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.     

Coumarinic derivatives as mechanism-based inhibitors of alpha-chymotrypsin and human leukocyte elastase

Novel coumarinic derivatives were synthesized and tested for their inhibitory potency toward alpha-CT and HLE. Cycloalkyl esters and amides were found to be essentially inactive on both enzymes. On the opposite, aromatic esters strongly inactivated alpha-CT whereas HLE was less efficiently inhibited with dichlorophenyl ester derivatives (kinact/K(I) = 4000 M(-1) s(-1) for 36). Representative examples of amide, ester, thioester and ketone derivatives were prepared in order to evaluate the influence of the link between the coumarinic ring and the phenyl side chain. The irreversible inactivation of alpha-CT by 6-chloromethyl derivatives should be due to alkylation of a histidine residue as suggested by the amino acid analysis of the modified chymotrypsin. Conversely the inhibition of HLE was transient. Intrinsic reactivity of coumarins has been calculated using a model of a nucleophilic reaction between the ligand and the couple methanol-water. From this calculation, it appears that differences in the inhibitory potency expressed by these molecules cannot only be explained by differences in the reactivity of the lactonic carbonyl group toward the nucleophilic attack.     

The mechanism of action of dipeptidyl aminopeptidase. Inhibition by amino acid derivatives and amines; activation by aromatic compounds.

A variety of amino acid and peptide amides have been shown to be inhibitors of dipeptidyl aminopeptidase. Among these compounds derivatives of strongly hydrophobic amino acids are the strongest inhibitors (Phe-NH2, Ki = 1.0 +/- 0.2 mM), while amides of basic amino acids were somewhat less effective (Lys-NH2, Ki = 36 +/- 3 mM). Short chain amino acid amides are notably weaker inhibitors (Gly-NH2, Ki = 293 +/- 50 mM). The interaction of the side chains of compounds with the enzyme appears to be at a site other than that at which the side chain of the amino-penultimate residue of the substrate interacts since the specificity of binding is different. Primary amines have been shown to inhibit, e.g., butylamine, Ki = 340 +/- 40 mM, and aromatic compounds have been shown to stimulate activity toward Gly-Gly-NH2 and Gly-Gly-OEt (phenol, 35% stimulation of activity at a 1:1 molar ratio with the substrate). The data suggest that inhibition involves binding at the site occupied by the free alpha-amino group and the N-terminal amino acid.     

SNAP-25 substrate peptide (residues 180-183) binds to but bypasses cleavage by catalytically active Clostridium botulinum neurotoxin E

Clostridium botulinum neurotoxins are the most potent toxins to humans. The recognition and cleavage of SNAREs are prime evente in exhibiting their toxicity. We report here the crystal structure of the catalytically active full-length botulinum serotype E catalytic domain (BoNT E) in complex with SNAP-25 (a SNARE protein) substrate peptide Arg(180)-Ile(181)-Met(182)-Glu(183) (P1-P3'). It is remarkable that the peptide spanning the scissile bond binds to but bypasses cleavage by the enzyme and inhibits the catalysis fairly with K(i) approximately 69 microm. The inhibitory peptide occupies the active site of BoNT E and shows well defined electron density. The catalytic zinc and the conserved key residue Tyr(350) of the enzyme facilitate the docking of Arg(180) (P1) by interacting with its carbonyl oxygen that displaces the nucleophilic water. The general base Glu(212) side chain interacts with the main chain amino group of P1 and P1'. Conserved Arg(347) of BoNT E stabilizes the proper docking of the Ile(181) (P1') main chain, whereas the hydrophobic pockets stabilize the side chains of Ile(181) (P1') and Met(182) (P2'), and the 250 loop stabilizes Glu(183) (P3'). Structural and functional analysis revealed an important role for the P1' residue and S1' pocket in driving substrate recognition and docking at the active site. This study is the first of its kind and rationalizes the substrate cleavage strategy of BoNT E. Also, our complex structure opens up an excellent opportunity of structure-based drug design for this fast acting and extremely toxic high priority BoNT E.     

Effect of P2' substituents on kinetic constants for hydrolysis by cysteine proteinases.

Intramolecularly quenched fluorogenic peptide substrates with the general sequence: DABCYL-Lys-Phe-Gly-Gly-Xxx-Ala-EDANS have been utilized to explore the effect of the hydrophobicity of amino acid side chains in the P2' position on the steady-state kinetic constants for papain catalyzed hydrolysis. The results demonstrate that subsite interactions between the enzyme and the peptide substrate modulate the enzyme specificity by slowing the release of the C-terminal product. This series of substrates can be used to characterize substrate specificity studies of other cysteine proteinases.     

Factors, determining the effectiveness of tryptophanase interaction with amino acids

Inhibition of tryptophanase-catalyzed decomposition of S-(o-nitrophenyl)-L-cysteine by a variety of amino acids has been investigated. For amino acids similar to the natural substrate and for those having minimal steric requirements for the side chain, the linear correlation exists between-RTlnKi and side chain hydrophobicity. L-ornithine and L-arginine are anomalously potent inhibitors taking into account low hydrophobicity of their side chains. This can be explained by an interaction between a positively charged group of the side chain of L-arginine or L-ornithine and a nucleophilic group of the active site. The comparison of affinity of tryptophanase for L-phenylalanine and L-homophenylalanine indicates that there is a special locus in the active site where aromatic groups are bound and oriented approximately parallel to the cofactor plane experiencing no steric hindrance. For a large number of amino acids the rates of the enzymic alpha-proton exchange in 2H2O are comparable with the rate of the reaction with L-tryptophan. Very low rate of alpha-proton exchange observed with L-alanine is an exception.     

Penicillopepsin-JT2, a recombinant enzyme from Penicillium janthinellum and the contribution of a hydrogen bond in subsite S3 to k(cat)

The nucleotide sequence of the gene (pepA) of a zymogen of an aspartic proteinase from Penicillium janthinellum with a 71% identity in the deduced amino acid sequence to penicillopepsin (which we propose to call penicillopepsin-JT1) has been determined. The gene consists of 60 codons for a putative leader sequence of 20 amino acid residues, a sequence of about 150 nucleotides that probably codes for an activation peptide and a sequence with two introns that codes for the active aspartic proteinase. This gene, inserted into the expression vector pGPT-pyrG1, was expressed in an aspartic proteinase-free strain of Aspergillus niger var. awamori in high yield as a glycosylated form of the active enzyme that we call penicillopepsin-JT2. After removal of the carbohydrate component with endoglycosidase H, its relative molecular mass is between 33,700 and 34,000. Its kinetic properties, especially the rate-enhancing effects of the presence of alanine residues in positions P3 and P2' of substrates, are similar to those of penicillopepsin-JT1, endothiapepsin, rhizopuspepsin, and pig pepsin. Earlier findings suggested that this rate-enhancing effect was due to a hydrogen bond between the -NH- of P3 and the hydrogen bond accepting oxygen of the side chain of the fourth amino acid residue C-terminal to Asp215. Thr219 of penicillopepsin-JT2 was mutated to Ser, Val, Gly, and Ala. Thr219Ser showed an increase in k(cat) when a P3 residue was present in the substrate, which was similar to that of the wild-type, whereas the mutants Thr219Val, Thr219Gly, and Thr219Ala showed no significant increase when a P3 residue was added. The results show that the putative hydrogen bond alone is responsible for the increase. We propose that by locking the -NH- of P3 to the enzyme, the scissile peptide bond between P1 and P1' becomes distorted toward a tetrahedral conformation and becomes more susceptible to nucleophilic attack by the catalytic apparatus without the need of a conformational change in the enzyme.     

The QM/MM molecular dynamics and free energy simulations of the acylation reaction catalyzed by the serine-carboxyl peptidase kumamolisin-As

Quantum mechanical/molecular mechanical molecular dynamics and free energy simulations are performed to study the acylation reaction catalyzed by kumamolisin-As, a serine-carboxyl peptidase, and to elucidate the catalytic mechanism and the origin of substrate specificity. It is demonstrated that the nucleophilic attack by the serine residue on the substrate may not be the rate-limiting step for the acylation of the GPH*FF substrate. The present study also confirms the earlier suggestions that Asp164 acts as a general acid during the catalysis and that the electrostatic oxyanion hole interactions may not be sufficient to lead a stable tetrahedral intermediate along the reaction pathway. Moreover, Asp164 is found to act as a general base during the formation of the acyl-enzyme from the tetrahedral intermediate. The role of dynamic substrate assisted catalysis (DSAC) involving His at the P1 site of the substrate is examined for the acylation reaction. It is demonstrated that the bond-breaking and -making events at each stage of the reaction trigger a change of the position for the His side chain and lead to the formation of the alternative hydrogen bonds. The back and forth movements of the His side chain between the C=O group of Pro at P2 and Odelta2 of Asp164 in a ping-pong-like mechanism and the formation of the alternative hydrogen bonds effectively lower the free energy barriers for both the nucleophilic attack and the acyl-enzyme formation and may therefore contribute to the relatively high activity of kumamolisin-As toward the substrates with His at the P1 site.     

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.     

Interaction of tyrosine-phenol-lyase from Citrobacter intermedius with amino acids and their derivatives: factors determining the effectiveness of binding

The inhibition by L-amino acids and their derivatives of tyrosine phenol-lyase is investigated. Tyramine, alpha-phenylethylamine and tryptamine have no detectable inhibition effect and hence are weakly bonded by an active site. The aromatic amino acid amides are competitive inhibitors but do not manifest an enzymatic isotope exchange of alpha-proton in D2O. Free amino acids however are competitive inhibitors and in the majority of cases exchange alpha-proton. The presence of COOH-group is therefore an important feature which determines the binding efficiency and causes the "active" conformation of the amino acid-PLP complex labelising alpha-proton. In the absence of functional and bulky groups in the amino acid side chain the hydrophobicity is found to be the main factor determining the binding efficiency. For these amino acids a correlation exists between-RTlnKi and side chain hydrophobicity. The amino acids bearing the bulky groups, i. e. valine, leucine and isoleucine have reduced binding efficiency. Lysine and arginine bearing positively charged functional groups possess no inhibition effect. Aspartic and glutamic acids are anomalously strong inhibitors taking into consideration low hydrophobicity of their side chains. One can assume that the electrophilic group able to interact with the terminal COO- -group of aspartic and glutamic acids is located in the active site of tyrosine phenollyase.     

Kinetic study of nucleophile specificity in dipeptide synthesis catalyzed by clostridiopeptidase B

The kinetic parameters of Clostridiopeptidase B-catalyzed aminolysis of carbobenzoxyarginyl methyl ester leading to the formation of various dipeptides are investigated. The deacylation rates of the acylenzyme were evaluated by direct product analysis using high-performance liquid chromatography on a reversed-phase column. On the basis of the partitioning ratio and the first-order and second-order rate constants for the deacylation step, large differences in the nucleophile reactivities, which appear to be related to a S'1-P'1 interaction, were observed. The order of specificity was established as Leu much greater than Ser greater than Phe greater than Val greater than Ala = Gly much greater than Pro with second-order rate constants ranging from 578,614 M-1 s-1 for leucinamide to 5132 M-1 s-1 in the case of prolinamide. All of the amino acid amides had a nucleophilic strength at least 10 times higher than that of water during the deacylation step. The data reported here represent the first experimental evidence for the existence of a S'1 site engaged in the recognition of the amino acid side chain residue for this enzyme. The recognition site showed an increase in the affinity along with an increase in the hydrophobicity of the amino acid amide side chains.     

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.     

Preparation of protected peptide amides using the Fmoc chemical protocol. Comparison of resins for solid phase synthesis.

Different resins were examined for their potential use in the solid phase synthesis of protected peptide amides using the 9-fluorenylmethoxycarbonyl (Fmoc) chemical protocol. The model protected peptide amide BocTyr-Gly-Gly-Phe-Leu-Arg(Pmc)NH2 (1) was synthesized on both the acid-labile 4-(2',4'-dimethoxyphenyl-Fmoc-aminomethyl)phenoxy resin (Rink amide resin) (2) and on resins containing the base-labile linker 4-hydroxymethylbenzoic acid. Of the resins examined only the methylbenzhydrylamine resin containing the 4-hydroxymethylbenzoic acid linkage, which was cleaved by ammonolysis in isopropanol, gave the model peptide 1 in good overall yield (53% including functionalization). Thus the synthesis of protected peptide amides by solid phase synthesis using Fmoc-protected amino acids with t-butyl-type side chain protecting groups is feasible. The choice of peptide-resin linkage and its cleavage conditions, however, are critical to the success of such syntheses. The potential application of this synthetic strategy to the preparation of novel peptide amides is discussed.     

Stereospecific binding of diastereomeric peptides to salmon sperm deoxyribonucleic acid. Further evidence for partial intercalation

A series of diastereomeric dipeptide amides, containing an N-terminal L-lysyl residue and a C-terminal L- or D-amino acid with a derivatized aromatic ring on the side chain, was synthesized to determine the dependence of (1) the chirality of the N-terminal amino acid alpha-carbon and (2) the length of the N-terminal amino acid side chain for intercalation of the aromatic ring. The nature of the complex between the peptide and DNA (i.e., electrostatic, intercalative, or a combination of these) was determined by UV and CD studies, viscometric titrations, and 1H NMR studies. The results of these studies reveal distinct differences in the binding site of the aromatic rings of the various peptides. In particular, the results suggest that the alpha- and epsilon-amino groups of the lysyl residue bind electrostatically to adjacent phosphates on the DNA backbone in a stereospecific manner. As a result of this stereospecificity, the aromatic rings of the peptides with the L-L designation point toward the DNA helix, while those of the peptides of the L-D designation point away from the helix. This is completely consistent with previously reported work [Gabbay, E.J., Adawadkar, P. D., & Wilson, W. D. (1976) Biochemistry 15, 146; Gabbay, E. J., Adawadkar, P. D., Kapicak, L., Pearce, S., & Wilson, W. D. (1976) Biochemistry 15, 152]. The results also indicate a great dependence on the length of the side chain for intercalation of the aromatic ring. Specifically, if the side chain is long enough, and flexible enough, the aromatic ring can fully or partially intercalate, regardless of the chirality of the N-terminal amino acid alpha-carbon. However, if the side chain is too short, only partial intercalation is observed for peptides of the L-D designation, and no intercalation is observed for peptides of the L-D designation.     

Substrate specificity of the human matrix metalloproteinase stromelysin and the development of continuous fluorometric assays.

To probe the specificity of the metalloendoproteinase stromelysin toward peptide substrates, we determined kc/Km values for the stromelysin-catalyzed hydrolyses of peptides whose design was based loosely on the structure of a known SLN substrate, substance P (Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-MetNH2, hydrolysis at Gln-Phe, kc/Km = 1700 M-1 s-1). Several noteworthy points emerge from this study: (i) Catalytic efficiency is dependent on peptide chain length with N-terminal truncation of substance P resulting in more pronounced rate-constant reductions than C-terminal truncation. These results suggest the existence of an extended active site for stromelysin. (ii) Preferences at positions P3, P2, P1, P1', and P2' are for the hydrophobic amino acids Pro, Leu, Ala, Nva, and Trp, respectively. (iii) Investigation of specificity at P3' supports our earlier hypothesis that SLN has a requirement for a hydrogen-bond donor at this position in its substrates. Based on these observations, we designed and had synthesized the fluorogenic substrate N-(2,4-dinitrophenyl)Arg-Pro-Lys-Pro-Leu-Ala-Nva-TrpNH2, whose stromelysin-catalyzed hydrolysis can be monitored continuously (kc/Km = 45,000 M-1 s-1).     

Mechanism of inhibition of the retroviral protease by a Rous sarcoma virus peptide substrate representing the cleavage site between the gag p2 and p10 proteins.

The activity of the avian myeloblastosis virus (AMV) or the human immunodeficiency virus type 1 (HIV-1) protease on peptide substrates which represent cleavage sites found in the gag and gag-pol polyproteins of Rous sarcoma virus (RSV) and HIV-1 has been analyzed. Each protease efficiently processed cleavage site substrates found in their cognate polyprotein precursors. Additionally, in some instances heterologous activity was detected. The catalytic efficiency of the RSV protease on cognate substrates varied by as much as 30-fold. The least efficiently processed substrate, p2-p10, represents the cleavage site between the RSV p2 and p10 proteins. This peptide was inhibitory to the AMV as well as the HIV-1 and HIV-2 protease cleavage of other substrate peptides with Ki values in the 5-20 microM range. Molecular modeling of the RSV protease with the p2-p10 peptide docked in the substrate binding pocket and analysis of a series of single-amino acid-substituted p2-p10 peptide analogues suggested that this peptide is inhibitory because of the potential of a serine residue in the P1' position to interact with one of the catalytic aspartic acid residues. To open the binding pocket and allow rotational freedom for the serine in P1', there is a further requirement for either a glycine or a polar residue in P2' and/or a large amino acid residue in P3'. The amino acid residues in P1-P4 provide interactions for tight binding of the peptide in the substrate binding pocket.     

Broadly distributed chemical reactivity of natural antibodies expressed in coordination with specific antigen binding activity

Antibody (Ab) nucleophilic reactivity was studied using hapten and polypeptide antigens containing biotinylated phosphonate diester groups (covalently reactive antigen analogs, CRAs). Polyclonal IgG from healthy donors formed covalent adducts with a positively charged hapten CRA at levels superior to trypsin. Each of the 16 single chain Fv clones studied expressed a similar reactivity, indicating the V domain location of the nucleophiles and their broad distribution in diverse Abs. The formation of hapten CRA-Fv adducts was correlated with Fv proteolytic activity determined by cleavage of a model peptide substrate. Despite excellent nucleophilicity, proteolysis by IgG proceeded at lower rates than trypsin, suggesting that events occurring after nucleophilic attack on the substrate limit the rate of Ab proteolysis. The extracellular domain of the epidermal growth factor receptor with phosphonate diester groups at Lys side chains and a synthetic peptide corresponding to residues 421- 431 of human immunodeficiency virus glycoprotein (gp) 120 with the phosphonate diester at the C terminus formed covalent adducts with specific polyclonal and monoclonal Abs raised by immunization with epidermal growth factor receptor and synthetic gp120-(421- 436) devoid of phosphonate diester groups, respectively. Adduct formation was inhibited by extracellular domain of the epidermal growth factor receptor (exEGFB) and synthetic gp120-(421- 436) devoid of phosphonate groups, suggesting that the nucleophiles are located within the antigen binding sites. These results suggest the innate character of the Ab nucleophilic reactivity, its functional coordination with non-covalent adaptive binding interactions developing over the course of B cell maturation, and novel routes toward permanent inhibition of Abs.     

Design and synthesis of substrate analogue inhibitors of peptide deformylase

Series of substrates derivatives of peptide deformylase were systematically synthesized and studied for their capacities to undergo hydrolysis. Data analysis indicated the requirement for a hydrophobic first side chain and for at least two main chain carbonyl groups in the substrate. For instance, Fo-Met-OCH3 and Fo-Nle-OCH3 were the minimal substrates of peptide deformylase obtained in this study, while positively charged Fo-Nle-ArgNH2 was the most efficient substrate (kcat/Km = 4.5 x 10(5) M-1.s-1). On the basis of this knowledge, 3-mercapto-2-benzylpropanoylglycine (thiorphan), a known inhibitor of thermolysin, could be predicted and further shown to inhibit the deformylation reaction. The inhibition by this compound was competitive and proved to depend on the hydrophobicity at the P1' position. Spectroscopic evidence that the sulfur group of thiorphan binds next to the active site metal ion on the enzyme could be obtained. Consequently, a small thiopseudopeptide derived from Fo-Nle-OCH3 was designed and synthesized. This compound behaved as a competitive inhibitor of peptide deformylase with KI = 52 +/- 5 microM. Introduction of a positive charge to this thiopeptide via addition of an arginine at P2' improved the inhibition constant up to 2.5 +/- 0.5 microM, a value 4 orders of magnitude smaller than that of the starting inhibitors. Evidence that this inhibitor, imino[(5-methoxy-5-oxo-4-[[2-(sulfanylmethyl)hexanoyl]amino]pentyl )am ino]methanamine, binds inside the active site cavity of peptide deformylase, while keeping intact the 3D fold of the protein, was provided by NMR. A fingerprint of the interaction of the inhibitor with the residues of the enzyme was obtained.     

Glycine flanked by hydrophobic bulky amino acid residues as minimal sequence for effective subtilisin catalysis.

The specificity of alkaline mesentericopeptidase (a proteinase closely related to subtilisin BPN') for the C-terminal moiety of the peptide substrate (Pi' specificity) has been studied in both hydrolysis and aminolysis reactions. N-Anthraniloylated peptide p-nitroanilides as fluorogenic substrates and amino acid or peptide derivatives as nucleophiles were used in the enzymic peptide hydrolysis and synthesis. Both hydrolysis and aminolysis kinetic data suggest a stringent specificity of mesentericopeptidase and related subtilisins to glycine as P1' residue and predilection for bulky hydrophobic P2' residues. A synergism in the action of S1' and S2'subsites has been observed. It appears that glycine flanked on both sides by hydrophobic bulky amino acid residues is the minimal amino acid sequence for an effective subtilisin catalysis.     

Specificity of human cathepsin S determined by processing of peptide substrates and MHC class II-associated invariant chain

Cathepsin S (CatS) is a lysosomal cysteine protease of the papain family, the members of which possess relatively broad substrate specificities. It has distinct roles in major histocompatibility complex (MHC) class II-associated peptide loading and in antigen processing in both the MHC class I and class II pathways. It may therefore represent a target for interference with antigen presentation, which could be of value in the therapy of (auto)immune diseases. To obtain more detailed information on the specificity of CatS, we mapped its cleavage site preferences at subsites S3-S1' by in vitro processing of a peptide library. Only five amino acid residues at the substrate's P2 position allowed for cleavage by CatS under time-limited conditions. Preferences for groups of amino acid residues were also observed at positions P3, P1 and P1'. Based on these results, we developed highly CatS-sensitive peptides. After processing of MHC class II-associated invariant chain (Ii), a natural protein substrate of CatS, we identified CatS cleavage sites in Ii of which a majority matched the amino acid residue preference data obtained with peptides. These observed cleavage sites in Ii might be of relevance for its in vivo processing by CatS.