Relationship between mutant amidases of Pseudomonas aeruginosa and hydroxyurea as an inhibitor.

Summary Hydroxyurea inhibited growth of Pseudomonas aeruginosa strain AI 3 on media containing either acetanilide (N-phenyl acetamide) or acetamide as sole carbon sources. Mutants resistant to hydroxyurea inhibition of growth on acetanilide (OUCH strains) and acetamide (AmOUCH strains) displayed altered growth properties on various amide media compared with the parent strain AI 3. AI 3 amidase, which catalyses the initial step in the metabolism of acetanilide and acetamide, was inhibited by hydroxyurea in a time-dependent reaction that was slowly reversible at pH 7.2 Compared with AI 3 amidase, amidases from the OUCH mutants were much less sensitive to inhibition by hydroxyurea and showed altered substrate specificities and pH/activity profiles; amidases from the AmOUCH mutants were more sensitive to hydroxyurea inhibition but showed increased activity towards acetamide. Association of resistance to hydroxyurea inhibition with a mutation in the amidase structural gene of strain OUCH 4 was confirmed by transduction.     

Pseudomonas aeruginosa mutants resistant to urea inhibition of growth on acetanilide.

Pseudomonas aeruginosa AI 3 was able to grow in medium containing acetanilide (N-phenylacetamide) as a carbon source when NH4+ was the nitrogen source but not when urea was the nitrogen source. AIU mutants isolated from strain AI 3 grew on either medium. Urease levels in bacteria grown in the presence of urea were 10-fold lower when NH4+ or acetanilide was also in the medium, but there were no apparent differences in urease or its synthesis between strain AI 3 and mutant AIU 1N. The first metabolic step in the acetanilide utlization is catalyzed by an amidase. Amidases in several AIU strains showed altered physiochemical properties. Urea inhibited amidase in a time-dependent reaction, but the rates of the inhibitory reaction with amidases from the AIU mutants were slower than with AI 3 amidase. The purified amidase from AIU 1N showed a marked difference in its pH/activity profile from that obtained with purified AI 3 amidase. These observations indicate that the ability of strain AIU 1N and the other mutants to grow on acetanilide/urea medium is associated with a mutation in the amidase structural gene; this was confirmed for strain AIU 1N by transduction.     

Substitutions of Thr-103-Ile and Trp-138-Gly in amidase from Pseudomonas aeruginosa are responsible for altered kinetic properties and enzyme instability

Pseudomonas aeruginosa Ph1 is a mutant strain derived from strain AI3. The strain AI3 is able to use acetanilide as a carbon source through a mutation (T103I) in the amiE gene that encodes an aliphatic amidase (EC 3.5.1.4). The mutations in the amiE gene have been identified (Thr103Ile and Trp138Gly) by direct sequencing of PCR-amplified mutant gene from strain Ph1 and confirmed by sequencing the cloned PCR-amplified gene. Site-directed mutagenesis was used to alter the wild-type amidase gene at position 138 for Gly. The wild-type and mutant amidase genes (W138G, T103I-W138G, and T103I) were cloned into an expression vector and these enzymes were purified by affinity chromatography on epoxy-activated Sepharose 6B-acetamide/phenylacetamide followed by gel filtration chromatography. Altered amidases revealed several differences in kinetic properties, namely, in substrate specificity, sensitivity to urea, optimum pH, and enzyme stability, compared with the wild-type enzyme. The W138G enzyme acted on acetamide, acrylamide, phenylacetamide, and p-nitrophenylacetamide, whereas the double mutant (W138G and T103I) amidase acted only on p-nitrophenylacetamide and phenylacetamide. On the other hand, the T103I enzyme acted on p-nitroacetanilide and acetamide. The heat stability of altered enzymes revealed that they were less thermostable than the wild-type enzyme, as the mutant (W138G and W138G-T103I) enzymes exhibited t _1/2 values of 7.0 and 1.5 min at 55°C, respectively. The double substitution T103I and W138G on the amidase molecule was responsible for increased instabiliby due to a conformational change in the enzyme molecule as detected by monoclonal antibodies. This conformational change in altered amidase did not alter its M _r value and monoclonal antibodies reacted differently with the active and inactive T103I-W138G amidase.     

Inhibition of the aliphatic amidase from Pseudomonas aeruginosa by urea and related compounds.

The time-dependent inhibition of amidase from Pseudomonas aeruginosa strain AI 3 by urea, hydroxyurea and cyanate displayed saturation kinetics fitting a model for the reaction sequence in which formation of a complex in a reversible step was followed by an irreversible step. Altered amidases from mutant strains AIU 1N and OUCH 4, selected for their resistance to inhibition of growth by urea and hydroxyurea respectively, had altered kinetic constants for inhibition indicating reduced binding capacity for the inhibitors. The substrate acetamide protected AI 3 amidase against inhibition by urea,.and altered Ki values for inhibition of the mutant amidases were paralleled by alterations in Km values for acetamide indicating that urea acted at the active site. Inhibition of AI 3 amidase involved the binding of one molecule of urea per molecule of enzyme. Urea inhibited amidase slowly regained activity at pH 7.2 through release of urea.     

Selection of amidases with novel substrate specificities from penicillin amidase of Escherichia coli

To obtain amidases with novel substrate specificity, the cloned gene for penicillin amidase of Escherichia coli ATCC 11105 was mutagenized and mutants were selected for the ability to hydrolyze glutaryl-(L)-leucine and provide leucine to Leu- host cells. Cells with the wild-type enzyme did not grow in minimal medium containing glutaryl-(L)-leucine as a sole source of leucine. The growth rates of Leu- cells that expressed these mutant amidases increased as the glutaryl-(L)-leucine concentration increased or as the medium pH decreased. Growth of the mutant strains was restricted by modulation of medium pH and glutaryl-(L)-leucine concentration, and successive generations of mutants that more efficiently hydrolyzed glutaryl-(L)-leucine were isolated. The kinetics of glutaryl-(L)-leucine hydrolysis by purified amidases from two mutants and the respective parental strains were determined. Glutaryl-(L)-leucine hydrolysis by the purified mutant amidases occurred most rapidly between pH 5 and 6, whereas hydrolysis by wild-type penicillin amidase at this pH was negligible. The second-order rate constants for glutaryl-(L)-leucine hydrolysis by two "second-generation" mutant amidases, 48 and 77 M-1 s-1, were higher than the rates of hydrolysis by the respective parental amidases. The increased rates of glutaryl-(L)-leucine hydrolysis resulted from both increases in the molecular rate constants and decreases in apparent Km values. The results show that it is possible to deliberately modify the substrate specificity of penicillin amidase and successively select mutants with amidases that are progressively more efficient at hydrolyzing glutaryl-(L)-leucine.     

Selection of amidases with novel substrate specificities from penicillin amidase of Escherichia coli.

To obtain amidases with novel substrate specificity, the cloned gene for penicillin amidase of Escherichia coli ATCC 11105 was mutagenized and mutants were selected for the ability to hydrolyze glutaryl-(L)-leucine and provide leucine to Leu- host cells. Cells with the wild-type enzyme did not grow in minimal medium containing glutaryl-(L)-leucine as a sole source of leucine. The growth rates of Leu- cells that expressed these mutant amidases increased as the glutaryl-(L)-leucine concentration increased or as the medium pH decreased. Growth of the mutant strains was restricted by modulation of medium pH and glutaryl-(L)-leucine concentration, and successive generations of mutants that more efficiently hydrolyzed glutaryl-(L)-leucine were isolated. The kinetics of glutaryl-(L)-leucine hydrolysis by purified amidases from two mutants and the respective parental strains were determined. Glutaryl-(L)-leucine hydrolysis by the purified mutant amidases occurred most rapidly between pH 5 and 6, whereas hydrolysis by wild-type penicillin amidase at this pH was negligible. The second-order rate constants for glutaryl-(L)-leucine hydrolysis by two "second-generation" mutant amidases, 48 and 77 M-1 s-1, were higher than the rates of hydrolysis by the respective parental amidases. The increased rates of glutaryl-(L)-leucine hydrolysis resulted from both increases in the molecular rate constants and decreases in apparent Km values. The results show that it is possible to deliberately modify the substrate specificity of penicillin amidase and successively select mutants with amidases that are progressively more efficient at hydrolyzing glutaryl-(L)-leucine.     

One-step affinity purification of amidase from mutant strains of Pseudomonas aeruginosa

Amidases (acylamide amidohydrolase EC 3.5.1.4) from mutant strains (i.e., B6, AI3, AIU1N, OUCH 4 and L10) of Pseudomonas aeruginosa were purified in one-step by ligand affinity chromatography using Epoxy-activated Sepharose 4B-acetamide. The yields of the purified enzymes were about 90% for all mutant strains with purification factors of about 10 and were apparently homogeneous when analysed by SDS-PAGE and native PAGE. The protein bands on native PAGE coincided with the stained band of enzyme activity for all amidase preparations. Affinity columns had a maximum binding capacity of 0.5 mg amidase protein/ml of sedimented gel and could be regenerated and reused several times without any loss of binding capacity and resolution. Affinity gels containing either semicarbazide or urea were also found useful for the isolation of amidase. The differences in substrate specificity of these amidases reported previously were also observed in the elution behaviour of these enzymes from the affinity columns.     

Effect of lacZY-marking of the 2,4-diacetyl-phloroglucinol producing Pseudomonas fluorescens-strain 5-2/4 on its physiological performance and root colonization ability

Transgenic Pseudomonas fluorescens 5-2/4 with reinforced 2,4-diacetyl phloroglucinol (phl) production had shown increased biocontrol ability towards Pythium ultimum (Pu), but inferior root colonization ability compared to its wild type 5.014. Therefore, enhanced root colonization ability of the transgenic strain by repeated inoculation and reisolation on tomato plants was suggested. As a preparation for repeated inoculation and reisolation cycles, the construction of a negative control of the transgenic strain 5-2/4 by marking with lacZY and screening for a mutant possessing qualities comparable to 5-2/4 was performed. Morphologically, colonies of all of the 11 selected mutants were similar on MLXgal medium. The root colonization ability of two of the lacZY-marked strains (mutants 1 and 10) was comparable to the parental strain. These were also able to compete with the resident microflora of tomato seedlings to the same extent as the parental strain. Five mutants were excluded due to lower growth rates on Yeast Malt, King's B Medium (KB) and 0.1 Tryptic Soy Agar (mutant 4, 5 and 8), excessive growth and higher siderophore production on KB (mutant 10) and increased protease production (mutant 2). With respect to in vitro-antagonism of Pu, no differences could be found between the target strain and mutants 1, 3, 6, 7 and 9. Examination of sole carbon source utilization of these five lacZY-marked strains revealed a significantly higher utilization of alpha-D-lactose and lactulose compared to 5-2/4. However, significant differences could be found for 51% of the utilized carbon sources. Cluster analysis showed a high degree of similarity between 5-2/4 and mutant 1 both when analyzed with and without alpha-D-lactose. As mutant 1 also represented the colonization pattern most similar to the parental strain 5-2/4, it presents a presumptive subject for a negative control in the following inoculation and reisolation studies on tomato.     

Occurrence of Amidases in the Industrial Microbe Rhodococcus rhodochrous J1

Rhodococcus rhodochrous J1, of which the high-M_r nitrile hydratase has been used for the industrial manufacture of acrylamide from acrylonitrile, produced at least two amidases differing in substrate specificity, judging from the effects of various amides on amidase activity in this strain. These amidases seemed to be inducible enzymes depending on amide compounds.     

Ultrasound promoted synthesis of 2-imidazolines in water: A greener approach toward monoamine oxidase inhibitors

A series of sixteen 2-substituted-2-imidazolines (where the substituent R = Ph, Me-4-Ph; MeO-4-Ph; (MeO)₂-3,4-Ph; (MeO)₃-3,4,5-Ph; Ph-4-O-C(O)-Ph; Cl-4-Ph; Cl-2-Ph; Cl₂-2,4-Ph; NO₂-4-Ph; NO₂-3-Ph; Naphth-2-yl; Fur-2-yl; Benzofur-2-yl; Pyridin-2-yl; Quinolin-2-yl) has been synthesized from the reaction of the substituted-aldehydes and ethylenediamine by ultrasound irradiation with NBS in an aqueous medium in high yields (80–99%). The 2-imidazoline ability to inhibit the activity of the A and B isoforms of monoamine oxidase (MAO) was investigated and some of them showed potent and selective MAO inhibitory activity especially for the MAO-B isoform and could become promising candidates for future development.     

长双歧杆菌N-乙酰氨基己糖1-位激酶的活性位点

【目的】研究长双歧杆菌(Bifidobacterium longum)JCM1217的N-乙酰氨基己糖1-位激酶(Nacetylhexosamine 1-kinase,Nah K)中对催化活性有影响的位点。【方法】利用点突变试剂盒,获得Nah K的4个位点的共10种单点突变体表达菌株。诱导表达并纯化野生型和突变体酶,用DNS法和NADH偶联的微孔板分光光度法检测野生型及突变体酶的最适p H和最适Mg~(2+)浓度,并测定酶促反应动力学参数。【结果】D208A、D208N、D208E和I24A四种突变体的催化活性几乎丧失。突变体H31A、H31V、F247A和I24V的最适p H由野生型的7.5变为7.0,突变体H31A和F247A的最适Mg~(2+)浓度由野生型的5 mmol/L变为10 mmol/L。反应动力学参数测定结果表明,突变体F247Y对底物Glc NAc/Gal NAc及ATP的催化活性均高于野生型。【结论】通过定点突变,确定了对Nah K催化活性有影响的4个位点,并且获得了一个催化效率提高的突变体(F247Y),为进一步对Nah K进行分子改造奠定了一定基础。     

Multiple defects in translation associated with altered ribosomal protein L4

The ribosomal proteins L4 and L22 form part of the peptide exit tunnel in the large ribosomal subunit. In Escherichia coli, alterations in either of these proteins can confer resistance to the macrolide antibiotic, erythromycin. The structures of the 30S as well as the 50S subunits from each antibiotic resistant mutant differ from wild type in distinct ways and L4 mutant ribosomes have decreased peptide bond-forming activity. Our analyses of the decoding properties of both mutants show that ribosomes carrying the altered L4 protein support increased levels of frameshifting, missense decoding and readthrough of stop codons during the elongation phase of protein synthesis and stimulate utilization of non-AUG codons and mutant initiator tRNAs at initiation. L4 mutant ribosomes are also altered in their interactions with a range of 30S-targeted antibiotics. In contrast, the L22 mutant is relatively unaffected in both decoding activities and antibiotic interactions. These results suggest that mutations in the large subunit protein L4 not only alter the structure of the 50S subunit, but upon subunit association, also affect the structure and function of the 30S subunit.     

Ras p21 proteins with high or low GTPase activity can efficiently transform NIH/3T3 cells

We sought to determine whether decreased in vitro GTPase activity is uniformly associated with ras p21 mutants possessing efficient transforming properties. Normal H-ras p21-[Gly12-Ala59] as well as an H-ras p21-[Gly12-Thr59] mutant exhibited in vitro GTPase activities at least fivefold higher than either H-ras p21-[Lys12-Ala59] or H-ras p21-[Arg12-Thr59] mutants. Microinjection of as much as 6 X 10(6) molecules/cell of bacterially expressed normal H-ras p21 induced no detectable alterations of NIH/3T3 cells. In contrast, inoculation of 4-5 X 10(5) molecules/cell of each p21 mutant induced morphologic alterations and stimulated DNA synthesis. Moreover, the transforming activity of each mutant expressed in a eukaryotic vector was similar and at least 100-fold greater than that of the normal H-ras gene. These findings establish that activation of efficient transforming properties by ras p21 proteins can occur by mechanisms not involving reduced in vitro GTPase activity.     

保加利亚乳杆菌H+-ATPase缺陷型菌株的筛选

【目的】从传统乳制品中筛选具有新霉素抗性的H+-ATPase缺陷的德氏乳杆菌保加利亚亚种自发突变株,为最终开发弱后酸化的酸奶发酵剂奠定基础。【方法】利用API 50 CH细菌鉴定系统和16s rRNA基因序列分析对菌株进行鉴定。新霉素作为筛选压力,筛选具有新霉素抗性自发突变菌株,比较亲本和突变菌株的H+-ATPase活力及其代谢情况。【结果】从内蒙古地区的传统发酵酸奶中分离鉴定出一株德氏乳杆菌保加利亚亚种（Lactobacillus delbrueckii subsp. bulgaricus）,并命名为KLDS 1.9201。以此为出发菌株,筛选出两株H+-ATPase缺陷的自发突变株,分别命名为KLDS 1.9201-1、KLDS 1.9201-4,它们的H+-ATPase活力分别比亲本KLDS 1.9201降低了46%和60%。在MRS培养基中生长24 h后,KLDS 1.9201、KLDS 1.9201-1和KLDS 1.9201-4对初始葡萄糖的代谢率分别为65%、41%和31%,终产物中乳酸的浓度分别为26g/L、18g/L和15g/L,突变菌株的生物量均低于亲本。【结论】H+-ATPase活力降低的德氏乳杆菌保加利亚亚种的自发突变株具有较低的生长速率和弱产酸能力,它们可被用于制作弱后酸化的酸奶发酵剂。     

Molecular basis of altered enzyme specificities in a family of mutant amidases from Pseudomonas aeruginosa.

A family of mutant amidases has been derived by experimental evolution of the aliphatic amidase of Pseudomonas aeruginosa strain PAC1. Mutation amiE16, in the structural gene for the enzyme, results in the production of the mutant B amidase by strain B6. This strain, unlike the wild-type, can utilize butyramide for growth. Strain B6 gave rise by a single mutational event to strain V9, utilizing valeramide, and strain PhB3, utilizing phenylacetamide. Strain V9 was not itself able to utilize phenylacetamide but gave rise by mutation to the phenylacetamide-utilizing mutant PhV1. Peptide 108 was isolated from chymotryptic digests of mutant amidases from strains B6, PhB3 and PhV1, but could not be detected in chymotryptic digests of the wild-type amidase. The sequence of peptide 108 was established as Met-Arg-His-Gly-Asp-Ile-Phe. Thermolytic digests of mutant amidases from strains B6, PhB3, PhV1 and V9 were compared with digests of the wild-type amidase. A peptide of the composition Met, Arg, His, Gly2, Asp3, Ile, Ser3, Thr, Val was found in the digest of the wild-type amidase and was replaced in the digests of the mutant amidases by a peptide of the composition Met, Arg, His, Gly2, Asp3, Ile, Ser3, Thr, Val, Phe. Mutation amiE16 is common to the four mutant enzymes and can be accounted for by the mutation Ser leads to Phe. The sequence of the chymotryptic peptide corresponds with the N-terminal sequence of the amidase protein, and can also be related to the thermolysin peptides. It is concluded that mutation amiE16 is a Ser leads to Phe change at position 7 from the N-terminus and the effect of this on the enzyme conformation is discussed.     

Probing the acyl binding site of acetylcholinesterase by protein engineering

Recombinant acetylcholinesterase from rat brain and two mutants were studied for their hydrolytic activity toward acetyl- and butyrylthiocholine substrates and for their sensitivity toward organophosphate and carbamate inhibitors. Both mutants, a point mutant where F295 was replaced by leucine, and a second mutant where loop PQES was replaced by SG, were designed for increased size of the acyl binding pocket. Wild type and mutant enzymes were expressed in baculovirus-infected insect cells and biochemically characterized. As expected, wild type rat brain acetylcholinesterase hydrolyzed acetylthiocholine, but not butyrylthiocholine. Sensitivity toward small- and medium-sized organophosphate inhibitors like paraoxon-methyl and paraoxon-ethyl was comparable, but bulky organophosphates like ethoprophos were less efficient inhibitors. This tendency applied to carbamates as well, since small carbamoyl moieties like carbofuran and aldicarb were stronger inhibitors than furathiocarb which features a bulky carbamoyl moiety. In contrast to wild type enzyme, both mutants were capable of hydrolyzing butyrylthiocholine. However, k_cat/K_m toward acetylthiocholine of the F295L mutant was reduced if compared to the wild type enzyme. All five organophosphate and three carbamate inhibitors inhibited mutant F295L more efficiently than the wild type enzyme.     

重组人组织型纤溶酶原激活剂(rht-PA)及其突变体的纯化

稳定高效表达重组人组织型纤溶酶原激活剂 (rht PA)的CHO细胞株和表达组合突变体的细胞株进行了 3L转瓶培养 .将培养上清分别进行了Lys Sepharose 4B亲和层析和Zn2 + Sepharose 4B层析两步纯化 ,rht PA纯度提高了 5 34倍 ,比活达 2 5× 10 5IU mg ,产率为 73% ;突变体纯度提高了1119倍 ,比活达 5 9× 10 5IU mg ,产率为 6 9% .纯化产物SDS PAGE分析显示 ,rht PA和突变体基本都呈单一条带 ,扫描分析均达到 98%以上纯度 .rht PA和突变体在纯化系统中的行为作对照分析发现 ,突变体的构建思想在Lys Sepharose 4B亲和层析过程中有充分体现 .这两步层析组合是很好的纯化t PA及其突变体的方法 ,尤其是Lys Sepharose 4B纯化突变体效果更好     

Characterization of a mutation affecting the function of Escherichia coli folylpolyglutamate synthetase-dihydrofolate synthetase and further mutations produced in vitro at the same locus

The folC gene from mutant strain SF4 was cloned into a pUC19 plasmid. Expression of the mutant gene from the lac promoter of the plasmid complemented the auxotrophy for methionine of the SF4 strain. The only difference in sequence between the mutant and wild-type genes was a G925A base change resulting in an A309T amino acid change. The mutant enzyme had a 30-fold higher Km for 10-formyltetrahydrofolate as well as a 60-fold higher Km for glutamate and a 200-fold higher Km for dihydropteroate of the dihydrofolate synthetase activity. Site-specific mutagenesis was used to substitute other amino acids at codon 309. Mutants with glycine, isoleucine, and valine substitutions at this position, when expressed from multicopy plasmids, complemented the SF4 strain. The glycine mutant had properties similar to the wild-type enzyme, whereas the isoleucine and valine mutants had properties similar to the threonine mutant, SF4. Mutant genes with arginine, glutamate, and leucine substitutions, which did not complement the SF4 strain, could complement a folC deletion strain, but produced smaller colonies on complex plates and did not grow on minimal medium. In the deletion strain, an increasing requirement for folate product supplements was observed as the folylpolyglutamate synthetase-dihydrofolate synthetase activities of the complementing mutants decreased.     

Characterization of monoclonal antibodies against altered (T103I) amidase from Pseudomonas aeruginosa

Monoclonal antibodies (MAbs) against mutant (T103I) amidase from Pseudomonas aeruginosa were raised by hybridoma technology. To select MAbs suitable for immunoaffinity chromatography, hybridoma clones secreting polyol-responsive MAbs (PR-MAbs) were screened that bind antigen tightly but release under mild and nondenaturing elution conditions. It was found that about 10% of enzyme-linked immunosorbent assay (ELISA)-positive hybridoma produce these MAbs as their ag-ab complex can be disrupted by propylene glycol in the presence of a suitable salt. Two of these hybridoma clones (F6G7 and E2A6) secreting PR-MAbs against mutant amidase were selected for optimization of experimental conditions for elution of amidase by using ELISA elution assay. These hybridoma cell lines secreted MAbs of IgM class that were purified in a single step by gel filtration chromatography, which revealed a single protein band on native polyacrylamide gel electrophoresis (PAGE). Specificity studies of this MAb revealed that it recognized specifically a common epitope on mutant and wild-type amidases as determined by direct ELISA. This MAb exhibited a higher affinity for denatured forms of wild-type and mutant amidases than for native forms as revealed by affinity constants (K), suggesting that it recognizes a cryptic epitope on an amidase molecule. Furthermore, MAb E2A6 inhibited about 60% of wild-type amidase activity, whereas it activated about 60% of mutant amidase (T103I) activity. The data presented in this work suggest that this MAb acts as a very useful probe to detect conformational changes in native and denatured amidases as well as to differentiate wild-type and mutant (T103I) amidases.     

Purification, characterization, gene cloning and nucleotide sequencing of D-stereospecific amino acid amidase from soil bacterium: Delftia acidovorans

The D-amino acid amidase-producing bacterium was isolated from soil samples using an enrichment culture technique in medium broth containing D-phenylalanine amide as a sole source of nitrogen. The strain exhibiting the strongest activity was identified as Delftia acidovorans strain 16. This strain produced intracellular D-amino acid amidase constitutively. The enzyme was purified about 380-fold to homogeneity and its molecular mass was estimated to be about 50 kDa, on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The enzyme was active preferentially toward D-amino acid amides rather than their L-counterparts. It exhibited strong amino acid amidase activity toward aromatic amino acid amides including D-phenylalanine amide, D-tryptophan amide and D-tyrosine amide, yet it was not specifically active toward low-molecular-weight D-amino acid amides such as D-alanine amide, L-alanine amide and L-serine amide. Moreover, it was not specifically active toward oligopeptides. The enzyme showed maximum activity at 40 degrees C and pH 8.5 and appeared to be very stable, with 92.5% remaining activity after the reaction was performed at 45 degrees C for 30 min. However, it was mostly inactivated in the presence of phenylmethanesulfonyl fluoride or Cd2+, Ag+, Zn2+, Hg2+ and As3+ . The NH2 terminal and internal amino acid sequences of the enzyme were determined; and the gene was cloned and sequenced. The enzyme gene damA encodes a 466-amino-acid protein (molecular mass 49,860.46 Da); and the deduced amino acid sequence exhibits homology to the D-amino acid amidase from Variovorax paradoxus (67.9% identity), the amidotransferase A subunit from Burkholderia fungorum (50% identity) and other enantioselective amidases.