Substrate recognition mechanism of thermophilic dual-substrate enzyme.

Aspartate aminotransferase from an extremely thermophilic bacterium, Thermus thermophilus HB8 (ttAspAT), has been believed to be specific for an acidic substrate. However, stepwise introduction of mutations in the active-site residues finally changed its substrate specificity to that of a dual-substrate enzyme. The final mutant, [S15D, T17V, K109S, S292R] ttAspAT, is active toward both acidic and hydrophobic substrates. During the course of stepwise mutation, the activities toward acidic and hydrophobic substrates changed independently. The introduction of a mobile Arg292* residue into ttAspAT was the key step in the change to a "dual-substrate" enzyme. The substrate recognition mechanism of this thermostable "dual-substrate" enzyme was confirmed by X-ray crystallography. This work together with previous studies on various enzymes suggest that this unique "dual-substrate recognition" mechanism is a feature of not only aminotransferases but also other enzymes.     

Substrate specificity of carboxypeptidase from Watermelon.

The substrate specificity of carboxypeptidase (F-II) purified from watermelon for various synthetic peptides and esters was examined kinetically. The enzyme showed a broad substrate specificity against various carbobenzoxy- and benzyl-dipeptides. Peptides containing glycine or proline were hydrolyzed slowly by the enzyme. 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. Inhibition studies with diisopropyl flurophosphate and diastereomers of carbobenzoxy-Phe-Ala demonstrated that the peptidase and esterase activities of the enzyme are both catalyzed by the same site of the enzyme molecule, but the binding sites for peptides and esters seem not to be the same. The enzyme also had amidase activity, which was optimal at pH 7.0.     

Substrate recognition mechanism of VAMP/synaptobrevin-cleaving clostridial neurotoxins

Botulinum neurotoxins (BoNTs) and tetanus neurotoxin (TeNT) inhibit neurotransmitter release by proteolyzing a single peptide bond in one of the three soluble N-ethylmaleimide-sensitive factor attachment protein receptors SNAP-25, syntaxin, and vesicle-associated membrane protein (VAMP)/synaptobrevin. TeNT and BoNT/B, D, F, and G of the seven known BoNTs cleave the synaptic vesicle protein VAMP/synaptobrevin. Except for BoNT/B and TeNT, they cleave unique peptide bonds, and prior work suggested that different substrate segments are required for the interaction of each toxin. Although the mode of SNAP-25 cleavage by BoNT/A and E has recently been studied in detail, the mechanism of VAMP/synaptobrevin proteolysis is fragmentary. Here, we report the determination of all substrate residues that are involved in the interaction with BoNT/B, D, and F and TeNT by means of systematic mutagenesis of VAMP/synaptobrevin. For each of the toxins, three or more residues clustered at an N-terminal site remote from the respective scissile bond are identified that affect solely substrate binding. These exosites exhibit different sizes and distances to the scissile peptide bonds for each neurotoxin. Substrate segments C-terminal of the cleavage site (P4-P4') do not play a role in the catalytic process. Mutation of residues in the proximity of the scissile bond exclusively affects the turnover number; however, the importance of individual positions at the cleavage sites varied for each toxin. The data show that, similar to the SNAP-25 proteolyzing BoNT/A and E, VAMP/synaptobrevin-specific clostridial neurotoxins also initiate substrate interaction, employing an exosite located N-terminal of the scissile peptide bond.     

Substrate recognition mechanism of prolyl aminopeptidase from Serratia marcescens

Molecular cloning of the gene and the crystal structure of the prolyl aminopeptidase [EC 3.4.11.5] from Serratia marcescens have been studied by us [J. Biochem. 122, 601-605 (1997); ibid. 126, 559-565 (1999)]. Through these studies, Phe139, Tyr149, Glu204, and Arg136 were estimated to be concerned with substrate recognition. To elucidate the details of the mechanism for the substrate specificity, the site-directed mutagenesis method was applied. The F139A mutant showed an 80-fold decrease in catalytic efficiency (k(cat)/K(m)), but the Y149A mutant did not show a significant change in catalytic efficiency. The catalytic efficiency of the E204Q mutant was about 4% of that of the wild type. The peptidase activity of the mutant (R136A) was markedly decreased, however, arylamidase activity with Pyr-bNA was retained as in the wild-enzyme. From these results, it was clarified that the pyrrolidine ring and the amino group of proline at the S1 site were recognized by Phe139 and Glu204, respectively. P1' of a substrate was recognized by Arg136. On the other hand, the enzyme had two cysteine residues. Mutants C74A and C271A were inhibited by PCMB, but the double mutated enzyme (C74/271A) was resistant to it.     

Proteinase C (carboxypeptidase Y) mutant of yeast.

A mutant of yeast lacking proteinase C (carboxypeptidase Y) activity has been found by using a histochemical stain to screen mutagenized colonies. This defect segregates 2:2 in meiotic tetrads. Cell extracts lacked the esterolytic, amidase, and proteolytic activities associated with proteinase C. The absence of proteinase C does not affect mitotic growth and has no obvious effect on the formation of viable ascospores or meiotic segregation. The mutant grows on peptides known to be cleaved by proteinase C in vitro. This finding is consistent with the idea that other enzymes exist in vivo with overlapping substrate specificities.     

Studies on a carboxypeptidase Y mutant of yeast and evidence for a second carboxypeptidase Activity.

Immunological studies on the carboxypeptidase Y mutant prcl-l of Saccharomyces cerevisiae revealed the origin of mutation in the structural gene of carboxypeptidase Y. The absence of carboxypeptidase Y has no effect on growth, even after drastic changes of growth conditions. A double mutant (prc 1- leu2-) lacking carboxypeptidase Y and auxotrophic for leucine is able to grow on the peptide benzyloxycarbonylglycylleucine (Cbz-Gly-Leu) as sole nitrogen source, indicating the existence of a second carboxypeptidase. Using a new peptidase test, the existence of this second enzyme, called carboxypeptidase S, was confirmed biochemically.     

Catalytic activity of carboxypeptidase B and of carboxypeptidase Y with anisylazoformyl substrates

Anisylazoformyllysine (CH3OC6H4-N = N-CO-Lys-OH) is rapidly hydrolyzed at the acyl-lysine linkage by the zinc-enzyme porcine carboxypeptidase B. The catalytic reaction is readily monitored spectrophotometrically by disappearance of the intense absorption (348.5 nm, epsilon 18400) of the azo chromophore, which chemically fragments after substrate cleavage. Carboxypeptidase Y has no activity toward this type of substrate.     

Reaction pathway and free energy profile determined for specific recognition of oligosaccharide moiety of carboxypeptidase Y

The interaction of mannose specific lectin (from Lens culinaris, LcL) with the carbohydrate moiety of carboxypeptidase Y (CaY) was studied using both atomic force microscope (AFM) and quartz crystal microbalance with dissipation monitoring (QCM-D). The AFM enables to determine the positions of energy barriers present in the energy landscape of the single complex undergoing dissociation. The QCM-D measurements allow the estimation of the quantitative parameters characterizing the kinetics of the studied molecular interaction (namely the association and dissociation rate constants and the association constant). The use of both methods not only delivers the complementary characterization of kinetic and thermodynamic parameters but also permits to investigate the mechanism of the binding and unbinding of the molecules. The results for LcL were compared with those obtained for concanavalin A i.e. lectin, which interacts with the carbohydrate moiety on a similar way.     

Peptide synthesis with immobilized carboxypeptidase Y

Enzymatic peptide synthesis was investigated using carboxypeptidase Y immobilized with glutaraldehyde on 10 mum microparticulate amino-silica. Carboxypeptidase Y was immobilized with 98.5% recovery of active enzyme to yield the immobilized enzyme having 0.55 units esterase activity/mg amino-silica support. The stability of the immobilized enzyme was examined as a function of pH, temperature, and reactant concentrations. Immobilized Carboxypeptidase Y was used in stirred batch and recirculating packed-bed reactors for peptide synthesis. Packed-bed reactors (40 x 4.6 mm, 60 x 4.6 mm) were used to catalyze the synthesis of 170 mg N-benzoyl-L-arginyl-L-methioninamide, 380 mg N-benzoyl-L-arginyl-L-methionyl-L-leucinamide, and 200 mg N-benzoyl-L-arginyl-L-methionyl-L-leucyl-L-phenylalaninamide in 8, 3, and 1 hour, respectively, as intermediates in the synthesis of L-methionyl-L-leucyl-L-phenylalanine. No inactivation of the immobilized enzyme was observed during the course of the reactions. The N-benzoyl-L-arginyl group served to increase the water solubility of the peptides and was removed by immobilized trypsin at the end of synthesis to obtain the final product. While the first two syntheses were conducted with aqueous reaction mixtures, the synthesis of N-benzoyl-L-arginyl-L-methionyl-L-leucyl-L-phenylalaninamide was carried out in a reaction mixture containing dimethylformamide to avoid precipitation of the product. HPLC and amino acid analysis confirmed the high purity and amino acid composition of the final product.     

Sub-zero temperature inactivation of carboxypeptidase Y under high hydrostatic pressure.

High hydrostatic pressure induced cold inactivation of carboxypeptidase Y. Carboxypeptidase Y was fully active when exposed to subzero temperature at 0.1 MPa; however, the enzyme became inactive when high hydrostatic pressure and subzero temperature were both applied. When the enzyme was treated at pressures higher than 300 MPa and temperatures lower than -5 degrees C, it underwent an irreversible inactivation in which nearly 50% of the alpha-helical structure was lost as judged by circular dichroism spectral analysis. When the applied pressure was limited to below 200 MPa, the cold inactivation process appeared to be reversible. In the presence of reducing agent, this reversible phenomenon, observed at below 200 MPa, diminished to give an inactive enzyme; the agent reduces some of disulfide bridge(s) in an area of the structure that is newly exposed area because of the cold inactivation. Such an area is unavailable if carboxypeptidase Y is in its native conformation. Because all the disulfide bridges in carboxypeptidase Y locate near the active site cleft, it is suggested that the structural destruction, if any, occurs preferentially in this disulfide rich area. A possible mechanism of pressure-dependent cold inactivation of CPY is to destroy the alpha-helix rich region, which creates an hydrophobic environment. This destruction is probably a result of the reallocation of water molecules. Experiments carried out in the presence of denaturing agents (SDS, urea, GdnHCl), salts, glycerol, and sucrose led to a conclusion consistent with the idea of water reallocation.     

Regulated overproduction and secretion of yeast carboxypeptidase Y

Summary Carboxypeptidase Y (CPY) is a glycosylated yeast vacuolar protease used commercially for synthesis of peptides. To increase the production of CPY in Saccharomyces cerevisiae we have placed its coding region (PRC1) under control of the strongly regulated yeast GAL1 promoter on multicopy plasmids and introduced the constructs into vpl1 mutant strains. Such mutants are known to secrete CPY. High levels of CPY production were obtained by induction of the GAL1 promoter when the cells had left the exponential phase, resulting in a growth-phase-dependent CPY production similar to that cells with PRC1 under the control of its own promoter. Introduction of a high copy number 2-URA3-EU2d plasmid with GAL1p-PRC1 fusion in a vpl1 strain resulted in a 200-fold increase of secreted CPY (about 40 mg/l) as compared to a vpl1 mutant carrying a single copy of the wild-type PRC1 gene. The overproduced, secreted CPY was active and had the normal N-terminal sequence. Sodium dodecyl sulphate polyacrylamide gel electrophoresis revealed two forms of active CPY, probably due to different levels of glycosylation. Offprint requests to: T. L. Nielsen     

Substrate recognition mechanism of a glycosyltrehalose trehalohydrolase from Sulfolobus solfataricus KM1

Glycosyltrehalose trehalohydrolase (GTHase) is an α-amylase that cleaves the α-1,4 bond adjacent to the α-1,1 bond of maltooligosyltrehalose to release trehalose. To investigate the catalytic and substrate recognition mechanisms of GTHase, two residues, Asp252 (nucleophile) and Glu283 (general acid/base), located at the catalytic site of GTHase were mutated (Asp252→Ser (D252S), Glu (D252E) and Glu283→Gln (E283Q)), and the activity and structure of the enzyme were investigated. The E283Q, D252E, and D252S mutants showed only 0.04, 0.03, and 0.6% of enzymatic activity against the wild-type, respectively. The crystal structure of the E283Q mutant GTHase in complex with the substrate, maltotriosyltrehalose (G3-Tre), was determined to 2.6-Å resolution. The structure with G3-Tre indicated that GTHase has at least five substrate binding subsites and that Glu283 is the catalytic acid, and Asp252 is the nucleophile that attacks the C1 carbon in the glycosidic linkage of G3-Tre. The complex structure also revealed a scheme for substrate recognition by GTHase. Substrate recognition involves two unique interactions: stacking of Tyr325 with the terminal glucose ring of the trehalose moiety and perpendicularly placement of Trp215 to the pyranose rings at the subsites −1 and +1 glucose.     

Structural requirements for nucleophilic substrates of carboxypeptidase Y

The composition and structural aspects of the amino and carboxylic acid groups required for incorporation into peptides by transpeptidation and inhibition of hydrolysis in carboxypeptidase Y-catalyzed reactions were studied. Separation of these two groups by even one carbon prevents incorporation by transpeptidation and does not inhibit incorporation of other amino acids into model peptides. Substitution of phosphonic or sulfonic acids for the carboxylic acid group also results in loss of incorporation by transpeptidation. Only the sulfonic acid analog of glycine causes inhibition of hydrolysis and this inhibition is lost when serine is included in the reaction. d-Serine is not incorporated by carboxypeptidase Y, and its presence in the reaction mixture does not inhibit the incorporation of the L-isomer.     

Gene dosage-dependent secretion of yeast vacuolar carboxypeptidase Y

The structural gene for yeast vacuolar carboxypeptidase Y (PRC1) has been cloned by complementation of the prc1-1 mutation. As much as an eightfold elevation in the level of carboxypeptidase Y (CPY) results when a multiple-copy plasmid containing the PRC1 gene is introduced into yeast. Unlike the situation with a single copy of PRC1 in which newly synthesized CPY is efficiently localized to the vacuole, plasmid-directed overproduction results in secretion of greater than 50% of the protein as the precursor form. Secretion is blocked in a mutant that is defective at a late stage in the transport of periplasmic proteins. Unlike normal cell surface glycoproteins, secreted CPY precursor acquires no additional oligosaccharide modifications beyond those that accompany normal transport to the vacuole. In the periplasm, the CPY precursor is proteolytically activated to an enzymatically active form by an enzyme that is unrelated to the vacuolar processing enzyme. These findings suggest that proper sorting and transport of CPY is saturable. This may reflect limiting amounts of a CPY-sorting receptor, or of CPY-modifying machinery that is essential for recognition by such a receptor.