Aminoacylase I is not a glycolipid-anchored ectoenzyme in pig kidney.

Subcellular fractionation of pig kidney cortex revealed that aminoacylase I (EC 3.5.1.14, N-acyl-L-amino-acid aminohydrolase) is predominantly a soluble enzyme with only 0.5% of the total activity being recovered in the membrane fraction. The aminoacylase I activity associated with the membrane preparations displayed neither rapid release following incubation with phosphatidylinositol-specific phospholipase C from Bacillus thuringiensis nor the distinctive differential pattern of detergent solubilization which was seen with glycosyl-phosphatidylinositol-anchored proteins (renal dipeptidase, alkaline phosphatase). When fractionated by phase separation in Triton X-114, integral membrane proteins of kidney microvillar membranes partitioned predominantly (greater than 90%) into the detergent-rich phase. In contrast, only 3.7% of aminoacylase I activity associated with microvillar membranes partitioned into the detergent-rich phase. Aminoacylase I activity of pig kidney would therefore appear to be a hydrophilic protein in nature and is not, as suggested previously, a G-PI-anchored integral membrane protein.     

Gene cloning, sequence analysis, purification, and characterization of a thermostable aminoacylase from Bacillus stearothermophilus.

A genomic DNA fragment encoding aminoacylase activity of the eubacterium Bacillus stearothermophilus was cloned into Escherichia coli. Transformants expressing aminoacylase activity were selected by their ability to complement E. coli mutants defective in acetylornithine deacetylase activity, the enzyme that converts N-acetylornithine to ornithine in the arginine biosynthetic pathway. The 2.3-kb cloned fragment has been entirely sequenced. Analysis of the sequence revealed two open reading frames, one of which encoded the aminoacylase. B. stearothermophilus aminoacylase, produced in E. coli, was purified to near homogeneity in three steps, one of which took advantage of the intrinsic thermostability of the enzyme. The enzyme exists as homotetramer of 43-kDa subunits as shown by cross-linking experiments. The deacetylating capacity of purified aminoacylase varies considerably depending on the nature of the amino acid residue in the substrate. The enzyme hydrolyzes N-acyl derivatives of aromatic amino acids most efficiently. Comparison of the predicted amino acid sequence of B. stearothermophilus aminoacylase with those of eubacterial acetylornithine deacylase, succinyldiaminopimelate desuccinylase, carboxypeptidase G2, and eukaryotic aminoacylase I suggests a common origin for these enzymes.     

Nuclear magnetic relaxation studies of the role of the metal ion in Mn2(+)-substituted aminoacylase I

Substitution of the essential Zn2+ ions of porcine kidney aminoacylase I (EC 3.5.1.14) by Mn2+ did not markedly affect the kinetic properties of the enzyme. Using Mn2+ as a paramagnetic probe, we were able to study the conformations of bound ligands by measuring the enhancement of ligand proton relaxation in 1H NMR. In addition, the effects of inhibitors on the paramagnetic enhancement of water proton relaxation rates were examined. The results of both approaches, in agreement with kinetic evidence, suggest that the metal center of aminoacylase I is too distant from the ligand binding site to allow direct participation of the metal in substrate binding or catalysis. We, therefore, propose that the metal ion of aminoacylase I plays a purely structural role.     

A simplified purification method of aminoacylase I

Taking advantage that the stability of aminoacylase I increases in the presence of Co2+, a simplified method of its purification, which includes a heating step, is described. This method is easy, fast, and gives a good yield of the enzyme. The properties of aminoacylase I thus prepared are similar to those described in the literature.     

Studies on Continuous Enzyme Reactions

The kinetics of hydrolysis of acetyl-dl-methionine in DEAE-cellulose-aminoacylase (EC 3.5.1.14) column and DEAE-Sephadex-aminoacylase column was studied.

The rate of hydrolysis of substrate was shown to be dependent on the flow rate and independent to the dimension of the enzyme column. The rate of hydrolysis of the substrate was equal in cases of down-ward flow and of up-ward flow. The deteriorated aminoacylase columns by long period operation were reactivated by the recharge of aminoacylase to them. The continuous enzyme reaction using an aminoacylase column was superior to the batch enzyme reaction using native aminoacylase.

The enzymatic properties of the water-insoluble aminoacylase prepared by linking mold aminoacylase (EC 3.5.1.14) to DEAE-Sephadex were studied and compared with those of the native aminoacylase.

Optimum pH values for hydrolysis of several substrates by the DEAE-Sephadex-amino-acylase complex (DSA-complex) shifted about 0.5~1.5 pH units more to the acid side than those by the native enzyme. On the effects of metal ions and inhibitors, substrate specificity, optical specificity and kinetic constants, no marked difference was observed between the native enzyme and the DSA-complex. Heat stability, optimum temperature and resistance towards proteases were increased by conversion from the native form to the insoluble enzyme. It was also observed that the DSA-complex was activated by urea.     

Isolation and characterization of N-long chain acyl aminoacylase from Pseudomonas diminuta

N-Long chain acyl aminoacylase II (Enzyme II) catalyzing the hydrolysis of N-long chain acyl amino acids was purified about 2,000-fold from the cell extracts of Pseudomonas diminuta with 1.8% of activity yield. The purified enzyme was homogeneous on polyacrylamide gel electrophoresis and the molecular weight was 220,000. Enzyme II differed from N-long chain acyl aminoacylase I (Enzyme I) in molecular weight, in substrate specificity, and in behavior toward temperature and pH. Enzyme II showed broader substrate specificity than Enzyme I and catalyzed the hydrolysis of lipoamino acids containing various amino acid residues, although Enzyme I was almost specific to the lipoamino acids containing L-glutamate. The extent of hydrolysis by Enzyme II reaction varied depending on the kinds of lipoamino acids and were: 100% for palmitoyl-L-glutamate, 91% for myristoyl-L-glutamate, 85% for lauroyl-L-glutamate, 54% for lauroyl-L-aspartate, 28% for stearoyl-L-glutamate and 17.5% for lauroyl-glycine.     

Further characterization of porcine kidney aminoacylase I reveals close similarity to 'renal dipeptidase'

We present data indicating that aminoacylase I (EC 3.5.1.14) from porcine kidney and 'renal dipeptidase' (EC 3.4.13.11) are closely related. We show that, in situ, a considerable fraction of aminoacylase activity ist attached to membranes. Incubation of washed microsomal membranes with phospholipase C from B. cereus results in the rapid solubilization of aminoacylase I, suggesting that aminoacylase--as shown for renal dipeptidase before--bears a glycolipid 'membrane anchor'. In agreement with this assumption, purified aminoacylase was found to contain myo-inositol, a characteristic component of phosphatidylinositol-anchored membrane proteins. A reexamination of the molecular mass of purified aminoacylase yielded values (46,000 +/- 2,000 Da by SDS polyacrylamide electrophoresis, 98,000 +/- 5,000 Da by sedimentation equilibrium centrifugation) similar to those reported for renal dipeptidase. The enzymes coelute during most of the procedures applied in the purification of aminoacylase or renal dipeptidase, but can be separated by hydrophobic interaction chromatography. A survey of the literature revealed a series of additional features of aminoacylase I and renal dipeptidase (amino-acid composition, isoelectric points, metal dependence, and more) that are strikingly similar.     

Reactivities of sulfhydryl groups in native and metal-free aminoacylase I

Aminoacylase I from porcine kidney (EC 3.5.1.14) contains seven cysteine residues per subunit. Three sulfhydryl groups are accessible to modification by 4-hydroxymercuribenzoate (p-MB). The kinetics of the reaction suggest that only one of these groups affects acylase activity when modified by p-MB. Its reaction rate increases 2-3-fold when the essential metal ion of aminoacylase is removed. Modification of metal-free apoenzyme by N-ethylmaleimide (NEM) abolishes its activity without impairing Zn2+ binding. This indicates that the sulfhydryl group reacting with NEM is not directly coordinated to the metal. DTNB (5,5'-Dithio-bis(2-nitrobenzoate), Ellman's reagent) also modifies three sulfhydryl groups per subunit. In this case, the reactivities of native aminoacylase and apoenzyme are not significantly different. N-Hydroxy-2-aminobutyrate, a strong aminoacylase inhibitor, substantially increases the reactivity of the slowest reacting sulfhydryl in both native enzyme and metal-free aminoacylase. It appears that binding of the inhibitor or removal of the metal ion induces conformational changes of the amino-acylase active site that render a buried sulfhydryl group more accessible to modification.     

N-Acyl-L-aromatic amino acid deacylase in animal tissues

An enzyme deacylating preferentially N-acyl-L-aromatic amino acids was partially purified from rat kidney. The purification procedure included DEAE-cellulose column chromatography, (NH4)2SO4 fractionation, gel-filtration on a Sephadex G-200 column and further DEAE-cellulose chromatography. The enzyme was thus separated from aminoacylase (N-acylamino-acid amidohydrolase, EC 3.5.1.14) (acylase I). Although the enzyme preparation contained other acylases, the experimental data (effect of p-chloromercuric benzoate, heat stability and inhibition between substrates) suggest that the enzyme acts preferentially on N-acyl derivatives of L-tryptophan, L-tyrosine, L-phenylalanine and L-histidine. This enzyme appears to be present in many animal tissues.     

Novel bifunctional hyperthermostable carboxypeptidase/aminoacylase from Pyrococcus horikoshii OT3

Genome sequencing of the thermophilic archaeon Pyrococcus horikoshii OT3 revealed a gene which had high sequence similarity to the gene encoding the carboxypeptidase of Sulfolobus solfataricus and also to that encoding the aminoacylase from Bacillus stearothermophilus. The gene from P. horikoshii comprises an open reading frame of 1,164 bp with an ATG initiation codon and a TGA termination codon, encoding a 43,058-Da protein of 387 amino acid residues. However, some of the proposed active-site residues for carboxypeptidase were not found in this gene. The gene was overexpressed in Escherichia coli with the pET vector system, and the expressed enzyme had high hydrolytic activity for both carboxypeptidase and aminoacylase at high temperatures. The enzyme was stable at 90 degrees C, with the highest activity above 95 degrees C. The enzyme contained one bound zinc ion per one molecule that was essential for the activity. The results of site-directed mutagenesis of Glu367, which corresponds to the essential Glu270 in bovine carboxypeptidase A and the essential Glu in other known carboxypeptidases, revealed that Glu367 was not essential for this enzyme. The results of chemical modification of the SH group and site-directed mutagenesis of Cys102 indicated that Cys102 was located at the active site and was related to the activity. From these findings, it was proven that this enzyme is a hyperthermostable, bifunctional, new zinc-dependent metalloenzyme which is structurally similar to carboxypeptidase but whose hydrolytic mechanism is similar to that of aminoacylase. Some characteristics of this enzyme suggested that carboxypeptidase and aminoacylase might have evolved from a common origin.     

Studies on immobilized enzymes. IX. Preparation and properties of aminoacylase covalently attached to halogenoacetylcelluloses

Immobilization of mold aminoacylase (N-acylamino acid amidohydrolase, EC 3.5.1.14) was investigated by covalently binding the enzyme to halogenoacetylcelluloses. As a result, the iodoacetylcellulose was found to be the best carrier among the halogenoacetylcelluloses. The yield of activity of the insoluble aminoacylase relative to that of the native aminoacylase used was 40–50%, and the specific activities of both enzyme preparations were the same within the limits of error of the estimation.     

Catalysis by hog-kidney aminoacylase does not involve a covalent intermediate

Hog kidney aminoacylase (N-acylamino acid amidohydrolase; acylase I) is shown to catalyze the exchange of acetate oxygens with water at a significant rate only when alanine is present simultaneously. These studies, conducted using the 18O-isotope induced shift on 13C-NMR spectra, provide evidence in favor of a linear kinetic mechanism as opposed to a 'ping-pong' double-displacement mechanism. At pH values above neutrality, aminoacylase I also catalyzes the exchange of alanine oxygens with those of water. Ionic strength and pH effects on the kinetics of aminoacylase I are examined and the results are interpreted in terms of a model of the enzyme active site.     

Properties of acylase preparations from an actinomycete culture

A comparative study of some physico-chemical properties of high-purified preparations of extracellular penicillin-V-acylase and aminoacylase, isolated from the actinomycete Streptoverticillium No 62, revealed the difference in pH and temperature optima, in the sensitivity to the ionic composition of buffer solutions, in the enzyme stability during storage. As for the aminoacylase preparation, its thermostability was studied at different pH values, as well as the effect of specific compounds was tested. Similar to other fungal enzymes, the aminoacylase possesses a wide substrate specificity, and by its stereospecificity can be related to L-aminoacylases, while penicillin-V-acylase is a high-specific enzyme, active against phenoxymethylpenicillin.     

The molecular basis of aminoacylase 1 deficiency

Aminoacylase 1 is a zinc-binding enzyme which hydrolyzes N-acetyl amino acids into the free amino acid and acetic acid. Deficiency of aminoacylase 1 due to mutations in the aminoacylase 1 (ACY1) gene follows an autosomal-recessive trait of inheritance and is characterized by accumulation of N-acetyl amino acids in the urine. In affected individuals neurological findings such as febrile seizures, delay of psychomotor development and moderate mental retardation have been reported. Except for one missense mutation which has been studied in Escherichia coli, mutations underlying aminoacylase 1 deficiency have not been characterized so far. This has prompted us to approach expression studies of all mutations known to occur in aminoacylase 1 deficient individuals in a human cell line (HEK293), thus providing the authentic human machinery for posttranslational modifications. Mutations were inserted using site directed mutagenesis and aminoacylase 1 enzyme activity was assessed in cells overexpressing aminoacylase 1, using mainly the natural high affinity substrate N-acetyl methionine. Overexpression of the wild type enzyme in HEK293 cells resulted in an approximately 50-fold increase of the aminoacylase 1 activity of homogenized cells. Most mutations resulted in a nearly complete loss of enzyme function. Notably, the two newly discovered mutations p.Arg378Trp, p.Arg378Gln and the mutation p.Arg393His yielded considerable residual activity of the enzyme, which is tentatively explained by their intramolecular localization and molecular characteristics. In contrast to aminoacylase 1 variants which showed no detectable aminoacylase 1 activity, aminoacylase 1 proteins with the mutations p.Arg378Trp, p.Arg378Gln and p.Arg393His were also detected in Western blot analysis. Investigations of the molecular bases of additional cases of aminoacylase 1 deficiency contribute to a better understanding of this inborn error of metabolism whose clinical significance and long-term consequences remain to be elucidated.     

Novel Bifunctional Hyperthermostable Carboxypeptidase/Aminoacylase from Pyrococcus horikoshii OT3

Genome sequencing of the thermophilic archaeon Pyrococcus horikoshii OT3 revealed a gene which had high sequence similarity to the gene encoding the carboxypeptidase of Sulfolobus solfataricus and also to that encoding the aminoacylase from Bacillus stearothermophilus. The gene from P. horikoshii comprises an open reading frame of 1,164 bp with an ATG initiation codon and a TGA termination codon, encoding a 43,058-Da protein of 387 amino acid residues. However, some of the proposed active-site residues for carboxypeptidase were not found in this gene. The gene was overexpressed in Escherichia coli with the pET vector system, and the expressed enzyme had high hydrolytic activity for both carboxypeptidase and aminoacylase at high temperatures. The enzyme was stable at 90°C, with the highest activity above 95°C. The enzyme contained one bound zinc ion per one molecule that was essential for the activity. The results of site-directed mutagenesis of Glu367, which corresponds to the essential Glu270 in bovine carboxypeptidase A and the essential Glu in other known carboxypeptidases, revealed that Glu367 was not essential for this enzyme. The results of chemical modification of the SH group and site-directed mutagenesis of Cys102 indicated that Cys102 was located at the active site and was related to the activity. From these findings, it was proven that this enzyme is a hyperthermostable, bifunctional, new zinc-dependent metalloenzyme which is structurally similar to carboxypeptidase but whose hydrolytic mechanism is similar to that of aminoacylase. Some characteristics of this enzyme suggested that carboxypeptidase and aminoacylase might have evolved from a common origin.     

Refolding intermediate of guanidine hydrochloride denatured aminoacylase

The refolding of aminoacylase denatured in 6M guanidine hydrochloride (GdnHCl) has been studied by measuring enzyme activity, fluorescence emission spectra, ANS fluorescence spectra and far-UV circular dichroism spectra. The results showed that GdnHCl-denatured aminoacylase could be refolded and reactivated by dilution. A refolding intermediate was observed for low concentrations of GdnHCl (between 0.5 and 1.2M). This refolding intermediate was characterized by an increased fluorescence emission intensity, a blue-shifted emission maximum, and by increased binding of the fluorescence probe 8-anilino-1-naphthalenesulfonate (ANS). The secondary structure of the intermediate was similar to that of the native enzyme, and was therefore quite similar to the molten globule state often found in the protein folding pathway. Combined with the previous evidence of existence of an intermediate during unfolding process, we therefore proposed that the unfolding and refolding of aminoacylase might share the same pathway. A comparison of the Apo-enzyme and Holo-enzyme showed that there was little effect of the zinc ion on the refolding of the aminoacylase. Our study, the first successful report of the refolding of this metalloenzyme, also showed that lowering the concentration and the temperature of the enzyme improved the refolding rate of aminoacylase. The system therefore provides a useful model to study the refolding of proteins with prosthetic groups.     

Role of osmolytes as chemical chaperones during the refolding of aminoacylase.

The refolding and reactivation of aminoacylase is particularly difficult because of serious off-pathway aggregation. The effects of 4 osmolytes--dimethylsulphoxide, glycerol, proline, and sucrose--on the refolding and reactivation of guanidine-denatured aminoacylase were studied by measuring aggregation, enzyme activity, intrinsic fluorescence spectra, 1-anilino-8-naphthalenesulfonate (ANS) fluorescence spectra, and circular dichroism (CD) spectra. The results show that all the osmolytes not only inhibit aggregation but also recover the activity of aminoacylase during refolding in a concentration-dependent manner. In particularly, a 40% glycerol concentration and a 1.5 mol/L sucrose concentration almost completely suppressed the aminoacylase aggregation. The enzyme activity measurements revealed that the influence of glycerol is more significant than that of any other osmolyte. The intrinsic fluorescence results showed that glycerol, proline, and sucrose stabilized the aminoacylase conformation effectively, with glycerol being the most effective. All 4 kinds of osmolytes reduced the exposure of the hydrophobic surface, indicating that osmolytes facilitate the formation of protein hydrophobic collapse. The CD results indicate that glycerol and sucrose facilitate the return of aminoacylase to its native secondary structure. The results of this study suggest that the ability of the various osmolytes to facilitate the refolding and renaturation of aminoacylase is not the same. A survey of the results in the literature, as well as those presented here, suggests that although the protective effect of osmolytes on protein activity and structure is equal for different osmolytes, the ability of osmolytes to facilitate the refolding of various proteins differs from case to case. In all cases, glycerol was found to be the best stabilizer and a folding aid.     

溴化+烷基三甲基铵滴定时氨基酰化酶的失活与构象变化的比较

研究了阳离子去污剂-溴化+烷基三甲基铵变性时氨基酰酶的失活与构象变化.当用溴化+烷基三甲基铵滴定氨基酰化酶时,随着去污剂浓度增大,酶的活力逐渐丧失,至50mmolL时酶完全失活.用荧光发射光谱(295nm激发)的方法监测了氨基酰化酶的构象变化.发现氨基酰化酶失活先于构象变化.从这一结果看来.金属酶的活性部位构象可能也是比整个分子的构象具有较大的柔性或运动性.     

溴化+烷基三甲基铵滴定时氨基酰化酶的失活与构象变化的比较

研究了阳离子去污剂-溴化+烷基三甲基铵变性时氨基酰酶的失活与构象变化.当用溴化+烷基三甲基铵滴定氨基酰化酶时,随着去污剂浓度增大,酶的活力逐渐丧失,至50mmolL时酶完全失活.用荧光发射光谱(295nm激发)的方法监测了氨基酰化酶的构象变化.发现氨基酰化酶失活先于构象变化.从这一结果看来.金属酶的活性部位构象可能也是比整个分子的构象具有较大的柔性或运动性.     

Aminoacylase I deficiency: a novel inborn error of metabolism

This is the first report of a patient with aminoacylase I deficiency. High amounts of N-acetylated amino acids were detected by gas chromatography-mass spectrometry in the urine, including the derivatives of serine, glutamic acid, alanine, methionine, glycine, and smaller amounts of threonine, leucine, valine, and isoleucine. NMR spectroscopy confirmed these findings and, in addition, showed the presence of N-acetylglutamine and N-acetylasparagine. In EBV transformed lymphoblasts, aminoacylase I activity was deficient. Loss of activity was due to decreased amounts of aminoacylase I protein. The amount of mRNA for the aminoacylase I was decreased. DNA sequencing of the encoding ACY1 gene showed a homozygous c.1057 C>T transition, predicting a p.Arg353Cys substitution. Both parents were heterozygous for the mutation. The mutation was also detected in 5/161 controls. To exclude the possibility of a genetic polymorphism, protein expression studies were performed showing that the mutant protein had lost catalytic activity.