Gene_locus Report for: yeast-cbpy1

Yeast carboxypeptidase Y (CPY) is a serine protease with broad substrate specificity. Structurally, CPY belongs to the alpha/beta hydrolase fold family and contains characteristic large helices, termed the V-shape helix, above the active site cavity. Four intramolecular disulfide bonds are located in and around the V-shape helix. In this study, mutant CPYs were constructed in which one of these disulfide bonds was disrupted. Mutants lacking the C193-C207 bond located at the beginning of the V-shape helix aggregated easily, while mutants lacking the C262-C268 bond located at the end of the V-shape helix displayed decreased hydrolytic activity. The results indicate that the V-shape helix is involved in CPY catalysis and in maintenance of its conformation.

In (serine)carboxypeptidase Y, the flexible side chain of Met 398 forms one side of the Si' binding pocket and the beta -and gamma-carbon atoms of Thr60 form the opposite side. Met398 has been substituted with the residues Gly,Ala,Val,lie,Leu,Phe,and Tyr while Thr60 has been substituted with the residues Ala,Val,Leu,Met,Phe,and Tyr by site-directed mutagenesis,and the resulting enzymes have been characterized with respect to their Pi' substrate preferences using thes ubstrate series FA-Phe-Xaa-OH (Xaa=Gly,Ala,Val,orLeu) and FA-Ala-Yaa-OH (Yaa=Leu,Gin,Glu,Lys,or Arg). The results show that Met398 is much more important for transition state stabilization than Thr60 although itappears that the selected non bulky amino acid residue(Thr) at position 60 is important for high Kcat values. The results further suggest that bulky amino acid side chains at position 398 are able to adjust the size of the Si' pocket such that favorable interactions with the substrate can be obtained with even small Pi' side chains,e.g., Gly. Accordingly,the hydrolysis of substrates with bulky/hydrophobic Pi' side chains is less dependent on the nature of the amino acid residue at position 398 than that of a substrate with a non bulky Pi' sid echain.The three-dimensional structure oft hemutant enzymeE65A+E145A has been determined, and it provides support for the high mobility of the Met398 side chain. In transpeptidation reactions the substitutions at position 398 also influence the interactions between the binding pocket and the amino acid leaving group as well as the added nucleophile competing with water in the deacylation reaction.Much higher aminolysis was obtained with some of the mutant enzymes, presumably due to a changed accessibility of water to the acyl-enzyme intermediate while the nucleophile/leaving group isbound at the Si' binding site.

The structure of monomeric serine carboxypeptidase from Saccharomyces cerevisiae (CPD-Y), deglycosylated by an efficient new procedure, has been determined by multiple isomorphous replacement and crystallographic refinement. The model contains 3333 non-hydrogen atoms, all 421 amino acids, 3 of 4 carbohydrate residues, 5 disulfide bridges, and 38 water molecules. The standard crystallographic R-factor is 0.162 for 10,909 reflections observed between 20.0- and 2.8-A resolution. The model has rms deviations from ideality of 0.016 A for bond lengths and 2.7 degrees for bond angles and from restrained thermal parameters of 7.9 A2. CPD-Y, which exhibits a preference for hydrophobic peptides, is distantly related to dimeric wheat serine carboxypeptidase II (CPD-WII), which has a preference for basic peptides. Comparison of the two structures suggests that substitution of hydrophobic residues in CPD-Y for negatively charged residues in CPD-WII in the binding site is largely responsible for this difference. Catalytic residues are in essentially identical configurations in the two molecules, including strained main-chain conformational angles for three active site residues (Ser 146, Gly 52, and Gly 53) and an unusual hydrogen bond between the carboxyl groups of Glu 145 and Glu 65. The binding of an inhibitor, benzylsuccinic acid, suggests that the C-terminal carboxylate binding site for peptide substrates is Asn 51, Gly 52, Glu 145, and His 397 and that the "oxyanion hole" consists of the amides of Gly 53 and Tyr 147. A surprising result of the study is that the domains consisting of residues 180-317, which form a largely alpha-helical insertion into the highly conserved cores surrounding the active site, are quite different structurally in the two molecules. It is suggested that these domains have evolved much more rapidly than other parts of the molecule and are involved in substrate recognition.

Yeast carboxypeptidase Y (CPY) is a serine protease with broad substrate specificity. Structurally, CPY belongs to the alpha/beta hydrolase fold family and contains characteristic large helices, termed the V-shape helix, above the active site cavity. Four intramolecular disulfide bonds are located in and around the V-shape helix. In this study, mutant CPYs were constructed in which one of these disulfide bonds was disrupted. Mutants lacking the C193-C207 bond located at the beginning of the V-shape helix aggregated easily, while mutants lacking the C262-C268 bond located at the end of the V-shape helix displayed decreased hydrolytic activity. The results indicate that the V-shape helix is involved in CPY catalysis and in maintenance of its conformation.

Bioethanol is a biofuel produced mainly from the fermentation of carbohydrates derived from agricultural feedstocks by the yeast Saccharomyces cerevisiae. One of the most widely adopted strains is PE-2, a heterothallic diploid naturally adapted to the sugar cane fermentation process used in Brazil. Here we report the molecular genetic analysis of a PE-2 derived diploid (JAY270), and the complete genome sequence of a haploid derivative (JAY291). The JAY270 genome is highly heterozygous (approximately 2 SNPs/kb) and has several structural polymorphisms between homologous chromosomes. These chromosomal rearrangements are confined to the peripheral regions of the chromosomes, with breakpoints within repetitive DNA sequences. Despite its complex karyotype, this diploid, when sporulated, had a high frequency of viable spores. Hybrid diploids formed by outcrossing with the laboratory strain S288c also displayed good spore viability. Thus, the rearrangements that exist near the ends of chromosomes do not impair meiosis, as they do not span regions that contain essential genes. This observation is consistent with a model in which the peripheral regions of chromosomes represent plastic domains of the genome that are free to recombine ectopically and experiment with alternative structures. We also explored features of the JAY270 and JAY291 genomes that help explain their high adaptation to industrial environments, exhibiting desirable phenotypes such as high ethanol and cell mass production and high temperature and oxidative stress tolerance. The genomic manipulation of such strains could enable the creation of a new generation of industrial organisms, ideally suited for use as delivery vehicles for future bioenergy technologies.

Saccharomyces cerevisiae has been used for millennia in winemaking, but little is known about the selective forces acting on the wine yeast genome. We sequenced the complete genome of the diploid commercial wine yeast EC1118, resulting in an assembly of 31 scaffolds covering 97% of the S288c reference genome. The wine yeast differed strikingly from the other S. cerevisiae isolates in possessing 3 unique large regions, 2 of which were subtelomeric, the other being inserted within an EC1118 chromosome. These regions encompass 34 genes involved in key wine fermentation functions. Phylogeny and synteny analyses showed that 1 of these regions originated from a species closely related to the Saccharomyces genus, whereas the 2 other regions were of non-Saccharomyces origin. We identified Zygosaccharomyces bailii, a major contaminant of wine fermentations, as the donor species for 1 of these 2 regions. Although natural hybridization between Saccharomyces strains has been described, this report provides evidence that gene transfer may occur between Saccharomyces and non-Saccharomyces species. We show that the regions identified are frequent and differentially distributed among S. cerevisiae clades, being found almost exclusively in wine strains, suggesting acquisition through recent transfer events. Overall, these data show that the wine yeast genome is subject to constant remodeling through the contribution of exogenous genes. Our results suggest that these processes are favored by ecologic proximity and are involved in the molecular adaptation of wine yeasts to conditions of high sugar, low nitrogen, and high ethanol concentrations.

Many industrial strains of Saccharomyces cerevisiae have been selected primarily for their ability to convert sugars into ethanol efficiently despite exposure to a variety of stresses. To begin investigation of the genetic basis of phenotypic variation in industrial strains of S. cerevisiae, we have sequenced the genome of a wine yeast, AWRI1631, and have compared this sequence with both the laboratory strain S288c and the human pathogenic isolate YJM789. AWRI1631 was found to be substantially different from S288c and YJM789, especially at the level of single-nucleotide polymorphisms, which were present, on average, every 150 bp between all three strains. In addition, there were major differences in the arrangement and number of Ty elements between the strains, as well as several regions of DNA that were specific to AWRI1631 and that were predicted to encode proteins that are unique to this industrial strain.

We sequenced the genome of Saccharomyces cerevisiae strain YJM789, which was derived from a yeast isolated from the lung of an AIDS patient with pneumonia. The strain is used for studies of fungal infections and quantitative genetics because of its extensive phenotypic differences to the laboratory reference strain, including growth at high temperature and deadly virulence in mouse models. Here we show that the approximately 12-Mb genome of YJM789 contains approximately 60,000 SNPs and approximately 6,000 indels with respect to the reference S288c genome, leading to protein polymorphisms with a few known cases of phenotypic changes. Several ORFs are found to be unique to YJM789, some of which might have been acquired through horizontal transfer. Localized regions of high polymorphism density are scattered over the genome, in some cases spanning multiple ORFs and in others concentrated within single genes. The sequence of YJM789 contains clues to pathogenicity and spurs the development of more powerful approaches to dissecting the genetic basis of complex hereditary traits.

Carboxypeptidase Y (CPY) inhibitor, IC, shows no homology to any other known proteinase inhibitors and rather belongs to the phosphatidylethanolamine-binding protein (PEBP) family. We report here on the crystal structure of the IC-CPY complex at 2.7 A resolution. The structure of IC in the complex with CPY consists of one major beta-type domain and a N-terminal helical segment. The structure of the complex contains two binding sites of IC toward CPY, the N-terminal inhibitory reactive site (the primary CPY-binding site) and the secondary CPY-binding site, which interact with the S1 substrate-binding site of CPY and the hydrophobic surface flanked by the active site of the enzyme, respectively. It was also revealed that IC had the ligand-binding site, which is conserved among PEBPs and the putative binding site of the polar head group of phospholipid. The complex structure and analyses of IC mutants for inhibitory activity and the binding to CPY demonstrate that the N-terminal inhibitory reactive site is essential both for inhibitory function and the complex formation with CPY and that the binding of IC to CPY constitutes a novel mode of the proteinase-protein inhibitor interaction. The unique binding mode of IC toward the cognate proteinase provides insights into the inhibitory mechanism of PEBPs toward serine proteinases and into the specific biological functions of IC belonging to the PEBP family as well.

Carboxypeptidase Y (CPY) inhibitor I(C) is a naturally occurring serine carboxypeptidase inhibitor from Saccharomyces cerevisiae, the sequence of which is not homologous with any other known proteinase inhibitor and is classified as the phosphatidylethanolamine-binding protein (PEBP). I(C) has been crystallized in complex with the deglycosylated form of CPY by the hanging-drop vapour-diffusion technique with ammonium sulfate as a precipitant. The crystals of the complex belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 81.13, b = 186.6, c = 65.14 A. Diffraction data were collected to 2.7 A resolution. Structure determination of the complex is in progress by the molecular-replacement method using the structure of CPY as a search model.

The serine carboxypeptidase inhibitor in the cytoplasm of Saccharomyces cerevisiae, IC, specifically inhibits vacuolar carboxypeptidase Y (CPY) and belongs to a functionally unknown family of phosphatidylethanolamine-binding proteins (PEBPs). In the presence of 1 M guanidine hydrochloride, a CPY-IC complex is formed and is almost fully activated. The reactivities of phenylmethylsulfonyl fluoride, p-chloromercuribenzoic acid, and diisopropyl fluorophosphate toward the complex are considerably increased in 1 M guanidine hydrochloride, indicating that IC contains a binding site other than its inhibitory reactive site. IC is able to form the complex with diisopropyl fluorophosphate-modified CPY. Tryptic digestion of the complex indicates that two fragments from IC are involved in complex formation with CPY. These findings demonstrate the multiple site binding of IC with CPY. Considering the fact that mouse PEBP has recently been identified as a novel thrombin inhibitor, the binding that characterizes the CPY-IC complex could be a common feature of PEBPs.

To investigate the structural importance of a "disulfide zipper" motif of carboxypeptidase Y, disulfide-deficient mutant enzymes were expressed in two strains of Saccharomyces cerevisiae. The mutant enzymes were rapidly degraded into fragments by intracellular proteases. Thus, it is concluded that the disulfide zipper is essential in maintaining the structural integrity of CPase Y against proteolytic susceptibility.

Carboxypeptidase Y (CPY) inhibitor, I(C), a cytoplasmic inhibitor of vacuolar proteinases in yeast, Saccharomyces cerevisiae, was purified by means of a high-level expression system using a proteinase-deficient strain, BJ2168, and an expression vector with the promoter GAL1. The purified I(C) exists as a monomeric beta-protein in solution with a mole-cular weight of 24,398.4 as determined by gel filtration chromatography, MALDI-TOF mass spectrometry, and far-UV CD spectroscopy. The acetylated N-terminal methionine residue is the sole posttranslational modification. I(C) specifically inhibits both the peptidase and anilidase activities of CPY with inhibitor constants (K(i)) of approximately 1.0 x 10(-9) M. The chemical modification of I(C) with sulfhydryl reagents indicated that it lacks disulfide bonds and has two free SH groups, which are responsible, not for the inhibitory function, but, apparently, for the folding of the overall structure. The formation of a complex of I(C) with CPY was highly specific, as evidenced by no detectable interaction with pro-CPY. Chemical modification studies of the CPY-I(C) complex with specific reagents demonstrated that the catalytic Ser146 and S1 substrate-binding site of CPY are covered in the complex.

Carboxypeptidase Y (CPY) inhibitor, I(C), a yeast cytoplasmic inhibitor in which the N-terminal amino acid is acetylated, was expressed in Escherichia coli and produced as an unacetylated form of I(C) (unaI(C)). Circular dichroism and fluorescence measurements showed that unaI(C) and I(C) were structurally identical and produce identical complexes with CPY. However, the K(i) values for unaI(C) for anilidase and peptidase activity of CPY were much larger, by 700- and 60-fold, respectively, than those of I(C). The reactivities of phenylmethylsulfonyl fluoride and p-chloromercuribenzoic acid toward the CPY-unaI(C) complex were considerably higher than those toward the CPY-I(C) complex. Thus, the N-terminal acetyl group of I(C) is essential for achieving a tight interaction with CPY and for its complete inactivation.

Cys341 of carboxypeptidase Y, which constitutes one side of the solvent-accessible surface of the S1 binding pocket, was replaced with Gly, Ser, Asp, Val, Phe or His by site-directed mutagenesis. Kinetic analysis, using Cbz-dipeptide substrates, revealed that polar amino acids at the 341 position increased K(m) whereas hydrophobic amino acids in this position tended to decrease K(m). This suggests the involvement of Cys341 in the formation of the Michaelis complex in which Cys341 favors the formation of hydrophobic interactions with the P1 side chain of the substrate as well as with residues comprising the surface of the S1 binding pocket. Furthermore, C341G and C341S mutants had significantly higher k(cat) values with substrates containing the hydrophobic P1 side chain than C341V or C341F. This indicates that the nonhydrophobic property conferred by Gly or Ser gives flexibility or instability to the S1 pocket, which contributes to the increased k(cat) values of C341G or C341S. The results suggest that Cys341 may interact with His397 during catalysis. Therefore, we propose a dual role for Cys341: (a) its hydrophobicity allows it to participate in the formation of the Michaelis complex with hydrophobic substrates, where it maintains an unfavorable steric constraint in the S1 subsite; (b) its interaction with the imidazole ring of His397 contributes to the rate enhancement by stabilizing the tetrahedral intermediate in the transition state.

The genes encoding carboxypeptidase Y (CPY) and CPY propeptide (CPYPR) from Saccharomyces cerevisiae were cloned and expressed in Escherichia coli. Six consecutive histidine residues were fused to the C-terminus of the CPYPR for facilitated purification. High-level expression of CPY and CPYPR-His(6) was achieved but most of the expressed proteins were present in the form of inclusion bodies in the bacterial cytoplasm. The CPY and CPYPR-His(6) produced as inclusion bodies were separated from the cells and solubilized in 6 and 3 M guanidinium chloride, respectively. The denatured CPYPR-His(6) was refolded by dilution 1:30 into the renaturation buffer (50 mM Tris-HCl containing 0.5 M NaCl and 3 mM EDTA, pH 8.0), and the refolded CPYPR-His(6) was further purified to 90% purity by single-step immobilized metal ion affinity chromatography. The denatured CPY was refolded by dilution 1:60 into the renaturation buffer containing CPYPR-His(6) at various concentrations. Increasing the molar ratio of CPYPR-His(6) to CPY resulted in an increase in the CPY refolding yield, indicating that the CPYPR-His(6) plays a chaperone-like role in in vitro folding of CPY. The refolded CPY was purified to 92% purity by single-step p-aminobenzylsuccinic acid affinity chromatography. When refolding was carried out in the presence of 10 molar eq CPYPR-His(6), the specific activity, N-(2-furanacryloyl)-l-phenylalanyl-l-phenylalanine hydrolysis activity per milligram of protein, of purified recombinant CPY was found to be about 63% of that of native S. cerevisiae CPY.

A yeast vacuolar protease, carboxypeptidase Y (CPY), is known to be involved in the C-terminal processing of peptides and proteins; however, its real function remains unclear. The CPY biosynthetic pathway has been used as a model system for protein sorting in eukaryotes. CPY is synthesized as a prepro-form that travels through the ER and Golgi to its final destination in vacuoles. In the course of studies on the transport mechanism of CPY, various post-translational events have been identified, e.g. carbohydrate modification and cleavage of the pre-segments. In addition, sorting signals and various sorting vehicles, similar to those found in higher eukaryotic cells, have been found. The catalytic triad in the active site of CPY makes this enzyme a serine protease. A unique feature distinguishing CPY from other serine proteases is its wide pH optimum, in particular its high activity at acidic pH. Several structural properties which might contribute to this unique feature exist such as a conserved free cysteine residue in the S1 substrate binding pocket, a recognition site for a C-terminal carboxyl group, and a disulfide zipper motif. The structural bases in CPY functions are discussed in this article.

A 25-kDa inhibitor of the vacuolar enzyme carboxypeptidase Y from Saccharomyces cerevisiae has been characterized. The inhibitor, Ic, binds tightly with an apparent Ki of 0.1 nM. Consistent with a cytoplasmic localization, Ic is soluble and contains no sequences which could serve as potential signals for transport into the endoplasmic reticulum. Surprisingly, Ic is encoded by TFS1, which has previously been isolated as a high-copy suppressor of cdc25-1. CDC25 encodes the putative GTP exchange factor for Ras1p/Ras2p in yeast. In an attempt to rationalize this finding, we looked for a physiological relationship by deleting or overexpressing the gene for carboxypeptidase Y in a cdc25-1 strain. However, this did not change the phenotype of this mutant strain. Ic is the first member of a new family of protease inhibitors. The inhibitor is not hydrolyzed on binding to CPY. It has fairly high degree of specificity, showing a 200-fold higher Ki toward a carboxypeptidase from Candida albicans which is highly homologous to carboxypeptidase Y. The TFS1 gene product shows extensive similarity to a class of proteins termed "21-23-kDa lipid binding proteins", members of which are found in several higher eukaryotes, including man. These proteins are highly abundant in some tissues (e.g., brain) and have in general been found to bind lipids. Considering their homology to Ic, it is tempting to speculate that they may also be inhibitors of serine carboxypeptidases.

In the present study we describe a novel method for obtaining highly pure carboxypeptidase Y, or derivatives thereof, in a single-step purification procedure. The method is based on affinity chromatography and the results demonstrate that an efficient method is obtained only when the affinity gel is fully saturated with enzyme. Thus, pilot experiments are required to determine the binding capacity of the resin with respect to a given enzyme. To avoid this additional experimental effort, we have developed a method utilizing reversed-flow affinity elution. The method has been successfully employed to purify hundreds of carboxypeptidase Y mutant enzymes.

The high activity of carboxypeptidase S1 with substrates having basic P1 residues is predicted to depend on the size of residue 312 in combination with the presence of a counter-charge in an alpha-helix above the S1 binding pocket. This hypothesis is tested by the construction of 32 mutant forms of carboxypeptidase Y that combines a reduction in size of residue 312 and the introduction of either a basic or an acidic residue at either position 241 or position 245. Kinetic characterization using substrates with Leu, Arg, Lys, Glu, or Asp in P1 demonstrates that most of these enzymes exhibit drastically altered catalytic properties. One mutant enzyme, N241D + W312L, hydrolyzes FA-Arg-Ala-OH with a kcat/KM value of 13 000 min-1 mM-1 corresponding to a 930-fold increase relative to the wild-type enzyme. This increased activity is due to an increase in kcat and is independent of ionic strength. The pH profile of kcat/KM exhibits an optimum around pH 5.5 similar to that observed for CPD-S1. Another mutant enzyme, L245R + W312S, hydrolyzes FA-Glu-Ala-OH and FA-Asp-Ala-OH with kcat/KM values of 5100 and 5300 min-1 mM-1, respectively, corresponding to 120 and 170-fold increases relative to wild-type values. With the latter substrate, a 280-fold reduction of KM is observed. The activity of L245R + W312S is also independent of ionic strength and displays a virtually unaltered dependence on pH. The P1 substrate preference of these two mutant enzymes for Arg versus Asp differs 2.5 x 10(6)-fold. values of single and double mutants demonstrate that the effects of reducing the size of Trp312 and introducing a charged residue at position 241 or 245 in some cases exceed 100% additivity. Thus, the double mutant enzyme gains more activation energy than can be accounted for by each individual single mutation.

The S'1 binding pocket of carboxypeptidase Y is hydrophobic, spacious, and open to solvent, and the enzyme exhibits a preference for hydrophobic P'1 amino acid residues. Leu272 and Ser297, situated at the rim of the pocket, and Leu267, slightly further away, have been substituted by site-directed mutagenesis. The mutant enzymes have been characterized kinetically with respect to their P'1 substrate preferences using the substrate series FA-Ala-Xaa-OH (Xaa = Leu, Glu, Lys, or Arg) and FA-Phe-Xaa-OH (Xaa = Ala, Val, or Leu). The results reveal that hydrophobic P'1 residues bind in the vicinity of residue 272 while positively charged P'1 residues interact with Ser297. Introduction of Asp or Glu at position 267 greatly reduced the activity toward hydrophobic P'1 residues (Leu) and increased the activity two- to three-fold for the hydrolysis of substrates with Lys or Arg in P'1. Negatively charged substituents at position 272 reduced the activity toward hydrophobic P'1 residues even more, but without increasing the activity toward positively charged P'1 residues. The mutant enzyme L267D + L272D was found to have a preference for substrates with C-terminal basic amino acid residues. The opposite situation, where the positively charged Lys or Arg were introduced at one of the positions 267, 272, or 297, did not increase the rather low activity toward substrates with Glu in the P'1 position but greatly reduced the activity toward substrates with C-terminal Lys or Arg due to electrostatic repulsion. The characterized mutant enzymes exhibit various specificities, which may be useful in C-terminal amino acid sequence determinations.

The propeptide of carboxypeptidase Y from Saccharomyces cerevisiae is important for folding of the enzyme. Previous work [Ramos, C., Winther, J.R. & Kielland-Brandt, M. C. (1994) J. Biol. Chem. 269, 7006-7012] suggested that the sequences essential for in vivo folding were situated in the COOH-proximal third of the propeptide. Concentrating on this region we have investigated the functionality of propeptide variants. Using a random mutagenesis approach we found that two segments can be defined: one in which there is a fairly high tolerance for substitution with unrelated sequences and another that has a more strict requirement for sequence conservation. Nevertheless, an overall lack of requirement for propeptide sequence conservation was found by substitution of the carboxypeptidase Y propeptide with that of a highly divergent propeptide sequence from an otherwise similar carboxypeptidase from Candida albicans. This propeptide was partially functional when combined with carboxypeptidase Y. Analysis of the biosynthesis of the mutant forms of the zymogen showed that a fraction of the molecules proceeded from the endoplasmic reticulum with fairly rapid kinetics, while the rest was degraded.

The essential histidine residue of carboxypeptidase Y (CPY) was modified by a site-specific reagent, a chloromethylketone derivative of benzyloxycarbonyl-L-phenylalanine. The single modified histidine residue was converted to N tau-carboxy-methyl histidine (cmHis) upon performic acid oxidation. A peptide containing cmHis was isolated from the tryptic-thermolytic digest. Based on the amino acid composition and sequence analysis, the peptide is shown to be Val-Phe-Asp-Gly-Gly-cmHis-MetO2-Val-Pro, which was derived from CPY cleaved by trypsin at Arg 391 and thermolysin at Phe 401, and thus His 397 was modified. This histidine residue has been implicated previously by X-ray analysis to participate in the charge-relay system of CPY.

In (serine)carboxypeptidase Y, the flexible side chain of Met 398 forms one side of the Si' binding pocket and the beta -and gamma-carbon atoms of Thr60 form the opposite side. Met398 has been substituted with the residues Gly,Ala,Val,lie,Leu,Phe,and Tyr while Thr60 has been substituted with the residues Ala,Val,Leu,Met,Phe,and Tyr by site-directed mutagenesis,and the resulting enzymes have been characterized with respect to their Pi' substrate preferences using thes ubstrate series FA-Phe-Xaa-OH (Xaa=Gly,Ala,Val,orLeu) and FA-Ala-Yaa-OH (Yaa=Leu,Gin,Glu,Lys,or Arg). The results show that Met398 is much more important for transition state stabilization than Thr60 although itappears that the selected non bulky amino acid residue(Thr) at position 60 is important for high Kcat values. The results further suggest that bulky amino acid side chains at position 398 are able to adjust the size of the Si' pocket such that favorable interactions with the substrate can be obtained with even small Pi' side chains,e.g., Gly. Accordingly,the hydrolysis of substrates with bulky/hydrophobic Pi' side chains is less dependent on the nature of the amino acid residue at position 398 than that of a substrate with a non bulky Pi' sid echain.The three-dimensional structure oft hemutant enzymeE65A+E145A has been determined, and it provides support for the high mobility of the Met398 side chain. In transpeptidation reactions the substitutions at position 398 also influence the interactions between the binding pocket and the amino acid leaving group as well as the added nucleophile competing with water in the deacylation reaction.Much higher aminolysis was obtained with some of the mutant enzymes, presumably due to a changed accessibility of water to the acyl-enzyme intermediate while the nucleophile/leaving group isbound at the Si' binding site.

The structure of monomeric serine carboxypeptidase from Saccharomyces cerevisiae (CPD-Y), deglycosylated by an efficient new procedure, has been determined by multiple isomorphous replacement and crystallographic refinement. The model contains 3333 non-hydrogen atoms, all 421 amino acids, 3 of 4 carbohydrate residues, 5 disulfide bridges, and 38 water molecules. The standard crystallographic R-factor is 0.162 for 10,909 reflections observed between 20.0- and 2.8-A resolution. The model has rms deviations from ideality of 0.016 A for bond lengths and 2.7 degrees for bond angles and from restrained thermal parameters of 7.9 A2. CPD-Y, which exhibits a preference for hydrophobic peptides, is distantly related to dimeric wheat serine carboxypeptidase II (CPD-WII), which has a preference for basic peptides. Comparison of the two structures suggests that substitution of hydrophobic residues in CPD-Y for negatively charged residues in CPD-WII in the binding site is largely responsible for this difference. Catalytic residues are in essentially identical configurations in the two molecules, including strained main-chain conformational angles for three active site residues (Ser 146, Gly 52, and Gly 53) and an unusual hydrogen bond between the carboxyl groups of Glu 145 and Glu 65. The binding of an inhibitor, benzylsuccinic acid, suggests that the C-terminal carboxylate binding site for peptide substrates is Asn 51, Gly 52, Glu 145, and His 397 and that the "oxyanion hole" consists of the amides of Gly 53 and Tyr 147. A surprising result of the study is that the domains consisting of residues 180-317, which form a largely alpha-helical insertion into the highly conserved cores surrounding the active site, are quite different structurally in the two molecules. It is suggested that these domains have evolved much more rapidly than other parts of the molecule and are involved in substrate recognition.

The S. cerevisiae VPS10 (vacuolar protein sorting) gene encodes a type I transmembrane protein of 1577 amino acids required for the sorting of the soluble vacuolar protein carboxypeptidase Y (CPY). Mutations in VPS10 result in the selective missorting and secretion of CPY; all other vacuolar proteins tested are delivered to the vacuole in vps10 mutants. Chemical cross-linking studies demonstrate that Vps10p and the Golgi-modified precursor form of CPY directly interact. A single amino acid change in the CPY vacuolar sorting signal prevents this interaction. Vps10p also interacts with a hybrid protein containing the CPY sorting signal fused to the normally secreted enzyme invertase. Subcellular fractionation indicates that the majority of Vps10p is localized to a late Golgi compartment where vacuolar proteins are sorted. We propose that VPS10 encodes a CPY sorting receptor that executes multiple rounds of sorting by cycling between the late Golgi and a prevacuolar endosome-like compartment.

Serine endopeptidases of the chymotrypsin family contain a salt bridge situated centrally within the active site, the acidic component of the salt bridge being adjacent to the catalytically essential serine. Serine carboxypeptidases also contain an acidic residue in this position but it interacts through a short hydrogen bond, probably of low-barrier type, with another acidic residue, hence forming a "glutamic acid bridge." In this study, the residues constituting this structural element in carboxypeptidase Y have been replaced by site-specific mutagenesis. It is demonstrated that the glutamic acid bridge contributes significantly to the stability of the enzyme below pH 6.5 and has an adverse effect at pH 9.5. Carboxypeptidase WII from wheat contains 2 such bridges, and it is more stable than carboxypeptidase Y at acidic pH.

Serine carboxypeptidases have the ability to hydrolyze peptides as well as peptide amides. Previously, it has been demonstrated that Asn51 and Glu145 (in the protonated form) each donate a hydrogen bond to the alpha-carboxylate of peptide substrate. It is here demonstrated by characterization of carboxypeptidase Y derivatives, mutationally altered at positions 51 and 145, that the same groups are involved in the interaction with the C-terminal carboxyamide group of peptide amides. Asn51 donates a hydrogen bond to the C = O group of the substrate, and Glu145 (in the charged form) accepts one from the NH2 group of the substrate. Thus, the ionic state of Glu145 is different when peptides are hydrolyzed as compared with when peptide amides are hydrolyzed. This explains why Km for the hydrolysis of peptides increases with pH, whereas it remains constant for peptide amides. As a consequence, kcat/Km for the hydrolysis of peptide amides is higher than for the hydrolysis of peptides at pH > 8. At physiological pH, peptides and peptide amides are hydrolyzed with rates of the same order of magnitude; this is in accordance with reports describing that serine carboxypeptidases are involved in the degradation of biologically active peptide amides.

The three-dimensional structure of (serine) carboxypeptidase Y suggests that the side chains of Trp49, Asn51, Glu65, and Glu145 could be involved in the recognition of the C-terminal carboxylate group of peptide substrates. The mutations Trp49-->Phe; Asn51-->Ala, Asp, Glu, Gln, Ser, or Thr; Glu65-->Ala; and Glu145-->Ala, Asp, Asn, Gln, or Ser have been performed. Enzymes with Ala at these positions were also produced as double and triple mutations. These mutations have only little effect on the esterase activity of the enzyme, consistent with the absence of a hydrogen bond acceptor in the P1' position of such substrates. On the other hand, removal of the hydrogen-bonding capacity by incorporation of Ala at any of these four positions results in reduced peptidase activity, in particular when Asn51 and Glu145 are replaced. The results are consistent with Trp49 and Glu65 orienting Asn51 and Glu145 by hydrogen bonds, such that these can function as hydrogen bond donors (Glu145 only in its protonated carboxylic acid form) with the C-terminal alpha-carboxylate group of the peptide substrate as acceptor. However, it appears that strong interactions are formed only in the transition state since the combined removal of Asn51 and Glu145 reduces kcat about 100-fold and leaves KM practically unchanged. The results obtained with enzymes in which Asn51 or Glu145 has been replaced with other residues possessing the capacity to donate a hydrogen bond demonstrate that there is no flexibility with respect to the nature of the hydrogen bond donor at position 145, whereas enzymes with Gln, Ser, or Thr at position 51 exhibit much higher activity than N51A, although none of them reaches the wild-type level. With carboxypeptidase Y as well as other serine carboxypeptidases the binding of peptide substrates in the ground state (KM) is adversely affected by an increase in pH. It is shown that deprotonation of a single ionizable group with a pKa of 4.3 on the enzyme is responsible for this pH effect. The results show that the group involved is either Glu65 or Glu145, the latter being the more probable. The effect of this ionization on KM is explained by charge repulsion between the carboxylate group of the substrate and that of Glu145, hence preventing substrate from binding.

Asn51 and Glu145 of (serine) carboxypeptidase Y function as binding sites for the C-terminal carboxylate group of peptide substrates, and Glu65 is involved in orienting these two amino acid residues. A series of mutants of carboxypeptidase Y where these three amino acid residues have been replaced were investigated for their applicability in transacylation reactions with amino acid esters as acceptors. With H-Val-OMethyl as the nucleophile, the fraction of aminolysis is significantly higher than with the corresponding amino acid, suggesting a beneficial effect of blocking the alpha-carboxylate group. Increasing the size of the alcohol moiety, i.e., -OEthyl, -OPropyl or OButyl, has an adverse effect on the binding of the nucleophile and on the maximum yield of aminolysis. Replacement of Asn51 and Glu145 with Ala or Gly has a pronounced beneficial effect both on binding and the maximum fraction of aminolysis. However, the results do not establish a specific type of interaction between the enzyme and these valine esters. It is probable that the rotational freedom around the ester bond allows multiple binding modes, depending on both the leaving group and type of structural change within the binding site. From a synthetic point of view, some of the mutant enzymes are much better than the wildtype enzyme when amino acid esters are used as nucleophiles.

The accessibility of the active-site cleft of procarboxypeptidase Y from Saccharomyces cerevisiae has been studied by chemical modifications of two specific amino-acid residues. Previous studies have shown that these residues, Cys-341 and Met-398 in the mature enzyme, are located in the S1 and S'1 substrate binding sites, respectively, of carboxypeptidase Y. We have found that these residues also in proCPY are accessible to modification with fairly bulky reagents and in the case of Met-398 the rate of modification is even faster than in carboxypeptidase Y. While the catalytic serine in the mature enzyme reacts with diisopropylfluorophosphate, this is not the case for procarboxypeptidase Y.

Carboxypeptidase Y is a vacuolar enzyme from Saccharomyces cerevisiae. It enters the vacuole as a zymogen, procarboxypeptidase Y, which is immediately processed in a reaction involving two endoproteases, proteinase A and proteinase B. We have investigated the in vitro activation of purified procarboxypeptidase Y by purified proteinase A. This has identified two different processing intermediates; one active and one inactive. The intermediates define a 33 amino acid segment of the 91 amino acid propeptide as sufficient for maintaining the enzyme in an inactive state. The inactive intermediate was isolated from a processing reaction at neutral pH. In order to investigate the influence of vacuolar pH on processing in vivo, the autoactivation of proteinase A and its processing of procarboxypeptidase Y were studied in a vma2 prb1 mutant, which is deficient in vacuolar acidification and proteinase B activity. Efficient processing of procarboxypeptidase Y in the absence of proteinase B is dependent on acidic vacuolar pH, and the processing at neutral pH is slow and takes place in two steps similar to those identified in vitro.

Carboxypeptidase Y is a serine carboxypeptidase isolated from Saccharomyces cerevisiae with a preference for C-terminal hydrophobic amino acid residues. In order to alter the inherent substrate specificity of CPD-Y into one for basic amino acid residues in P'1, we have introduced Asp and/or Glu residues at a number of selected positions within the S'1 binding site. The effects of these substitutions on the substrate specificity, pH dependence and protein stability have been evaluated. The results presented here demonstrate that it is possible to obtain significant changes in the substrate preference by introducing charged amino acids into the framework provided by an enzyme with a quite different specificity. The introduced acidic amino acid residues provide a marked pH dependence of the (kcat/Km)FA-A-R-OH/(kcat/Km)FA-A-L-OH ratio. The change in stability upon introduction of Asp/Glu residues can be correlated to the difference in the mean buried surface area between the substituted and the substituting amino acid. Thus, the effects of acidic amino acid residues on the protein stability depend upon whether the introduced amino acid protrudes from the solvent accessible surface as defined by the surrounding residues in the wild type enzyme or is submerged below.

Efficient folding of carboxypeptidase Y is dependent on the presence of the proregion. Thus, denatured procarboxypeptidase Y, in contrast to the mature enzyme, refolds efficiently in vitro in low ionic strength buffers. Under these conditions denatured mature carboxypeptidase Y forms an inactive, soluble folding intermediate, which has been characterized in the present study. The inactive intermediate can be folded into the active enzyme at a low efficiency (5-10%) by the addition of 0.9 M ammonium sulfate. The refolding is accompanied by pronounced structural changes. As seen for other protease zymogens the isolated proregion from carboxypeptidase Y was found to stimulate refolding without covalent linkage to the mature part. However, the added proregion does not form a stable complex with the native enzyme and requires the presence of 0.9 M ammonium sulfate to exhibit its function. The proregion increases the yield of correctly folded enzyme, and kinetic analysis suggests that this is due to a reduction of the rate of nonproductive folding or aggregation. In addition, the proregion stabilizes carboxypeptidase Y toward thermoinactivation.

A series of 18 phenacyl bromide and iodoacetamide analogues have been synthesized and used to alkylate Met-398 situated in the S'1 binding site of carboxypeptidase Y. The course of the reactions was monitored by measurements of the peptidase and esterase activities. All except four of the reagents reacted selectively, and from these preparations the modified enzymes were purified and kinetically characterized toward a methyl ester substrate and a peptide substrate with a large leaving group in the P'1 position. The Km, kcat, and kcat/Km for the hydrolysis of these substrates have been quantitatively correlated to parameters describing the properties of the modification reagents. The esterase activity depends only on the steric bulk of the para-substituents with the phenacyl-modified enzymes, but on both steric and electronic factors of the N-alkyl substituents with the acetamide modified enzymes. The peptidase activity, on the other hand, is dependent on steric and electronic factors with both types of modified enzymes.

The pro region of carboxypeptidase Y (CPY) from yeast is necessary for the correct folding of the enzyme [Winther, J. R., & Sorensen P. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 9330-9334]. Using fluorescence, circular dichroism, and heteronuclear NMR analyses, it is demonstrated that the isolated pro region is a partially folded protein domain under the conditions where it is functional. It is characterized by a relatively high content of secondary structural elements but a very low content of defined tertiary structure. Although these characteristics are reminiscent of the compact denatured states that have been identified as intermediates in protein folding ("molten globules"), the pro region exhibits only very weak binding of the hydrophobic probe 1-anilino-8-naphthalenesulfonate, and it is resistant toward complete thermal unfolding. Altogether the data indicate an extremely flexible structure that has little regular structural core. It is proposed that the feature of a partially folded domain per se is important for the function of the pro region of CPY as a "co-translational chaperone".

The C-terminal amidation of calcitonin represents an important technological problem. A method using a serine carboxypeptidase-catalyzed transpeptidation reaction in combination with photochemical cleavage to give the warranted peptide amide is described. The overall yield is higher than 95%.

The zymogen of the vacuolar carboxypeptidase Y from Saccharomyces cerevisiae was purified and characterized with respect to activation as well as refolding in vitro. The purified procarboxypeptidase Y has no detectable activity but can be efficiently activated by proteinase K from Tritirachium album. We used this method of activation as a tool for the investigation of refolding procarboxypeptidase Y in vitro. The proenzyme, denatured in 6 M guanidinium chloride, is renatured efficiently after dilution of the denaturant, whereas the mature enzyme regains little activity in the same procedure. Changes in intrinsic fluorescence reveal the mature enzyme to be considerably more stable than the proenzyme toward denaturation with guanidinium chloride. This suggests that the propeptide induces a metastable structure important for overcoming energy barriers that might otherwise obstruct a productive folding pathway. The relatively large number of charged amino acid residues and a high theoretical potential for alpha-helix formation in the carboxypeptidase Y propeptide suggest a structural similarity to a number of other propeptides and heat shock proteins.

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 of cells with PRC1 under the control of its own promoter. Introduction of a high copy number 2 mu-URA3-LEU2d 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.

Carboxypeptidase Y is a serine carboxypeptidase assumed to contain a catalytic triad similar to the serine endopeptidases. On the basis of the homology between various serine carboxypeptidases His-397 is suspected to be part of the catalytic triad. To test this it was exchanged with Ala and Arg by site-directed mutagenesis of the cloned PRC1 gene. The catalytic efficiency of the mutant enzymes were reduced by a factor of 2 X 10(4) and 7 X 10(2), respectively, confirming the key role of His-397 in catalysis. Treatment of Ala-397-CPD-Y with Hg++ or CNBr, hence modifying Cys-341 located in the vicinity of the active site abolished the residual activity of the enzyme, indicating an additional involvement of this residue in catalysis.

It is demonstrated that site-directed mutagenesis successfully can be combined with chemical modification creating enzyme derivatives with altered properties. A methionyl residue located in the S1' binding site of carboxypeptidase Y was replaced by a cysteinyl residue and the mutant enzyme was isolated and modified with various alkylating and thioalkylating reagents. Treatment of the mutant carboxypeptidase Y with bulky reagents like phenacyl bromide and benzyl methanethiolsulfonate caused a drastic reduction in the activity towards substrates with bulky leaving groups in the P1' position, i.e. -OBzl, -Val-NH2 and amino acids (except -Gly-OH), while substrates with small groups in that position, i.e. -OMe and -NH2, were hydrolysed with increased rates. The presence of a positive charge, in addition to a bulky group, had a further adverse effect on the activity towards substrates with large leaving groups, whereas the activity towards those with small leaving groups remained unaffected by such a group. The derivatives obtained by modification of the mutant enzyme with benzyl methanethiolsulfonate and methyl methanethiolsulfonate were effective in deamidations of peptide amides and peptide synthesis reactions, respectively.

We have isolated cis-acting mutations in the gene encoding the yeast vacuolar protein carboxypeptidase Y (CPY) that result in missorting and aberrant secretion of up to 95% of newly synthesized CPY. The CPY polypeptides synthesized by these mutants use the late secretory pathway to exit the cell, since the late-acting sec1 mutation prevents their secretion. The mutant versions of CPY are secreted as the proCPY zymogen and are enzymatically activatable in vivo and in vitro. All the mutations, including small deletions and an amino acid substitution, map to the amino-terminal propeptide region and define a discrete yeast vacuolar localization domain whose integrity is required for efficient sorting of the CPY zymogen. Thus, the N-terminal propeptide of CPY carries out at least three functions: it mediates translocation across the endoplasmic reticulum, renders the enzyme inactive during transit, and targets the molecule to the vacuole.

We report in vitro studies on the interaction of several substrates with the carboxypeptidase Y-inhibitor complex of yeast. Inhibition of carboxypeptidase Y cleavage of two peptides by carboxypeptidase Y-inhibitor is shown to be competitive. The experiments show a wide variation in the degree of cleavage of a variety of peptide substrates by carboxypeptidase Y, despite the presence of the inhibitor protein. The most likely explanation for this behaviour is a different capacity for the peptides to dissociate the inhibitor protein from the substrate-binding site of carboxypeptidase Y. While the carboxypeptidase Y-inhibitor is insensitive to proteolytic inactivation when complexed with carboxypeptidase Y, it is sensitive when in the free state. Addition of the substrate, N-Cbz-Phe-Leu, to the carboxypeptidase Y-inhibitor complex, however, allows proteolytic inactivation of the inhibitor protein. We suggest that the proteinase-inhibitor may play a crucial role in the regulation of proteinase activity. The inhibitor protein generally protects proteins from unwanted proteinase action. However, it will allow cleavage of proteins which, by some signal triggered metabolically, become substrates due to the exposure of amino acid sequences normally buried, and exhibiting a high affinity for the proteinase.

The metal content of carboxypeptidase Y was analyzed by the atomic absorption method. After exhaustive dialysis against an EDTA solution, the enzyme showed no loss of activity nor any significant content of metals (Zh,Mg,Ca,Cu,Mn,Ni,Fe, and Co). The activity was, however, rather sensitive to preincubation with various metals. The reactivity of a serine residue of the enzyme was also reevaluated. Diisopropyl fluorophosphate (DFP) and phenylmethanesulfonyl fluoride (PMSF) stoichiometrically and irreversively inhibited the enzyme. The rate of inactivation with DFP was much faster than that for typsin [EC 3.4.21.4] and chymotrypsin [EC 3.4.21.1.], while the rate with PMSF was one-fifteenth of that for chymotrypsin. The pH-dependence of the inactivation by DFP was similar to that of the enzymatic hydrolysis of acetylphenylalanine ethyl ester. The present results indicate that carboxypeptidase Y is free of metals and has a serine residue with a vital role in the catalytic process, though the functional role of this SH group remains to be clarified.