Substrate Specificity of the Highly Alkalophilic Bacterial Proteinase Esperase: Relation to the X-Ray Structure

Esperase is a highly alkalophilic bacterial proteinase produced by Bacillus lentus. The enzyme hydrolyzes peptide bonds comprising the carboxylic groups of hydrophobic as well as hydrophilic residues in the oxidized insulin B chain. Some of these bonds are not attacked by other alkaline microbial proteinases. P1-P4 specificity was determined by a series of peptide nitroanilides. The S1 recognition loop exhibits a preference for Phe. The "cleft" of the smallest subsite S2 prefers Ala and exhibits low affinity for the larger chain of Leu. S3 is more open than the other subsites and can accept a variety of residues. Hydrophobic interactions predominate in the S4-P4 interactions because S4 can accommodate Phe very well. The results characterize Esperase as an endopeptidase with a broader specificity in comparison with other microbial serine proteinases. This is probably owing to a more flexible substrate binding site.     

Engineering the primary substrate specificity of Streptomyces griseus trypsin

Streptomyces griseus trypsin (SGT) was chosen as a model scaffold for the development of serine proteases with enhanced substrate specificity. Recombinant SGT has been produced in a Bacillus subtilis expression system in a soluble active form and purified to homogeneity. The recombinant and native proteases have nearly identical enzymatic properties and structures. Four SGT mutants with alterations in the S1 substrate binding pocket (T190A, T190P, T190S, and T190V) were also expressed. The T190P mutant demonstrated the largest shift to a preference for Arg versus Lys in the P1 site. This was shown by a minor reduction in catalytic activity toward an Arg-containing substrate (k(cat) reduction of 25%). The crystal structures of the recombinant SGT and the T190P mutant in a complex with the inhibitor benzamidine were obtained at high resolution (approximately 1.9 A). The increase in P1 specificity, achieved with minimal effect on the catalytic efficiency, demonstrates that the T190P mutant is an ideal candidate for the design of additional substrate specificity engineered into the S2 to S4 binding pockets.     

Extensive comparison of the substrate preferences of two subtilisins as determined with peptide substrates which are based on the principle of intramolecular quenching.

Subtilisins are serine endopeptidases with an extended binding cleft comprising at least eight binding subsites. Interestingly, subsites distant from the scissile bond play a dominant role in determining the specificity of the enzymes. The development of internally quenched fluorogenic substrates, which allow polypeptides of more than 11 amino acids to be inserted between the donor and the acceptor, has rendered it possible to perform a highly systematic mapping of the individual subsites of the active sites of subtilisin BPN' from Bacillus amyloliquefaciens and Savinase from Bacillus lentus. For each enzyme, the eight positions S5-S'3 were characterized by determination of kcat/KM values for the hydrolysis of substrates in which the amino acids were systematically varied. The results emphasize that in both subtilisin BPN' and Savinase interactions between substrate and S4 and S1 are very important. However, it is apparent that interactions between other subsites and the substrate exert a significant influence on the substrate preference. The results are rationalized on the basis of the structural data available for the two enzymes.     

Interaction of the factor XIII activation peptide with alpha -thrombin. Crystal structure of its enzyme-substrate analog complex

The serine protease thrombin proteolytically activates blood coagulation factor XIII by cleavage at residue Arg(37); factor XIII in turn cross-links fibrin molecules and gives mechanical stability to the blood clot. The 2.0-A resolution x-ray crystal structure of human alpha-thrombin bound to the factor XIII-(28-37) decapeptide has been determined. This structure reveals the detailed atomic level interactions between the factor XIII activation peptide and thrombin and provides the first high resolution view of this functionally important part of the factor XIII molecule. A comparison of this structure with the crystal structure of fibrinopeptide A complexed with thrombin highlights several important determinants of thrombin substrate interaction. First, the P1 and P2 residues must be compatible with the geometry and chemistry of the S1 and S2 specificity sites in thrombin. Second, a glycine in the P5 position is necessary for the conserved substrate conformation seen in both factor XIII-(28-37) and fibrinopeptide A. Finally, the hydrophobic residues, which occupy the aryl binding site of thrombin determine the substrate conformation further away from the catalytic residues. In the case of factor XIII-(28-37), the aryl binding site is shared by hydrophobic residues P4 (Val(34)) and P9 (Val(29)). A bulkier residue in either of these sites may alter the substrate peptide conformation.     

Crystal structure of the alkaline proteinase Savinase from Bacillus lentus at 1.4 A resolution.

Savinase (EC3.4.21.14) is secreted by the alkalophilic bacterium Bacillus lentus and is a representative of that subgroup of subtilisin enzymes with maximum stability in the pH range 7 to 10 and high activity in the range 8 to 12. It is therefore of major industrial importance for use in detergents. The crystal structure of the native form of Savinase has been refined using X-ray diffraction data to 1.4 A resolution. The starting model was that of subtilisin Carlsberg. A comparison to the structures of the closely related subtilisins Carlsberg and BPN' and to the more distant thermitase and proteinase K is presented. The structure of Savinase is very similar to those of homologous Bacillus subtilisins. There are two calcium ions in the structure, equivalent to the strong and the weak calcium-binding sites in subtilisin Carlsberg and subtilisin BPN', well known for their stabilizing effect on the subtilisins. The structure of Savinase shows novel features that can be related to its stability and activity. The relatively high number of salt bridges in Savinase is likely to contribute to its high thermal stability. The non-conservative substitutions and deletions in the hydrophobic binding pocket S1 result in the most significant structural differences from the other subtilisins. The different composition of the S1 binding loop as well as the more hydrophobic character of the substrate-binding region probably contribute to the alkaline activity profile of the enzyme. The model of Savinase contains 1880 protein atoms, 159 water molecules and two calcium ions. The crystallographic R-factor [formula; see text].     

Interdependency of the binding subsites in subtilisin.

Subtilisins are endopeptidases with an extended binding cleft comprising at least eight subsites, and kinetic studies have revealed that subsites distant from the scissile bond are important in determining the substrate preference of the enzymes. With the subtilisin enzyme Savinase, the interdependency of the individual Sn-Pn interactions has been investigated. It was found that the contributions from each subsite interaction to kcat/KM are not always additive. Such interdependency was also observed between subsites which are remote from each other. With a series of substrates covering S6 to S'4 of Savinase, it was observed that favorable amino acids in P1 or, more significantly, P4 of the substrate shield adverse effects of less favorable amino acids at other positions. Thus, an upper limit of kcat/KM was observed, suggesting a limit on the amount of substrate interaction energy which can be converted into transition-state stabilization. Furthermore, with substrates in which all positions had been optimized, an upper limit of kcat/KM (approximately 2 x 10(9) min-1 M-1) was seen, both for a substrate with a high kcat and for one with a low KM. These results emphasize that the design of optimal substrates or substrate-derived inhibitors for endopeptidases preferably should be based on subsite mappings where interdependent substrate-subsite interactions have been eliminated.     

Mapping the active site of meprin-A with peptide substrates and inhibitors

The extended substrate-binding site of meprin-A, a tetrameric metalloendopeptidase from brush border membranes of mouse kidney proximal tubules, was mapped with a series of peptide substrates. Previous studies led to the development of the chromogenic substrate Phe5(4-nitro)bradykinin for meprin-A. With this substrate, several biologically active peptides were screened as alternate substrate inhibitors, and, of these, bradykinin (RPPGFSPFR) was found to be the best substrate with a single cleavage site (Phe5-Ser6). Three types of bradykinin analogues were used for a systematic investigation of substrate specificity: (1) nonchromogenic bradykinin analogues with substitutions in the P3 to P3' subsites were used as alternative substrate inhibitors of nitrobradykinin hydrolysis, (2) analogues of nitrobradykinin with variations in the P1' position were tested as substrates, and (3) intramolecularly quenched fluorogenic bradykinin analogues with substitutions in the P1 to P3 sites were tested as substrates. A wide variety of substitutions in P1' had little effect on KM (174-339 microM) but markedly affected kcat (51.5 s-1 = A greater than S greater than R greater than F greater than K greater than T greater than E = 0). Substitutions in P1 had a greater effect on KM (366 microM-2.46 mM) and also strongly affected kcat (98.5 s-1 = A greater than F much greater than L greater than E greater than K = 2.4 s-1). The variety of allowed cleavages indicates that meprin-A does not have strict requirements for residues adjacent to the cleavage site. Substitutions farther from the scissle bond also affected binding and hydrolysis, demonstrating that multiple subsite interactions are involved in meprin-A action.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate specificities of growth factor associated kallikreins of the mouse submandibular gland

The kinetic constants for the hydrolysis of a series of tripeptide p-nitroanilide substrates by mouse epidermal growth factor binding protein (EGF-BP), the gamma-subunit of mouse nerve growth factor (gamma-NGF), bovine pancreatic trypsin (BPT), and porcine pancreatic kallikrein (PPK) have been evaluated. These substrates correspond to the carboxyl-terminal three amino acids of the mature forms of epidermal growth factor (EGF) and beta-nerve growth factor (beta-NGF), as well as various substitutions in the penultimate and antepenultimate positions, and, as such, represent potential recognition sites for precursor processing. The mouse kallikreins (EGF-BP and gamma-NGF) preferentially hydrolyze the substrates with the sequences of their specifically associated growth factors; however, the constants derived from these reactions do not account for the association constants observed with the mature growth factors, and additional significant binding interactions between EGF-BP and EGF and between gamma-NGF and beta-NGF are predicted to exist outside of the catalytic binding site, i.e., the P3 to P1 positions. A comparison of the kinetic constants of BPT, PPK, and the mouse kallikreins indicates that EGF-BP and gamma-NGF display a hybrid catalytic character. A favorable substrate P1 arginine guanidinium group interaction exists for the mouse kallikreins, similar to that of BPT, but a preference for a hydrophobic side chain in the substrate P2 position makes the mouse kallikreins, especially EGF-BP, more closely resemble PPK than BPT. These findings have significant implications with regard to molecular modeling of the mouse kallikreins.     

Altered flexibility in the substrate-binding site of related native and engineered high-alkaline Bacillus subtilisins.

High-alkaline serine proteases have been successfully applied as protein degrading components of detergent formulations and are subject to extensive protein engineering efforts to improve their stability and performance. Dynamics has been suggested to play an important role in determining enzyme activity and specificity and it is therefore of interest to establish how local changes in internal mobility affect protein stability, specificity and performance. Here we present the dynamic properties of the 269 residue serine proteases subtilisin PB92 (Maxacal(TM)) and subtilisin BLS (Savinase(TM)), secreted by Bacillus lentus, and an engineered quadruple variant, DSAI, that has improved washing performance. T1, T2 and heteronuclear NOE measurements of the 15N nuclei indicate that for all three proteins the majority of the backbone is very rigid, with only a limited number of residues being involved in local mobility. Many of the residues that constitute the S1 and S4 pockets, determining substrate specificity, are flexible in solution. In contrast, the backbone amides of the residues that constitute the catalytic triad do not exhibit any motion. Subtilisins PB92, BLS and DSAI demonstrate similar but not identical NMR relaxation rates. A detailed analysis of local flexibility indicates that the motion of residues Thr143 and Ala194 becomes more restricted in subtilisin BLS and DSAI. Noteworthy, the loop regions involved in substrate binding become more structured in the engineered variant as compared with the two native proteases, suggesting a relation between altered dynamics and performance. Similar conclusions have been established by X-ray crystallograpic methods, as shown in the accompanying paper.     

Comparison of the substrate specificity of the human T-cell leukemia virus and human immunodeficiency virus proteinases.

Human T-cell leukemia virus type-1 (HTLV-1) is associated with a number of human diseases. Based on the therapeutic success of human immunodeficiency virus type 1 (HIV-1) PR inhibitors, the proteinase (PR) of HTLV-1 is a potential target for chemotherapy. To facilitate the design of potent inhibitors, the subsite specificity of HTLV-1 PR was characterized and compared to that of HIV-1 PR. Two sets of substrates were used that contained single amino-acid substitutions in peptides representing naturally occurring cleavage sites in HIV-1 and HTLV-1. The original HIV-1 matrix/capsid cleavage site substrate and most of its substituted peptides were not hydrolyzed by the HTLV-1 enzyme, except for those with hydrophobic residues at the P4 and P2 positions. On the other hand, most of the peptides representing the HTLV-1 capsid/nucleocapsid cleavage site were substrates of both enzymes. A large difference in the specificity of HTLV-1 and HIV-1 proteinases was demonstrated by kinetic measurements, particularly with regard to the S4 and S2 subsites, whereas the S1 subsite appeared to be more conserved. A molecular model of the HTLV-1 PR in complex with this substrate was built, based on the crystal structure of the S9 mutant of Rous sarcoma virus PR, in order to understand the molecular basis of the enzyme specificity. Based on the kinetics of shortened analogs of the HTLV-1 substrate and on analysis of the modeled complex of HTLV-1 PR with substrate, the substrate binding site of the HTLV-1 PR appeared to be more extended than that of HIV-1 PR. Kinetic results also suggested that the cleavage site between the capsid and nucleocapsid protein of HTLV-1 is evolutionarily optimized for rapid hydrolysis.     

Bacillus licheniformis Variant DY Proteinase: Specificity in Relation to the Geometry of the Substrate Recognition Site

S1–S4 specificity of the Bacillus licheniformis variant DY proteinase (subtilisin DY) was determined by a series of peptide nitroanilides. The broad S1 specificity is due to the relative flexibility of the binding loop, which exhibits a preference for phenylalanine and accepts poorly the side chains of alanine, valine, lysine, and especially that of glutamic acid, due probably to a steric repulsion by Asn 155 and the narrow entrance of the “pocket.” Alanine in position P2 of the substrate is more favorable for the catalysis than glycine. S3 is located on the protein surface. It is more open than the other subsites and can accept a variety of residues. S4 exhibits an extremely high affinity for the aromatic group of phenylalanine. Evidently, hydrophobic forces predominate in the S4–P4 interactions. The results characterize subtilisin DY as a bacterial proteinase with a broad specificity due to the specific geometry and flexibility of the substrate recognition site, which can accommodate different types of amino acid side chains.     

Conservative and nonconservative mutations of the transmembrane CPC motif in ZntA: effect on metal selectivity and activity

ZntA from Escherichia coli belongs to the P1B-ATPase transporter family and mediates resistance to toxic levels of selected divalent metal ions. P1B-type ATPases can be divided into subgroups based on substrate cation selectivity. ZntA has the highest selectivity for Pb2+, followed by Zn2+ and Cd2+; it also shows low levels of activity with Cu2+, Ni2+, and Co2+. It has two high-affinity metal-binding sites, one each in the N-terminus and the transmembrane domains. Ligands to the transmembrane metal site in ZntA include the cysteine residues of the conserved 392CPC394 motif in the sixth transmembrane helix. Pro393 is invariant in all P-type ATPases. For ZntA homologues with different metal ion selectivity, the cysteines are replaced by serine, histidine, and threonine. To test the effect on activity and metal ion selectivity, single alanine, histidine, and serine substitutions at Cys392 or Cys394 in ZntA were characterized, as well as double substitutions of both cysteines by histidine or serine. P393A was also characterized. C392A, C394A, and P393A lost the ability to bind a metal ion with high affinity in the transmembrane domain. Histidine and serine substitutions at Cys392 and Cys394 resulted in loss of binding of Pb2+ at the transmembrane site, indicating that both cysteines of the CPC motif are required for binding Pb2+ with high affinity in ZntA homologues. However, C392H, C392S, C394H, C394S, C392S/C394S, and C392H/C394H could bind other divalent metal ions at the transmembrane site and retained low but measurable activity. Interestingly, these mutants lost the predominant selectivity for Zn2+ and Cd2+ shown by wtZntA. Therefore, conserved residues contribute to metal selectivity by supplying ligands that bind metal ions not only with high affinity, as for Pb2+, but also with the most favorable binding geometry that results in efficient catalysis.     

Substrate specificity of Bacillus subtilis intracellular serine protease. Hydrolysis of insulin beta-chain, native ribonuclease A and p-nitroanilide peptide substrates

Intracellular serine protease, termed ISP-103, was isolated from Bacillus subtilis, strain 103. The substrate specificity of the enzyme was compared to that of secretory subtilisins. Similar to subtilisins, ISP-103 cleaves a single peptide bond Ala20-Ser21 within the native pancreatic ribonuclease A, which results in the accumulation of trypsin-sensitive ribonuclease S, consisting of a non-covalently bound S-peptide (20 amino acid residues) and S-protein (104 amino acid residues). The enzyme hydrolyzes a single peptide bond Leu15-Tyr16 of the B-chain of oxidized bovine insulin, in contrast to the subtilisins cleaving four additional bonds. ISP prefers Leu rather than Phe in the P1 binding site of the rho-nitroanilide peptide substrates and shows a more strict dependence of the activity on the presence of the hydrophobic residues in the P2 and P3 sites. The data obtained indicate that the substrate specificity of ISP, being within the borders of subtilisin specificity, is nevertheless much more restricted.     

Alteration of substrate specificity of cholesterol oxidase from Streptomyces sp. by site-directed mutagenesis

Despite the structural similarities between cholesterol oxidase from Streptomyces and that from Brevibacterium, both enzymes exhibit different characteristics, such as catalytic activity, optimum pH and temperature. In attempts to define the molecular basis of differences in catalytic activity or stability, substitutions at six amino acid residues were introduced into cholesterol oxidase using site-directed mutagenesis of its gene. The amino acid substitutions chosen were based on structural comparisons of cholesterol oxidases from Streptomyces and BREVIBACTERIUM: Seven mutant enzymes were constructed with the following amino acid substitutions: L117P, L119A, L119F, V145Q, Q286R, P357N and S379T. All the mutant enzymes exhibited activity with the exception of that with the L117P mutation. The resulting V145Q mutant enzyme has low activities for all substrates examined and the S379T mutant enzyme showed markedly altered substrate specificity compared with the wild-type enzyme. To evaluate the role of V145 and S379 residues in the reaction, mutants with two additional substitutions in V145 and four in S379 were constructed. The mutant enzymes created by the replacement of V145 by Asp and Glu had much lower catalytic efficiency for cholesterol and pregnenolone as substrates than the wild-type enzyme. From previous studies and this study, the V145 residue seems to be important for the stability and substrate binding of the cholesterol oxidase. In contrast, the catalytic efficiencies (k(cat)/K(m)) of the S379T mutant enzyme for cholesterol and pregnenolone were 1.8- and 6.0-fold higher, respectively, than those of the wild-type enzyme. The enhanced catalytic efficiency of the S379T mutant enzyme for pregnenolone was due to a slightly high k(cat) value and a low K(m) value. These findings will provide several ideas for the design of more powerful enzymes that can be applied to clinical determination of serum cholesterol levels and as sterol probes.     

On the catalytic and binding sites of porcine enteropeptidase.

The active site of porcine enteropeptidase (EC 3.4.21.9) was investigated in order to characterize better both catalytic and binding sites. The participation of a serine and a histidine residue in the catalytic process was fully confirmed and the two residues were located on the light chain of the enzyme. The binding site was found to be composed of at least 2 subsites S1 and S2. The subsite S1 (similar to the trypsin-binding site) is responsible for the interactions with the small substrates of trypsin and the lysine side chain of trypsinogen, while subsite S2 (probably a cluster of lysines) is responsible for the interactions with the polyanionic sequence found in all trypsinogens. Binding of substrate by subsite S2 led to an increased efficiency of the catalytic site which can be correlated to the known high specificity of enteropeptidase.     

Modular construction for function of a ribonucleoprotein enzyme: the catalytic domain of Bacillus subtilis RNase P complexed with B. subtilis RNase P protein

The bacterial RNase P holoenzyme catalyzes the formation of the mature 5′-end of tRNAs and is composed of an RNA and a protein subunit. Among the two folding domains of the RNase P RNA, the catalytic domain (C-domain) contains the active site of this ribozyme. We investigated specific binding of the Bacillus subtilis C-domain with the B.subtilis RNase P protein and examined the catalytic activity of this C-domain–P protein complex. The C-domain forms a specific complex with the P protein with a binding constant of ~0.1 µM. The C-domain–P protein complex and the holoenzyme are equally efficient in cleaving single-stranded RNA (~0.9 min^–1 at pH 7.8) and substrates with a hairpin–loop 3′ to the cleavage site (~40 min^–1). The holoenzyme reaction is much more efficient with a pre-tRNA substrate, binding at least 100-fold better and cleaving 10–500 times more efficiently. These results demonstrate that the RNase P holoenzyme is functionally constructed in three parts. The catalytic domain alone contains the active site, but has little specificity and affinity for most substrates. The specificity and affinity for the substrate is generated by either the specificity domain of RNase P RNA binding to a T stem–loop-like hairpin or RNase P protein binding to a single-stranded RNA. This modular construction may be exploited to obtain RNase P-based ribonucleoprotein complexes with altered substrate specificity.     

Comparison of the structures of the cyclotheonamide A complexes of human alpha-thrombin and bovine beta-trypsin.

Thrombin, a trypsin-like serine protease present in blood, plays a central role in the regulation of thrombosis and hemostasis. A cyclic pentapeptide, cyclotheonamide A (CtA), isolated from sponges of the genus Theonella, inhibits thrombin, trypsin, and certain other serine proteases. Enzyme inhibition data for CtA indicate that it is a moderate inhibitor of alpha-thrombin (K(i) = 1.0 nM), but substantially more potent toward trypsin (K(i) = 0.2 nM). The comparative study of the crystal structures of the CtA complexes of alpha-thrombin and beta-trypsin reported here focuses on structure-function relationships in general and the enhanced specificity of trypsin, in particular. The crystal structures of the CtA complexes of thrombin and trypsin were solved and refined at 1.7 and 2.0 A resolution, respectively. The structures show that CtA occupies the active site with the Pro-Arg motif positioned in the S2 and S1 binding sites. The alpha-keto group of CtA is involved in a tetrahedral intermediate hemiketal structure with Ser 195 OG of the catalytic triad and is positioned within bonding distance from, and orthogonal to, the re-face of the carbonyl of the arginine of CtA. As in other productive binding modes of serine proteases, the Ser 214-Gly 216 segment runs in a twisted antiparallel beta-strand manner with respect to the diaminopropionic acid (Dpr)-Arg segment of CtA. The Tyr 60A-Thr 60I insertion loop of thrombin makes a weak aromatic stacking interaction with the v-Tyr of CtA through Trp 60D. The Glu 39 Tyr and Leu 41 Phe substitutions in trypsin produce an enhanced aromatic interaction with D-Phe of CtA, which also leads to different orientations of the side chains of D-Phe and the v-Tyr. The comparison of the CtA complexes of thrombin and trypsin shows that the gross structural features of both in the active site region are the same, whereas the differences observed are mainly due to minor insertions and substitutions. In trypsin, the substitution of Ile 174-Arg 175 by Gly 174-Gln 175 makes the S3 aryl site more polar because the Arg 175 side chain is directed away from thrombin and into the solvent, whereas Gln 175 is not. Because the site is occupied by the Dpr group of CtA, the occupancy of the S3 site is better in trypsin than in thrombin. In trypsin, the D-Phe side chain of CtA fits between Tyr 39 and Phe 41 in a favorable manner, whereas in thrombin, these residues are Glu 39 and Leu 41. The higher degree of specificity for trypsin is most likely the result of these substitutions and the absence of the fairly rigid Tyr 60A-Thr 60I insertion loop of thrombin, which narrows access to the active site and forces less favorable orientations for the D-Phe and v-Tyr residues.     

Catalytic efficiencies of alkaline proteinases from microorganisms

Catalytic efficiencies of proteinase K and mesentericopeptidase were determined using series of peptide-4-nitroanilide substrates and compared with those of subtilisin DY, savinase and esperase. For each enzyme the subsites S1-S4 were characterized. The data for the enzyme specificities were related to our high resolution X-ray models of the five enzymes and their complexes with peptides. The catalytic efficiencies of the alkaline proteinases are modulated by the hydrophobicity, solvent accessibility, flexibility and electrostatic effects in the substrate binding sites. The longer and nonpolar S1 loop offers more possibilities for hydrophobic interactions and increases the enzyme efficiency. S2 is a small narrow cleft which limits the possibilities for effective substitutions in P2. The wide specificity of S3 is due to its location on the protein surface of all investigated proteinases. The affinity of S4 for aromatic groups depends on the nature of the residues building the hydrophobic cavity.     

Principles for designing enzyme-like catalysts based on the rate-acceleration mechanisms of semisynthetic oxidases.

Combinations of substrate-binding sites and catalytic groups constitute various kinds of enzyme-like catalysts. The design of such catalysts can be evaluated by the enhancement of the overall catalytic activity by combining these parts into one catalyst. For a catalyst having one substrate-binding site and one catalytic group, an equation was obtained which shows the relationship between the rate-acceleration due to the combination, the affinity of the site (1/Kd), intrinsic effective concentration (kin/kex) and substrate concentration ([S]). The intrinsic effective concentration is the ratio of the first-order rate constant (kin) of the intramolecular reaction between the catalytic group and the bound substrate and the second-order rate constant (kex) of the intermolecular reaction between the catalytic group and the free substrate; the value depends on the method of linking the catalytic group and the binding site. This equation provides the following principles for designing catalysts of this type with a considerable grade of rate-acceleration: [S] less than or equal to kin/kex and (1/10)[S] less than or equal to Kd less than or equal to kin/kex. To increase kin/kex, the structure of the binding site is required not to reduce the reactivity of the bound substrate, and the linker connecting the binding site and the catalytic group is required to be flexible and to have an appropriate length. A subunit structure is also found to be effective to improve the catalytic activity: the activity of an n-mer is at most n2 times as high as that of the monomer. As for the substrate-binding sites, the sites of natural enzymes and antibodies are good candidates because various kinds of binding sites with high affinity and specificity to the corresponding substrates are available. In addition, the equation relating the rate-acceleration with Kd, kin/kex, and [S] is used for explaining the catalytic efficiency of enzymes energetically. The principle for designing a multifunctional catalyst having several kinds of binding sites for its substrates and intermediates and several kinds of catalytic groups was then investigated. In this case, the diffusion of the intermediates strongly affects the activity of the multifunctional catalyst, and such a diffusion process was also analyzed. On the basis of these analyses, the following principles were obtained.(ABSTRACT TRUNCATED AT 400 WORDS)     

Bare-faced curassow lysozyme carrying amino acid substitutions at subsites E and F shows a change in activity against chitooligosaccharide caused by a local conformational change

A new form of avian lysozyme, bare-faced curassow lysozyme (BCL), was purified and chemically sequenced. Of the 26 substitutions relative to chicken lysozyme, three, F34Y, T47S, and R114H, are of substrate-interacting residues in the E and F subsites, which would contribute to the acceptor binding for transglycosylation. T47S is a novel substitution in this lysozyme class. While other lysozymes also have substitutions at positions 114 and 34, they also contain numerous others, including ones in the other substrate binding sites, A-D. Furthermore, T47S lies on the left side, while F34Y and R114H are located on the right side of the E-F subsites. BCL therefore should allow comparison of the independent contributions of these sites to substrate binding and transglycosylation. The activity toward the N-acetylglucosamine pentamer revealed that the substitutions at the E-F sites reduced the binding free energies at the E-F sites and the rate constant for transglycosylation without the conformation change of other substrate binding sites on the protein. MD simulation analysis of BCL suggested that the substituted amino acids changed the local conformation of this lysozyme at the E-F sites.