Organic solvent changes the chymotrypsin specificity with respect to nucleophiles.

In alpha-chymotrypsin-catalyzed acyl-transfer reactions in water the specificity of the enzyme (the nucleophile reactivity of amino acid amides) is correlated with the substrate hydrophobicity and increases as the hydrophobicity of the side chain of the amino acid amides is increased. In a low water system (4% H2O) bulky amino acid amides are less efficient nucleophiles. The specificity of alpha-chymotrypsin towards the amino acid amides in acyl transfer reactions in this case does not depend on the hydrophobicity of the amino acid side chains but correlates with their size. Therefore, different factors can be responsible for the specificity of enzymes in water and in a mainly organic medium.     

Enzymatic synthesis of beta-lactam antibiotics and N-fatty-acylated amino compounds by the acyl-transfer reaction catalyzed by penicillin V acylase from Streptomyces mobaraensis

Penicillin V acylase from Streptomyces mobaraensis (Sm-PVA) showed high acyl-transfer activity in reactions using methyl esters of carboxylic acid (acyl donor) and amino compounds (nucleophile), to produce the corresponding amides. Moreover, Sm-PVA had broad substrate specificity, as indicated by the fact that it catalyzed the efficient synthesis of beta-lactam antibiotics, capsaicin derivatives, and N-fatty-acyl-amino acid/N-fatty-acyl-peptide derivatives.     

Contributions to the S'-subsite specificity of papain.

The product ratio was analyzed for the papain-catalyzed acyl transfer from the specific acyl donor Mal-Phe-Ala-OEtCl to various nucleophilic amino components, ranging from amino acid amides to tripeptide amides. The data obtained are discussed in terms of binding specificity. From the structure-activity relationships for the S'1-P'1 interaction it follows that only three methyl(ene) groups can be accommodated in the S'1 subsite. Hydrophilic side chains are bound better to S'1 than indicated by their hydrophobicities. Negatively charged amino components are inefficient deacylating agents. However, there was no evidence for electrostatic contributions to the nucleophile binding. Amino components with bulky hydrophobic amino acid residues in the P'2 and in the P'3 position, respectively, are preferentially bound to Mal-Phe-Ala-papain. The results of this study can be applied to the planning of papain-catalyzed peptide synthesis reactions.     

Enzymatic Synthesis of β-Lactam Antibiotics and N-Fatty-Acylated Amino Compounds by the Acyl-Transfer Reaction Catalyzed by Penicillin V Acylase from Streptomyces mobaraensis

Penicillin V acylase from Streptomyces mobaraensis (Sm-PVA) showed high acyl-transfer activity in reactions using methyl esters of carboxylic acid (acyl donor) and amino compounds (nucleophile), to produce the corresponding amides. Moreover, Sm-PVA had broad substrate specificity, as indicated by the fact that it catalyzed the efficient synthesis of β-lactam antibiotics, capsaicin derivatives, and N-fatty-acyl-amino acid/N-fatty-acyl-peptide derivatives.     

Optimization of Protease-Catalyzed Acyl Transfer Reactions. Determination of the Partition Constant Characterizing Nucleophile Efficiency

The partitioning of the acyl-enzyme between aminolysis by an added nucleophile and hydrolysis plays a key-role in protease-catalyzed acyl transfer reactions. It can be characterized by the partition constant, which is equal to the nucleophile concentration for which aminolysis and hydrolysis proceed at the same velocity. We describe a method for calculation of the partition constant from the product ratio which is based on the integrated rate equation. Therefore, it can be applied to reactions performed under synthesis-like conditions, i.e. a high degree of nucleophile consumption during the reaction. In principle, the dependence of the partition constant on nucleophile concentration can be determined from a single reaction. V8-protease-catalyzed acyl transfer reactions using Z-Glu-OMe as acyl donor and amino acid amides as nucleophiles were investigated as an application of the method. The central role of the partition constant in optimization of preparative protease-catalyzed acyl transfer reactions is discussed.     

Optimization of Protease-Catalyzed Acyl Transfer Reactions. Determination of the Partition Constant Characterizing Nucleophile Efficiency

The partitioning of the acyl-enzyme between aminolysis by an added nucleophile and hydrolysis plays a key-role in protease-catalyzed acyl transfer reactions. It can be characterized by the partition constant, which is equal to the nucleophile concentration for which aminolysis and hydrolysis proceed at the same velocity. We describe a method for calculation of the partition constant from the product ratio which is based on the integrated rate equation. Therefore, it can be applied to reactions performed under synthesis-like conditions, i.e. a high degree of nucleophile consumption during the reaction. In principle, the dependence of the partition constant on nucleophile concentration can be determined from a single reaction. V8-protease-catalyzed acyl transfer reactions using Z-Glu-OMe as acyl donor and amino acid amides as nucleophiles were investigated as an application of the method. The central role of the partition constant in optimization of preparative protease-catalyzed acyl transfer reactions is discussed.     

The reactive serine residue of epidermolytic toxin A.

Comparison of amino acid sequence data suggested that there may be a functional relationship between the staphylococcal epidermolytic toxins and V8 proteinase. The hypothesis was tested by treating epidermolytic toxin with di-isopropyl phosphorofluoridate, which bound specifically at serine-195, the homologue of the active-site serine residue of V8 proteinase.     

Purification, characterization and gene cloning of a novel glutamic acid-specific endopeptidase from Staphylococcus aureus ATCC 12600.

Twenty strains of Staphylococcus aureus from ATCC type cultures and strains found in clinical studies were cultivated, and their endopeptidase activity specific for glutamic acid was surveyed using benzyloxycarbonyl-Phe-Leu-Glu-p-nitroanilide (Z-Phe-Leu-Glu-pNA) as a substrate. The activity was found in two of the strains, ATCC 12600 and ATCC 25923. A glutamic acid-specific proteinase, which we propose to call SPase, was purified from the culture filtrate of S. aureus strain ATCC 12600 by a series of column chromatographies on DEAE-Sepharose twice and on Sephacryl S-200. A single band was observed on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of the purified SPase. The molecular weight of the proteinase was estimated to be 34000 by SDS-PAGE. When synthetic peptides and oxidized insulin B-chain were used as substrates, SPase showed the same substrate specificity as V8 proteinase, EC 3.4.21.9, which specifically cleaves peptide bonds on the C-terminal side of glutamic acid and aspartic acid. Examination with p-nitroanilides of glutamic acid and aspartic acid as substrates, however, revealed that both proteinases are highly specific for a glutamyl bond in comparison with an aspartyl bond. To elucidate the complete primary structure of SPase, its gene was cloned from genomic DNA of S. aureus ATCC 12600, and the nucleotide sequence was determined. Taking the amino acid sequence of SPase from the NH2-terminus to the 27th residue into consideration, the clones encode a mature peptide of 289 amino acids, which follows a prepropeptide of 68 residues. SPase was confirmed to be a novel endopeptidase specific for glutamic acid, being different from V8 proteinase which consists of 268 amino acids.     

Protease-catalyzed fragment condensation via substrate mimetic strategy: a useful combination of solid-phase peptide synthesis with enzymatic methods.

The concept of substrate mimetic strategy represents a new powerful method in the field of enzymatic peptide synthesis. This strategy takes advantage of the shift in the site-specific amino acid moiety from the acyl residue to the ester-leaving group of the carboxyl component enabling acylation of the enzyme by nonspecific acyl residues. As a result, peptide bond formation occurs independently of the primary specificity of proteases. Moreover, because of the coupling of nonspecific acyl residues, the newly formed peptide bond is not subject to secondary hydrolysis achieving irreversible peptide synthesis. Here, we report the combination of solid-phase peptide synthesis with substrate mimetic-mediated enzymatic peptide fragment condensations. First, the utility of the oxime resin strategy for the synthesis of peptide fragments in the form of substrate mimetics esterified as 4-guanidinophenyl-, phenyl- and mercaptopropionic acid esters was investigated. The study was completed by using the resulting N(alpha)-protected peptide esters as acyl donors in trypsin-, alpha-chymotrypsin- and V8 protease-catalyzed fragment condensations.     

Isolation and primary characterization of an amidase from Rhodococcus rhodochrous

Amidase (EC 3.5.1.4) was purified to homogeneity from Rhodococcus rhodochrous M8 using isopropanol fractionation and exchange chromatography on Mono Q. The isolated amidase consists of four identical subunits with molecular weight 42+/-2 kD. The activity of the enzyme is maximal at 55-60 degrees C and within the pH range 5-8. The amidase from R. rhodochrous M8 is highly sensitive to such sulfhydryl reagents as Hg2+ and Cu2+. Chelators (EDTA and o-phenanthroline) and serine proteinase inhibitors (PMSF and DIFP) did not inhibit the activity of the enzyme. The enzyme exhibits hydrolytic and acyl transferase activity and does not possess urease activity. Aliphatic amides (acetamide and propionamide) were the best substrates for the amidase from R. rhodochrous M8, whereas bulky aromatic amides were poor substrates of this enzyme. The properties of the isolated enzyme are similar to those found in the corresponding amidase from Arthrobacter sp. J-1 and an amidase with wide substrate specificity from Brevibacterium sp. R312.     

C-terminal amidation of acylamino acids and peptides using a transpeptidation method catalyzed by carboxypeptidase Y

The carboxypeptidase Y-catalyzed reaction of acyl transfer of acylamino acid and peptide residues from the corresponding esters to ammonia and to amides of amino acids has been studied, and conditions for obtaining amides of amino acids and peptides with the yields up to 90% found.     

Functional analysis of the amine substrate specificity domain of pepper tyramine and serotonin N-hydroxycinnamoyltransferases

Pepper (Capsicum annuum) serotonin N-hydroxycinnamoyltransferase (SHT) catalyzes the synthesis of N-hydroxycinnamic acid amides of serotonin, including feruloylserotonin and p-coumaroylserotonin. To elucidate the domain or the key amino acid that determines the amine substrate specificity, we isolated a tyramine N-hydroxycinnamoyltransferase (THT) gene from pepper. Purified recombinant THT protein catalyzed the synthesis of N-hydroxycinnamic acid amides of tyramine, including feruloyltyramine and p-coumaroyltyramine, but did not accept serotonin as a substrate. Both the SHT and THT mRNAs were found to be expressed constitutively in all pepper organs. Pepper SHT and THT, which have primary sequences that are 78% identical, were used as models to investigate the structural determinants responsible for their distinct substrate specificities and other enzymatic properties. A series of chimeric genes was constructed by reciprocal exchange of DNA segments between the SHT and THT cDNAs. Functional characterization of the recombinant chimeric proteins revealed that the amino acid residues 129 to 165 of SHT and the corresponding residues 125 to 160 in THT are critical structural determinants for amine substrate specificity. Several amino acids are strongly implicated in the determination of amine substrate specificity, in which glycine-158 is involved in catalysis and amine substrate binding and tyrosine-149 plays a pivotal role in controlling amine substrate specificity between serotonin and tyramine in SHT. Furthermore, the indisputable role of tyrosine is corroborated by the THT-F145Y mutant that uses serotonin as the acyl acceptor. The results from the chimeras and the kinetic measurements will direct the creation of additional novel N-hydroxycinnamoyltransferases from the various N-hydroxycinnamoyltransferases found in nature.     

Alteration of chain length substrate specificity of Aeromonas caviae R-enantiomer-specific enoyl-coenzyme A hydratase through site-directed mutagenesis

Aeromonas caviae R-specific enoyl-coenzyme A (enoyl-CoA) hydratase (PhaJ(Ac)) is capable of providing (R)-3-hydroxyacyl-CoA with a chain length of four to six carbon atoms from the fatty acid beta-oxidation pathway for polyhydroxyalkanoate (PHA) synthesis. In this study, amino acid substitutions were introduced into PhaJ(Ac) by site-directed mutagenesis to investigate the feasibility of altering the specificity for the acyl chain length of the substrate. A crystallographic structure analysis of PhaJ(Ac) revealed that Ser-62, Leu-65, and Val-130 define the width and depth of the acyl-chain-binding pocket. Accordingly, we targeted these three residues for amino acid substitution. Nine single-mutation enzymes and two double-mutation enzymes were generated, and their hydratase activities were assayed in vitro by using trans-2-octenoyl-CoA (C(8)) as a substrate. Three of these mutant enzymes, L65A, L65G, and V130G, exhibited significantly high activities toward octenoyl-CoA than the wild-type enzyme exhibited. PHA formation from dodecanoate (C(12)) was examined by using the mutated PhaJ(Ac) as a monomer supplier in recombinant Escherichia coli LS5218 harboring a PHA synthase gene from Pseudomonas sp. strain 61-3 (phaC1(Ps)). When L65A, L65G, or V130G was used individually, increased molar fractions of 3-hydroxyoctanoate (C(8)) and 3-hydroxydecanoate (C(10)) units were incorporated into PHA. These results revealed that Leu-65 and Val-130 affect the acyl chain length substrate specificity. Furthermore, comparative kinetic analyses of the wild-type enzyme and the L65A and V130G mutants were performed, and the mechanisms underlying changes in substrate specificity are discussed.     

Isolation and properties of an extracellular proteinase of Staphylococcus aureus

Serine proteinase splitting the peptide bonds which are formed by carboxyl groups of dicarboxylic amino acids was isolated from the supernatant of the Staphylococcus aureus culture liquid. It is similar to the enzyme isolated by Drapeau from Staphylococcus aureus strain V8 in its specifidity, molecular weight, amino acid composition, existence of two pH optima (pH 4.6 and 8.2). But there are some differences between the two proteinase in the content of dicarbonic amino acid residues. It was found that the enzyme can exist in two molecular forms.     

Peptide synthesis by proteases in organic solvents: medium effect on substrate specificity.

The substrate specificities of alpha-chymotrypsin and subtilisins for peptide synthesis in hydrophilic organic solvents were investigated. Chymotrypsin exhibited high specificity to aromatic amino acids as acyl donors, while subtilisin Carlsberg and subtilisin BPN' were specific to aromatic and neutral aliphatic amino acids, in accordance with the S1 specificities of the enzymes for peptide hydrolysis in aqueous solutions. On the contrary, chymotrypsin exhibited higher specificities to hydrophilic amino acid amides as acyl acceptors (nucleophiles) for peptide synthesis with N-acetyl-L-tyrosine ethyl ester, in contrast to the S1' specificity for peptide hydrolysis and peptide synthesis in aqueous solutions. Furthermore, nucleophile specificity changed with the change in water-organic solvent composition; the increase in water content led to increase in relative reactivity of leucinamide to that of alaninamide. It was also found that protection of the carboxyl group of alanine by amidation is much preferable to protection by esterification in terms of reactivity as nucleophiles.     

Purification and Properties of a Highly Thermostable, Sodium Dodecyl Sulfate-Resistant and Stereospecific Proteinase from the Extremely Thermophilic Archaeon Thermococcus stetteri

The cultivation of the extremely thermophilic archaeon Thermococcus stetteri in a dialysis membrane reactor was paralleled by the production of an extremely heat-stable proteinase(s). By applying preparative sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, an SDS-resistant proteinase was purified 67-fold in one step with a yield of 34%. The purified enzyme, which was composed of a single polypeptide chain with a molecular mass of 68 kDa, showed a broad temperature and pH profile (50 to 100(deg)C; pH 5 to 11). The optimal activity with substantial thermal stability was measured with casein at 85(deg)C and pH 8.5 to 9. Inhibition by phenylmethylsulfonyl fluoride and diisopropylfluorophosphate demonstrated that the enzyme was a serine proteinase. The enzyme displayed a relatively narrow substrate specificity, catalyzing the hydrolysis only of N-protected p-nitroanilides or p-nitrophenyl esters of basic (Arg or Lys) or hydrophobic (Phe or Tyr) l-amino acids. l-Phenylglycine amide was also attacked by the proteinase, but with a lower specificity constant. Within the detection limit, no hydrolysis of d-amino acid derivatives was observed. The catalytic efficiency of the enzyme at 80(deg)C (k(infcat)/K(infm) for benzoyl-Arg-p-nitroanilide, 10(sup4)) is the same order of magnitude when compared with that of functionally similar mesophilic enzymes. The proteinase also acts as a transferase, catalyzing the acyl transfer from protected amino acid ester or amide to amino acid amide. The observed thermostability, SDS resistance, relatively narrow substrate specificity, high stereospecificity, and limited catalytic efficiency probably reflect the tighter packing of the thermostable protein molecule and its limited flexibility. This was supported by fluorescence spectra of the enzyme, mainly due to tryptophan residues, in the temperature range of 30 to 90(deg)C. Structural reorganization was observed at temperatures over 100(deg)C. The results obtained could be of relevance for the better understanding of the structure-function relationship of enzymes from extreme thermophiles and suggest possible biotechnological application of the proteinase for resolution of racemic mixtures.     

Enzymatic peptide synthesis by the recombinant proline-specific endopeptidase from Flavobacterium meningosepticum and its mutationally altered Cys-556 variant

Proline-specific endopeptidase (PSE) (EC 3.4.21.26) was investigated for its potential as a catalyst in peptide synthesis. Using an activated peptide ester or a peptide amide as the acyl component, the enzyme catalyzed kinetically controlled aminolysis and transpeptidation respectively, with various amino acid amides as acyl acceptors. To a certain extent the nucleophile preference reflected the amino acid preference in the S₁-position of the enzyme in peptide hydrolysis: the highest fractions of aminolysis were obtained using amino acid amides with hydrophobic side-chains (e.g. Leu-NH₂, Phe-NH₂). PSE also catalyzed the thermodynamically controlled condensation of short peptides with a free carboxyterminus and various amino acid amides. This enabled us to examine the acceptance of different acyl components in the substrate-binding site of the enzyme with regard to their amino acid composition: In the S₁ position proline was clearly favored, but alanine was also accepted, whereas the S₂ subsite accepted various amino acids rather unspecifically. Since PSE was shown to be extremely sensitive against water-miscible organic solvents, an alternative approach was used to increase yields in enzymatic peptide synthesis: a derivative of PSE in which the catalytic Ser-556 is converted to a Cys was constructed by protein engineering. This mutant (PSE_cys) exhibited a dramatically increased peptide ligase activity in aqueous solution.     

The sites of phosphorylation of rabbit brain phosphofructo-1-kinase by cyclic AMP-dependent protein kinase

The three isozymic subunits of phosphofructo-1-kinase present in rabbit brain and designated A, B and C were phosphorylated in vitro by cyclic AMP-dependent protein kinase with 32P-labeled ATP. Limited digestion of the labeled enzymes with trypsin or with Staphylococcus aureus V8 proteinase led to the solubilization of radiolabeled peptides derived from the three isozymic subunits. Limited digestion by V8 proteinase was accompanied by a slight reduction in the apparent sizes of the subunits, indicating that the phosphorylated sites are located near either the amino or carboxyl termini of the protein. V8 proteinase digestion led to no change in the maximal activity of the enzyme but did abolish sensitivity to ATP inhibition. The phosphopeptides of the tryptic and the V8 digests were purified by chromatography and their amino acid sequences were determined and compared to the previously established sequence from rabbit muscle isozyme A. PFK-A E H I S R K R S G E A T V PFK-B H V T R R S L S M A K G F PFK-C V S A S P R G S Y R K F L In each instance, the phosphorylated serine, underlined in the above sequences, was found to be one or two residues toward the C-terminus of one or more basic residues. No other similarities in structure were noted.     

Complete amino acid sequence of chicken liver acyl carrier protein derived from the fatty acid synthase

The acyl carrier protein domain of the chicken liver fatty acid synthase has been isolated after tryptic treatment of the synthase. The isolated domain functions as an acceptor of acetyl and malonyl moieties in the synthase-catalyzed transfer of these groups from their coenzyme A esters and therefore indicates that the acyl carrier protein domain exists in the complex as a discrete entity. The amino acid sequence of the acyl carrier protein was derived from analyses of peptide fragments produced by cyanogen bromide cleavage and trypsin and Staphylococcus aureus V8 protease digestions of the molecule. The isolated acyl carrier protein domain consists of 89 amino acid residues and has a calculated molecular weight of 10,127. The protein contains the phosphopantetheine group attached to the serine residue at position 38. The isolated acyl carrier protein peptide shows some sequence homology with the acyl carrier protein of Escherichia coli, particularly in the vicinity of the site of phosphopantetheine attachment, and shows extensive sequence homology with the acyl carrier protein from the uropygial gland of goose.     

Substrate specificities of cathepsin A,L and A,S from pig kidney

The substrate specificities of two different molecular sizes of cathepsin A, A,L (large form) and A,S (small form), for synthetic substrates were examined kinetically. Both enzymes showed a similar broad substrate specificity against various acyl dipeptides, amino acid esters, and amino acid amides. Z-Phe-Ala and Ac-Phe-OEt were good substrates. Peptides containing hydrophobic amino acids were hydrolyzed rapidly. The presence of hydrophobic amino acid residues, not only at the C-terminal position but also at the second position and probably the third position from the C-terminal, resulted in an increase in the rate of hydrolysis. Peptides containing glycine and proline were hydrolyzed slowly. Inhibition studies with Z-D-Phe-D-Ala and Z-Phe suggested that the peptidase and esterase activities of the enzymes are both catalyzed by the same site of the enzyme molecule, but it remains to be elucidated whether or not the binding sites for peptides and esters are the same.