Thermostabilization of recombinant human and bovine CuZn superoxide dismutases by replacement of free cysteines

Human CuZn superoxide dismutase (HSOD) has two free cysteines: a buried cysteine (Cys6) located in a beta-strand, and a solvent accessible cysteine (Cys111) located in a loop region. The highly homologous bovine enzyme (BSOD) has a single buried Cys6 residue. Cys6 residues in HSOD and BSOD were replaced by alanine and Cys111 residues in HSOD by serine. The mutant enzymes were expressed and purified from yeast and had normal specific activities. The relative resistance of the purified proteins to irreversible inactivation of enzymatic activity by heating at 70 degrees C was HSOD Ala6 Ser111 greater than BSOD Ala6 Ser109 greater than BSOD Cys6 Ser109 (wild type) greater than HSOD Ala6 Cys111 greater than HSOD Cys6 Ser111 greater than HSOD Cys111 (wild type). In all cases, removal of a free cysteine residue increased thermostability.     

Effect of Mutation of the Conservative Glycine Residues Gly100 and Gly147 on Stability of <Emphasis Type="Italic">Escherichia coli</Emphasis> Inorganic Pyrophosphatase

Sequence alignment of inorganic pyrophosphatases (PPases) isolated from the different organisms shows that glycine residues Gly100 and Gly147 are conservative. These residues are located in flexible segments of a polypeptide chain that have similar structure in the different PPases. To elucidate the possible role of these segments in the functioning of PPase, the mutant variants Gly100Ala and Gly147Val in conservative loops have been obtained. In this work, the influence of these mutations on stability of PPase globular structure has been studied. Differential scanning calorimetry has been used to determine the apparent enthalpy of thermal denaturation for the native PPase and its mutant variants Gly100Ala and Gly147Val. Guanidine hydrochloride-induced chemical denaturation of PPase has also been studied. It is shown that the substitutions of Gly100 and Gly147 result in overall destabilization of the globular structure.     

Crystal structures of E. coli CcmG and its mutants reveal key roles of the N-terminal beta-sheet and the fingerprint region

CcmG, also designated DsbE, functions as a periplasmic protein thiol:disulfide oxidoreductase and is required for cytochrome c maturation. Here we report the crystal structures of Escherichia coli CcmG and its two mutants, P144A and the N-terminal fifty seven-residue deletion mutant, and two additional deletion mutants were studied by circular dichroism. Structural comparison of E. coli CcmG with its deletion mutants reveals that the N-terminal beta-sheet is essential for maintaining the folding topology and consequently maintaining the active-site structure of CcmG. Pro144 and Glu145 are key residues of the fingerprint region of CcmG. Pro144 is in cis-configuration, and it makes van der Waals interactions with the active-site disulfide Cys80-Cys83 and forms a C--H...O hydrogen bond with Thr82, helping stabilize the active-site structure. Glu145 forms a salt-bridge and hydrogen-bond network with other residues of the fingerprint region and with Arg158, further stabilizing the active-site structure. The cis-configuration of Pro144 makes the backbone nitrogen and oxygen of Ala143 exposed to solvent, favorable for interacting with binding partners. The key role of cis-Pro144 is verified by the P144A mutant, which contains trans-Ala144 and displays redox property changes. Structural comparison of E. coli CcmG with the recently reported structure of CcmG in complex with the N-terminal domain of DsbD reveals that Tyr141 undergoes conformational changes upon binding DsbD. A cis-proline located at the N-terminus of the first beta-strand of the betabetaalpha motif of the thioredoxin-like domain is a conserved structural feature of the thioredoxin superfamily.     

Mutational effects on thermostable superoxide dismutase from Aquifex pyrophilus: understanding the molecular basis of protein thermostability

We designed two mutants of superoxide dismutase (SOD), one is thermostable and the other is thermolabile, which provide valuable insight to identify amino acid residues essential for the thermostability of the SOD from Aquifex pyrophilus (ApSOD). The mutant K12A, in which Lys12 was replaced by Ala, had increased thermostability compared to that of the wild type. The T(1/2) value of K12A was 210 min and that of the wild type was 175 min at 95 degrees C. However, the thermostability of the mutant E41A, which has a T(1/2) value of 25 min at 95 degrees C, was significantly decreased compared to the wild type of ApSOD. To explain the enhanced thermostability of K12A and thermolabile E41A on the structural basis, the crystal structures of the two SOD mutants have been determined. The results have clearly shown the general significance of hydrogen bonds and ion-pair network in the thermostability of proteins.     

一个耐热碱性磷酸酯酶突变型的研究

为了进一步揭示蛋白质的耐热机制,对含有耐热碱性磷酸酯酶（ＦＤ－ＴＡＰ）的表达质粒ｐＴＡＰ５０３Ｆ进行了随机诱变,用菌落原位显色法从约５０００个转化子中筛选到４个耐热性下降的突变型克隆,并对其中１克隆（ＴＡＰＭ３）进行了部分酶学性质、ＤＮＡ和氨基酸序列的研究。酶学性质研究表明,与野生型相比,该突变型酶的耐热性有较大幅度的下降,而热激活性无明显改变。ＤＮＡ序列分析表明在１２３９位ＴＡＰＭ３发生Ｇ→Ａ转     

Improvement in thermostability and psychrophilicity of psychrophilic alanine racemase by site-directed mutagenesis

A psychrophilic alanine racemase from Bacillus psychrosaccharolyticus has a higher catalytic activity than a thermophilic alanine racemase from Bacillus stearothermophilus even at 60 °C in the presence of pyridoxal 5′-phosphate (PLP), although the thermostability of the former enzyme is lower than that of the latter one [FEMS Microbial. Lett. 192 (2000) 169]. In order to improve the thermostability of the psychrophilic enzyme, two hydrophilic amino acid residues (Glu150 and Arg151) at a surface loop surrounding the active site of the enzyme were substituted with the corresponding residues (Val and Ala) in the B. stearothermophilus alanine racemase. The mutant enzyme (ER150,151VA) showed a higher thermostability, and a markedly lower K_m value for PLP, than the wild type one. In addition, the catalytic activities at low temperatures and kinetic parameters of the two enzymes indicated that the mutant enzyme was more psychrophilic than the wild type one. Thus, the psychrophilic alanine racemase was improved in both psychrophilicity and thermostability by the site-directed mutagenesis. The mutant enzyme may be useful for the production of stereospecifically deuterated NADH and various -amino acids.     

Genetic engineering of EcoRI mutants with altered amino acid residues in the DNA binding site: physicochemical investigations give evidence for an altered monomer/dimer equilibrium for the Gln144Lys145 and Gln144Lys145Lys200 mutants

We have genetically engineered the Arg200----Lys mutant, the Glu144Arg145----GlnLys double mutant, and the Glu144Arg145Arg200----GlnLysLys triple mutant of the EcoRI endonuclease in extension of previously published work on site-directed mutagenesis of the EcoRI endonuclease in which Glu144 had been exchanged for Gln and Arg145 for Lys [Wolfes et al. (1986) Nucleic Acids Res. 14, 9063]. All these mutants carry modifications in the DNA binding site. Mutant EcoRI proteins were purified to homogeneity and characterized by physicochemical techniques. All mutants have a very similar secondary structure composition. However, whereas the Lys200 mutant is not impaired in its capacity to form a dimer, the Gln144Lys145 and Gln144Lys145Lys200 mutants have a very much decreased propensity to form a dimer or tetramer depending on concentration as shown by gel filtration and analytical ultracentrifugation. This finding may explain the results of isoelectric focusing experiments which show that these two mutants have a considerably more basic pI than expected for a protein in which an acidic amino acid was replaced by a neutral one. Furthermore, while wild-type EcoRI and the Lys200 mutant are denatured in an irreversible manner upon heating to 60 degrees C, the thermal denaturation process as shown by circular dichroism spectroscopy is fully reversible with the Gln144Lys145 double mutant and the Gln144Lys145Lys200 triple mutant. All EcoRI endonuclease mutants described here have a residual enzymatic activity with wild-type specificity, since Escherichia coli cells overexpressing the mutant proteins can only survive in the presence of EcoRI methylase. The detailed analysis of the enzymatic activity and specificity of the purified mutant proteins is the subject of the accompanying paper [Alves et al. (1989) Biochemistry (following paper in this issue)].     

Use of Ramachandran Plot for Increasing Thermal Stability of Bacterial Formate Dehydrogenase

From analysis of Ramachandran plot for NAD+-dependent formate dehydrogenase from the methylotrophic bacterium Pseudomonas sp. 101 (FDH, EC 1.2.1.2), five amino acid residues with non-optimal values phi and psi have been located in beta- and pi-turns of the FDH polypeptide chain, e.g., Asn136, Ala191, Tyr144, Asn234, and His263. To clarify their role in the enzyme stability, the residues were replaced with Gly by means of site-directed mutagenesis. The His263Gly mutation caused FDH destabilization and a 1.3-fold increase in the monomolecular inactivation rate constant. The replacements Ala191Gly and Asn234Gly had no significant effect on the stability. The mutations Asn136Gly and Tyr144Gly resulted in higher thermal stability and decreased the inactivation rate by 1.2- and 1.4-fold, respectively. The stabilizing effect of the Tyr144Gly mutation was shown to be additive when introduced into the previously obtained mutant FDH with enhanced thermal stability.     

49P（del）点突变提高中性纤维素内切酶EGV热稳定性的初步研究

目的：探讨利用点突变方法改善EGV热稳定性的可能性和有效性。方法：对来源于Melanocarpus albomyces endoglucanase的耐热性纤维素酶maEG进行同源建模和序列比较,删除49位脯氨酸49P（del）进行定点突变,并将得到的突变体在毕氏酵母X33中表达,对表达产物进行酶活性和热稳定性检测。结果：突变酶49P（del）在70℃处理120min,热稳定性比EGV提高了21．6％,且突变酶其他性质与野生型酶基本相似。结论：通过对中性纤维素内切酶EGV的定点突变,提高了该酶的热稳定性,并为进一步研究其结构和功能提供了材料。结果同时表明利用生物信息学和分子模拟技术,缩短表面环区对于酶的热稳定性有一定的作用。     

Characterization of Two Second-Site Mutations Preventing Wild Type Protein Aggregation Caused by a Dominant Negative PMA1 Mutant

The correct biogenesis and localization of Pma1 at the plasma membrane is essential for yeast growth. A subset of PMA1 mutations behave as dominant negative because they produce aberrantly folded proteins that form protein aggregates, which in turn provoke the aggregation of the wild type protein. One approach to understand this dominant negative effect is to identify second-site mutations able to suppress the dominant lethal phenotype caused by those mutant alleles. We isolated and characterized two intragenic second-site suppressors of the PMA1-D378T dominant negative mutation. We present here the analysis of these new mutations that are located along the amino-terminal half of the protein and include a missense mutation, L151F, and an in-frame 12bp deletion that eliminates four residues from Cys409 to Ala412. The results show that the suppressor mutations disrupt the interaction between the mutant and wild type enzymes, and this enables the wild type Pma1 to reach the plasma membrane.     

A single amino acid change (substitution of glutamate 3 with alanine) in the N-terminal region of rat liver carnitine palmitoyltransferase I abolishes malonyl-CoA inhibition and high affinity binding

We have recently shown by deletion mutation analysis that the conserved first 18 N-terminal amino acid residues of rat liver carnitine palmitoyltransferase I (L-CPTI) are essential for malonyl-CoA inhibition and binding (Shi, J., Zhu, H., Arvidson, D. N. , Cregg, J. M., and Woldegiorgis, G. (1998) Biochemistry 37, 11033-11038). To identify specific residue(s) involved in malonyl-CoA binding and inhibition of L-CPTI, we constructed two more deletion mutants, Delta12 and Delta6, and three substitution mutations within the conserved first six amino acid residues. Mutant L-CPTI, lacking either the first six N-terminal amino acid residues or with a change of glutamic acid 3 to alanine, was expressed at steady-state levels similar to wild type and had near wild type catalytic activity. However, malonyl-CoA inhibition of these mutant enzymes was reduced 100-fold, and high affinity malonyl-CoA binding was lost. A mutant L-CPTI with a change of histidine 5 to alanine caused only partial loss of malonyl-CoA inhibition, whereas a mutant L-CPTI with a change of glutamine 6 to alanine had wild type properties. These results demonstrate that glutamic acid 3 and histidine 5 are necessary for malonyl-CoA binding and inhibition of L-CPTI by malonyl-CoA but are not required for catalysis.     

Stabilization of E. coli Ribonuclease HI by the 'stability profile of mutant protein' (SPMP)-inspired random and non-random mutagenesis

The change in the structural stability of Escherichia coli ribonuclease HI (RNase HI) due to single amino acid substitutions has been estimated computationally by the stability profile of mutant protein (SPMP) [Ota, M., Kanaya, S. Nishikawa, K., 1995. Desk-top analysis of the structural stability of various point mutations introduced into ribonuclease H. J. Mol. Biol. 248, 733-738]. As well, an effective strategy using random mutagenesis and genetic selection has been developed to obtain E. coli RNase HI mutants with enhanced thermostability [Haruki, M., Noguchi, E., Akasako, A., Oobatake, M., Itaya, M., Kanaya, S., 1994. A novel strategy for stabilization of Escherichia coli ribonuclease HI involving a screen for an intragenic suppressor of carboxyl-terminal deletions. J. Biol. Chem. 269, 26904-26911]. In this study, both methods were combined: random mutations were individually introduced to Lys99-Val101 on the N-terminus of the alpha-helix IV and the preceding beta-turn, where substitutions of other amino acid residues were expected to significantly increase the stability from SPMP, and then followed by genetic selection. Val101 to Ala, Gln, and Arg mutations were selected by genetic selection. The Val101-->Ala mutation increased the thermal stability of E. coli RNase HI by 2.0 degrees C in Tm at pH 5.5, whereas the Val101-->Gln and Val101-->Arg mutations decreased the thermostability. Separately, the Lys99-->Pro and Asn100-->Gly mutations were also introduced directly. The Lys99-->Pro mutation increased the thermostability of E. coli RNase HI by 1.8 degrees C in Tm at pH 5.5, whereas the Asn100-->Gly mutation decreased the thermostability by 17 degrees C. In addition, the Lys99-->Pro mutation altered the dependence of the enzymatic activity on divalent metal ions.     

Role of C-terminal region of Staphylococcal nuclease for foldability,stability, and activity

The role of the C-terminal region of Staphylococcal nuclease (SNase) was examined by deletion mutation. Deletions up to eight residues do not affect the structure and function. The structure and enzymatic activity were partially lost by deleting Ser141-Asn149 (Delta141-149), and deletion of Trp140-Asn149 (Delta140-149) resulted in further loss of structure and activity. A 13-residue deletion showed the same effect as the 10-residue deletion. Both Ser141Gln and Ser141Ala mutations for an eight-residue deletion mutant did not alter properties as well as Ser141A1a for full-length SNase. In contrast, Trp140Ala mutation for Delta141-149 shows the same effect as the deletion of Trp140. Trp140Ala mutation for full-length SNase causes the loss of native structure. These observations indicate the significance of the 140th and the 141st residues. The side-chain of the 140th residue is required to be tryptophan; however, the backbone of the 141st residue is solely critical for foldability, but the side-chain information is not crucial. All of the mutants that take a non-native conformation show enzymatic activity and inhibitor-induced folding, suggesting that foldability is required for the activity.     

Quinoprotein ethanol dehydrogenase from <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis>: the unusual disulfide ring formed by adjacent cysteine residues is essential for efficient electron transfer to cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>550</Subscript>

All pyrroloquinoline quinone (PQQ)-dependent alcohol dehydrogenases contain an unusual disulfide ring formed between adjacent cysteine residues. A mutant enzyme that is lacking this structure was generated by replacing Cys105 and Cys106 with Ala in quinoprotein ethanol dehydrogenase (QEDH) from Pseudomonas aeruginosa ATCC17933. Heterologously expressed quinoprotein ethanol dehydrogenase in which Cys-105 and Cys-106 have been replaced by Ala (Cys105Ala/Cys106Ala apo-QEDH) was successfully converted to enzymatic active holo-enzyme by incorporation of its cofactor PQQ in the presence of Ca²⁺. The enzymatic activity of the mutant enzyme in the artificial dye test with N-methylphenazonium methyl sulfate (PMS) and 2,6-dichlorophenol indophenol (DCPIP) at pH 9 did not depend on an activating amine which is essential for wild type activity under these conditions. The mutant enzyme showed increased Michaelis constants for primary alcohols, while the affinity for the secondary alcohol 2-propanol was unaltered. Surprisingly, for all substrates tested the specific activity of the mutant enzyme in the artificial dye test was higher than that found for wild type QEDH. On the contrary, in the ferricyanide test with the natural electron acceptor cytochrome c ₅₅₀ the activity of mutant Cys105Ala/Cys106Ala was 15-fold lower than that of wild type QEDH. We demonstrate for the first time unambiguously that the unusual disulfide ring is essential for efficient electron transfer at pH 7 from QEDH to its natural electron acceptor cytochrome c ₅₅₀.     

Importance of arginines 63 and 423 in modulating the bile salt-dependent and bile salt-independent hydrolytic activities of rat carboxyl ester lipase

Previous studies using chemical modification approach have shown the importance of arginine residues in bile salt activation of carboxyl ester lipase (CEL) activity. However, the x-ray crystal structure of CEL failed to show the involvement of arginine residues in CEL-bile salt interaction. The current study used a site-specific mutagenesis approach to determine the role of arginine residues 63 and 423 in bile salt-dependent and bile salt-independent hydrolytic activities of rat CEL. Mutations of Arg(63) to Ala(63) (R63A) and Arg(423) to Gly(423) (R423G) resulted in enzymes with increased bile salt-independent hydrolytic activity against lysophosphatidylcholine, having 6.5- and 2-fold higher k(cat) values, respectively, in comparison to wild type CEL. In contrast, the R63A and R423A mutant enzymes displayed 5- and 11-fold decreases in k(cat), in comparison with wild type CEL, for bile salt-dependent cholesteryl ester hydrolysis. Although taurocholate induced similar changes in circular dichroism spectra for wild type, R63A, and R423G proteins, this bile salt was less efficient in protecting the mutant enzymes against thermal inactivation in comparison with control CEL. Lipid binding studies revealed less R63A and R423G mutant CEL were bound to 1,2-diolein monolayer at saturation compared with wild type CEL. These results, along with computer modeling of the CEL protein, indicated that Arg(63) and Arg(423) are not involved directly with monomeric bile salt binding. However, these residues participate in micellar bile salt modulation of CEL enzymatic activity through intramolecular hydrogen bonding with the C-terminal domain. These residues are also important, probably through similar intramolecular hydrogen bond formation, in stabilizing the enzyme in solution and at the lipid-water interface.     

The Interaction between Thermodynamic Stability and Buried Free Cysteines in Regulating the Functional Half-Life of Fibroblast Growth Factor-1

Protein biopharmaceuticals are an important and growing area of human therapeutics; however, the intrinsic property of proteins to adopt alternative conformations (such as during protein unfolding and aggregation) presents numerous challenges, limiting their effective application as biopharmaceuticals. Using fibroblast growth factor-1 as model system, we describe a cooperative interaction between the intrinsic property of thermostability and the reactivity of buried free-cysteine residues that can substantially modulate protein functional half-life. A mutational strategy that combines elimination of buried free cysteines and secondary mutations that enhance thermostability to achieve a substantial gain in functional half-life is described. Furthermore, the implementation of this design strategy utilizing stabilizing mutations within the core region resulted in a mutant protein that is essentially indistinguishable from wild type as regard protein surface and solvent structure, thus minimizing the immunogenic potential of the mutations. This design strategy should be generally applicable to soluble globular proteins containing buried free-cysteine residues.     

Site-directed mutagenesis of Petunia hybrida 5-enolpyruvylshikimate-3-phosphate synthase: Lys-23 is essential for substrate binding

Chemical modification of Escherichia coli 5-enolpyruvylshikimate-3-phosphate synthase, a target for the nonselective herbicide glyphosate (N-phosphonomethylglycine), with pyridoxal 5'-phosphate suggested that Lys-22 (equivalent to Lys-23 of the Petunia hybrida enzyme) is a potential active site residue (Huynh, Q. K., Kishore, G. M., and Bild, G. S. (1988) J. Biol. Chem. 263, 735-739). To investigate the possible role of this residue in the reaction mechanism, we have used site-directed mutagenesis to replace Lys-23 of the P. hybrida enzyme with 3 other amino acid residues: Ala, Glu, and Arg. Analysis of these mutant enzymes indicates that of these only the Lys-23 to Arg mutant enzyme is active; the other two replacements (Ala and Glu) result in inactivation of the enzyme. Two of the mutant enzymes (Lys-23 to Arg and Ala) were purified to homogeneity and characterized. The purified Lys-23 to Arg mutant enzyme is less sensitive than the wild type enzyme to pyridoxal 5'-phosphate. It showed identical Km values for substrates and a 5-fold higher I50 value for glyphosate in comparison with those from the wild type enzyme. Binding studies using fluorescence measurements revealed that the substrate shikimate 3-phosphate and glyphosate were able to bind the purified Lys-23 to Arg mutant enzyme but not to the purified catalytically inactive Lys-23 to Ala mutant enzyme. The above results suggest that the cationic group at position 23 of the enzyme may play an important role in substrate binding.     

A combined approach of mass spectrometry, molecular modeling, and site-directed mutagenesis highlights key structural features responsible for the thermostability of Sulfolobus solfataricus carboxypeptidase

Sulfolobus solfataricus carboxypeptidase (CPSso) is a thermostable zinc-metalloenzyme, consisting of four identical subunits with a M(r) of 43,000. In a previous paper (Occhipinti et al., Biophys J 2003; 85:1165-1175), we developed a structure of the enzyme by molecular modeling and validated it by site-directed mutagenesis and small angle X-ray scattering. Here, we report investigations aimed at further validating the model, as well as at identifying molecular determinants responsible for thermostability. To this end, we took advantage of mass spectrometry techniques, notably LC-MS/MS. The structure was confirmed by such approaches, in that they lead to the identification of a disulfide bridge formed by Cys286 and Cys293, whose location in the model is well suited for giving rise to the crosslink. More notably, we also identified a protease-resistant core consisting of the N- and C-terminal antiparallel alpha-helices, which in the model are predicted to interact with each other via hydrophobic quadrants. On the basis of the model, we also tentatively identified the most tightly interacting residues as Leu7, Ala380, and Leu376. Although the replacement of Ala380 by serine did not detectably impair protein stability, a dramatic drop in thermostability was observed when the two leucines were replaced by either aspartate (L7D; L376D) or asparagine (L7N; L376N). We then investigated the kinetic thermal stability of the wild type and the mutants by determining the thermodynamic activation parameters, DeltaG++, DeltaH++, and DeltaS++. Besides highlighting the key role of the hydrophobic core in thermostability, these results suggest clearly different mechanisms of destabilization by the single mutations, depending on whether the leucines are replaced by asparagines or aspartates.     

Automated Gas Chromatographic Monitoring of Ethylene Evolution out of Rice Seedlings Infected with Blast Fungus

To find amino acid residues which are required for glucoamylase activity, mutant glucoamylase genes were constructed by in vitro mutations of GLU1 DNA encoding Saccharomycopsis fibuligera glucoamylase and introduced into Saccharomyces cerevisiae, and the resulting mutant proteins were assayed for enzymatic activities. Eighteen mutant proteins were obtained by random insertions of a BamHX linker DNA. Six out of 7 proteins with mutations in conserved regions among divergent glucoamylases showed no activities, while 8 out of 11 proteins with mutations in unconserved regions had similar specific activities to a wild-type value, suggesting that the conserved regions are important to the activity. A series of amino-terminal deletion mutants were also constructed. A mutant protein with a deletion of only two amino acid residues from the amino terminus had a significant reduction in the activity, suggesting an essential role for the amino-terminal peptide. Ten mutant proteins with single amino acid replacements were produced by site-directed mutagenesis. Analyses for thermal stability and temperature dependency of these mutant proteins revealed that Ala81, Asp89, Trp94, Arg96, Asp97, and Trp166 are required for wild-type levels of activities, and that at least Ala81 and Asp89 are not essential to catalytic activities, but act in thermal stability.     

Glutamic acid-149 is important for enzymatic activity of yeast inorganic pyrophosphatase

Modification of Saccharomyces cerevisiae inorganic pyrophosphatase (PPase) with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide is known to lead to a loss of enzymatic activity, the rate of which is decreased in the presence of ligands binding to the active site [Cooperman, B. S., & Chiu, N. Y. (1973) Biochemistry 12, 1676-1682; Heitman, P., & Uhlig, H. J. (1974) Acta Biol. Med. Ger. 32, 565-594]. In this work we show that, when such inactivation is carried out in the presence of [14C]glycine ethyl ester (GEE), GEE is covalently incorporated into PPase, incorporation into the most highly labeled tryptic peptide is site-specific, as evidenced by the reduction of such incorporation in the presence of the active site ligands Zn2+ and Pi, the extent of formation of this specifically labeled peptide correlates with the fractional loss of PPase activity, and the specifically labeled peptide corresponds to residues 145-153 and the position of incorporation within this peptide is Glu-149. The significance of our findings for the location of the active site and for the catalytic mechanism of PPase is briefly considered in the light of the 3-A X-ray crystallographic structure of Arutyunyun and his colleagues [Arutyunyun, E. G., et al. (1981) Dokl. Akad. Nauk SSSR 258, 1481-1485; Kuranova, I. P., et al. (1983) Bioorg. Khim. 9, 1611-1919; Terzyan, S. S., et al. (1984) Bioorg. Khim. 10, 1469-1482].