of the glycosyl hydrolases. Crystals have been obtained in the presence of N-acetyl- d-glucosamine (GlcNAc) in the crystallization solution and two well-defined GlcNAc molecules have been identified in the catalytic cleft of the enzyme, at subsites -2 and +1. These GlcNAc moieties bind to the protein via an extensive network of interactions which also involves many hydrogen bonds mediated by water molecules, underlying their role in the catalytic mechanism. A complex of the enzyme with a tetra-GlcNAc molecule has been elaborated, using the experimental interactions observed for the bound GlcNAc saccharides. This model allows to define four major substrate interacting regions in the enzyme, comprising residues located around the catalytic Glu67 (His66 and Thr69), the short segment E89-R90 containing the second catalytic residue Glu89, the region 120-124 (residues Ser120, Trp121, Tyr123, and Asn124), and the alpha-helical segment 198-202 (residues Ile198, Asn199, Gly201, and Leu202). Water molecules from the crystal structure were introduced during the modeling procedure, allowing to pinpoint several additional residues involved in ligand binding that were not previously reported in studies of poly-GlcNAc/family 19 chitinase complexes. This work underlines the role played by water-mediated hydrogen bonding in substrate binding as well as in the catalytic mechanism of the GH family 19 chitinases. Finally, a new sequence motif for family 19 chitinases has been identified between residues Tyr111 and Tyr125.     

The iota-carrageenase of Alteromonas fortis. A beta-helix fold-containing enzyme for the degradation of a highly polyanionic polysaccharide

Carrageenans are gel-forming hydrocolloids extracted from the cell walls of marine red algae. They consist of d-galactose residues bound by alternate alpha(1-->3) and beta(1-->4) linkages and substituted by one (kappa-carrageenan), two (iota-carrageenan), or three (lambda-carrageenan) sulfate-ester groups per disaccharide repeating unit. Both the kappa- and iota-carrageenan chains adopt ordered conformations leading to the formation of highly ordered aggregates of double-stranded helices. Several kappa-carrageenases and iota-carrageenases have been cloned from marine bacteria. Kappa-carrageenases belong to family 16 of the glycoside hydrolases, which essentially encompasses polysaccharidases specialized in the hydrolysis of the neutral polysaccharides such as agarose, laminarin, lichenan, and xyloglucan. In contrast, iota-carrageenases constitute a novel glycoside hydrolase structural family. We report here the crystal structure of Alteromonas fortis iota-carrageenase at 1.6 A resolution. The enzyme folds into a right-handed parallel beta-helix of 10 complete turns with two additional C-terminal domains. Glu(245), Asp(247), or Glu(310), in the cleft of the enzyme, are proposed as candidate catalytic residues. The protein contains one sodium and one chloride binding site and three calcium binding sites shown to be involved in stabilizing the enzyme structure.     

Crystal structure of microbial transglutaminase from Streptoverticillium mobaraense

The crystal structure of a microbial transglutaminase from Streptoverticillium mobaraense has been determined at 2.4 A resolution. The protein folds into a plate-like shape, and has one deep cleft at the edge of the molecule. Its overall structure is completely different from that of the factor XIII-like transglutaminase, which possesses a cysteine protease-like catalytic triad. The catalytic residue, Cys(64), exists at the bottom of the cleft. Asp(255) resides at the position nearest to Cys(64) and is also adjacent to His(274). Interestingly, Cys(64), Asp(255), and His(274) superimpose well on the catalytic triad "Cys-His-Asp" of the factor XIII-like transglutaminase, in this order. The secondary structure frameworks around these residues are also similar to each other. These results imply that both transglutaminases are related by convergent evolution; however, the microbial transglutaminase has developed a novel catalytic mechanism specialized for the cross-linking reaction. The structure accounts well for the catalytic mechanism, in which Asp(255) is considered to be enzymatically essential, as well as for the causes of the higher reaction rate, the broader substrate specificity, and the lower deamidation activity of this enzyme.     

Analysis of subunit assembly and function of the Saccharomyces cerevisiae RNase H2 complex

RNase H2 of Saccharomyces cerevisiae consists of three essential subunits (Rnh201, Rnh202 and Rnh203) and plays a critical role in the removal of RNA incorporated in duplex DNA. In the present study, we purified individual subunits and heterodimeric subcomplexes to examine the assembly and biochemical function of subunits of RNase H2 in vitro. Reconstitution experiments revealed that Rnh202 and Rnh203 first form a subcomplex, followed by the recruitment of Rnh201 to complete complex formation. Rnh201 alone or in combination with Rnh203 showed neither substrate-binding, nor catalytic activity, indicating that both activities of Rnh201 are latent until it becomes an integral part of the complex. However, Rnh202 by itself showed substrate-binding activity. RNase H2 containing mutant Rnh202 defective in substrate binding had decreased substrate-binding activity, indicating that Rnh202 contributes directly to substrate binding. Reconstitution of RNase H2 complexes with various mutant subunits allowed us to assess the influence of conserved amino acid residues in either Rnh201 or Rnh202 on substrate-binding and catalytic activities. We found that the substrate-binding activities of both Rnh201 and Rnh202 were critical for cleavage of the phosphodiester bond present between DNA and RNA in RNase H2 substrates.     

A conserved hydrogen-bond network in the catalytic centre of animal glutaminyl cyclases is critical for catalysis

QCs (glutaminyl cyclases; glutaminyl-peptide cyclotransferases, EC 2.3.2.5) catalyse N-terminal pyroglutamate formation in numerous bioactive peptides and proteins. The enzymes were reported to be involved in several pathological conditions such as amyloidotic disease, osteoporosis, rheumatoid arthritis and melanoma. The crystal structure of human QC revealed an unusual H-bond (hydrogen-bond) network in the active site, formed by several highly conserved residues (Ser(160), Glu(201), Asp(248), Asp(305) and His(319)), within which Glu(201) and Asp(248) were found to bind to substrate. In the present study we combined steady-state enzyme kinetic and X-ray structural analyses of 11 single-mutation human QCs to investigate the roles of the H-bond network in catalysis. Our results showed that disrupting one or both of the central H-bonds, i.e., Glu(201)...Asp(305) and Asp(248)...Asp(305), reduced the steady-state catalysis dramatically. The roles of these two COOH...COOH bonds on catalysis could be partly replaced by COOH...water bonds, but not by COOH...CONH(2) bonds, reminiscent of the low-barrier Asp...Asp H-bond in the active site of pepsin-like aspartic peptidases. Mutations on Asp(305), a residue located at the centre of the H-bond network, raised the K(m) value of the enzyme by 4.4-19-fold, but decreased the k(cat) value by 79-2842-fold, indicating that Asp(305) primarily plays a catalytic role. In addition, results from mutational studies on Ser(160) and His(319) suggest that these two residues might help to stabilize the conformations of Asp(248) and Asp(305) respectively. These data allow us to propose an essential proton transfer between Glu(201), Asp(305) and Asp(248) during the catalysis by animal QCs.     

Structure-function relationships of purple acid phosphatase from red kidney beans based on heterologously expressed mutants

Purple acid phosphatases are binuclear metalloenzymes, which catalyze the conversion of orthophosphoric monoesters to alcohol and orthophosphate. The enzyme from red kidney beans is characterized with a Fe(III)-Zn(II) active center. So far, the reaction mechanisms postulated for PAPs assume the essentiality of two amino acids, residing near the bimetallic active site. Based on the amino acid sequence of kidney bean PAP (kbPAP), residues H296 and H202 are believed to be essential for catalytic function of the enzyme. In the present study, the role of residue H202 has been elucidated. Mutants H202A and H202R were prepared by site-directed mutagenesis and expressed in baculovirus-infected insect cells. Based on kinetic studies, residue H202 is assumed to play a role in stabilizing the transition state, particularly in charge compensation, steric positioning of the substrate, and facilitating the release of the product by protonating the substrate leaving groups. The study confirmed the essentiality and elucidates the functional role of H202 in the catalytic mechanism of kbPAP.     

Analysis of catalytic residues of Thermoactinomyces vulgaris R-47 alpha-amylase II (TVA II) by site-directed mutagenesis

To confirm that the catalytic residues (Asp325, Glu354, and Asp421) are necessary for the hydrolysis of starch, pullulan, and cyclodextrins, we constructed TVA II mutated by site-directed mutagenesis. The mutated enzymes (D325N, E354Q, and D421N) had markedly reduced levels of activity, less than 0.006% of the wild type, indicating that these three residues are the catalytic sites for these substrates. Even E354D had reduced levels of activity, less than 0.05% of wild type. These four mutated enzymes retained a trace of activity. From the result of hydrolysis patterns for maltohexaose, in particular, D421N, unlike D325N and E354Q, catalyzed transglycosylation rather than hydrolysis. The results suggest that Asp421 could function to capture water molecules.     

Kinetic studies of site-directed mutational isomalto-dextranase-catalyzed hydrolytic reactions on a 27 MHz quartz-crystal microbalance

A quartz-crystal microbalance (QCM) technique was applied to analyze effects of site-directed mutagenesis of a glycosidase (isomalto-dextranase) on the hydrolysis mechanism of the substrate binding (k(on), k(off), and K(d)) and the catalytic process (k(cat)), separately, by using a dextran-immobilized QCM in buffer solution. D266N, D198N, and D313N mutants, which are predicted as critical residues of the isomalto-dextranase hydrolytic activity, dramatically decreased the apparent enzyme activity. The D266N mutant, however, did not change the substrate binding ability (K(d)), and the D198N and D313N mutants largely increased K(d) values due to the increase of k(off) and/or the decrease of k(on) values, as well as the negatively small k(cat) values. From these results, we estimate the reaction mechanism, in which Asp266 acts as only a general acid in the catalytic process, Asp198 acts as both nucleophile in the catalytic process and binding the substrate, and Asp313 acts as only the substrate binding.     

Importance of van der Waals contact between Glu 35 and Trp 109 to the catalytic action of human lysozyme.

The importance of van der Waals contact between Glu 35 and Trp 109 to the active-site structure and the catalytic properties of human lysozyme (HL) has been investigated by site-directed mutagenesis. The X-ray analysis of mutant HLs revealed that both the replacement of Glu 35 by Asp or Ala, and the replacement of Trp 109 by Phe or Ala resulted in a significant but localized change in the active-site cleft geometry. A prominent movement of the backbone structure was detected in the region of residues 110 to 120 and in the region of residues 100 to 115 for the mutations concerning Glu 35 and Trp 109, respectively. Accompanied by the displacement of the main-chain atoms with a maximal deviation of C alpha atom position ranging from 0.7 A to 1.0 A, the mutant HLs showed a remarkable change in the catalytic properties against Micrococcus luteus cell substrate as compared with native HL. Although the replacement of Glu 35 by Ala completely abolished the lytic activity, HL-Asp 35 mutant retained a weak but a certain lytic activity, showing the possible involvement of the side-chain carboxylate group of Asp 35 in the catalytic action. The kinetic consequence derived from the replacement of Trp 109 by Phe or Ala together with the result of the structural change suggested that the structural detail of the cleft lobe composed of the residues 100 to 115 centered at Ala 108 was responsible for the turnover in the reaction of HL against the bacterial cell wall substrate. The results revealed that the van der Waals contact between Glu 35 and Trp 109 was an essential determinant in the catalytic action of HL.     

Analysis of Catalytic Residues of Thermoactinomyces vulgaris R-47 α-Amylase II (TVA II) by Site-directed Mutagenesis

To confirm that the catalytic residues (Asp325, Glu354, and Asp421) are necessary for the hydrolysis of starch, pullulan, and cyclodextrins, we constructed TVA II mutated by site-directed mutagenesis. The mutated enzymes (D325N, E354Q, and D421N) had markedly reduced levels of activity, less than 0.006% of the wild type, indicating that these three residues are the catalytic sites for these substrates. Even E354D had reduced levels of activity, less than 0.05% of wild type. These four mutated enzymes retained a trace of activity. From the result of hydrolysis patterns for maltohexaose, in particular, D421N, unlike D325N and E354Q, catalyzed transglycosylation rather than hydrolysis. The results suggest that Asp421 could function to capture water molecules.     

Substrate binding mode and its implication on drug design for botulinum neurotoxin A

The seven antigenically distinct serotypes of Clostridium botulinum neurotoxins, the causative agents of botulism, block the neurotransmitter release by specifically cleaving one of the three SNARE proteins and induce flaccid paralysis. The Centers for Disease Control and Prevention (CDC) has declared them as Category A biowarfare agents. The most potent among them, botulinum neurotoxin type A (BoNT/A), cleaves its substrate synaptosome-associated protein of 25 kDa (SNAP-25). An efficient drug for botulism can be developed only with the knowledge of interactions between the substrate and enzyme at the active site. Here, we report the crystal structures of the catalytic domain of BoNT/A with its uncleavable SNAP-25 peptide (197)QRATKM(202) and its variant (197)RRATKM(202) to 1.5 A and 1.6 A, respectively. This is the first time the structure of an uncleavable substrate bound to an active botulinum neurotoxin is reported and it has helped in unequivocally defining S1 to S5' sites. These substrate peptides make interactions with the enzyme predominantly by the residues from 160, 200, 250 and 370 loops. Most notably, the amino nitrogen and carbonyl oxygen of P1 residue (Gln197) chelate the zinc ion and replace the nucleophilic water. The P1'-Arg198, occupies the S1' site formed by Arg363, Thr220, Asp370, Thr215, Ile161, Phe163 and Phe194. The S2' subsite is formed by Arg363, Asn368 and Asp370, while S3' subsite is formed by Tyr251, Leu256, Val258, Tyr366, Phe369 and Asn388. P4'-Lys201 makes hydrogen bond with Gln162. P5'-Met202 binds in the hydrophobic pocket formed by the residues from the 250 and 200 loop. Knowledge of interactions between the enzyme and substrate peptide from these complex structures should form the basis for design of potent inhibitors for this neurotoxin.