Characterization,subsite mapping and N-terminal sequence of miliin,a serine-protease isolated from the latex of Euphorbia milii

Miliin is a serine protease purified from the latex of Euphorbia milii. This work reports the effect of pH and temperature on the catalytic activity of miliin, using fluorescence resonance energy transfer (FRET) substrates. Miliin displayed the highest activity at pH 9 and 35 °C. Subsite mapping shows that subsites S₂ to S₂′ prefer uncharged residues. The S₂ subsite prefers hydrophobic aliphatic amino acids (Val, Pro and Ile) and defines the cleavage site. This work is the first one that reports subsite mapping of Euphorbiacea proteases. The N-terminal sequence showed higher similarity (40%) with the serine protease LIM9 isolated from Lilium. The presence of Tyr, Pro and Lys at positions 2, 5 and 10 respectively, were observed for most of the serine proteases used for comparison. The N-terminal sequence has striking differences with those reported previously for milin and eumiliin, other serine proteases isolated from the latex of E. milii.     

Purification and biochemical characterization of an extracellular serine peptidase from Aspergillus terreus

Peptidases are important because they play a central role in pharmaceutical, food, environmental, and other industrial processes. A serine peptidase from Aspergillus terreus was isolated after two chromatography steps that showed a yield of 15.5%. Its molecular mass was determined to be 43 kD, by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). This peptidase was active between pH 5.0 to 8.0 and had maximum activity at pH 7.0, at 45°C. When exposited with 1 M of urea, the enzyme maintained 100% activity and used azocasein as substrate. The N-terminal (first 15 residues) showed 33% identity with the serine peptidase of Aspergillus clavatus ES1. The kinetics assays showed that subsite S₂ did not bind polar basic amino acids (His and Arg) nonpolar acidic amino acids (Asp and Glu). The subsite S₁ showed higher catalytic efficiency than the S₂ and S₃ subsites.     

Synthesis and subcellular distribution of heparan sulfate in the rat exocrine pancreas.

A kinetic study was conducted to investigate the properties of subsites S₁′ and S₂′ of α-chymotrypsin and subtilisin BPN′, which were deduced from model complexes with a pancreatic trypsin inhibitor and a hexapeptide substrate, respectively. For this purpose,

and

(AA, various amino acid residues) were synthesized. Since they were susceptible to cleavage at the positions shown by the arrows, we could examine the effect of P₁′ or P₂′ amino acid residue on hydrolysis [amino acid residues in peptide substrates and the corresponding subsites in enzymes are numbered according to the system of Schechter and Berger (1967)Biochem. Biophys. Res. Commun.27, 157–162]. The results agreed well with interactions of the leaving group with the corresponding subsites in both enzymes, which were deduced from the model complexes.     

Mutagenesis and subsite mapping underpin the importance for substrate specificity of the aglycon subsites of glycoside hydrolase family 11 xylanases

Glycoside hydrolase family (GH) 11 xylanase A from Bacillus subtilis (BsXynA) was subjected to site-directed mutagenesis to probe the role of aglycon active site residues with regard to activity, binding of decorated substrates and hydrolysis product profile. Targets were those amino acids identified to be important by 3D structure analysis of BsXynA in complex with substrate bound in the glycon subsites and the + 1 aglycon subsite. Several aromatic residues in the aglycon subsites that make strong substrate–protein interactions and that are indispensable for enzyme activity, were also important for the specificity of the xylanase. In the + 2 subsite of BsXynA, Tyr65 and Trp129 were identified as residues that are involved in the binding of decorated substrates. Most interestingly, replacement of Tyr88 by Ala in the + 3 subsite created an enzyme able to produce a wider variety of hydrolysis products than wild type BsXynA. The contribution of the + 3 subsite to the substrate specificity of BsXynA was established more in detail by mapping the enzyme binding site of the wild type xylanase and mutant Y88A with labelled xylo-oligosaccharides. Also, the length of the cord – a long loop flanking the aglycon subsites of GH11 xylanases – proved to impact the hydrolytic action of BsXynA. The aglycon side of the active site cleft of BsXynA, therefore, offers great potential for engineering and design of xylanases with a desired specificity.     

Sequence and Structural Features of Subsite Residues in GH10 and GH11 Xylanases

Xylanases are the enzymes that breakdown complex plant cell wall polysaccharide xylan into xylose by hydrolysing the β-(1→4) glycosidic linkage between xylosides. They mainly belong to the families GH10 and GH11 of the glycoside hydrolase claβs of enzymes. GH10 xylanases have (α/β)₈-barrel type of fold whereas GH11 xylanases have β-jelly roll type of fold. Both enzymes have several substrate binding subsites. This study analysed in detail the sequence and structural conservation of subsites residues by examining their 3D structures crystallized with homoxylan or its non-hydrolysable form as substrate. A total of 19 structures from GH10 and 6 structures from GH11 were analysed. It was found that in GH10 the subsites -3 to -1 consisted of conserved residues, whereas in GH11 subsites -1, -3 and +1 were found to be conserved. The substrate and subsite interaction analysed based on the presence of h-bonds and CH-π interactions showed that Face-to-Face or Edge-to-Face CH-π interactions are formed in the subsites of GH10, whereas such specific CH-π interactions were no at all observed in case of GH11 xylanases. The spatial conservation of subsite residues was also analysed using a distance matrix based approach. It was found that in GH10 xylanases conserved residues have conserved spatial position of those residues as opposed to GH11 enzymes where in subsites -2 and +2 conserved residues showed non-conservation in their spatial positions. The results presented in this study can be used in discovering new xylanases and in the engineering highly efficient xylanases.     

A Naturally Variable Residue in the S1 Subsite of M1 Family Aminopeptidases Modulates Catalytic Properties and Promotes Functional Specialization

M1 family metallo-aminopeptidases fulfill a wide range of critical and in some cases medically relevant roles in humans and human pathogens. The specificity of M1-aminopeptidases is dominated by the interaction of the well defined S1 subsite with the side chain of the first (P1) residue of the substrate and can vary widely. Extensive natural variation occurs at one of the residues that contributes to formation of the cylindrical S1 subsite. We investigated whether this natural variation contributes to diversity in S1 subsite specificity. Effects of 11 substitutions of the S1 subsite residue valine 459 in the Plasmodium falciparum aminopeptidase PfA-M1 and of three substitutions of the homologous residue methionine 260 in Escherichia coli aminopeptidase N were characterized. Many of these substitutions altered steady-state kinetic parameters for dipeptide hydrolysis and remodeled S1 subsite specificity. The most dramatic change in specificity resulted from substitution with proline, which collapsed S1 subsite specificity such that only substrates with P1-Arg, -Lys, or -Met were appreciably hydrolyzed. The structure of PfA-M1 V459P revealed that the proline substitution induced a local conformational change in the polypeptide backbone that resulted in a narrowed S1 subsite. The restricted specificity and active site backbone conformation of PfA-M1 V459P mirrored those of endoplasmic reticulum aminopeptidase 2, a human enzyme with proline in the variable S1 subsite position. Our results provide compelling evidence that changes in the variable residue in the S1 subsite of M1-aminopeptidases have facilitated the evolution of new specificities and ultimately novel functions for this important class of enzymes.     

Mapping of the substrate-binding site of the human granulocyte elastase by the aid of tripeptidyl-p-nitroanilide substrates

The kinetic properties of the human granulocyte elastase /EC 3.4.21.11/ were investigated with 24 tripeptidyl-pNA substrates. By the regression analysis of the kinetic data obtained with 15 substrates a relatively hydrophobic compound, Boc-D-Phe-Ala-Nle-pNA, was predicted as the optimal substrate sequence. The compound was synthesized, assayed and the predicted K_m = 4.2 uM was confirmed experimentally. The substrate-binding site of granulocyte elastase appeared to be hydrophobic and very much similar to that of the pancreatic enzyme at the S₂–S₄ subsites, but the S₁ subsite, which determines the primary specificity, could accomodate bulkier residues and it was less selective than that in the pancreatic enzyme.     

9-(6-Deoxy- β -D-Allofuranosyl)Adenine Cyclic 3′,5′ -Phosphor-Amidate: A New Cyclic AMP Amide Derivative Containing an Equatorial Methyl Group at the 5′-Position

Abstract

R _P and S _P phosphorus diastereoisomers of the title compound (2) are prepared from the corresponding cyclic monophosphate. Solution conformation of the dioxaphosphor-inane ring and hydrolysis of R _p-2 and S _p-2 are studied and compared with those of the phosphorus diastereoisomers of the isomeric compound that contains the 5′-methyl group in the axial position.     

Importance of secondary enzyme-substrate interactions in human cathepsin G and chymotrypsin II catalysis

The active center of human leukocyte cathepsin G, human pancreatic chymotrypsin II, and bovine α-chymotrypsin has been investigated with a series of substrates of general formula succinyl-(l-alanine)_n-phenylalanine-p-nitroanilide (n = 0 to 3). The three proteinases have an extended substrate binding site which includes at least six subsites. Secondary interactions are very important for their catalytic power since the longest substrate is hydrolyzed 600 to 1100 times faster than the shortest one. The regulatory subsite is S₄ for bovine α-chymotrypsin and human cathepsin G whereas it is S₅ for human chymotrypsin II. Cathepsin G is a poor catalyst compared to the two other enzymes.     

Crystal structure and substrate recognition mechanism of Aspergillus oryzae isoprimeverose-producing enzyme

Isoprimeverose-producing enzymes (IPases) release isoprimeverose (α-d-xylopyranosyl-(1?→?6)-d-glucopyranose) from the non-reducing end of xyloglucan oligosaccharides. Aspergillus oryzae IPase (IpeA) is classified as a member of the glycoside hydrolase family 3 (GH3); however, it has unusual substrate specificity compared with other GH3 enzymes. Xylopyranosyl branching at the non-reducing ends of xyloglucan oligosaccharides is vital for IpeA activity. We solved the crystal structure of IpeA with isoprimeverose at 2.4?Å resolution, showing that the structure of IpeA formed a dimer and was composed of three domains: an N-terminal (β/α)₈ TIM-barrel domain, α/β/α sandwich fold domain, and a C-terminal fibronectin-like domain. The catalytic TIM-barrel domain possessed a catalytic nucleophile (Asp300) and acid/base (Glu524) residues. Interestingly, we found that the cavity of the active site of IpeA was larger than that of other GH3 enzymes, and subsite ?1′ played an important role in its activity. The glucopyranosyl and xylopyranosyl residues of isoprimeverose were located at subsites ?1 and ?1′, respectively. Gln58 and Tyr89 contributed to the interaction with the xylopyranosyl residue of isoprimeverose through hydrogen bonding and stacking effects, respectively. Our findings provide new insights into the substrate recognition of GH3 enzymes.     

The active site of an acidic endo-1,4-beta-xylanase of Aspergillus niger

The substrate binding site of an acidic endo-1,4-beta-xylanase (1,4-beta-D-xylan xylanohydrolase, EC 3.2.1.8) of Aspergillus niger was investigated using 1,4-beta-xylooligosaccharides (1-3H)-labelled at the reducing end. Bond cleavage frequencies and V/Km parameters of the oligosaccharides were determined under conditions of unimolecular hydrolysis and, according to the method of Suganuma et al. (J. Biochem. (Tokyo) (1978) 84, 293-316), used for evaluation of subsite affinities. The substrate binding site of the enzyme was found to consist of seven subsites, numbered -IV, -III, -II, -I, I, II and III, towards the subsite binding the reducing end unit of xyloheptaose. The catalytic groups were localized between subsites -I and I, the affinities of which have not been determined. All other subsites showed positive values of affinities for binding xylosyl residues. The values decrease from subsites -II and II, similarly in both directions. As a consequence of such an almost symmetric distribution of affinities around the catalytic groups, the enzyme cleaves preferentially the bonds in the oligosaccharides which are most distant from both terminals. Thus, the acidic A. niger beta-xylanase appears to be an endo-1,4-beta-xylanase attacking polymeric substrates in a random fashion. This conclusion was supported by viscosimetric measurements with carboxymethylxylan as a substrate.     

Engineering lower inhibitor affinities in β-d-xylosidase

β-d-Xylosidase catalyzes hydrolysis of xylooligosaccharides to d-xylose residues. The enzyme, SXA from Selenomonas ruminantium, is the most active catalyst known for the reaction; however, its activity is inhibited by d-xylose and d-glucose (K _i values of ～10^?2?M). Higher K _i’s could enhance enzyme performance in lignocellulose saccharification processes for bioethanol production. We report here the development of a two-tier high-throughput screen where the 1° screen selects for activity (active/inactive screen) and the 2° screen selects for a higher K _i(d-xylose) and its subsequent use in screening ～5,900 members of an SXA enzyme library prepared using error-prone PCR. In one variant, termed SXA-C3, K _i(d-xylose) is threefold and K _i(d-glucose) is twofold that of wild-type SXA. C3 contains four amino acid mutations, and one of these, W145G, is responsible for most of the lost affinity for the monosaccharides. Experiments that probe the active site with ligands that bind only to subsite ?1 or subsite +1 indicate that the changed affinity stems from changed affinity for d-xylose in subsite +1 and not in subsite ?1 of the two-subsite active site. Trp145 is 6 Å from the active site, and its side chain contacts three active-site residues, two in subsite +1 and one in subsite ?1.     

HIV-1 Protease Uses Bi-Specific S2/S2′ Subsites to Optimize Cleavage of Two Classes of Target Sites

Retroviral proteases (PRs) have a unique specificity that allows cleavage of sites with or without a P1′ proline. A P1′ proline is required at the MA/CA cleavage site due to its role in a post-cleavage conformational change in the capsid protein. However, the HIV-1 PR prefers to have large hydrophobic amino acids flanking the scissile bond, suggesting that PR recognizes two different classes of substrate sequences. We analyzed the cleavage rate of over 150 combinations of six different HIV-1 cleavage sites to explore rate determinants of cleavage. We found that cleavage rates are strongly influenced by the two amino acids flanking the amino acids at the scissile bond (P2–P1/P1′–P2′), with two complementary sets of rules. When P1′ is proline, the P2 side chain interacts with a polar region in the S2 subsite of the PR, while the P2′ amino acid interacts with a hydrophobic region of the S2′ subsite. When P1′ is not proline, the orientations of the P2 and P2′ side chains with respect to the scissile bond are reversed; P2 residues interact with a hydrophobic face of the S2 subsite, while the P2′ amino acid usually engages hydrophilic amino acids in the S2′ subsite. These results reveal that the HIV-1 PR has evolved bi-functional S2 and S2′ subsites to accommodate the steric effects imposed by a P1′ proline on the orientation of P2 and P2′ substrate side chains. These results also suggest a new strategy for inhibitor design to engage the multiple specificities in these subsites.     

Isolation and characterization of phospholipase A2, from Agkistrodon bilineatus (common cantil) venom

• 1.1. Phospholipase A₂ was isolated from Agkistrodon bilineatus venom by Sephadex G-75 and CM-Cellulose column chromatographies.
• 2.2. The purified phospholipase A₂-I gave a single band on disc polyacrylamide gel electrophoresis, isoelectric focusing and sodium dodecyl sulfate polyacrylamide gel electrophoresis.
• 3.3. The enzyme preparation had a molecular weight of 14,000, isoelectric point of pH 8.77 and possessed 123 amino acid residues.
• 4.4. The purified phospholipase A₂ possessed lethal, indirect hemolytic and anticoagulant activities.
• 5.5. The enzyme hydrolyzed the phospholipids phosphatidyl choline (PC), phosphatidyl ethanolamine (PE), phosphatidyl inositol (PI) and phosphatidyl serine (PS).
• 6.6. The concentration of mouse diaphragm was inhibited and the contraction of guinea pig left atrium was increased by phospholipase A₂-I.
• 7.7. Phospholipase A₂ activity of this preparation was inhibited by ethylenediamine tetraacetic acid, p-bromo phenacyl bromide, n-bromo succinimide or dithiothreitol, but not by diisopropyl fluorophosphate or benzamidine.

     

Substrate recognition mechanism of alpha-1,6-glucosidic linkage hydrolyzing enzyme, dextran glucosidase from Streptococcus mutans

We have determined the crystal structure of Streptococcus mutans dextran glucosidase, which hydrolyzes the α-1,6-glucosidic linkage of isomaltooligosaccharides from their non-reducing ends to produce α-glucose. By using the mutant of catalytic acid Glu236→Gln, its complex structure with the isomaltotriose, a natural substrate of this enzyme, has been determined. The enzyme has 536 amino acid residues and a molecular mass of 62,001 Da. The native and the complex structures were determined by the molecular replacement method and refined to 2.2 Å resolution, resulting in a final R-factor of 18.3% for significant reflections in the native structure and 18.4% in the complex structure. The enzyme is composed of three domains, A, B and C, and has a (β/α)₈-barrel in domain A, which is common to the α-amylase family enzymes. Three catalytic residues are located at the bottom of the active site pocket and the bound isomaltotriose occupies subsites −1 to +2. The environment of the glucose residue at subsite −1 is similar to the environment of this residue in the α-amylase family. Hydrogen bonds between Asp60 and Arg398 and O4 atom of the glucose unit at subsite −1 accomplish recognition of the non-reducing end of the bound substrate. The side-chain atoms of Glu371 and Lys275 form hydrogen bonds with the O2 and O3 atoms of the glucose residue at subsite +1. The positions of atoms that compose the scissile α-1,6-glucosidic linkage (C1, O6 and C6 atoms) are identical with the positions of the atoms in the scissile α-1,4 linkage (C1, O4 and C4 atoms) of maltopentaose in the α-amylase structure from Bacillus subtilis. The comparison with the α-amylase suggests that Val195 of the dextran glucosidase and the corresponding residues of α-1,6-hydrolyzing enzymes participate in the determination of the substrate specificity of these enzymes.     

Osmoprotection of Bacillus subtilis through Import and Proteolysis of Proline-Containing Peptides

Bacillus subtilis can attain cellular protection against the detrimental effects of high osmolarity through osmotically induced de novo synthesis and uptake of the compatible solute l-proline. We have now found that B. subtilis can also exploit exogenously provided proline-containing peptides of various lengths and compositions as osmoprotectants. Osmoprotection by these types of peptides is generally dependent on their import via the peptide transport systems (Dpp, Opp, App, and DtpT) operating in B. subtilis and relies on their hydrolysis to liberate proline. The effectiveness with which proline-containing peptides confer osmoprotection varies considerably, and this can be correlated with the amount of the liberated and subsequently accumulated free proline by the osmotically stressed cell. Through gene disruption experiments, growth studies, and the quantification of the intracellular proline pool, we have identified the PapA (YqhT) and PapB (YkvY) peptidases as responsible for the hydrolysis of various types of Xaa-Pro dipeptides and Xaa-Pro-Xaa tripeptides. The PapA and PapB peptidases possess overlapping substrate specificities. In contrast, osmoprotection by peptides of various lengths and compositions with a proline residue positioned at their N terminus was not affected by defects in the PapA and PapB peptidases. Taken together, our data provide new insight into the physiology of the osmotic stress response of B. subtilis. They illustrate the flexibility of this ubiquitously distributed microorganism to effectively exploit environmental resources in its acclimatization to sustained high-osmolarity surroundings through the accumulation of compatible solutes.     

Refined crystal structure of the potato inhibitor complex of carboxypeptidase A at 2.5 Å resolution

The exopeptidase carboxypeptidase A forms a tight complex with a 39 residue inhibitor protein from potatoes. We have determined the crystal structure of this complex, and refined the atomic model to a crystallographic R-factor of 0.196 at 2.5 Å resolution. The structure of the inhibitor protein is organized around a core of disulfide bridges. No α-helices or β-sheets are present in this protein, although there is one turn of 3₁₀ helix. The four carboxy-terminal residues of the inhibitor protein bind in the active site groove of carboxypeptidase A, defining binding subsites S′₁, S₁, S₂ and S₃ on the enzyme. The carboxy-terminal glycine of the inhibitor is cleaved from the remainder of the inhibitor in the complex, and remains trapped in the back of the active site pocket. Interactions between the inhibitor and residues Tyr248 and Arg71 of carboxypeptidase A resemble possible features of binding stages for substrates both prior and subsequent to peptide bond hydrolysis. Not all of these interactions would be available to different types of ester substrates, however, which may be in part responsible for the observed kinetic differences in hydrolysis between peptides and various classes of esters. With the exception of residues involved in the binding of the inhibitor protein (such as Tyr248), the structure of carboxypeptidase A as determined in the inhibitor complex is quite similar to the structure of the unliganded enzyme (Lipscomb et al., 1968), which was solved from an unrelated crystal form.     

The effect of substrate modification on porcine pancreatic α-amylase subsite binding: Hydrolysis of substrates containing 2-deoxy-d-glucose and 2-amino-2-deoxy-d-glucose

Modified α-d-(1 → 4)-glucans containing a small proportion of ¹⁴C-labeled 2-deoxy-d-glucose or 2-amino-2-deoxy-d-glucose were examined as substrates for porcine pancreatic α-amylase (PPA). Cyclomaltoheptaose containing single 2-deoxy-d-glucose residues, synthesized by incubation of 2-deoxyglucosylglycogen with cyclomaltodextrin glucanotransferase in the presence of Triton X-100, was hydrolyzed by PPA to produce 2-deoxy-d-glucose; two isomers of 2-deoxymaltose, and a mixture of modified maltotrioses. These results indicate that 2-deoxy-d-glucose may be productively bound at all five subsites of the PPA active site. Reaction kinetics and the distribution of products formed suggest, however, that productive binding of the modified residue does not occur readily at the point of catalytic attack (subsite 3) and that the preferred position of hydrolysis of modified substrates may be different from that of unmodified substrates. Results of PPA hydrolysis of glycogen containing [¹⁴C]-2-amino-2-deoxy-d-glucose showed that a modified trisaccharide and a modified disaccharide were the smallest substituted products formed. Analysis of these products indicated that they did not contain modified residues at their reducing ends. Formation of the observed 2-amino-2-deoxy-maltooligosaccharides is consistent with a scheme where productive binding of 2-amino-2-deoxy-d-glucose is allowed at subsites 1, 2, 4, and 5, but not at subsite 3, the subsite at which hydrolysis occurs.     

Multiple sugar binding sites in α-glucosidase

Twenty-five analogs of d-glucose were examined as reversible inhibitors of yeast α-glucosidase (EC 3.2.1.20). The K_i values range from 0.38 mM for 6-deoxy-d-glucose (quinovose) to 1.0 M for d-lyxose at pH=6.3 (0.1 M NaCl, 25°). All the monosaccharides and the three disaccharides (maltose, isomaltose and α,α-trehalose) were found to be linear competitive inhibitors with respect to α-p-nitrophenyl glucoside (pNPG) hydrolysis. Multiple inhibition analysis reveals that there are at least three monosaccharide binding sites on the enzyme. One of these can be occupied by glucose [K_i=1.8(±0.1) mM], one by d-galactose [K_i=164(±11) mM] and one by d-mannose [K_i=120(±9) mM]. The pH dependence for glucose binding closely follows that of V/K [pK_a1=5.55(±0.15), pK_a2=6.79(±0.15)], but the binding of mannose does not. Although the glucose subsite can be occupied simultaneously with the mannose or galactose subsites in the enzyme–product complex, no transglucosylation can be detected between pNPG and either mannose or galactose. This suggests that neither of these nonglucose subsites can be occupied in a productive manner in the covalent glucosyl-enzyme intermediate.     

Crystal structure and mode of action of a class V chitinase from <Emphasis Type="Italic">Nicotiana tabacum</Emphasis>

A class V chitinase from Nicotiana tabacum (NtChiV) with amino acid sequence similar to that of Serratia marcescens chitinase B (SmChiB) was expressed in E. coli and purified to homogeneity. When N-acetylglucosamine oligosaccharides [(NAG)_n] were hydrolyzed by the purified NtChiV, the second glycosidic linkage from the non-reducing end was predominantly hydrolyzed in a manner similar to that of SmChiB. NtChiV was shown to hydrolyze partially N-acetylated chitosan non-processively, whereas SmChiB hydrolyzes the same substrate processively. The crystal structure of NtChiV was determined by the single-wavelength anomalous dispersion method at 1.2 Å resolution. The protein adopts a classical (β/α)₈-barrel fold (residues 1–233 and 303–348) with an insertion of a small (α + β) domain (residues 234–302). This is the first crystal structure of a plant class V chitinase. The crystal structure of the inactive mutant NtChiV E115Q complexed with (NAG)₄ was also solved and exhibited a linear conformation of the bound oligosaccharide occupying ?2, +1, +2, and +3 subsites. The complex structure corresponds to an initial state of (NAG)₄ binding, which is proposed to be converted into a bent conformation through sliding of the +1, +2, and +3 sugar units to ?1, +1, and +2 subsites. Although NtChiV is similar to SmChiB, the chitin-binding domain is present in the C-terminus of the latter, but not in the former. Aromatic amino acid residues found in the substrate binding cleft of SmChiB, including Trp97, are substituted with aliphatic residues in NtChiV. These structural differences appear to be responsible for NtChiV being a non-processive enzyme.