Opposing influences by subsite -1 and subsite +1 residues on relative xylopyranosidase/arabinofuranosidase activities of bifunctional β-D-xylosidase/α-L-arabinofuranosidase

Conformational inversion occurs 7-8kcal/mol more readily in furanoses than pyranoses. This difference is exploited here to probe for active-site residues involved in distorting pyranosyl substrate toward reactivity. Spontaneous glycoside hydrolysis rates are ordered 4-nitrophenyl-α-l-arabinofuranoside (4NPA)>4-nitrophenyl-β-d-xylopyranoside (4NPX)>xylobiose (X2). The bifunctional β-d-xylosidase/α-l-arabinofuranosidase exhibits the opposite order of reactivity, illustrating that the enzyme is well equipped in using pyranosyl groups of natural substrate X2 in facilitating glycoside hydrolysis. Probing the roles of all 17 active-site residues by single-site mutation to alanine and by changing both moieties of substrate demonstrates that the mutations of subsite -1 residues decrease the ratio k(cat)(4NPX/4NPA), suggesting that the native residues support pyranosyl substrate distortion, whereas the mutations of subsite +1 and the subsite -1/+1 interface residues increase the ratio k(cat)(4NPX/4NPA), suggesting that the native residues support other factors, such as C1 migration and protonation of the leaving group. Alanine mutations of subsite -1 residues raise k(cat)(X2/4NPX) and alanine mutations of subsite +1 and interface residues lower k(cat)(X2/4NPX). We propose that pyranosyl substrate distortion is supported entirely by native residues of subsite -1. Other factors leading to the transition state are supported entirely by native residues of subsite +1 and interface residues.     

Subsite mapping of Aspergillus niger endopolygalacturonase II by site-directed mutagenesis

To assess the subsites involved in substrate binding in Aspergillus niger endopolygalacturonase II, residues located in the potential substrate binding cleft stretching along the enzyme from the N to the C terminus were subjected to site-directed mutagenesis. Mutant enzymes were characterized with respect to their kinetic parameters using polygalacturonate as a substrate and with respect to their mode of action using oligogalacturonates of defined length (n = 3-6). In addition, the effect of the mutations on the hydrolysis of pectins with various degrees of esterification was studied. Based on the results obtained with enzymes N186E and D282K it was established that the substrate binds with the nonreducing end toward the N terminus of the enzyme. Asn(186) is located at subsite -4, and Asp(282) is located at subsite +2. The mutations D183N and M150Q, both located at subsite -2, affected catalysis, probably mediated via the sugar residue bound at subsite -1. Tyr(291), located at subsite +1 and strictly conserved among endopolygalacturonases appeared indispensable for effective catalysis. The mutations E252A and Q288E, both located at subsite +2, showed only slight effects on catalysis and mode of action. Tyr(326) is probably located at the imaginary subsite +3. The mutation Y326L affected the stability of the enzyme. For mutant E252A, an increased affinity for partially methylesterified substrates was recorded. Enzyme N186E displayed the opposite behavior; the specificity for completely demethylesterified regions of substrate, already high for the native enzyme, was increased. The origin of the effects of the mutations is discussed.     

Substrate specificity of the serine proteinase from Bacillus subtilis, strain 72

A comparative study of the hydrolysis of various p-nitroanilide substrates (Z-A2-A1-pNA, Z-A3-A2-A1-pNA, and Z-A4-A3-A2-A1-pNA, where A1-An are various amino acid residues, Z is the benzoyloxycarbonylic group and pNA is the p-nitroanilide group), catalyzed by serine proteinase from Bacillus subtilis strain 72, was carried out. It was found that depending on the substrate structure, the hydrolysis may involve both the peptide-p-nitroaniline and the amino acid-amino acid bonds. A kinetic analysis of substrate hydrolysis occurring simultaneously at these two bonds was carried out. The physico-chemical meaning of the kinetic parameters of the given scheme was determined. The quantitative estimation of the enzyme specificity with respect to both hydrolyzing bonds can be found by using the parameters calculated during the analysis of the kinetic curve of p-nitroaniline production. It was found that according to their specificity the amino acid residues at position A1 can be arranged in the following order: L-Leu greater than P-Phe greater than L-Ile greater than L-Ala. The beta-branched amino acid residues, L-Val and L-Ile, do not bind to subsite S1. If these residues occupy position A1, the substrate splitting occurs exclusively between residues A1 and A2. The tetrapeptide N-protected p-nitroanilide substrates are also hydrolyzed at this bond. Partial hydrolysis of the amino acid-amino acid bond between residues A1 and A2 occurs in two cases: i) when residue A1 is loosely bound to subsite S1 and/or, ii) when residue A2 is firmly bound to subsite S1.     

Sequence specificities of human fibroblast and neutrophil collagenases.

The sequence specificities of human fibroblast and neutrophil collagenases have been investigated by measuring the rate of hydrolysis of 60 synthetic oligopeptides covering the P4 through P'5 subsites of the substrate. The choice of peptides was patterned after both known cleavage sites in noncollagenous proteins and potential cleavage sites (those containing Gly-Ile-Ala, Gly-Leu-Ala, or Gly-Ile-Leu sequences) found in types I, II, III, and IV collagens. The initial rate of hydrolysis of the P1-P'1 bond of each peptide has been measured under first-order conditions ([SO] much less than KM), and kcat/KM values have been calculated from the initial rates. The amino acids in subsites P4 through P'4 all influence the hydrolysis rates for both collagenases. However, the effects of substitutions at each site are distinctive and are consistent with the view that human fibroblast and neutrophil collagenases are homologous but nonidentical enzymes. For peptides with unblocked NH2 and COOH termini, occupancy of subsites P3 through P'3 is necessary for rapid hydrolysis. Compared with the alpha 1(I) cleavage sequence, none of the substitutions investigated at subsites P3, P2, and P'4 produces markedly improved substrates. In contrast, many substitutions at subsites P1, P'1, and P'2 improve specificity. The preferences of both collagenases for alanine in subsite P1 and tryptophan or phenylalanine in subsite P'2, is noteworthy. Human neutrophil collagenase accommodates aromatic residues in subsite P'1 much better than human fibroblast collagenase. The subsite preferences observed for human fibroblast collagenase in these studies agree well with the residues found at cleavage sites in noncollagenous substrates. However, the sequence specificities of these collagenases cannot explain the failure of these enzymes to hydrolyze many potentially cleavable but apparently protected sites in intact collagens. This represents additional support for the notion that the local structure of collagen is important in determining the location of collagenase cleavage sites.     

Enantioselective ester hydrolysis catalyzed by beta-cyclodextrin conjugated with beta-hairpin peptides

Designed cyclodextrin-peptide conjugates, which have one or two beta-hairpin peptides, have been synthesized as catalysts for ester hydrolysis. One or two beta-hairpin peptides were located at the primary hydroxyl group side of beta-cyclodextrin so as to arrange two histidine residues that act as a general acid and a general base catalysts and provide the substrate recognition subsite. Kinetic studies revealed that the two-beta-hairpin peptide was more effective than that of the one-beta-hairpin peptide for substrate recognition.     

Automated docking of alpha-(1-->4)- and alpha-(1-->6)-linked glucosyl trisaccharides and maltopentaose into the soybean beta-amylase active site

The Lamarckian genetic algorithm of AutoDock 3.0 was used to dock alpha-maltotriose, methyl alpha-panoside, methyl alpha-isopanoside, methyl alpha-isomaltotrioside, methyl alpha-(6(1)-alpha-glucopyranosyl)-maltoside, and alpha-maltopentaose into the closed and, except for alpha-maltopentaose, into the open conformation of the soybean beta-amylase active site. In the closed conformation, the hinged flap at the mouth of the active site closes over the substrate. The nonreducing end of alpha-maltotriose docks preferentially to subsites -2 or +1, the latter yielding nonproductive binding. Some ligands dock into less optimal conformations with the nonreducing end at subsite -1. The reducing-end glucosyl residue of nonproductively-bound alpha-maltotriose is close to residue Gln194, which likely contributes to binding to subsite +3. In the open conformation, the substrate hydrogen-bonds with several residues of the open flap. When the flap closes, the substrate productively docks if the nonreducing end is near subsites -2 or -1. Trisaccharides with alpha-(1-->6) bonds do not successfully dock except for methyl alpha-isopanoside, whose first and second glucosyl rings dock exceptionally well into subsites -2 and -1. The alpha-(1-->6) bond between the second and third glucosyl units causes the latter to be improperly positioned into subsite +1; the fact that isopanose is not a substrate of beta-amylase indicates that binding to this subsite is critical for hydrolysis.     

The electrophilic and leaving group phosphates in the catalytic mechanism of yeast pyrophosphatase

Binding of pyrophosphate or two phosphate molecules to the pyrophosphatase (PPase) active site occurs at two subsites, P1 and P2. Mutations at P2 subsite residues (Y93F and K56R) caused a much greater decrease in phosphate binding affinity of yeast PPase in the presence of Mn(2+) or Co(2+) than mutations at P1 subsite residues (R78K and K193R). Phosphate binding was estimated in these experiments from the inhibition of ATP hydrolysis at a sub-K(m) concentration of ATP. Tight phosphate binding required four Mn(2+) ions/active site. These data identify P2 as the high affinity subsite and P1 as the low affinity subsite, the difference in the affinities being at least 250-fold. The time course of five "isotopomers" of phosphate that have from zero to four (18)O during [(18)O]P(i)-[(16)O]H(2)O oxygen exchange indicated that the phosphate containing added water is released after the leaving group phosphate during pyrophosphate hydrolysis. These findings provide support for the structure-based mechanism in which pyrophosphate hydrolysis involves water attack on the phosphorus atom located at the P2 subsite of PPase.     

Role of active-site residues of dispersin B, a biofilm-releasing beta-hexosaminidase from a periodontal pathogen, in substrate hydrolysis

Dispersin B (DspB), a family 20 beta-hexosaminidase from the oral pathogen Aggregatibacter actinomycetemcomitans, cleaves beta(1,6)-linked N-acetylglucosamine polymer. In order to understand the substrate specificity of DspB, we have undertaken to characterize several conserved and nonconserved residues in the vicinity of the active site. The active sites of DspB and other family 20 hexosaminidases possess three highly conserved acidic residues, several aromatic residues and an arginine at subsite -1. These residues were mutated using site-directed mutagenesis and characterized for their enzyme activity. Our results show that a highly conserved acid pair in beta-hexosaminidases D183 and E184, and E332 play a critical role in the hydrolysis of the substrates. pH activity profile analysis showed a shift to a higher pH (6.8) in the optimal activity for the E184Q mutant, suggesting that this residue might act as the acid/base catalyst. The reduction in k(cat) observed for Y187A and Y278A mutants suggests that the Y187 residue (unique to DspB) located on a loop might play a role in substrate specificity and be a part of subsite +1, whereas the hydrogen-bond interaction between Y278A and the N-acetyl group might help to stabilize the transition state. Mutation of W237 and W330 residues abolished hydrolytic activity completely suggesting that alteration at these positions might collapse the binding pocket for the N-acetyl group. Mutation of the conserved R27 residue (to R27A or R27K) also caused significant reduction in k(cat) suggesting that R27 might be involved in stabilization of the transition state. From these results, we conclude that in DspB, and possibly in other structurally similar family 20 hydrolases, some residues at the active site assist in orienting the N-acetyl group to participate in the substrate-assisted mechanism, whereas other residues such as R27 and E332 assist in holding the terminal N-acetylglucosamine during the hydrolysis.     

X-ray crystallographic study of xylopentaose binding to Pseudomonas fluorescens xylanase A

The structure of the complex between a catalytically compromised family 10 xylanase and a xylopentaose substrate has been determined by X-ray crystallography and refined to 3.2 A resolution. The substrate binds at the C-terminal end of the eightfold betaalpha-barrel of Pseudomonas fluorescens subsp. cellulosa xylanase A and occupies substrate binding subsites -1 to +4. Crystal contacts are shown to prevent the expected mode of binding from subsite -2 to +3, because of steric hindrance to subsite -2. The loss of accessible surface at individual subsites on binding of xylopentaose parallels well previously reported experimental measurements of individual subsites binding energies, decreasing going from subsite +2 to +4. Nine conserved residues contribute to subsite -1, including three tryptophan residues forming an aromatic cage around the xylosyl residue at this subsite. One of these, Trp 313, is the single residue contributing most lost accessible surface to subsite -1, and goes from a highly mobile to a well-defined conformation on binding of the substrate. A comparison of xylanase A with C. fimi CEX around the +1 subsite suggests that a flatter and less polar surface is responsible for the better catalytic properties of CEX on aryl substrates. The view of catalysis that emerges from combining this with previously published work is the following: (1) xylan is recognized and bound by the xylanase as a left-handed threefold helix; (2) the xylosyl residue at subsite -1 is distorted and pulled down toward the catalytic residues, and the glycosidic bond is strained and broken to form the enzyme-substrate covalent intermediate; (3) the intermediate is attacked by an activated water molecule, following the classic retaining glycosyl hydrolase mechanism.     

Subsite mapping of an acidic amino acid-specific endopeptidase from Streptomyces griseus, GluSGP, and protease V8.

The substrate specificities of an acidic amino acid-specific endopeptidase of Streptomyces griseus, GluSGP, and protease V8 [EC 3.4.21.19] were investigated with peptide p-nitroanilide substrates which have a Glu residue at the P1 position. GluSGP and protease V8 favored Pro and Leu residues at S2, respectively, while the S3 subsite of GluSGP preferred Phe over either Ala or Leu. The S3 subsite of protease V8 preferred Leu over either Ala or Phe. The best substrates for GluSGP and for protease V8 were Boc-Ala-Phe-Pro-Glu-pNA with a Km value of 0.41 mM (0.1 M Tris-HCl, pH 8.8) and Boc-Ala-Leu-Leu-Glu-pNA with a Km value of 0.25 mM (0.1 M phosphate, pH 7.8), respectively. The kcat/Km values for these substrates obtained with GluSGP were about one hundred to twenty thousand times larger than those obtained with protease V8. Protease V8 exhibited a single optimal pH of around 8 for the hydrolysis of Boc-Ala-Ala-Leu-Glu-pNA and Boc-Ala-Leu-Leu-Asp-pNA.     

Catalytic mechanism of fungal glucoamylase as defined by mutagenesis of Asp176, Glu179 and Glu180 in the enzyme from Aspergillus awamori

Asp176, Glu179 and Glu180 of Aspergillus awamori glucoamylase appeared by differential labeling to be in the active site. To test their functions, they were replaced by mutagenesis with Asn, Gln and Gln respectively, and kinetic parameters and pH dependencies of all enzyme forms were determined. Glu179----Gln glucoamylase was not active on maltose or isomaltose, while the kcat for maltoheptaose hydrolysis decreased almost 2000-fold and the KM was essentially unchanged from wild-type glucoamylase. The The Glu180----Gln mutation drastically increased the KM and moderately decreased the kcat with maltose and maltoheptaose, but affected isomaltose hydrolysis less. Difference in substrate activation energies between Glu180----Gln and wild-type glucoamylases indicate that Glu180 binds D-glucosyl residues in subsite 2. The Asp176----Asn substitution gave moderate increases and decreases in KM and kcat respectively, and therefore similar increases in activation energies for the three substrates. This and the differences in subsite binding energies between Asp176----Asn and wild-type glucoamylases suggest that Asp176 is near subsite 1, where it stabilizes the transition state and interacts with Trp120 at subsite 4. Glu179 and Asp176 are thus proposed as the general catalytic acid and base of pKa 5.9 and 2.7 respectively. The charged Glu180 contributes to the high pKa value of Glu179.     

Substrate specificity of beta-collagenase from Clostridium histolyticum

The substrate specificity of beta-collagenase from Clostridium histolyticum has been investigated by measuring the rate of hydrolysis of more than 50 tri-, tetra-, penta-, and hexapeptides covering the P3 to P3' subsites of the substrate. The choice of peptides was patterned after sequences found in the alpha 1 and alpha 2 chains of type I collagen. Each peptide contained either a 2-furanacryloyl (FA) or cinnamoyl (CN) group in subsite P2 or the 4-nitrophenylalanine (Nph) residue in subsite P1. Hydrolysis of the P1-P1' bond produces an absorbance change in these chromophoric peptides that has been used to quantitate the rates of their hydrolysis under first order conditions ([S] much less than KM) from kcat/KM values have been obtained. The identity of the amino acids in all six subsites (P3-P3') markedly influences the hydrolysis rates. In general, the best substrates have Gly in subsites P3 and P1', Pro or Ala in subsite P2', and Hyp, Arg, or Ala in subsite P3'. This corresponds well with the frequency of occurrence of these residues in the Gly-X-Y triplets of collagen. In contrast, the most rapidly hydrolyzed substrates do not have residues from collagen-like sequences in subsites P2 and P1. For example, CN-Nph-Gly-Pro-Ala is the best known substrate for beta-collagenase with a kcat/KM value of 4.4 X 10(7) M-1 min-1, in spite of the fact that there is neither Pro nor Ala in P2 or Hyp nor Ala in P1. These results indicate that the previously established rules for the substrate specificity of the enzyme require modification.     

Crystal Structure of the Pig Pancreatic α-Amylase Complexed with ρ-Nitrophenyl-α-D-Maltoside-Flexibility in the Active Site

The X-ray structure analysis of a crystal of pig pancreatic alpha-amylase soaked with a rho-nitrophenyl-alpha-D-maltoside (pNPG2) substrate showed a pattern of electron density corresponding to the binding of a rho-nitrophenol unit at subsite -2 of the active site. Binding of the product to subsite -2 after hydrolysis of the pNPG2 molecules, may explain the low catalytic efficiency of the hydrolysis of pNPG2 by PPA. Except a small movement of the segment from residues 304-305 the typical conformational changes of the "flexible loop" (303-309), that constitutes the surface edge of the substrate binding cleft, were not observed in the present complex structure. This result supports the hypothesis that significant movement of the loop may depend on aglycone site being filled (Payan and Qian, J. Protein Chen. 22: 275, 2003). Structural analyses have shown that pancreatic alpha-amylases undergo an induced conformational change of the catalytic residue Asp300 upon substrate binding; in the present complex the catalytic residue is observed in its unliganded orientation. The results suggest that the induced reorientation is likely due to the presence of a sugar unit at subsite -1 and not linked to the closure of the flexible surface loop. The crystal structure was refined at 2.4 A resolution to an R factor of 17.55% (Rfree factor of 23.32%).     

Crystallographic analysis shows substrate binding at the -3 to +1 active-site subsites and at the surface of glycoside hydrolase family 11 endo-1,4-beta-xylanases

GH 11 (glycoside hydrolase family 11) xylanases are predominant enzymes in the hydrolysis of heteroxylan, an abundant structural polysaccharide in the plant cell wall. To gain more insight into the protein-ligand interactions of the glycone as well as the aglycone subsites of these enzymes, catalytically incompetent mutants of the Bacillus subtilis and Aspergillus niger xylanases were crystallized, soaked with xylo-oligosaccharides and subjected to X-ray analysis. For both xylanases, there was clear density for xylose residues in the -1 and -2 subsites. In addition, for the B. subtilis xylanase, there was also density for xylose residues in the -3 and +1 subsite showing the spanning of the -1/+1 subsites. These results, together with the observation that some residues in the aglycone subsites clearly adopt a different conformation upon substrate binding, allowed us to identify the residues important for substrate binding in the aglycone subsites. In addition to substrate binding in the active site of the enzymes, the existence of an unproductive second ligand-binding site located on the surface of both the B. subtilis and A. niger xylanases was observed. This extra binding site may have a function similar to the separate carbohydrate-binding modules of other glycoside hydrolase families.     

Substrate recognition by unsaturated glucuronyl hydrolase from Bacillus sp. GL1

Bacterial unsaturated glucuronyl hydrolases (UGLs) together with polysaccharide lyases are responsible for the complete depolymerization of mammalian extracellular matrix glycosaminoglycans. UGL acts on various oligosaccharides containing unsaturated glucuronic acid (DeltaGlcA) at the nonreducing terminus and releases DeltaGlcA through hydrolysis. In this study, we demonstrate the substrate recognition mechanism of the UGL of Bacillus sp. GL1 by determining the X-ray crystallographic structure of its substrate-enzyme complexes. The tetrasaccharide-enzyme complex demonstrated that at least four subsites are present in the active pocket. Although several amino acid residues are crucial for substrate binding, the enzyme strongly recognizes DeltaGlcA at subsite -1 through the formation of hydrogen bonds and stacking interactions, and prefers N-acetyl-d-galactosamine and glucose rather than N-acetyl-d-glucosamine as a residue accommodated in subsite +1, due to the steric hindrance.     

Role of arginine residues in the active site of the membrane-bound lytic transglycosylase B from Pseudomonas aeruginosa

Lytic transglycosylases cleave the beta-(1-->4)-glycosidic bond in the bacterial cell wall heteropolymer peptidoglycan between the N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) residues with the concomitant formation of a 1,6-anhydromuramoyl residue. On the basis of both sequence alignments with and structural considerations of soluble lytic transglycosylase Slt35 from Escherichia coli, four residues were predicted to be involved in substrate binding at the -1 subsite in the soluble derivative of Pseudomonas aeruginosa membrane-bound lytic transglycosylase MltB. These residues were targeted for site-specific replacement, and the effect on substrate binding and catalysis was determined. The residues Arg187 and Arg188, believed to be involved in binding the stem peptide on MurNAc, were shown to play an important role in substrate binding, as evidenced by peptidoglycan affinity assays and SUPREX analysis using MurNAc-dipeptide as ligand. The Michaelis-Menten parameters were determined for the respective mutants using insoluble peptidoglycan as substrate. In addition to affecting the steady-state binding of ligand to enzyme, as indicated by increases in K(M) values, significant decreases in k(cat) values suggested that replacement of either Arg187 and Arg188 with alanine perturbed the stabilization of both the transition state(s) and reaction intermediate. Thus, it appears that Arg187 and Arg188 are vital for proper orientation of the substrate in the active site, and furthermore this supports the proposed role of the stem peptide at binding subsite -2 in catalysis. Replacement of Gln100, a residue that would appear to interact with the N-acetyl group on MurNAc, did not show any changes in substrate affinity or activity.     

Subsite structure of Saccharomycopsis alpha-amylase secreted from Saccharomyces cerevisiae

The kinetic parameters (kcat/Km) and the cleaved-bond distributions for the hydrolysis of linear maltooligosaccharides Gn (3 less than or equal to n less than or equal to 9) by Saccharomycopsis alpha-amylase (Sfamy) secreted from Saccharomyces cerevisiae were determined at pH 5.25 and 25 degrees C. The subsite affinities of Sfamy were also evaluated from these data. The subsite structure of Sfamy is characteristic of the active site of an endo-cleavage type enzyme, consisting of internal repulsive sites with the catalytic residues and external attractive sites. Moreover, the pKa values of the catalytic residues were calculated from the pH dependence plot of the kinetic parameter (kcat/Km). The amino acid residues which contribute to the subsite affinities and the catalytic activity of Sfamy are proposed and compared with those of Taka-amylase A.     

Substrate activation in acetylcholinesterase induced by low pH or mutation in the pi-cation subsite

Substrate inhibition is considered a defining property of acetylcholinesterase (AChE), whereas substrate activation is characteristic of butyrylcholinesterase (BuChE). To understand the mechanism of substrate inhibition, the pH dependence of acetylthiocholine hydrolysis by AChE was studied between pH 5 and 8. Wild-type human AChE and its mutants Y337G and Y337W, as well as wild-type Bungarus fasciatus AChE and its mutants Y333G, Y333A and Y333W were studied. The pH profile results were unexpected. Instead of substrate inhibition, wild-type AChE and all mutants showed substrate activation at low pH. At high pH, there was substrate inhibition for wild-type AChE and for the mutant with tryptophan in the pi-cation subsite, but substrate activation for mutants containing small residues, glycine or alanine. This is particularly apparent in the B. fasciatus AChE. Thus a single amino acid substitution in the pi-cation site, from the aromatic tyrosine of B. fasciatus AChE to the alanine of BuChE, caused AChE to behave like BuChE. Excess substrate binds to the peripheral anionic site (PAS) of AChE. The finding that AChE is activated by excess substrate supports the idea that binding of a second substrate molecule to the PAS induces a conformational change that reorganizes the active site.     

Study on substrate specificity at subsites for severe acute respiratory syndrome coronavirus 3CL protease

Autocleavage assay and peptide-based cleavage assay were used to study the substrate specificity of 3CL protease from the severe acute respiratory syndrome coronavirus. It was found that the recognition between the enzyme and its substrates involved many positions in the substrate, at least including residues from P4 to P2＇. The deletion of either P4 or P2＇ residue in the substrate would decrease its cleavage efficiency dramatically. In contrast to the previous suggestion that only small residues in substrate could be accommodated to the S 1＇ subsite, we have found that bulky residues such as Tyr and Trp were also acceptable. In addition, based on both peptide-based assay and autocleavage assay, Ile at the PI＇ position could not be hydrolyzed, but the mutant L27A could hydrolyze the Ile peptide fragment. It suggested that there was a stereo hindrance between the S 1＇ subsite and the side chain of Ile in the substrate. All 20 amino acids except Pro could be the residue at the P2＇ position in the substrate, but the cleavage efficiencies were clearly different. The specificity information of the enzyme is helpful for potent anti-virus inhibitor design and useful for other coronavirus studies.     

Discriminating between the activities of human cathepsin G and chymase using fluorogenic substrates

Cathepsin G (CG) (EC 3.4.21.20) and chymase (EC 3.4.21.39) are two closely-related chymotrypsin-like proteases that are released from cytoplasmic granules of activated mast cells and/or neutrophils. We investigated the potential for their substrate-binding subsites to discriminate between their substrate specificities, aiming to better understand their respective role during the progression of inflammatory diseases. In addition to their preference for large aromatic residues at P1, both preferentially accommodate small hydrophilic residues at the S1' subsite. Despite significant structural differences in the S2' subsite, both prefer an acidic residue at that position. The Ala226/Glu substitution at the bottom of the CG S1 pocket, which allows CG but not chymase to accommodate a Lys residue at P1, is the main structural difference, allowing discrimination between the activities of these two proteases. However, a Lys at P1 is accommodated much less efficiently than a Phe, and the corresponding substrate is cleaved by β2-tryptase (EC 3.4.21.59). We optimized a P1 Lys-containing substrate to enhance sensitivity towards CG and prevent cleavage by chymase and β2-tryptase. The resulting substrate (ABZ-GIEPKSDPMPEQ-EDDnp) [where ABZ is O-aminobenzoic acid and EDDnp is N-(2,4-dinitrophenyl)-ethylenediamine] was cleaved by CG but not by chymase and tryptase, with a specificity constant of 190 mM(-1)·s(-1). This allows the quantification of active CG in cells or tissue extracts where it may be present together with chymase and tryptase, as we have shown using a HMC-1 cell homogenate and a sputum sample from a patient with severe asthma.