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.     

Molecular mutagenesis at Tyr-101 of the amylomaltase transcribed from a gene isolated from soil DNA

The wild-type (WT) amylomaltase gene was directly isolated from soil DNA and cloned into a pET19b vector to express in E. coli BL21(DE3). The ORF of this gene consisted of 1,572 bp, encoding an enzyme of 523 amino acids. Though showing 99% sequence identity to amylomaltse from Thermus thermophilus ATCC 33923, this enzyme is unique in its alkaline optimum pH. In order to alter amylomaltase with less coupling or hydrolytic activity to enhance cycloamylose (CA) formation through cyclization reaction, site-directed mutagenesis of the second glucan binding site involving in CA production was performed at Tyr-101. The result revealed that the mutated Y101S enzyme showed a small increase in cyclization activity while significantly decreased disproportionation, coupling and hydrolytic activities. Mutation also resulted in the change in substrate specificity for disproportionation reaction. The WT enzyme preferred maltotriose, while the activity of mutated enzyme was the highest with maltopentaose substrate. Product analysis by HPAEC-PAD demonstrated that the main CAs of the WT amylomaltase were CA29-CA37. Y101S mutation did not change the product pattern, however, the amount of CAs formed by the mutated enzyme tended to increase especially at long incubation time. The article is published in the original.     

Characterization of thermostable aminoacylase from hyperthermophilic archaeon Pyrococcus horikoshii

The gene encoding putative aminoacylase (ORF: PH0722) in the genome sequence of a hyperthermophilic archaeon, Pyrococcus horikoshii, was cloned and overexpressed in Escherichia coli. The recombinant enzyme was determined to be thermostable aminoacylase (PhoACY), forming a homotetramer. Purified PhoACY showed the ability to release amino acid molecules from the substrates N-acetyl-L-Met, N-acetyl-L-Gln and N-acetyl-L-Leu, but had a lower hydrolytic activity towards N-acetyl-L-Phe. The kinetic parameters K(m) and k(cat) were determined to be 24.6 mm and 370 s(-1), respectively, for N-acetyl-l-Met at 90 degrees C. Purified PhoACY contained one zinc atom per subunit. EDTA treatment resulted in the loss of PhoACY activity. Enzyme activity was fully recovered by the addition of divalent metal ions (Zn(2+), Mn(2+) and Ni(2+)), and Mn(2+) addition caused an alteration in substrate specificity. Site-directed mutagenesis analysis and structural modeling of PhoACY, based on Arabidopsis thaliana indole-3-acetic acid amino acid hydrolase as a template, revealed that, amongst the amino acid residues conserved in PhoACY, His106, Glu139, Glu140 and His164 were related to the metal-binding sites critical for the expression of enzyme activity. Other residues, His198 and Arg260, were also found to be involved in the catalytic reaction, suggesting that PhoACY obeys a similar reaction mechanism to that proposed for mammalian aminoacylases.     

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.     

α-Glucosidase from a strain of deep-sea Geobacillus: a potential enzyme for the biosynthesis of complex carbohydrates

An α-glucosidase from Geobacillus sp. strain HTA-462, one of the deepest sea bacteria isolated from the sediment of the Mariana Trench, was purified to homogeneity and estimated to be a 65-kDa protein by SDS-PAGE. At low ion strength, the enzyme exists in the homodimeric form (130 kDa). It is a thermo- and alkaline-stable enzyme with a half-life of 13.4 h and a maximum hydrolytic activity at 60°C and pH 9.0 in 15 mM glycine–NaOH buffer. The enzyme exclusively hydrolyzed α-1,4-glycosidic linkages of oligosaccharides in an exo-type manner. The enzyme had an overwhelming transglycosylation activity and glycosylated various non-sugar molecules when maltose was used as a sugar donor. It converted maltose to isomaltose. The gene encoding the enzyme was cloned and sequenced. The recombinant enzyme could be extracellularly overproduced by Bacillus subtilis harboring its gene and preserved the primary properties of the native enzyme. Site-directed mutagenesis experiments showed that Asp98 is essential for the enzyme activity in addition to Asp199, Asp326, and Glu256.     

Glu300 of rat carboxypeptidase E is essential for enzymatic activity but not substrate binding or routing to the regulated secretory pathway

Several recently discovered members of the carboxypeptidase E (CPE) gene family lack critical active site residues that are conserved in other family members. For example, three CPE-like proteins contain a Tyr in place of Glu300 (equivalent to Glu270 of carboxypeptidase A and B). To investigate the importance of this position, Glu300 of rat CPE was converted into Gln, Lys, or Tyr, and the proteins expressed in Sf9 cells using the baculovirus system. All three mutants were secreted from the cells, but the media showed no enzyme activity above background levels. Wild-type CPE and the Gln300 point mutant bound to a p-aminobenzoyl-Arg-Sepharose affinity resin, and this binding was competed by an active site-directed inhibitor, guanidinoethylmercaptosuccinic acid. The affinity purified mutant CPE protein showed no detectable enzyme activity (<0.004% of wild-type CPE) toward dansyl-Phe-Ala-Arg. Expression of the Gln300 and Lys300 mutant CPE proteins in the NIT3 mouse pancreatic beta-cell line showed that these mutants are routed into secretory vesicles and secreted via the regulated pathway. Taken together, these results indicate that Glu300 of CPE is essential for enzyme activity, but not required for substrate binding or for routing into the regulated secretory pathway.     

Helix-loop-helix peptide foldamers and their use in the construction of hydrolase mimetics

De novo designed helix-loop-helix peptide foldamers containing cis-2-aminocyclopentanecarboxylic acid residues were evaluated for their conformational stability and possible use in enzyme mimetic development. The correlation between hydrogen bond network size and conformational stability was demonstrated through CD and NMR spectroscopies. Molecules incorporating a Cys/His/Glu triad exhibited enzyme-like hydrolytic activity.     

Contribution of conserved Glu255 and Cys289 residues to catalytic activity of recombinant aldehyde dehydrogenase from <Emphasis Type="Italic">Bacillus licheniformis</Emphasis>

Based on the sequence homology, we have modeled the three-dimensional structure of Bacillus licheniformis aldehyde dehydrogenase (BlALDH) and identified two different residues, Glu255 and Cys289, that might be responsible for the catalytic function of the enzyme. The role of these residues was further investigated by site-directed mutagenesis and biophysical analysis. The expressed parental and mutant proteins were purified by nickel-chelate chromatography, and their molecular masses were determined to be approximately 53 kDa by SDS-PAGE. As compared with the parental BlALDH, a dramatic decrease or even complete loss of the dehydrogenase activity was observed for the mutant enzymes. Structural analysis showed that the intrinsic fluorescence and circular dichroism spectra of the mutant proteins were similar to the parental enzyme, but most of the variants exhibited a different sensitivity towards thermal- and guanidine hydrochloride-induced denaturation. These observations indicate that residues Glu255 and Cys289 play an important role in the dehydrogenase activity of BlALDH, and the rigidity of the enzyme has been changed as a consequence of the mutations.     

Engineering the pH-optimum of activity of the GH12 family endoglucanase by site-directed mutagenesis

Endo-1,4-β-glucanase from Penicillium verruculosum (PvEGIII) belongs to family 12 of glycoside hydrolases (GH12). Analysis of the enzyme 3D model structure showed that the amino acid residue Asp98 may directly affect the pH-profile of enzyme activity since it is located at the distance of hydrogen bond formation from Glu203 that plays the role of a general acid in catalysis. The gene encoding the PvEGIII was cloned into Escherichia coli. After the deletion of two introns, a plasmid construction was obtained allowing the PvEGIII expression in E. coli. Using site-directed mutagenesis, the Asp98Asn mutant of the PvEGIII was obtained. Both the wild type and mutant PvEGIIIs were expressed in E. coli with a yield of up to 1 g/L and then isolated in a highly purified form. The enzyme specific activity against soluble carboxymethylcellulose was not changed after a single amino acid substitution. However, the pH-optimum of activity of the mutant PvEGIII was shifted from pH 4.0 to 5.1, compared to the wild type enzyme. The shift in the enzyme pH-optimum to more neutral pH was also observed on insoluble cellulose, in the process of enzymatic depigmentation of denim fabric. Similar situation featuring the effect of the Asp/Asn residue, located near the Glu catalytic residue, on the enzyme activity pH-profile has previously been described for xylanases of the GH11 family. Thus, the glycoside hydrolases belonging to the GH11 and GH12 families function by a rather similar mechanism of catalysis.     

Molecular cloning and enzymological characterization of pyridoxal 5′-phosphate independent aspartate racemase from hyperthermophilic archaeon <Emphasis Type="Italic">Thermococcus</Emphasis><Emphasis Type="Italic">litoralis</Emphasis> DSM 5473

We succeeded in expressing the aspartate racemase homolog gene from Thermococcus litoralis DSM 5473 in Escherichia coli Rosetta (DE3) and found that the gene encodes aspartate racemase. The aspartate racemase gene consisted of 687 bp and encoded 228 amino acid residues. The purified enzyme showed aspartate racemase activity with a specific activity of 1590 U/mg. The enzyme was a homodimer with a molecular mass of 56 kDa and did not require pyridoxal 5′-phosphate as a coenzyme. The enzyme showed aspartate racemase activity even at 95 °C, and the activation energy of the enzyme was calculated to be 51.8 kJ/mol. The enzyme was highly thermostable, and approximately 50 % of its initial activity remained even after incubation at 90 °C for 11 h. The enzyme showed a maximum activity at a pH of 7.5 and was stable between pH 6.0 and 7.0. The enzyme acted on l-cysteic acid and l-cysteine sulfinic acid in addition to d- and l-aspartic acids, and was strongly inhibited by iodoacetic acid. The site-directed mutagenesis of the enzyme showed that the essential cysteine residues were conserved as Cys83 and Cys194. d-Forms of aspartic acid, serine, alanine, and valine were contained in T. litoralis DSM 5473 cells.     

Use of Random and Saturation Mutageneses To Improve the Properties of Thermus aquaticus Amylomaltase for Efficient Production of Cycloamyloses

Amylomaltase from Thermus aquaticus catalyzes intramolecular transglycosylation of α-1,4 glucans to produce cyclic α-1,4 glucans (cycloamyloses) with degrees of polymerization of 22 and higher. Although the amylomaltase mainly catalyzes the transglycosylation reaction, it also has weak hydrolytic activity, which results in a reduction in the yield of the cycloamyloses. In order to obtain amylomaltase with less hydrolytic activity, random mutagenesis was perfromed for the enzyme gene. Tyr54 (Y54) was identified as the amino acid involved in the hydrolytic activity of the enzyme. When Y54 was replaced with all other amino acids by site-directed mutagenesis, the hydrolytic activities of the mutated enzymes were drastically altered. The hydrolytic activities of the Y54G, Y54P, Y54T, and Y54W mutated enzymes were remarkably reduced compared with that of the wild-type enzyme, while those of the Y54F and Y54K mutated enzymes were similar to that of the wild-type enzyme. Introducing an amino acid replacement at Y54 also significantly affected the cyclization activity of the amylomaltase. The Y54A, Y54L, Y54R, and Y54S mutated enzymes exhibited cyclization activity that was approximately twofold higher than that of the wild-type enzyme. When the Y54G mutated enzyme was employed for cycloamylose production, the yield of cycloamyloses was more than 90%, and there was no decrease until the end of the reaction.     

Bacillus subtilis CwlQ (previous YjbJ) is a bifunctional enzyme exhibiting muramidase and soluble-lytic transglycosylase activities

CwlQ (previous YjbJ) is one of the putative cell wall hydrolases in Bacillus subtilis. Its domain has an amino acid sequence similar to the soluble-lytic transglycosylase (SLT) of Escherichia coli Slt70 and also goose lysozyme (muramidase). To characterize the enzyme, the domain of CwlQ was cloned and expressed in E. coli. The purified CwlQ protein exhibited cell wall hydrolytic activity. Surprisingly, RP-HPLC, mass spectrometry (MS), and MS/MS analyses showed that CwlQ produces two products, 1,6-anhydro-N-acetylmuramic acid and N-acetylmuramic acid, thus indicating that CwlQ is a bifunctional enzyme. The site-directed mutagenesis revealed that glutamic acid 85 (Glu-85) is an amino acid residue essential to both activities.     

Identification of amino acid residues essential for the substrate specificity of Flavobacterium sp. endo-beta-N-acetylglucosaminidase

The gene encoding the endo-beta-N-acetylglucosaminidase from Flavobacterium sp. (Endo-Fsp) was sequenced. The Endo-Fsp gene was overexpressed in Escherichia coli cells, and was purified from inclusion bodies after denaturation by 8 M urea. The renatured Endo-Fsp had the same optimum pH and substrate specificity as the native enzyme. Endo-Fsp had 60% sequence identity with the endo-beta-N-acetylglucosaminidase from Streptomyces plicatus (Endo-H), and the putative catalytic residues were conserved. Site-directed mutagenesis was done at conserved residues based on the three-dimensional structure and mutagenesis of Endo-H. The mutant of Glu-128, corresponding to Glu-132 in Endo-H and identified as an active site residue, was inactivated. Mutagenesis around the predicted active site of Endo-Fsp reduced the enzymatic activity. Moreover, the hydrolytic activity toward hybrid-type oligosaccharides was decreased compared to that toward high-mannose type oligosaccharides by mutagenesis of Asp-126 and Asp-127. Therefore, site-directed mutagenesis of some of these conserved residues indicates that the predicted active sites are essential to the enzymatic activity of Endo-Fsp, and may have similar roles in catalysis as their counterparts in Endo-H.     

Alteration of catalytic function of 6-aminohexanoate-dimer hydrolase by site-directed mutagenesis

Alteration of Asp181 in a nylon oligomer-degrading enzyme, 6-aminohexanoate-dimer hydrolase (EII) of Flavobacterium sp. KI72, to Asn and to Glu by site-directed mutagenesis increased K_m values toward 6-aminohexanoate-dimer 4 times and 11 times, respectively. Replacement to His or to Lys caused complete loss of the activity (less than 0.02% of the activity of the EII enzyme). Thus, a single amino acid alteration at position 181 of the enzyme drastically affects the catalytic function.     

Identification of essential amino acid residues for catalytic activity and thermostability of novel chitosanase by site-directed mutagenesis

The functional importance of a conserved region in a novel chitosanase from Bacillus sp. CK4 was investigated. Each of the three carboxylic amino acid residues (Glu-50, Glu-62, and Asp-66) was changed to Asp and Gln or Asn and Glu by site-directed mutagenesis, respectively. The Asp-66-->Asn and Asp-66-->Glu mutation remarkably decreased kinetic parameters such as Vmax and kcat to approximately 1/1,000 those of the wild-type enzyme, indicating that the Asp-66 residue was essential for catalysis. The thermostable chitosanase contains three Cys residues at positions 49, 72, and 211. The Cys-49-->Ser/Tyr and Cys-72-->Ser/Tyr mutant enzymes were as stable to thermal inactivation and denaturating agents as the wild-type enzyme. However, the half-life of the Cys-211-->Ser/Tyr mutant enzyme was less than 10 min at 80 degrees C, while that of the wild-type enzyme was about 90 min. Moreover, the residual activity of Cys-211-->Ser/Tyr enzyme was substantially decreased by 8 M urea; and it lost all catalytic activity in 40% ethanol. These results show that the substitution of Cys with any amino acid residues at position 211 seems to affect the conformational stability of the chitosanase.     

Functioning of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> Pma1 H<Superscript>+</Superscript>-ATPase carrying the minimal number of cysteine residues

Pma1 H⁺-ATPase is the primary proton pump in the plasma membrane of the yeast Saccharomyces cerevisiae. It generates an electrochemical proton gradient, thus providing energy for secondary solute transport systems. The enzyme contains nine cysteines, three (Cys148, Cys312, and Cys867) in transmembrane segments and the rest (Cys221, Cys376, Cys409, Cys472, Cys532, and Cys569) in the cytosolic parts of the molecule. Although individually they are not essential for the functioning of the ATPase, substitution of all of them leads to the loss of enzyme activity and impairment of biogenesis. By means of site-directed mutagenesis combined with other molecular-biological and biochemical methods, this work defines different combinations of minimal cysteine content that are consistent with ATPase function.     

Probing the Role of Cysteine Residues in Glucosamine-1-Phosphate Acetyltransferase Activity of the Bifunctional GlmU Protein from Escherichia coli: Site-Directed Mutagenesis and Characterization of the Mutant Enzymes

The glucosamine-1-phosphate acetyltransferase activity but not the uridyltransferase activity of the bifunctional GlmU enzyme from Escherichia coli was lost when GlmU was stored in the absence of β-mercaptoethanol or incubated with thiol-specific reagents. The enzyme was protected from inactivation in the presence of its substrate acetyl coenzyme A (acetyl-CoA), suggesting the presence of an essential cysteine residue in or near the active site of the acetyltransferase domain. To ascertain the role of cysteines in the structure and function of the enzyme, site-directed mutagenesis was performed to change each of the four cysteines to alanine, and plasmids were constructed for high-level overproduction and one-step purification of histidine-tagged proteins. Whereas the kinetic parameters of the bifunctional enzyme appeared unaffected by the C296A and C385A mutations, 1,350- and 8-fold decreases of acetyltransferase activity resulted from the C307A and C324A mutations, respectively. The K_m values for acetyl-CoA and GlcN-1-P of mutant proteins were not modified, suggesting that none of the cysteines was involved in substrate binding. The uridyltransferase activities of wild-type and mutant GlmU proteins were similar. From these studies, the two cysteines Cys307 and Cys324 appeared important for acetyltransferase activity and seemed to be located in or near the active site.     

Amino acid substitution at the substrate-binding subsite alters the specificity of the Phanerochaete chrysosporium cellobiose dehydrogenase

The active site of cellobiose dehydrogenase from Phanerochaete chrysosporium is composed of two subsites, a catalytic C subsite and a substrate-binding B subsite. Based on the crystal structure of the enzyme with a cellobiose analogue, residue Glu279 was selected for site-directed mutagenesis studies. Substitution of Glu279 to Ala, Asn, and Asp had no effect on the expression of the protein in Pichia pastoris but completely abolished its enzymatic activity. Substitution of Glu279 to Gln drastically altered the enzyme’s substrate specificity. While the wild-type cellobiose dehydrogenase efficiently oxidizes cellobiose and lactose, the Glu279Gln mutant retained most of its activity with cellobiose but was completely inactive with lactose. We generated structural models of the active site interacting with cellobiose and lactose to provide an interpretation of these results.     

Human carbonic anhydrase I: Effect of specific site mutations on its function

Carbonic anhydrase I (CAI) is one out of ten CA isoenzymes that have been identified in humans. X-ray crystallographic and inhibitor complex studies of human carbonic anhydrase I (HCAI) and related studies in other CA isoenzymes identified several residues, in particular Thr199, GlulO6, Tyr7, Glull7, His l07, with likely involvement in the catalytic activity of HCAI. To further study the role of these residues, we undertook, site-directed mutagenesis of HCAI. Using a polymerase chain reaction based strategy and altered oligonucleotide primers, we modified a cloned wild type hCAI gene so as to produce mutant genes encoding proteins with single amino acid substitutions. Thrl99Val, Thrl99Cys, Thr199Ser, GlulO6Ile, Glul06Gln, Tyr7Trp, Glu.117Gln, and His 107Val mutations were thus generated and the activity of each measured by ester hydrolysis. Overproduction of the Glu117Gln and HisI07Val mutant proteins inEscherichia coli resulted in a large proportion of the enzyme forming aggregates probably due to folding defect. The mutations Thr199Val, GlulO6Ile and GlulO6Gln gave soluble protein with drastically reduced enzyme activity, while the Tyr7Trp mutation had only marginal effect on the activity, thus s.uggesting important roles for Thr199 and Glu lO6 but not for Tyr7 in the catalytic function of HCAI.