Reaction mechanism, specificity and pH-dependence of peptide synthesis catalyzed by the metalloproteinase thermolysin

The initial rates of peptide bond formation catalyzed by the metalloproteinase thermolysin were determined. The dependence of the formation rates on the concentration of the carboxyl donor and the acceptor can be explained by a rapid-equilibrium random bireactant mechanism, in which the binding of one substrate has a positive influence on the binding of the other (synergism). The specificity of the enzyme for the donor and acceptor in the condensation reaction was further investigated by determining the apparent kinetic parameters kcat and Km for various substrates. The pH-dependence of the initial rates of synthesis was found to be identical to the pH-dependence of the hydrolytic action of the enzyme. The rates are also shown to be independent of the pKa of the amino group of the acceptor, indicating that deprotonation of the attacking nucleophile in the synthetic reaction is not rate-limiting.     

Separation of tryptophan pyrrolooxygenase into three molecular forms. A study of their substrate specificities using tryptophyl-containing peptides and proteins

Tryptophan pyrrolooxygenase from wheat germ was separated into three molecular forms by microgranular DEAE-cellulose using a stepwise or a linear gradient elution procedure. In the first case molecular forms A and B were eluted with 10 mM Tris/HCl buffer (pH 7.4) and molecular form C was eluted with 50 mM KCl in the same buffer. The same separation could also be achieved with a linear KCl gradient (0-100 mM) in 10 mM Tris/HCl buffer (pH 7.4). The three molecular forms of tryptophan pyrrolooxygenase oxidized L-, D-, DL-Trp as well as many Trp derivatives with formation of N-formylkynurenyl derivatives. They also efficiently oxidized Trp-Phe, Trp-Tyr, Trp-Ala, Ala-Trp, Trp-Gly, Gly-Trp, Trp-Leu, Leu-Trp, Pro-Trp and Val-Trp, although the dipeptides were oxidized at different rates by the three molecular forms. A number of tryptophyl-containing tetra-, penta-, octa-, nona- and decapeptides were also oxidized. The oligopeptides which were known to have a helical conformation were better substrates than the smaller oligopeptides which were devoid of the conformational factor. The three molecular forms of tryptophan pyrrolooxygenase oxidized the tryptophyl residues of lysozyme, pepsin, chymotrypsin, trypsin and bovine serum albumin. It was found that molecular form A oxidized the more exposed (or hydrophilic) Trp residues of the proteins, while molecular form C also oxidized the Trp residues of a more hydrophobic nature. The three molecular forms were inhibited by chelating agents (alpha, alpha'-dipyridyl, EDTA and omicron-phenanthroline), although they differed in their sensitivities to these agents. Their optimum temperatures and inactivation rates at 65 degrees C was also different.     

Studies on interaction of oligopeptides with sodium dodecyl sulfate: Stopped-flow kinetics of chemical modification of tryptophan residues withN-bromosuccinimide

The stopped-flow kinetics of the reaction between oligopeptides containing tryptophan residues andN-bromosuccinimide (NBS) were studied in 50 mM sodium phosphate buffer (pH 7.0) containing sodium dodecyl sulfate (SDS). Decreases in the reaction rates attributable to the interaction between oligopeptides and SDS were observed, and oligopeptides studied were classified into types I and II on the basis of the interaction modes. Type I oligopeptides were dissolved in SDS micelles; type II oligopeptides interacted cooperatively with SDS monomers. The manner of interaction between SDS and oligopeptides of type II could be interpreted by a simple equilibrium relation: oligopeptide+n·(SDS)=oligopeptide·(SDS) _n .     

Studies on interaction of oligopeptides with sodium dodecyl sulfate: Stopped-flow kinetics of chemical modification of tryptophan residues withN-bromosuccinimide

The stopped-flow kinetics of the reaction between oligopeptides containing tryptophan residues andN-bromosuccinimide (NBS) were studied in 50 mM sodium phosphate buffer (pH 7.0) containing sodium dodecyl sulfate (SDS). Decreases in the reaction rates attributable to the interaction between oligopeptides and SDS were observed, and oligopeptides studied were classified into types I and II on the basis of the interaction modes. Type I oligopeptides were dissolved in SDS micelles; type II oligopeptides interacted cooperatively with SDS monomers. The manner of interaction between SDS and oligopeptides of type II could be interpreted by a simple equilibrium relation: oligopeptide+n·(SDS)=oligopeptide·(SDS) _n .     

Isolation and characterization of pepsinogen from Trimeresurus flavoviridis (Habu snake)

Pepsinogen was isolated from the gastric mucosa of Trimeresurus flavoviridis (Habu snake) by DEAE-cellulose and DEAE-Sepharose ion-exchange chromatographies, and Sephacryl S-200 gel-chromatography. The yield calculated from the crude extract was 29% with 6.2-fold purification. The purified pepsinogen gave a single band on both native- and SDS-PAGE. As no other active enzyme was detected on the chromatographies, it was concluded that the Habu snake has one major pepsinogen. The molecular mass of the pepsinogen was estimated to be 38 kDa by SDS-PAGE. The sequence of the N-terminal 26 amino acid residues was determined and compared with those of other pepsinogens. The N-terminal structure of Habu snake pepsinogen was more homologous with those of mammalian pepsinogens C than those of mammalian pepsinogens A. The pepsinogen was rapidly converted to pepsin by way of an intermediate form induced by acidification. The optimum pH of Habu snake pepsin for bovine hemoglobin was 1.5-2.0, and it retained full activity at pH 6.2 and 30 degrees C on incubation for 30 min. The optimum temperature for the snake pepsin was 50 degrees C and it was stable at 40 degrees C on incubation for 10 min. The proteolytic activity of the pepsin toward bovine hemoglobin was about two times higher than that of porcine pepsin A, however, the activity toward oxidized bovine insulin B-chain was lower than that of porcine pepsin A, and it did not hydrolyze oligopeptides. The specificity for oxidized bovine insulin B-chain of the pepsin was different from that of porcine pepsin A. Habu snake pepsin was inhibited by pepstatin A but not by serine, cysteine, or metallo protease inhibitors.     

The evolution of function in strictosidine synthase-like proteins

The exponential growth of sequence data provides abundant information for the discovery of new enzyme reactions. Correctly annotating the functions of highly diverse proteins can be difficult, however, hindering use of this information. Global analysis of large superfamilies of related proteins is a powerful strategy for understanding the evolution of reactions by identifying catalytic commonalities and differences in reaction and substrate specificity, even when only a few members have been biochemically or structurally characterized. A comparison of >2500 sequences sharing the six-bladed β-propeller fold establishes sequence, structural, and functional links among the three subgroups of the functionally diverse N6P superfamily: the arylesterase-like and senescence marker protein-30/gluconolactonase/luciferin-regenerating enzyme-like (SGL) subgroups, representing enzymes that catalyze lactonase and related hydrolytic reactions, and the so-called strictosidine synthase-like (SSL) subgroup. Metal-coordinating residues were identified as broadly conserved in the active sites of all three subgroups except for a few proteins from the SSL subgroup, which have been experimentally determined to catalyze the quite different strictosidine synthase (SS) reaction, a metal-independent condensation reaction. Despite these differences, comparison of conserved catalytic features of the arylesterase-like and SGL enzymes with the SSs identified similar structural and mechanistic attributes between the hydrolytic reactions catalyzed by the former and the condensation reaction catalyzed by SS. The results also suggest that despite their annotations, the great majority of these >500 SSL sequences do not catalyze the SS reaction; rather, they likely catalyze hydrolytic reactions typical of the other two subgroups instead. This prediction was confirmed experimentally for one of these proteins.     

Selective cleavage of pepsin by molybdenum metallopeptidase

In this study, the cleavage of protein by molybdenum cluster is reported for the first time. The protein target used is porcine pepsin. The data presented in this study show that pepsin is cleaved to at least three fragments with molecular weights of ～23, ～19 and ～16 kDa when the mixture of the protein and ammonium heptamolybdate tetrahydrate ((NH(4))(6)Mo(7)O(24)·4H(2)O) was incubated at 37°C for 24h. No self cleavage of pepsin occurs at 37 °C, 24h indicating that the reaction is mediated by the metal ions. N-terminal sequencing of the peptide fragments indicated three cleavage sites of pepsin between Leu 112-Tyr 113, Leu 166-Leu 167 and Leu 178-Asn 179. The cleavage reaction occurs after incubation of the mixture of pepsin and (NH(4))(6)Mo(7)O(24)·4H(2)O) only for 2h. However, the specificity of the cleavage decreases when incubation time is longer than 48 h. The mechanism for cleavage of pepsin is expected to be hydrolytic chemistry of the amide bonds in the protein backbone.     

Role of S'1 loop residues in the substrate specificities of pepsin A and chymosin

Proteolytic specificities of human pepsin A and monkey chymosin were investigated with a variety of oligopeptides as substrates. Human pepsin A had a strict preference for hydrophobic/aromatic residues at P'1, while monkey chymosin showed a diversified preferences accommodating charged residues as well as hydrophobic/aromatic ones. A comparison of residues forming the S'1 subsite between mammalian pepsins A and chymosins demonstrated the presence of conservative residues including Tyr(189), Ile(213), and Ile(300) and group-specific residues in the 289-299 loop region near the C terminus. The group-specific residues consisted of hydrophobic residues in pepsin A (Met(289), Leu/Ile/Val(291), and Leu(298)) and charged or polar residues in chymosins (Asp/Glu(289) and Gln/His/Lys(298)). Because the residues in the loop appeared to be involved in the unique specificities of respective types of enzymes, site-directed mutagenesis was undertaken to replace pepsin-A-specific residues by chymosin-specific ones and vice versa. A yeast expression vector for glutathione-S-transferase fusion protein was newly developed for expression of mutant proteins. The specificities of pepsin-A mutants could be successfully altered to the chymosin-like preference and those of chymosin mutants, to pepsin-like specificities, confirming residues in the S'1 loop to be essential for unique proteolytic properties of the enzymes. An increase in preference for charged residues at P'1 in pepsin-A mutants might have been due to an increase in the hydrogen-bonding interactions. In chymosin mutants, the reverse is possible. The changes in the catalytic efficiency for peptides having charged residues at P'1 were dominated by k(cat) rather than K(m) values.     

Synthesis and hydrolysis by pepsin and trypsin of a cyclic hexapeptide containing lysine and phenylalanine.

1. A cyclic hexapeptide, cyclo(-Gly2-Phe2-Gly-Lys-), and the corresponding open-chain hexapeptides, Gly2-Phe2-Gly-Lys and Phe-Gly-Lys-Gly2-Phe, have been synthesized and their susceptibilities to the hydrolytic action of pepsin and trypsin were determined. 2. The cyclic peptide was hydrolyzed slowly by trypsin to a hexapeptide Gly2-Phe2-Gly-Lys, the value of the Michaelis constant for this reaction being Km equals 0.00022 M. 3. The cyclic peptide was not cleaved by pepsin at all, but Gly2-Phe2-Gly-Lys was hydrolyzed rapidly at a Phe-Phe bond; Km equals 0.0091 M. 4. The cyclic peptide inhibits the hydrolysis of Gly2-Phe2-Gly-Lys by pepsin in a linear non-competitive manner, the value of the inhibition constant being Ki equals 0.004 M.     

Factors regulating the elongation of palmitic and stearic acid by rat liver microsomes.

Analysis of the rates of overall chain elongation and condensation of malonyl-CoA with palmitoyl-CoA and stearoyl-CoA as primers demonstrated that for each primer, the rate of the overall metabolic process was similar to the initial condensation. The specific activity for condensation with palmitoyl-CoA was eleven times greater than for stearoyl-CoA. The specific activities of both the beta-hydroxyacyl-CoA dehydrase and 2-trans-enoyl-CoA reductase reactions were much higher than for either condensation or chain elongation, although these rates were somewhat greater with the intermediates required in chain elongating palmitoyl-CoA than for stearoyl-CoA. Both substrates were incorporated into phospholipids at low rates and there was a time-dependent hydrolytic cleavage of the acyl-CoA primers which was partially prevented by bovine serum albumin. These findings demonstrate that there was no selective removal of either primer which could result in specific substrate depletion and an apparent reduction in the rate of condensation. These combined results firmly establish the rate-limiting nature and high degree of substrate specificity exhibited during the initial condensation step in fatty acid elongation.     

Peptide synthesis using o-nitrophenylsulfenyl N-carboxy alpha-amino acid anhydrides. Sequential oligopeptides having alternate gamma-methyl L-glutamyl and L-phenylalanyl residues.

A series of sequential oligopeptides having the sequence alternating γ-methyl L -glutamyl and L -phenylalanyl residues have been successfully prepared by a rapid method involving the reaction of o-nitrophenylsulfenyl N-carboxy α-amino acid anhydrides with amino acid and peptide esters. The sequential oligopeptides, which are interesting from a conformational aspect, were obtained in optical pure forms above 74% yields. This result demonstrates that the o-nitrophenylsulfenyl N-carboxy α-amino acid anhydride method is especially useful for easy synthesis of protected oligopeptides with o-nitrophenylsulfenyl group.     

Preparation and characterization of urea-formaldehyde-pepsin bioconjugate: a new biocatalyst system

This study describes the synthesis of urea formaldehyde (UF) microspheres by a dispersion polycondensation polymerization method. These microspheres with proper F/U molar ratio can provide highly reactive groups, capable of further condensation with the amino acid residues of enzyme/proteins. Presence of methylols groups in UF microspheres was confirmed by 13C NMR study. Pepsin, a proteolytic enzyme, was immobilized on the UF microspheres to form bioconjugate system. As compared to the free enzyme in solution, the pepsin in the bioconjugate system exhibited significantly enhanced pH and temperature stability. The urea-formaldehyde-pepsin bioconjugate system also exhibited excellent proteolytic activity over eight successive reuse cycles with more than 50% of initial activity. A highlight of this new biocatalyst is the ease with which separation of this biocatalyst from the reaction medium may be achieved by mild centrifugation.     

Mutants of Mucor hiemalis endo-beta-N-acetylglucosaminidase show enhanced transglycosylation and glycosynthase-like activities

Endo-beta-N-acetylglucosaminidase from Mucor hiemalis (Endo-M), a family 85 glycoside hydrolase, acts on the beta1,4 linkage of N,N'-diacetylchitobiose moiety in the N-linked glycans of glycoproteins and catalyzes not only the hydrolysis reaction but also the transglycosylation reaction that transfers the releasing sugar chain to an acceptor other than water to form a new glycosidic linkage. The transglycosylation activity of Endo-M holds a great promise for the chemo-enzymatic synthesis and glyco-engineering of glycoproteins, but the inherent hydrolytic activity for product hydrolysis and low transglycosylation have hampered its broad applications. This paper describes the site-directed mutagenesis on residues in the putative catalytic region of Endo-M to generate mutants with superior transglycosylation activity. Two interesting mutants were discovered. The Y217F mutant was found to possess much enhanced transglycosylation activity and yet much diminished hydrolytic activity in comparison with the wild-type Endo-M. Kinetic analyses revealed that the Km value of Y217F for an acceptor substrate 4-methylumbelliferyl-beta-D-N-acetylglucosaminide was only one-tenth of that of the wild-type, implicating a much higher affinity of Y217F for the acceptor substrate than the wild-type. The other mutant, N175A, acts like a glycosynthase. It was found that mutation at Asn175"knocked out" the hydrolytic activity, but the mutant was able to take the highly active sugar oxazolines (the transition state mimics) as donor substrates for transglycosylation. This is the first glycosynthase derived from endo-beta-N-acetylglucosaminidases that proceed via a substrate-assisted mechanism. Our findings provide further insights on the substrate-assisted mechanism of GH85. The usefulness of the novel glycosynthase was exemplified by the efficient synthesis of a human immunodeficiency virus, type 1 (HIV-1) glycopeptide with potent anti-HIV activity.     

Specific cleavage of reduced and S-carboxamidomethylated neurophysin II by the collagenase of Clostridium histolyticum.

Purified collagenase of Clostridium histolyticum was shown to cleave reduced and S-carboxamidomethylated bovine neurophysin between Cys-13 and Gly-14. The scission resulted in formation of two separable fragments: a smaller peptide arising from residues 1 through 13, and a larger peptide comprising the remainder of the residues of the protein. By dansylation procedures, the smaller peptide was shown to have amino-terminal alanine as expected from the sequence of neurophysin II, and the larger peptide had amino-terminal glycine as anticipated. These results show that collagenase indeed cleaves bovine neurophysin II in accord with the specificity postulated for that enzyme, i.e., scission between -X-Gly- in a sequence of -Pro-X-Gly-Pro-Y-. This result, obtained with a non-collagenous protein substrate, is further confirmation of the specificity of collagenase as established by its action on collagens and on synthetic oligopeptides.     

Kinetics and specificity of serine proteases in peptide synthesis catalyzed in organic solvents

Initial rates of peptide-bond synthesis catalyzed by poly(ethylene glycol)-modified chymotrypsin in benzene were determined using high-performance liquid chromatography. Enzymatic synthesis of N-benzoyl-L-tyrosyl-L-phenylalanine amide from N-benzoyl-L-tyrosine ethyl ester and L-phenylalanine amide was found to obey Michaelis-Menten kinetics an to be consistent with a ping-pong mechanism modified by a hydrolytic branch. The catalytic activity of modified chymotrypsin was dependent on both water concentration and type of organic solvent, the highest synthesis rate being obtained in toluene. Since the chymotrypsin specificity in the organic phase was actually altered, the enzyme's apparent kinetic parameters were determined for different substrates and compared to those obtained with other serine proteases in benzene. Both N-benzoyl-L-tyrosine ethyl ester and N-alpha-benzoyl-L-lysine methyl ester were comparable acyl donors in benzene and the (kcat/Km)app value of modified chymotrypsin was only 10-fold smaller than that obtained with poly(ethylene glycol)-modified trypsin in the synthesis of N-alpha-benzoyl-L-lysyl-L-phenylalanine amide. The change in chymotrypsin specificity was also confirmed through the binding of trypsin inhibitors in benzene. The overall results suggest that hydrophobic bonding between the enzyme and its substrate should not be taken into account during catalysis in the organic phase. In general, if hydrophobic interactions are involved in the binding of substrates to the active site in aqueous media, the replacement of water by hydrophobic solvents will induce some change in enzyme specificity. Moreover, secondary residues of enzyme-binding sites may also exert a significant influence on specificity since, as observed in this study, chymotrypsin exhibited high affinity for cationic substrates and cationic inhibitors as well in apolar solvents.     

Elimination of competing hydrolysis and coupling side reactions of a cyclodextrin glucanotransferase by directed evolution

Thermoanaerobacterium thermosulfurigenes cyclodextrin glucanotransferase primarily catalyses the formation of cyclic alpha-(1,4)-linked oligosaccharides (cyclodextrins) from starch. This enzyme also possesses unusually high hydrolytic activity as a side reaction, thought to be due to partial retention of ancestral enzyme function. This side reaction is undesirable, since it produces short saccharides that are responsible for the breakdown of the cyclodextrins formed, thus limiting the yield of cyclodextrins produced. To reduce the competing hydrolysis reaction, while maintaining the cyclization activity, we applied directed evolution, introducing random mutations throughout the cgt gene by error-prone PCR. Mutations in two residues, Ser-77 and Trp-239, on the outer region of the active site, lowered the hydrolytic activity up to 15-fold with retention of cyclization activity. In contrast, mutations within the active site could not lower hydrolytic rates, indicating an evolutionary optimized role for cyclodextrin formation by residues within this region. The crystal structure of the most effective mutant, S77P, showed no alterations to the peptide backbone. However, subtle conformational changes to the side chains of active-site residues had occurred, which may explain the increased cyclization/hydrolysis ratio. This indicates that secondary effects of mutations located on the outer regions of the catalytic site are required to lower the rates of competing side reactions, while maintaining the primary catalytic function. Subsequent functional analysis of various glucanotransferases from the superfamily of glycoside hydrolases also suggests a gradual evolutionary progression of these enzymes from a common 'intermediate-like' ancestor towards specific transglycosylation activity.     

Systematic mutagenesis of the active site omega loop of TEM-1 beta-lactamase.

Beta-Lactamase is a bacterial protein that provides resistance against beta-lactam antibiotics. TEM-1 beta-lactamase is the most prevalent plasmid-mediated beta-lactamase in gram-negative bacteria. Normally, this enzyme has high levels of hydrolytic activity for penicillins, but mutant beta-lactamases have evolved with activity toward a variety of beta-lactam antibiotics. It has been shown that active site substitutions are responsible for changes in the substrate specificity. Since mutant beta-lactamases pose a serious threat to antimicrobial therapy, the mechanisms by which mutations can alter the substrate specificity of TEM-1 beta-lactamase are of interest. Previously, screens of random libraries encompassing 31 of 55 active site amino acid positions enabled the identification of the residues responsible for maintaining the substrate specificity of TEM-1 beta-lactamase. In addition to substitutions found in clinical isolates, many other specificity-altering mutations were also identified. Interestingly, many nonspecific substitutions in the N-terminal half of the active site omega loop were found to increase ceftazidime hydrolytic activity and decrease ampicillin hydrolytic activity. To complete the active sight study, eight additional random libraries were constructed and screened for specificity-altering mutations. All additional substitutions found to alter the substrate specificity were located in the C-terminal half of the active site loop. These mutants, much like the N-terminal omega loop mutants, appear to be less stable than the wild-type enzyme. Further analysis of a 165-YYG-167 triple mutant, selected for high levels of ceftazidime hydrolytic activity, provides an example of the correlation which exists between enzyme instability and increased ceftazidime hydrolytic activity in the ceftazidime-selected omega loop mutants.     

Pepsin as a catalyst for peptide synthesis: formation of peptide bonds not typical for pepsin substrate specificity.

Porcine pepsin in water solutions containing 15-28% of dimethylformamide at pH 5 and 20-37 degrees C catalysed the formation of peptide bonds between Z-Ala-Ala-Phe-OH and various amino acid or peptide derivatives. Substrate binding subsite S1' of pepsin demonstrated broad specificity in these reactions but revealed a certain preference for hydrophobic amino acid residues, including non-proteinous homophenylalanine, p-nitrophenylalanine, S-methylcysteine, as well as for those that contained, in addition to the hydrophobic elements, a group capable of donating a hydrogen bond, e.g. o-nitrotyrosine. This observation increases the range of peptides that might be prepared by pepsin-catalysed synthesis.     

Studies on the catalytic action of poly-alpha-amino acids. VII. Stereospecificity in the enzyme-like hydrolysis of benzoyl-L-(D)-arginine-p-nitroanilides by copoly (Cys, Glu).

The substrate specificity in the hydrolysis of L-, DL-, and D-BAPA (benzoylarginine-p-nitro-anilide) by copoly (L-Cys, L-Glu) and copoly (D-Cys, D-Glu) was studied, and enzyme-like stereospecific hydrolyses by poly-alpha-amino acids were identified for the first time. The L-type copolymer hydrolyzed L-BAPA faster than D-BAPA and the rates (v) of BAPA hydrolyses by L-type copolymer were found to be in the order vL greater than vDL greater than vD. On the other hand, the D-type copolymer hydrolysed D-BAPA faster than L-BAPA and the rates of BAPA hydrolyses by D-type copolymer were in the order vD greater than vDL greater than vL. In all cases, the reaction followed Michaelis-Menten kinetics when the substrate concentration was corrected, and the optimum conditions of the reaction were pH 6.0 and 40 degrees. The activity appeared after a certain amount of BAPA had combined with the polymer. D- and L-substrates combine competitively with the polymer and the different rates of hydrolysis are presumably due to the different substrate configurations in relation to the conformation of the active site in the polymer. The polymer shows activity near the range of random coil conformation, where some alpha-helical conformation is still present. Only some of the cysteine residues in the copolymer are involved in the hydrolytic activity.     

Modified proteinases in peptide synthesis in organic media

We showed that modified proteases could catalyze synthesis of a wide variety of peptides of various lengths and structures both in solution and on solid phase in organic solvents. The following modified proteases were studied as catalysts for enzymatic peptide synthesis in polar organic solvents (acetonitrile, dimethylformamide, and ethanol): pepsin sorbed on celite, a noncovalent complex of subtilisin with sodium dodecylsulfate, and subtilisin or thermolysin covalently immobilized on a cryogel of polyvinyl alcohol. The use of the noncovalent complex of subtilisin with sodium dodecylsulfate and immobilized subtilisin is especially promising for the segment condensation of peptide fragments containing residues of trifunctional amino acids with unprotected ionogenic groups in side chains, such as Lys, Arg, His, Glu, and Asp.