The pH dependence of the action pattern in porcine pancreatic alpha-amylase-catalyzed reaction for maltooligosaccharide substrates

Porcine pancreatic alpha-amylase (EC 3.2.1.1; abbreviated PPA), which hydrolyzes alpha-D-(1,4) glucosidic bonds in starch and amylose, displays an optimum at pH 6.9 for the majority of substrates. The optimum pH, however, shifted to 5.2 for the hydrolysis of some low molecular substrates (Ishikawa, K., et al., 1990, Biochemistry 29, 7119-7123). Details of the substrate-dependent shift of the optimum pH in PPA were studied by use of a series of maltooligosaccharides with 14C-labeled reducing end glucose as substrates. The optimum pH for maltotriose was 5.2, whereas that for maltopentaose and maltohexaose was unchanged at pH 6.9. The pH profile for the intermediate size substrate maltotetraose showed abnormality; the apparent optimum pH was broadened between 5.5 and 6.5 and the bond cleavage pattern depended on pH, unlike that for the other substrates examined. These results were independent of either buffer systems or substrate concentration. Analyses of the hydrolysates of the maltooligosaccharides revealed that the shift of the optimum pH to the neutral region occurred only when the fifth subsite of PPA in the productive binding modes was occupied by a glucosyl residue of a substrate. The three-catalytic residue model of PPA deduced from the analysis of the hydrolysis of some modified maltooligosaccharides (p-nitrophenyl-alpha-D-maltoside, gamma-cyclodextrin, maltopentaitol, and maltohexaitol) (Ishikawa, K., et al., 1990, Biochemistry 29, 7119-7123) was successfully adapted to the linear maltooligosaccharides used in this work. These results indicate that the different productive binding modes of the linear oligosaccharide substrates affect directly the catalytic power and the optimum pH of PPA.     

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.     

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.     

Effect of secondary substrate binding in penicillopepsin: contributions of subsites S3 and S2' to kcat

The kinetic parameters kcat, KM, and kcat/KM were determined at 25 degrees C and pH 4.5, 5.5, and 6.0 for the series of penicillopepsin substrates Ac-Alam-Lys-(NO2)Phe-Alan-amide, where (NO2)Phe is p-nitrophenylalanine and m and n equal 0-3. KM values at pH 6.0 were the same for all 12 peptides and averaged 0.088 +/- 0.02 mM but increased to different degrees at lower pH. In contrast, kcat values increased with increasing chain length. At pH 6 and at the pH optimum of kcat, the largest increases (about 37-fold on average) were obtained when alanine residues were added in positions P2' and P3. Only 1-2-fold increases were observed for positions P2, P3', P4, and P4'. These results show that occupation of subsites S2' and S3 is largely responsible for the rate enhancements caused by secondary substrate interactions with this series of peptides. Additional support for an important role of subsite S3 comes from the observation that the two peptides where m = 1 and n = 1 or 2, respectively, are cleaved not only between lysine and p-nitrophenylalanine but also between the latter and alanine, suggesting that occupation of subsite S3 by the N-terminal alanine overcomes the unfavorable interaction of alanine in subsite P1'. Subsite S3 is also important in the binding of pepstatin analogues and in transpeptidation reactions. It is proposed that the roles of subsites S3 and S2' are to facilitate the conversion of the first enzyme-substrate complex into a productive complex and to assist in the distortion of the scissile bond.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of substrate modification on binding of porcine pancreatic alpha amylase: hydrolysis of modified amylose containing D-allose residues

A modified amylose containing 10% of tritiated D-allose residues has been hydrolyzed by porcine pancreatic alpha amylase (PPA). This reaction produced a number of radioactive oligosaccharides of low molecular weight, including modified mono-, di-, and tri-saccharides, as well as larger products. Analysis of these products by chemical and enzymic methods identified D-allose, two isomers of modified maltose, and isomers of modified maltotriose. These results may be interpreted in terms of current PPA models to indicate that D-allose residues may be productively bound at all five subsites of the active site of the enzyme. The distribution of modified residues in these products, however, further suggests that productive binding of D-allose at the subsite where catalytic attack occurs (subsite 3) is less favorable than binding of D-glucose. These results are compared with results of a series of PPA substrates having modifications at C-3 and at other positions. Trends observed in enzyme hydrolysis of these modified substrates reflect factors that contribute to PPA catalysis, with respect to steric, electronic, and hydrogen-bonding interactions between enzyme and substrate.     

The determination of subsite binding energies of porcine pancreatic alpha-amylase by comparing hydrolytic activity towards substrates

The active centre of porcine pancreatic alpha-amylase contains five subsites. Their occupancy has been studied using as a substrate maltooligosaccharide of various chain lengths (maltose up to maltoheptaose), some of their p- and o-nitrophenylated derivatives, and 412-residue amylose. Quantitative analysis of the digestion products allowed the determination of the subsite occupancy for the various productive complexes, the bond cleavage frequency and respective kcati (where i is the binding mode). The catalytic efficiency (kcat/Km) increases with chain length from maltose (2 M-1 X S-1) up to amylose (1.06 X 10(7) M-1 X S-1). The kinetic parameters of p-nitrophenylmaltoside hydrolysis are quite close to those of maltose, and the ortho compound behaves as maltotriose. Determination of binding energy of glucose residue at the various subsites calculated according to the method of Hiromi et al. (Hiromi, K., Nitta, Y., Numata, C. and Ono, S. (1973) Biochim. Biophys. Acta 302, 362-375) did not give consistent results. A method is proposed based on certain properties of porcine pancreatic alpha-amylase, especially the non-interaction of the p-nitrophenyl moiety of the maltose derivative with subsites 1 and 2, and the o-nitrophenyl group which interacts in a similar way to a glucose residue at the reducing end, and on the grounds that the amylase-amylose complexes are of the productive type. In addition, binding energy differences were calculated from substrates with the same chain length. The subsite energy profile is characterized by a low value at subsite 3 which confirms this subsite as the catalytic one. Another consequence is that the hydrolysis rate constant of productive complexes (kintn) (where n is the number of glucose or glucose equivalent residues for a given substrate) varies with chain length which is in conflict with the hypothesis of Hiromi et al.     

Comparative enzymatic studies of human renin acting on pure natural or synthetic substrates

Some of the essential structural requirements for the enzymatic reaction of pure human renin acting on pure human and rat angiotensinogen and on their synthetic tetradecapeptide substrates were investigated. The five carboxy terminal amino acids of synthetic tetradecapeptides played a significant role in substrate recognition and/or hydrolysis by human renin. Kinetic constants Km, Kcat and kcat/Km of the various human renin assays were different according to the substrate used. The presence of either an asparagine or a threonine residue in the S'4 renin subsite did not affect significantly the kinetic constant values. A tyrosine residue, rather than a histidine residue, in the S'3 renin subsite gave the best synthetic substrate studied. When tyrosine residue was present in the S'2 renin subsite an important decrease in kcat was observed. Human angiotensinogen was hydrolysed by human renin with lower Km and kcat values than those measured with human and porcine synthetic substrates, suggesting that the 3-dimensional structure of human angiotensinogen plays a key role in the hydrolysis. This finding was supported by assays performed with rat angiotensinogen, which was cleared by human renin with the same kcat value as rat tetradecapeptide, but with a 49-fold lower Km. Between human and rat angiotensinogen a kcat/Km value of only 2-fold higher has been found in the renin assay using human substrate.     

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.     

Barnase has subsites that give rise to large rate enhancements.

Barnase is found to have a series of subsites for binding its substrates that confers large rate enhancements. Ribonucleotide substrates of the type Zp0Gp1Xp2Y have been synthesized, where p is phosphate, X, Y, and Z are nucleosides, and G is guanosine. G occupies the primary specificity site. The most important subsite is for p2, followed by that for Y. There appears to be no subsite for the Z or p0 positions. Occupation of the subsite for p2 gives rise to a 1000-fold increase in kcat/Km, composed of a 100-fold increase in kcat and a 10-fold decrease in Km. The Y subsite gives rise to further 20-fold increase in kcat/Km. Rates approaching diffusion control for kcat/Km are observed. kcat for the dinucleotide monophosphate GpU = 0.55 s-1, and Km = 240 microM; this compares with 53 s-1 and 20 microM for GpUp, and 3.3 x 10(3) s-1 and 17 microM for GpApA (the best substrate tested). Cleavage occurs at the 3'-phosphate of guanosine in all cases. There are differences in base specificity at the two subsites for X and Y downstream of the scissile bond. The binding energies of different substrates have been analyzed using thermodynamic cycles. These show that the contributions of the X and Y sites are nonadditive.     

Barley alpha-amylase Met53 situated at the high-affinity subsite -2 belongs to a substrate binding motif in the beta-->alpha loop 2 of the catalytic (beta/alpha)8-barrel and is critical for activity and substrate specificity.

Met53 in barley alpha-amylase 1 (AMY1) is situated at the high-affinity subsite -2. While Met53 is unique to plant alpha-amylases, the adjacent Tyr52 stacks onto substrate at subsite -1 and is essentially invariant in glycoside hydrolase family 13. These residues belong to a short sequence motif in beta-->alpha loop 2 of the catalytic (beta/alpha)8-barrel and site-directed mutagenesis was used to introduce a representative variety of structural changes, Met53Glu/Ala/Ser/Gly/Asp/Tyr/Trp, to investigate the role of Met53. Compared to wild-type, Met53Glu/Asp AMY1 displayed 117/90% activity towards insoluble Blue Starch, and Met53Ala/Ser/Gly 76/58/38%, but Met53Tyr/Trp only 0.9/0.1%, even though both Asp and Trp occur frequently at this position in family 13. Towards amylose DP17 (degree of polymerization = 17) and 2-chloro-4-nitrophenyl beta-d-maltoheptaoside the activity (kcat/Km) of all mutants was reduced to 5.5-0.01 and 1.7-0.02% of wild-type, respectively. Km increased up to 20-fold for these soluble substrates and the attack on glucosidic linkages in 4-nitrophenyl alpha-d-maltohexaoside (PNPG6) and PNPG5 was determined by action pattern analysis to shift to be closer to the nonreducing end. This indicated that side chain replacement at subsite -2 weakened substrate glycon moiety contacts. Thus whereas all mutants produced mainly PNPG2 from PNPG6 and similar amounts of PNPG2 and PNPG3 accounting for 85% of the products from PNPG5, wild-type released 4-nitrophenol from PNPG6 and PNPG and PNPG2 in equal amounts from PNPG5. Met53Trp affected the action pattern on PNPG7, which was highly unusual for AMY1 subsite mutants. It was also the sole mutant to catalyze substantial transglycosylation - promoted probably by slow substrate hydrolysis - to produce up to maltoundecaose from PNPG6.     

Effects of secondary interactions on the kinetics of peptide and peptide ester hydrolysis by tissue kallikrein and trypsin

Kinetic constants for the hydrolysis by porcine tissue beta-kallikrein B and by bovine trypsin of a number of peptides related to the sequence of kininogen (also one containing a P2 glycine residue instead of phenylalanine) and of a series of corresponding arginyl peptide esters with various apolar P2 residues have been determined under strictly comparative conditions. kcat and kcat/Km values for the hydrolysis of the Arg-Ser bonds of the peptides by trypsin are conspicuously high. kcat for the best of the peptide substrates, Ac-Phe-Arg-Ser-Val-NH2, even reaches kcat for the corresponding methyl ester, indicating rate-limiting deacylation also in the hydrolysis of a peptide bond by this enzyme. kcat/Km for the hydrolysis of the peptide esters with different nonpolar L-amino acids in P2 is remarkably constant (range 1.7), as it is for the pair of the above pentapeptides with P2 glycine or phenylalanine. kcat for the ester substrates varies fivefold, however, being greatest for the P2 glycine compounds. Obviously, an increased potential of a P2 residue for interactions with the enzyme lowers the rate of deacylation. In contrast to results obtained with chymotrypsin and pancreatic elastase, trypsin is well able to tolerate a P3 proline residue. In the hydrolysis of peptide esters, tissue kallikrein is definitely superior to trypsin. Conversely, peptide bonds are hydrolyzed less efficiently by tissue kallikrein and the acylation reaction is rate-limiting. The influence of the length of peptide substrates is similar in both enzymes and indicates an extension of the substrate recognition site from subsite S3 to at least S'3 of tissue kallikrein and the importance of a hydrogen bond between the P3 carbonyl group and Gly-216 of the enzymes. Tissue kallikrein also tolerates a P3 proline residue well. In sharp contrast to the behaviour of trypsin is the very strong influence of the P2 residue in tissue-kallikrein-catalyzed reactions. kcat/Km varies 75-fold in the series of the dipeptide esters with nonpolar L-amino acid residues in P2, a P2 glycine residue furnishing the worst and phenylalanine the best substrate, whereas this exchange in the pentapeptides changes kcat/Km as much as 730-fold. This behaviour, together with the high value of kcat/Km for Ac-Phe-Arg-OMe of 3.75 X 10(7) M-1 s-1, suggests rate-limiting binding (k1) in the hydrolysis of the best ester substrates.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of the loop structure of the catalytic domain in rice class I chitinase

In the three-dimensional structure of a rice class I chitinase (OsChia1b) determined recently, a loop structure (loop II) is located at the end of the substrate-binding cleft, and is thus suggested to be involved in substrate binding. In order to test this assumption, deletion of the loop II region from the catalytic domain of OsChia1b and replacement of Trp159 in loop II with Ala were carried out. The loop II deletion and the W159A mutation increased hydrolytic activity not only towards (GlcNAc)6 but also towards polysaccharide substrates. Similar results were obtained for kcat/Km values determined for substrate reduced-(GlcNAc)5. The two mutations shifted the splitting positions in (GlcNAc)6 to the reducing end side, but the shift was less intensive in the Trp mutant. Theoretical analysis of the reaction time course indicated that sugar residue affinity at the +3 subsite was reduced from -2 kcal/mol to +0.5 kcal/mol by loop II deletion. Reduced affinity at the +3 subsite might enhance the release of product fragments, resulting in higher turnover and higher enzymatic activities. Thus, we concluded that loop II is involved in sugar residue binding at the +3 subsite, but that Trp159 itself appears to contribute only partly to sugar residue interaction at the subsite.     

A comparison of the catalytic activities of human plasma kallikreins I and II.

Subsites in the S2-S4 region [Schechter & Berger (1967) Biochem. Biophys. Res. Commun. 27, 157-162] were identified in human plasma kallikrein II (EC 3.4.21.8). Kinetic constants (kcat, Km) were determined for a series of seven extended N-aminoacyl-L-arginine methyl esters based on the C-terminal sequence of bradykinin (-Pro-Phe-Arg) or (Gly)n-Arg. With these substrates it was found that deacylation of the enzyme was rate-limiting. It was possible to infer that L-proline at residue P3 interacted with subsite S3 of the enzyme and L-phenylalanine at residue P2 interacts hydrophobically with subsite S2 in addition to hydrogen-bonded interactions with this subsite region. By comparison with the results of a similar study with human plasma kallikrein I, it is observed that although broadly similar subsite interactions occur between the two enzyme forms, the rate of deacylation of kallikrein II is approx. 35% of that observed for kallikrein I, and the latter form is up to ten times more active (in terms of kcat./Km) than kallikrein II.     

Kinetic investigation of soybean trypsin-like enzyme catalysis

Various esters and amides of benzoylarginine and of benzyloxycarbonylarginine were subjected to enzymic hydrolysis at pH 8.5 and 7.2 by soybean trypsin-like enzyme (STLE). The kcat values for the hydrolysis of esters and amides were essentially identical regardless of the kind of leaving group. These results suggest that the STLE-catalyzed hydrolysis of ester and amide substrates proceeds via an acylenzyme intermediate and that the deacylation step is rate-determining. Hydrolysis of various 4-methylcoumaryl-7-amides of varying chain length and amino acid sequence was carried out at pH 8.5. Analysis of kinetic parameters revealed that STLE does not exhibit any remarkable subsite requirement, but somewhat preferentially hydrolyzes shorter substrates. These observations are consistent with the fact that STLE does not hydrolyze protein substrates or oxidized insulin B chain but hydrolyzes oligopeptides (Nishikata, M. (1984) J. Biochem. 95, 1169-1177). It is possible that the active site of STLE is located at a deep position in the enzyme molecule. From the pH dependency of kcat/Km, the participation of a histidine residue in the catalytic process of STLE was suggested.     

Chemical Modification of Sulfhydryl Groups in Porcine Pancreatic α-Amylase,and Purification and Properties of the Modified Amylase

The behavior of SH groups of porcine pancreatic α-amylase, called PPA II, was studied by chemical modification with 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB). Only two SH groups in PPA II reacted, in a pseudo-first-order reaction, and the modification was accompanied with the inactivation of the amylase. The reactivity of SH groups with DTNB was influenced by the ionic strength of the medium. The SH groups were protected against modification by the addition of some substrate analogs; maltopentaitol, maltotetraitol, maltotriitol and cyclomaltohexaose were effective analogs, whereas maltitol, d-glucitol and methyl α-d-glucoside did not protect these groups. The modified enzymes (M₁ and M₂), in which one and two SH groups reacted with DTNB, respectively, were purified in an electrophoretically homogeneous state by chromatography on Bio-Gel P-2 and TSK-Gel DEAE-Toyopearl 650S. The optimum pH of the modified enzyme (M₂) was 6.9~7.0, which was the same as that of the native PPA II. The isoelectric points of M₁ and M₂ were estimated to be 5.8 and 5.2, respectively, by the method of Catsimpoolas. The CD spectrum of PPA II was altered partially by the modification of SH groups with DTNB. Moreover, a precipitin line with a spur was observed in a double immunodiffusion test of PPA II and M₂ to rabbit antiserum of PPA II. It is concluded that the free SH group(s) in PPA II, located near the substrate binding site, don’t participate directly in its catalytic activity, but that the SH group(s) are involved in the antigenicity of PPA II.     

Protein-carbohydrate interactions in human lysozyme probed by combining site-directed mutagenesis and affinity labeling

The synergism between apolar and polar interactions in the carbohydrate recognition by human lysozyme (HL) was probed by site-directed mutagenesis and affinity labeling. The three-dimensional structures of the Tyr63-->Leu mutant HL labeled with 2',3'-epoxypropyl beta-glycoside of N,N'-diacetylchitobiose (L63-HL/NAG-NAG-EPO complex) and the Asp102-->Glu mutant HL labeled with the 2',3'-epoxypropyl beta-glycoside of N-acetyllactosamine were revealed by X-ray diffraction at 2.23 and 1.96 A resolution, respectively. Compared to the wild-type HL labeled with the 2', 3'-epoxypropyl beta-glycoside of N,N'-diacetylchitobiose, the N-acetylglucosamine residue at subsite B of the L63-HL/NAG-NAG-EPO complex markedly moved away from the 63rd residue, with substantial loss of hydrogen-bonding interactions. Evidently, the stacking interaction with the aromatic side chain of Tyr63 is essential in positioning the N-acetylglucosamine residue in the productive binding mode. On the other hand, the position of the galactose residue in subsite B of HL is almost unchanged by the mutation of Asp102 to Glu. Most hydrogen bonds, including the one between the carboxylate group of Glu102 and the axial 4-OH group of the galactose residue, were maintained by local movement of the backbone from residues 102-104. In both structures, the conformation of the disaccharide was conserved, reflecting an intrinsic conformational rigidity of the disaccharides. The structural analysis suggested that CH-pi interactions played an important role in the recognition of the carbohydrate residue at subsite B of HL.     

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%).     

Binding of substrate analogs to hen egg-white lysozyme with an ester linkage between Glu 35 and Trp 108.

The interactions of the substrate analogs beta-methyl-GlcNAc, (GlcNAc)2, and (GlcNAc)3 with hen egg-white lysozyme [EC 3.2.1.17] in which an ester linkage had been formed between Glu 35 and Trp 108 (108 ester lysozyme), were studied by the circular dichroic and fluorescence techniques, and were compared with those for intact lysozyme. The binding constants of beta-methyl-GlcNAc and (GlcNAc)2 to 108 ester lysozyme were essentially the same as those for intact lysozyme in the pH range of 1 to 5. Above pH 5, the binding constants of these saccharides to 108 ester lysozyme did not change with pH, while the binding constants to intact lysozyme decreased. This indicates that Glu 35 (pK 6.0 in intact lysozyme) participates in the binding of these saccharides. The extent and direction of the pK shifts of Asp 52 (pK 3.5), Asp 48 (pK 4.4), and Asp 66 (pK 1.3) observed when beta-methyl-GlcNAc is bound to 108 ester lysozyme were the same as those for intact lysozyme. The participation of Asp 101 and Asp 66 in the binding of (GlcNAc)2 to 108 ester lysozyme was also the same as that for intact lysozyme. These findings indicate that the conformations of subsites B and C are not changed by the formation of the ester linkage. On the other hand, the binding constants of (GlcNAc)3 to 108 ester lysozyme were higher than those for intact lysozyme at all pH values studied. This result is interpreted in terms of an increase in the affinity for a GlcNAc residue of subsite D, which is situated near the esterified Glu 35.     

Mechanistic studies on thrombin catalysis

The kinetic mechanism of the cleavage of four p-nitroanilide (pNA) substrates by human alpha-thrombin has been investigated by using a number of steady-state kinetic techniques. Solvent isotope and viscosity effects were used to determine the stickiness of the substrates at the pH optimum of the reaction; a sticky substrate is defined as one that undergoes catalysis faster than it dissociates from the Michaelis complex. Whereas benzoyl-Arg-pNA could be classified as a nonsticky substrate, D-Phe-pipecolyl-Arg-pNA was very sticky. The other two substrates (tosyl-Gly-Pro-Arg-pNA and acetyl-D-Phe-pipecolyl-Arg-pNA) were slightly sticky. The pH profiles of kcat/Km were bell-shaped for all substrates. The pKa values determined from the pH dependence of kcat/Km for benzoyl-Arg-pNA were about 7.5 and 9.1. Similar pKa values were determined from the pH profiles of kcat/Km for tosyl-Gly-Pro-Arg-pNA and acetyl-D-Phe-pipecolyl-Arg-pNA and for the binding of the competitive inhibitor N alpha-dansyl-L-arginine-4-methylpiperidine amide. The groups responsible for the observed pKa values were proposed to be His57 and the alpha-amino group of Ile16. The temperature dependence of the pKa values was consistent with this assignment. The pKa values of 6.7 and 8.6 observed in the pH profile of kcat/Km for D-Phe-pipecolyl-Arg-pNA were displaced to lower values than those observed for the other substrates. The displacement of the acidic pKa value could be attributed to the stickiness of this substrate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Catalytic mechanism of penicillin-binding protein 5 of Escherichia coli

Penicillin-binding proteins (PBPs) and beta-lactamases are members of large families of bacterial enzymes. These enzymes undergo acylation at a serine residue with their respective substrates as the first step in their catalytic events. Penicillin-binding protein 5 (PBP 5) of Escherichia coli is known to perform a dd-carboxypeptidase reaction on the bacterial peptidoglycan, the major constituent of the cell wall. The roles of the active site residues Lys47 and Lys213 in the catalytic machinery of PBP 5 have been explored. By a sequence of site-directed mutagenesis and chemical modification, we individually introduced gamma-thialysine at each of these positions. The pH dependence of kcat/Km and of kcat for the wild-type PBP 5 and for the two gamma-thialysine mutant variants at positions 47 and 213 were evaluated. The pH optimum for the enzyme was at 9.5-10.5. The ascending limb to the pH optimum is due to Lys47; hence, this residue exists in the free-base form for catalysis. The descending limb from the pH optimum is contributed to by both Lys213 and a water molecule coordinated to Lys47. These results have been interpreted as Lys47 playing a key role in proton-transfer events in the course of catalysis during both the acylation and deacylation events. However, the findings for Lys213 argue for a protonated state at the pH optimum. Lys213 serves as an electrostatic anchor for the substrate.