5-Oxo-L-prolinase (L-pyroglutamate hydrolase). Purification and catalytic properties.

5-Oxo-L-prolinase, an enzyme that catalyzes the conversion of 5-oxo-L-proline (L-pyroglutamate; L-2-pyrrolidone-5-carboxylate) to L-glutamate coupled with the cleavage of ATP to ADP and Pi, has been purified about 1600-fold from rat kidney. Purification was carried out in the presence of 5-oxo-L-proline which protects the enzyme under a variety of conditions. An estimate of the molecular weight (about 325,000) was made by gel filtration on Sephadex G-200. K+ (or NH4+) and Mg2+ were required for activity. GTP, ITP, CTP, and UTP were much less active than ATP; dATP was 43% as active as ATP. ADP inhibited and addition of pyruvate kinase and phosphoenolpyruvate activated the reaction. The enzyme, which is protected during storage by dithiothreitol, is inhibited by p-hydroxymercuribenzoate, N-ethylmaleimide, and iodoacetamide. The apparent Km values for 5-oxo-L-proline and ATP are, respectively, 0.05 and 0.17 mM. The pH profile indicates a broad range of activity from about pH 5.5 to pH 11.2 with apparent maxima at about pH 7 and pH 9.7. The formation of Pi and glutamate was equimolar over a wide pH range. When the enzyme was incubated with ATP, Mg2+, K+, and L-2-imidazolidone-4-carboxylate or L-dihydroorotate, cleavage of ATP to ADP and Pi occurred, but no cleavage of the imino acid substrates was observed; when the enzyme was incubated under these conditions with 2-piperidone-6-carboxylate, 4-oxy-5-oxoproline, and 3-oxy-5-oxoproline, the corresponding dicarboxylic amino acids were formed, but the molar ratio of Pi to amino acid formation was significantly greater than unity.     

Studies on the cholesterol ester hydrolase of Trogoderma (Coleoptera).

The enzyme cholesterol ester hydrolase (EC 3.1.1.13) was detected in the larvae of the khapra beetle, Trogoderma granarium (Everts). The pH and temperature optima for the enzyme were 6.6 degrees and 37 degrees C respectively. The mol.wt. of the enzyme was 76000-80000. The enzyme was equally effective in hydrolysing cholesteryl acetate, stearate and oleate. Cholesterol derivatives, namely the chloride and the methyl ether, inhibited the enzyme activity almost completely. It was also inhibited completely by p-hydroxymercuribenzoate. This inhibition was reversed by the addition of dithiothreitol, reduced glutathione or cysteine. The enzyme activity was associated predominantly with the 104000 g fraction.     

Studies on rat brain acyl-coenzyme A hydrolase (short chain).

A mitochondrial short chain acyl-CoA hydrolase, purified 1375-fold from rat brain, has a molecular weight of approximately 1.55 × 10⁵, a pH optimum of 8.1, an ionic strength optimum for activity and stability of 100–300 mM, is product activated by acetate and inhibited by DL-lipoic acid (K_i ? 5 μM) and 0.1 M orthophosphate (>50%). Acetyl, propionyl, butyryl, succinyl, acetoacetyl, malonyl and octanoyl-CoA are substrates. The highest maximum velocity and product activation was observed with acetyl-CoA as substrate.     

Quantum chemical studies of the catalytic mechanism of N-terminal nucleophile hydrolase

Modeling of the catalytic mechanism of penicillin acylase, a member of the N-terminal nucleophile hydrolase superfamily, is for the first time conducted at ab initio quantum chemistry level. The uniqueness of this family of enzymes is that their active site lacks His and Asp (Glu) residues, comprising together with a serine residue the classical catalytic triad. The current investigation confirms that the amino group of the N-terminal serine residue in N-terminal hydrolases is capable of activating its own hydroxyl group. Using the MP2/RHF method with the 6−31+G** basis set, stationary points on the potential energy surface of the considered molecular system were located, corresponding to local minima (complexes of reagents, products, intermediate) and to saddle points (transition states). It turned out that the stage of acyl-serine formation proceeds via two transition states; the first one, which separates reagents from the so-called tetrahedral intermediate, has the highest relative energy (30 kcal/mol). In contrast to recently proposed empiric suggestions, we have found that participation of a bridging water molecule in proton shuttling is not necessary for the catalysis. The quantum chemical calculations showed a crucial role of a specific solvation in decreasing the activation barrier of the reaction by approximately 10 kcal/mol. Published in Russion in Biokhimiya, 2007, Vol. 72, No. 5, pp. 615–621.     

Brassica napus soluble epoxide hydrolase (BNSEH1).

Epoxide hydrolase (EC 3.3.2.3) in plants is involved in the metabolism of epoxy fatty acids and in mediating defence responses. We report the cloning of a full-length epoxide hydrolase cDNA (BNSEH1) from oilseed rape (Brassica napus) obtained by screening of a cDNA library prepared from methyl jasmonate induced leaf tissue, and the 5'-RACE technique. The cDNA encodes a soluble protein containing 318 amino acid residues. The identity on the protein level is 85% to an Arabidopsis soluble epoxide hydrolase (sEH) and 50-60% to sEHs cloned from other plants. A 5 x His tag was added to the N-terminus of the BNSEH1 and the construct was over-expressed in the yeast Pichia pastoris. The recombinant protein was recovered at high levels after Ni-agarose chromatography of lysed cell extracts, had a molecular mass of 37 kDa on SDS/PAGE and cross-reacted on Western blots with antibodies raised to a sEH from Arabidopsis thaliana. BNSEH1 was shown to be a monomer by gel filtration analysis. The activity was low towards cis-stilbene oxide but much higher using trans-stilbene oxide as substrate with Vmax of 0.47 micro mol.min.mg-1, Km of 11 micro m and kcat of 0.3 s-1. The optimum temperature of the recombinant enzyme was 55 degrees C and the optimum pH 6-7 for trans-stilbene oxide hydrolysis. The isolation of BNSEH1 will facilitate metabolic engineering of epoxy fatty acid metabolism for functional studies of resistance and seed oil modification in this important oilcrop.     

Stereospecificity of peptidyl dipeptide hydrolase (angiotensin I-converting enzyme).

The stereospecificity of peptidyl dipeptide hydrolase [EC 3.4.15.1] was investigated. Six free and N-blocked alanyl peptides containing D-alanine were synthesized and tested as substrates. Their susceptibilities were determined by measuring Ala-Ala release by cation exchange column chromatography. Their Michaelis constants, Km values, and velocity maxima, Vmax values, were also determined. The enzyme showed high stereospecificity for an amino acyl residue in position 3 from C-terminus: it had an absolute requirement for the alanyl residue of the L-configuration in this position. An alanyl residue of the L-configuration in position 1 or 2 increased, but was not essential for activity. The enzyme showed little stereospecificity for an alanyl residue in position 4 from the C-terminus.     

Studies of the molecular mechanism of discrimination between cGMP and cAMP in the allosteric sites of the cGMP-binding cGMP-specific phosphodiesterase (PDE5).

The regulatory domain of the cGMP-binding cGMP-specific 3':5'-cyclic nucleotide phosphodiesterase (PDE5) contains two homologous segments of amino acid sequence that encode allosteric cyclic nucleotide-binding sites, referred to as site a and site b, which are highly selective for cGMP over cAMP. The possibility that the state of protonation in these sites contributes to cyclic nucleotide selectivity was investigated. The binding of cGMP or cAMP was determined using saturation and competition kinetics at pH values between 5.2 and 9.5. The total cGMP binding by PDE5 was unchanged by variation in pH, but the relative affinity for cGMP versus cAMP progressively decreased as the pH was lowered. Using site-directed mutagenesis, a conserved residue, Asp-289, in site a of PDE5 has been identified as being important for cyclic nucleotide discrimination in this site. It is proposed that deprotonation of Asp-289 enhances the number and strength of bonds formed with cGMP, while concomitantly decreasing the interactions with cAMP.     

A rapid colorimetric assay for gamma-glutamyl hydrolase (conjugase).

A simple procedure for the measurement of gamma-glutamyl hydrolase (conjugase) activity is described. Glutamic acid released from pteroylpenta-gamma-glutamate by hog kidney and chicken pancreas conjugases was quantitated using the dye 4,4'-bis(dimethylamino)benzophenone hydrazone. The procedure involves hydrolysis of the folylpoly-gamma-glutamate substrate by conjugase, conversion of glutamate to alpha-ketoglutarate by L-glutamate dehydrogenase and colorimetric measurement of the BDBH derivative of alpha-ketoglutarate. The release of as little as one nmol of glutamic acid from the substrate can be measured by this procedure, which is well suited for the assay of a variety of conjugase preparations. In addition, the method should provide a general assay for the enzymatic hydrolysis of various folate and antifolate polyglutamates.     

Some enzymatic properties of peptidyl dipeptide hydrolase (angiotensin I-converting enzyme).

Peptidyldipeptide hydrolase [angiotensin I-converting enzyme, EC 3.4.15.1] was inhibited by inorganic and organic phosphorus compounds tested, except for beta-glycerophosphate, 5'-AMP, and 5'-ADP, at the reagent concentrations used. Orthophosphate and pyrophosphate nonspecifically inhibited the enzyme activity. The enzyme was also inhibited specifically by carboxylates. The degree of inhibition by aliphatic monocarboxylates increased in proportion to their chain length up to C14. Aromatic and omega-phenylalkylcarboxylates also inhibited the enzyme activity. The enzyme was noncompetitively inhibited by acetate, 3-phenylpropionate and laurate. The Ki's for acetate, 3-phenylpropionate, and laurate were 60, 3.3, and 2.5 mM, respectively.     

Studies on the specificity of acetylaminoacyl-peptide hydrolase.

In a continuing attempt to explore the types of specificity determinants that may affect protein-protein (peptide) interactions, a number of short (2-5 residues) acetylated peptides have been compared as substrates for the enzyme acetylaminoacyl-peptide hydrolase (EC 3.4.19.1). The reference substrate was Ac-AAAA, and most of the other substrates were derived from this basic structure by single amino acid substitutions. The Km and kcat for the different substrates were determined by standard steady-state kinetics, and the corresponding delta delta GT++ value derived from kcat/Km was used for the comparison, setting delta detal GT++ for Ac-AAAA equal to 0. The best substrates were found to be those containing negative charges (Asp > Glu) or aromatic residues in positions 1', 2', or 3' (delta delta GT++ values of 2-5 kJ); the negative charge provided by the C-terminus of the substrate also appears to be important, since the amide and O-Me ester derivatives caused a change in delta delta GT++ values of -7 to -8 kJ from the reference peptide. The stimulating effect of the negative charges is consistent with the inhibitory effect of positive charges in similar peptides (Krishna RG, Wold F, 1992, Protein Sci 1:582-589), and the proposed active site model incorporates subsites for both charge-charge and hydrophobic interactions. In assessing all the data, it is clear that the properties of the individual substrates reflect the total make-up of each peptide and not only the effect of a single residue in a given position.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the metabolic role of peptidyl-tRNA hydrolase

Summary A mutant strain of Eschrichia coli that is temperature-sensitive for growth stopped protein biosynthesis at 43° C after a brief lag (Fig. 1). Cell-free extracts from the strain showed no specific defect in aminoacyl-tRNA synthetases, binding initiator tRNA to ribosomes (Table 1), protein chain elongation (Tables 2, 5) or protein chain termination (Tables 3, 4) at high temperature.The partially purified enzyme peptidyl-tRNA hydrolase, however, was temperature-sensitive (Table 6); the mutant hydrolase was inactivated rapidly at 43° C (Table 7). Mixing experiments ruled out the presence, in the mutant enzyme preparation, of an inhibitor and also demonstrated, on the mutant enzyme, a protective effect by wild type enzyme that was not shown by general coli proteins (Tables 8, 9).Interrupted mating allowed the temperature-sensitive growth phenotype to be mapped near to and before trp (Figs. 4, 5). Co-transsduction, mediated by bacteriophage P1, with trp ⁺ (frequency 7.5%) located the marker at 24 min on the coli map. All transductants for temperature-sensitive growth also had temperature-sensitive peptidyl-tRNA hydrolase activity in crude sonicates (Table 10). We provisionally conclude that the temperature-sensitive protein synthesis and growth are caused by a single genetic change in the structural gene (pth) for peptidyl-tRNA hydrolase.After shift to 43° C the polysomes of the mutant cells broke down into 70S particles (Figs. 2, 3). A defect in protein biosynthesis thus appeared to be located after termination and before reformation of new polysomes.The metabolic role of peptidyl-tRNA hydrolase is discussed in the light of these experiments.Journal paper No. J-7465 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa, project no. 1747.     

Purification and characterization of guinea pig serum aminoacylproline hydrolase (aminopeptidase P).

Aminoacylproline hydrolase (EC 3.4.11.9) of guinea pig serum has been obtained as two apparently homogeneous isoforms. Dialyzed serum was chromatographed successively on Affi-gel blue, hydroxyapatite, DE-cellulose, phenyl-Sepharose, an affinity matrix for angiotensin converting enzyme and concanavalin-Sepharose. On the latter matrix, 68% of the enzyme activity was eluted with alpha-methyl mannoside at 10 and 100 mM, and 29% was eluted with alpha-methyl glucoside, 500 mM, at 56 degrees C. The two fractions ('biantennary' and 'high mannose' fractions, respectively) were concentrated and then chromatographed separately on Sephacryl S-200HR. Both fractions were eluted as expected for a globular protein of Mr 217,000. On SDS-PAGE, under reducing and non-reducing conditions, each of the concanavalin-Sepharose fractions was separated into two protein bands, Mr 89,000 and Mr 81,500. Each of the bands was found to be N-blocked when N-terminal amino acid sequencing was attempted. The reaction of the 'biantennary' fraction with the synthetic substrate Arg-Pro-Pro-[3H]benzylamide was characterized in part: Km 0.7 microM, kcat 124.6 min-1, kcat/Km 1.78.10(8) M-1 min-1. Hydrolysis of the substrate was strongly inhibited by bradykinin and those of its lower homologs that contain two adjacent proline residues. Cu2+ was strongly inhibitory. Co2+ at 30 microM activated the enzyme, as did Mn2+, Mg2+ and Ca2+ at higher concentrations. Sulfhydryl compounds, including captopril, inhibited the enzyme as did 1,10-phenanthroline. Iodoacetamide and N-ethylmaleimide had no effects, but 4-hydroxymercuribenzoate conferred a partial inhibition over a remarkably wide concentration range: 0.34-1400 microM. Amastatin and bestatin did not inhibit the enzyme. Aminoacylproline hydrolase of guinea pig serum appears to be a heterogeneous, glycosylated metallo-enzyme with a high affinity for bradykinin and related peptides in which the sequence Pro-Pro, Xaa-Pro-Pro or Xaa-Pro-Hyp is N-terminal.     

Divergence of chemical function in the alkaline phosphatase superfamily: structure and mechanism of the P-C bond cleaving enzyme phosphonoacetate hydrolase

Phosphonates constitute a class of natural products that mimic the properties of the more common organophosphate ester metabolite yet are not readily degraded owing to the direct linkage of the phosphorus atom to the carbon atom. Phosphonate hydrolases have evolved to allow bacteria to utilize environmental phosphonates as a source of carbon and phosphorus. The work reported in this paper examines one such enzyme, phosphonoacetate hydrolase. By using a bioinformatic approach, we circumscribed the biological range of phosphonoacetate hydrolase to a select group of bacterial species from different classes of Proteobacteria. In addition, using gene context, we identified a novel 2-aminoethylphosphonate degradation pathway in which phosphonoacetate hydrolase is a participant. The X-ray structure of phosphonoformate-bound phosphonoacetate hydrolase was determined to reveal that this enzyme is most closely related to nucleotide pyrophosphatase/diesterase, a promiscuous two-zinc ion metalloenzyme of the alkaline phosphatase enzyme superfamily. The X-ray structure and metal ion specificity tests showed that phosphonoacetate hydrolase is also a two-zinc ion metalloenzyme. By using site-directed mutagenesis and (32)P-labeling strategies, the catalytic nucleophile was shown to be Thr64. A structure-guided, site-directed mutation-based inquiry of the catalytic contributions of active site residues identified Lys126 and Lys128 as the most likely candidates for stabilization of the aci-carboxylate dianion leaving group. A catalytic mechanism is proposed which combines Lys12/Lys128 leaving group stabilization with zinc ion activation of the Thr64 nucleophile and the substrate phosphoryl group.     

The chemical structure of prostaglandin X (prostacyclin).

The chemical structure of prostaglandin X, the anti-aggregatory substance derived from prostaglandin endoperoxides, is 9-deoxy-6, 6alpha-epoxy-delta5-PGF1alpha. The stable compound formed when prostaglandin X undergoes a chemical transformation in biological systems in 6-keto-PGF1alpha. Prostaglandin X is stabilized in aqueous preparations by raising the pH to 8.5 or higher. The trivial name prostacyclin is proposed for 9-deoxy-6, 9alpha-epoxy-delta5-PGF1alpha.     

Sequence determination and analysis of S-adenosyl-L-homocysteine hydrolase from yellow lupine (Lupinus luteus).

The coding sequences of two S-adenosyl-L-homocysteine hydrolases (SAHases) were identified in yellow lupine by screenig of a cDNA library. One of them, corresponding to the complete protein, was sequenced and compared with 52 other SAHase sequences. Phylogenetic analysis of these proteins identified three groups of the enzymes. Group A comprises only bacterial sequences. Group B is subdivided into two subgroups, one of which (B1) is formed by animal sequences. Subgroup B2 consist of two distinct clusters, B2a and B2b. Cluster B2b comprises all known plant sequences, including the yellow lupine enzyme, which are distinguished by a 50-residue insert. Group C is heterogeneous and contains SAHases from Archaea as well as a new class of animal enzymes, distinctly different from those in group B1.     

Inactivation of S-adenosylhomocysteine hydrolase by 5'-deoxy-5'-methylthioadenosine

In the coupling of ATP pyrophosphorolysis to Ca²⁺ transport in beef heart mitochondria, for each molecule of ATP cleaved, one proton is released and one Ca²⁺ is transported into the interior space. With the use of tritium labelled ATP, it could be shown that ATP is pyrophosphorylyzed into a species equivalent to Pi that moves inward, and a species equivalent to ADP that is extruded into the aqueous space on the exterior of the mitochondrion. The species equivalent to Pi has been identified as a negatively charged form of Pi (PO^?) and the species equivalent to ADP as a positively charged form (ADP⁺). The inward flow of PO^? is coupled to the inward flow of Ca²⁺ in 1:1 stoichiometry—a token that Ca²⁺ must enter in the form of Ca²⁺A^?, where A^? is a monovalent anion. During ATP pyrophosphorolysis protons are released on the I side and taken up on the M side—one proton for each molecule of ATP cleaved. The alkalinization of the matrix space leads to the deposition of Ca₃(PO₄)₂ and to the extrusion of the two species released by this deposition (Pi, K⁺). Two thirds of the PO^? is trapped as Ca₃(PO₄)₂ in the matrix space and one third is extruded into the external space. The extrusion of K⁺ provides a mechanism by which protons can be continuously brought into the matrix space to sustain a high rate of coupled pyrophosphorolysis of ATP. The coupling pattern for Ca²⁺ transport driven by ATP pyrophosphorolysis is identical with the corresponding pattern for Ca²⁺ transport driven by electron transfer. This identity is suggestive that coupling mediated by the Fo-F₁ system and coupling mediated by electron transfer complexes are mechanistically indistinguishable.     

Salt induced transitions between multiple conformations of poly (rG-m5dC).poly (rG-m5dC).

Salt induced transitions between four conformations of the methylated ribo-deoxyribo co-polymer poly (rG-m5dC).poly (rG-m5dC) have been studied using phosphorous-NMR, Raman spectroscopy, and circular dichroism. A high salt A-Z transition is observed for the polymer. However, the methylated polymer does not enter the high salt Z form more readily than the analogous unmethylated polymer, unlike the effect of methylation on the fully deoxy polymer poly (dG-dC).poly (dG-dC). The methylated polymer fails to undergo a low salt A-Z transition in 5 mM Tris buffer, unlike the unmethylated poly (rG-dC).poly (rG-dC). However, if the counterion is changed to triethanolamine buffer, an A-Z transition does take place. In 5 mM Tris buffer the phosphorous-NMR spectrum of poly (rG-m5dC).poly (rG-m5dC) shows one resonance in the absence of NaCl that splits into two closely spaced resonances as the NaCl level is increased to 30 mM. The Raman spectrum of poly (rG-m5dC).poly (rG-m5dC) shows that it is in the A conformation at intermediate salt concentrations. From this we conclude that poly (rG-m5dC).poly (rG-m5dC) is in a regular A conformation in Tris buffer at low Na+ levels, shifting to an alternating A conformation with a dinucleotide repeat at intermediate salt concentrations.