Nylon oligomer degradation gene, nylC, on plasmid pOAD2 from a Flavobacterium strain encodes endo-type 6-aminohexanoate oligomer hydrolase: purification and characterization of the nylC gene product.

A new type of nylon oligomer degradation enzyme (EIII) was purified from an Escherichia coli clone harboring the EIII gene (nylC). This enzyme hydrolyzed the linear trimer, tetramer, and pentamer of 6-aminohexanoate by an endo-type reaction, and this specificity is different from that of the EI (nylA gene product) and EII (nylB gene product). Amino acid sequencing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified EIII demonstrated that the enzyme is made of two polypeptide chains arising from an internal cleavage between amino acid residues 266 and 267.     

The nylon oligomer biodegradation system ofFlavobacterium andPseudomonas

This review article is a compendium of the available information on the degradation of a man-made compound, 6-aminohexanoate-oligomer, inFlavobacterium andPseudomonas strains, and discusses the molecular basis for adaptation of microorganisms toward these xenobiotic compounds. Three plasmid-encoded enzymes, 6-aminohexanoate-cyclic-dimer hydrolase (EI), 6-aminohexanoate-dimer hydrolase (EII), and endo-type 6-aminohexanoate-oligomer hydrolase (EIII) are responsible for the degradation of the oligomers. Two repeated sequences, designated RS-I and RS-II, are found on plasmid pOAD2, which is involved in 6-aminohexanoate degradation inFlavobacterium. RS-I appears 5 times on the pOAD2, and all copies have the same sequences as insertion sequence IS6100. RS-II appears twice on the plasmid. RS-IIA contains the gene encoding EII, while RS-IIB contains the gene for the analogous EII' protein. Both EII and EII' are polypeptides of 392 amino acids, which differ by 46 amino acid residues. The specific activity of the EII enzyme is 200-fold higher than that of EII'. Construction of various hybrid genes demonstrated that only the combination of two amino acid residues in the EII' enzyme can enhance the activity of the EII' to the same level as that of EII enzyme.Abbreviations EI 6-aminohexanoate-cyclic-dimer hydrolase - EII 6-aminohexanoate-dimer hydrolase - EIII endo-type 6-aminohexanoate-oligomer hydrolase - F-EI EI fromFlavobacterium - F-EII EII fromFlavobacterium - P-EI EI fromPseudomonas - P-EII EII fromPseudomonas - EII' a protein having 88% homology to the EII encoded on the RS-IIB region of pOAD2 - nylA gene for the EI enzyme - nylB gene for the EII enzyme - nylC gene for the EIII enzyme - nylB' gene for the EII' protein - kb kilo-base-pairs     

Biodegradation of nylon oligomers

This mini-review is a compendium of the degradation of a man-made compound, 6-aminohexanoate-oligomer, in Flavobacterium strains. The results are summarized as follows: 1. Three enzymes, 6-aminohexanoate-cyclic-dimer hydrolase (EI), 6-aminohexanoate-dimer hydrolase (EII), and endotype 6-aminohexanoate-oligomer hydrolase (EIII) were responsible for degradation of the oligomers. 2. The genes coding these enzymes were located on pOAD2, one of three plasmids harbored in Flavobacterium sp. KI72, which comprised 45,519 bp. 3. The gene coding the EII′ protein (a protein having 88% homology with EII) and five IS6100 elements were identified on pOAD2. 4. The specific activity of EII was 200-fold higher than that of EII′. However, altering two amino acid residues in the EII′ enzyme enhanced the activity of EII′ to the same level as that of the EII enzyme. 5. The deduced amino acid sequences from eight regions of pOAD2 had significant similarity with the sequences of gene products such as oppA-F (encoding oligopeptide permease), ftsX (filamentation temperature sensitivity), penDE (isopenicillin N-acyltransferase) and rep (plasmid replication). 6. The EI and EII genes of Pseudomonas sp. NK87 (another nylon oligomer-degrading bacterium) were also located on plasmids. 7. Through selective cultivation using nylon oligomers as a sole source of carbon and nitrogen, two strains which initially had no metabolic activity for nylon oligomers, Flavobacterium sp. KI725 and Pseudomonas aeruginosa PAO1, were given the ability to degrade xenobiotic compounds. A molecular basis for the adaptation of microorganisms toward xenobiotic compounds was described. Received: 25 February 2000 / Received revision: 22 May 2000 / Accepted: 26 May 2000     

Amino acid alterations essential for increasing the catalytic activity of the nylon-oligomer-degradation enzyme of Flavobacterium sp

The structural genes of two homologous enzymes, 6-aminohexanoate-dimer hydrolase (EII; nylB) and its evolutionally related protein EII' (nylB') of Flavobacterium sp. KI72 have an open reading frame encoding a peptide of 392 amino acids, of which 47 are different, and conserved restriction sites. The specific activity of EII towards 6-aminohexanoate dimer is about 1000-fold that of EII'. Construction of various hybrid genes obtained by exchanging fragments flanked by conserved restriction sites of the two genes demonstrated that two amino acid replacements in the EII' enzyme, i.e. Gly181----Asp (EII type) and His266----Asn (EII type), enhanced the activity toward 6-aminohexanoate dimer 1000-fold.     

DNA-DNA hybridization analysis of nylon oligomer-degradative plasmid pOAD2: identification of the DNA region analogous to the nylon oligomer degradation gene.

Fine structure of the gene of 6-aminohexanoic acid cyclic dimer hydrolase, one of the enzymes responsible for the degradation of the nylon oligomer (6-aminohexanoic acid cyclic dimer), on the plasmid pOAD2 harbored in Flavobacterium sp. KI72 was determined by constructing miniplasmids from plasmid pNDH5 (a hybrid plasmid consisting of pBR322 and a 9.1-kilobase-pair HindIII fragment of pOAD2 ). The 6-aminohexanoic acid cyclic dimer hydrolase produced by cells of Escherichia coli C600 harboring pNDH5 or its miniplasmid was examined immunologically and electrophoretically and was found to be identical to that of Flavobacterium sp. KI72 . A fragment of pOAD2 (17.2- to 19.1-kilobase-pair region on pOAD2 ) was detected as hybridized fragment by Southern blotting experiments, indicating the presence of the DNA region analogous to the 6-aminohexanoic acid cyclic dimer hydrolase gene on the plasmid.     

Plasmid-determined enzymatic degradation of nylon oligomers.

The nylon oligomer (6-aminohexanoic acid cyclic dimer) degradation genes on plasmid pOAD2 of Flavobacterium sp. KI72 were cloned into Escherichia coli vector pBR322. The locus of one of the genes, the structural gene of 6-aminohexanoic acid linear oligomer hydrolase, was determined by constructing various deletion plasmids and inserting the lacUV5 promoter fragment of E. coli into the deletion plasmid. Two kinds of repeated sequences (RS-I and RS-II) were detected on pOAD2 by DNA-DNA hybridization experiments. These repeated sequences appeared five times (RS-I) or twice (RS-II) on pOAD2. One of the RS-II regions and the structural gene of the hydrolase overlapped.     

X-ray crystallographic analysis of 6-aminohexanoate-dimer hydrolase: molecular basis for the birth of a nylon oligomer-degrading enzyme

6-Aminohexanoate-dimer hydrolase (EII), responsible for the degradation of nylon-6 industry by-products, and its analogous enzyme (EII') that has only approximately 0.5% of the specific activity toward the 6-aminohexanoate-linear dimer, are encoded on plasmid pOAD2 of Arthrobacter sp. (formerly Flavobacterium sp.) KI72. Here, we report the three-dimensional structure of Hyb-24 (a hybrid between the EII and EII' proteins; EII'-level activity) by x-ray crystallography at 1.8 A resolution and refined to an R-factor and R-free of 18.5 and 20.3%, respectively. The fold adopted by the 392-amino acid polypeptide generated a two-domain structure that is similar to the folds of the penicillin-recognizing family of serine-reactive hydrolases, especially to those of d-alanyl-d-alanine-carboxypeptidase from Streptomyces and carboxylesterase from Burkholderia. Enzyme assay using purified enzymes revealed that EII and Hyb-24 possess hydrolytic activity for carboxyl esters with short acyl chains but no detectable activity for d-alanyl-d-alanine. In addition, on the basis of the spatial location and role of amino acid residues constituting the active sites of the nylon oligomer hydrolase, carboxylesterase, d-alanyl-d-alanine-peptidase, and beta-lactamases, we conclude that the nylon oligomer hydrolase utilizes nucleophilic Ser(112) as a common active site both for nylon oligomer-hydrolytic and esterolytic activities. However, it requires at least two additional amino acid residues (Asp(181) and Asn(266)) specific for nylon oligomer-hydrolytic activity. Here, we propose that amino acid replacements in the catalytic cleft of a preexisting esterase with the beta-lactamase fold resulted in the evolution of the nylon oligomer hydrolase.     

Phospholipids in Castor Seeds

Sites of restriction endonucleases were mapped on pOAD2, a plasmid harbored in Flavobacterium sp. KI72. The plasmid codes 6-aminohexanoic acid cyclic dimer hydrolase and 6-aminohexanoic acid linear oligomer hydrolase. pOAD2 (molecular weight: 28.8 megadaltons [Mdal]) had 6 HindIII and 5 EcoRI sites, which were located at 0, 8.4, 8.9, 11.1, 19.0 and 25.0 Mdal (for HindIII) and 3.3, 5.4, 20.4, 20.8, 22.6 Mdal (for EcoRI). A mutant which could not grow on 6-aminohexanoic acid cyclic dimer but grew on the linear dimer as the sole carbon and nitrogen source harbored a deletion plasmid pOAD21 derived from pOAD2. By comparing the restriction sites of these two plasmids, the deleted region was localized on which the 6-aminohexanoic acid cyclic dimer hydrolase was coded.     

Plasmid Control of 6-Aminohexanoic Acid Cyclic Dimer Degradation Enzymes of Flavobacterium sp. K172

Flavobacterium sp. K172, which is able to grow on 6-aminohexanoic acid cyclic dimer as the sole source of carbon and nitrogen, and plasmid control of the responsible enzymes, 6-aminohexanoic acid cyclic dimer hydrolase and 6-aminohexanoic acid linear oligomer hydrolase, were studied. The wild strain of K172 harbors three kinds of plasmid, pOAD1 (26.2 megadaltons), pOAD2 (28.8 megadaltons), and pOAD3 (37.2 megadaltons). The wild strain K172 was readily cured of its ability to grow on the cyclic dimer by mitomycin C, and the cyclic dimer hydrolase could not be detected either as catalytic activity or by antibody precipitation. No reversion of the cured strains was detected. pOAD2 was not detected in every cured strain tested but was restored in a transformant. The transformant recovered both of the enzyme activities, and the cyclic dimer hydrolase of the transformant was immunologically identical with that of the wild strain. All of the strains tested, including the wild, cured, and transformant ones, possessed identical pOAD3 irrespective of the metabolizing activity. Some of the cured strains possessed pOAD1 identical with the wild strain, but the others harbored plasmids with partially altered structures which were likely to be derived from pOAD1 by genetic rearrangements such as deletion, insertion, or substitution. These results suggested that the genes of the enzymes were borne on pOAD2.     

Characterization of hybrid enzymes between 6-aminohexanoate-Dimer hydrolase and its analogous protein

6-Aminohexanoate-dimer hydrolase (EII) and its analogous protein (EII′), of Flavobacterium sp. K172 are composed of 392 amino acids, in which 47 are different. The enzyme activity of EII′ toward 6-aminohexanoate dimer is approximately 0.5% of that of EII. We have constructed various hybrids of the two genes by exchanging fragments flanked by conserved restriction sites such as PvuII, BglII, SalI, and BamHI (respectively 74, 483, 771, and 1,141 bp downstream of the initiation codon), and purified their gene products to homogeneity. Hyb-12 protein, which was obtained by the replacement of the BglII-SalI region of the EII′ with the corresponding region of EII, had 12 times higher specific activity towards the 6-aminohexanoate dimer and its related substrates than EII′ protein. Hyb-10, which was composed of the N-terminal -BglII regions of EII′ and the BglII-C terminal region of EII, had activity toward these substrates nearly equal to the activity of the EII enzyme. Comparisons of the activity toward 6-aminohexanoate dimer and its analogues has demonstrated that EII, EII′, and their hybrid enzymes are highly active only toward the substrates that contain 6-aminohexanoate as the N-terminal residue, while the recognition of the C-terminal residue in the substrate was not stringent. The substrate specificity, pH-activity profile, and heat stability of these enzymes varied slightly.     

Metabolic pathway of 6-aminohexanoate in the nylon oligomer-degrading bacterium Arthrobacter sp. KI72: identification of the enzymes responsible for the conversion of 6-aminohexanoate to adipate

Arthrobacter sp. strain KI72 grows on a 6-aminohexanoate oligomer, which is a by-product of nylon-6 manufacturing, as a sole source of carbon and nitrogen. We cloned the two genes, nylD ₁ and nylE ₁ , responsible for 6-aminohexanoate metabolism on the basis of the draft genomic DNA sequence of strain KI72. We amplified the DNA fragments that encode these genes by polymerase chain reaction using a synthetic primer DNA homologous to the 4-aminobutyrate metabolic enzymes. We inserted the amplified DNA fragments into the expression vector pColdI in Escherichia coli, purified the His-tagged enzymes to homogeneity, and performed biochemical studies. We confirmed that 6-aminohexanoate aminotransferase (NylD₁) catalyzes the reaction of 6-aminohexanoate to adipate semialdehyde using α-ketoglutarate, pyruvate, and glyoxylate as amino acceptors, generating glutamate, alanine, and glycine, respectively. The reaction requires pyridoxal phosphate (PLP) as a cofactor. For further metabolism, adipate semialdehyde dehydrogenase (NylE₁) catalyzes the oxidative reaction of adipate semialdehyde to adipate using NADP⁺ as a cofactor. Phylogenic analysis revealed that NylD₁ should be placed in a branch of the PLP-dependent aminotransferase sub III, while NylE₁ should be in a branch of the aldehyde dehydrogenase superfamily. In addition, we established a NylD₁/NylE₁ coupled system to quantify the aminotransferase activity and to enable the conversion of 6-aminohexaoate to adipate via adipate semialdehyde with a yield of > 90%. In the present study, we demonstrate that 6-aminohexanoate produced from polymeric nylon-6 and nylon oligomers (i.e., a mixture of 6-aminohexaoate oligomers) by nylon hydrolase (NylC) and 6-aminohexanoate dimer hydrolase (NylB) reactions are sequentially converted to adipate by metabolic engineering technology.

     

Emergence of nylon oligomer degradation enzymes in Pseudomonas aeruginosa PAO through experimental evolution.

Through selective cultivation with 6-aminohexanoate linear dimer, a by-product of nylon-6 manufacture, as the sole source of carbon and nitrogen, Pseudomonas aeruginosa PAO, which initially has no enzyme activity to degrade this xenobiotic compound, was successfully expanded in its metabolic ability. Two new enzyme activities, 6-aminohexanoate cyclic dimer hydrolase and 6-aminohexanoate dimer hydrolase, were detected in the adapted strains.     

Mutational analysis of 6-aminohexanoate-dimer hydrolase: relationship between nylon oligomer hydrolytic and esterolytic activities

Carboxylesterase (EII') from Arthrobacter sp. KI72 has 88% homology to 6-aminohexanoate-dimer hydrolase (EII) and possesses ca. 0.5% of the level of 6-aminohexanoate-linear dimer (Ald)-hydrolytic activity of EII. To study relationship between Ald-hydrolytic and esterolytic activities, random mutations were introduced into the gene for Hyb-24 (an EII/EII' hybrid with the majority of the sequence deriving for EII' and possessing an EII'-like level of Ald-hydrolytic activity). Either a G181D or a D370Y substitution in Hyb-24 increased the Ald-hydrolytic activity ca. 10-fold, and a G181D/D370Y double substitution increased activity ca. 100-fold. On the basis of kinetic studies and the three-dimensional structure of the enzyme, we suggest that binding of Ald is improved by these mutations. D370Y increased esterolytic activity for glycerylbutyrate ca. 30-50-fold, whereas G181D decreased the activity to 30% of the parental enzyme.     

Construction of hybrid genes of 6-aminohexanoic acid-oligomer hydrolase and its analogous enzyme. Estimation of the intramolecular regions important for the enzyme evolution

Hybrids were constructed of the genes for two homologous enzymes, 6-aminohexanoic acid-oligomer hydrolase (EII, one of the nylon oligomer degradation enzymes), and its probable evolutionary antecedent (EII'). The structural genes of EII (nylB) and EII' (nylB') have 88% similarity in their nucleotide sequences, an open frame encoding a peptide of 392 amino acids, conserved restriction sites, and in vitro recombination between these genes at the corresponding restriction sites generated genes directing various hybrid enzymes. In a comparison of the EII, EII', and the hybrid enzymes, we concluded that one or more of the four amino acid alterations that occurred in the intramolecular region (between amino acids 162-257) of EII' is essential to the adaptation of the enzyme to nylon oligomer degradation, and that its effect is enhanced 20-fold by one or more further alterations in the 258-380 region. Our results also suggest that this technique is useful for improving enzyme characteristics.     

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.     

Novel extremophilic proteases from Pseudomonas aeruginosa M211 and their application in the hydrolysis of dried distiller's grain with solubles

Proteases are the most important group of industrial enzymes and they can be used in several fields including biorefineries for the valorization of industrial byproducts. In this study, we purified and characterized novel extremophilic proteases produced by a Pseudomonas aeruginosa strain isolated from Mauritia flexuosa palm swamps soil samples in Peruvian Amazon. In addition, we tested their ability to hydrolyze distillers dried grains with solubles (DDGS) protein. Three alkaline and thermophilic serine proteases named EI, EII, and EIII with molecular weight of 35, 40, and 55 kDa, respectively, were purified. EI and EIII were strongly inhibited by EDTA and Pefabloc being classified as serine-metalloproteases, while EII was completely inhibited only by Pefabloc being classified as a serine protease. In addition, EI and EII exhibited highest enzymatic activity at pH 8, while EIII at pH 11 maintaining almost 100% of it at pH 12. All the enzymes demonstrated optimum activity at 60°C. Enzymatic activity of EI was strongly stimulated in presence of Mn²⁺ (6.9-fold), EII was stimulated by Mn²⁺ (3.7-fold), while EIII was slightly stimulated by Zn²⁺, Ca²⁺, and Mg²⁺. DDGS protein hydrolysis using purified Pseudomonas aeruginosa M211 proteases demonstrated that, based on glycine released, EIII presented the highest proteolytic activity toward DDGS. This enzyme enabled the release 63% of the total glycine content in wheat DDGS protein, 2.2-fold higher that when using the commercial Pronase®. Overall, our results indicate that this novel extremopreoteases have a great potential to be applied in DDGS hydrolysis. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2728, 2019     

A novel aryl acylamidase from Nocardia farcinica hydrolyses polyamide

An alkali stable polyamidase was isolated from a new strain of Nocardia farcinica. The enzyme consists of four subunits with a total molecular weight of 190 kDa. The polyamidase cleaved amide and ester bonds of water insoluble model substrates like adipic acid bishexylamide and bis(benzoyloxyethyl)terephthalate and hydrolyzed different soluble amides to the corresponding acid. Treatment of polyamide 6 with this amidase led to an increased hydrophilicity based on rising height and tensiometry measurements and evidence of surface hydrolysis of polyamide 6 is shown. In addition to amidase activity, the enzyme showed activity on p-nitrophenylbutyrate. On hexanoamide the amidase exhibited a K(m) value of 5.5 mM compared to 0.07 mM for p-nitroacetanilide. The polyamidase belongs to the amidase signature family and is closely related to aryl acylamidases from different strains/species of Nocardia and to the 6-aminohexanoate-cyclic dimer hydrolase (EI) from Arthrobacter sp. KI72.     

Three-dimensional structure of nylon hydrolase and mechanism of nylon-6 hydrolysis

We performed x-ray crystallographic analyses of the 6-aminohexanoate oligomer hydrolase (NylC) from Agromyces sp. at 2.0 Å-resolution. This enzyme is a member of the N-terminal nucleophile hydrolase superfamily that is responsible for the degradation of the nylon-6 industry byproduct. We observed four identical heterodimers (27 kDa + 9 kDa), which resulted from the autoprocessing of the precursor protein (36 kDa) and which constitute the doughnut-shaped quaternary structure. The catalytic residue of NylC was identified as the N-terminal Thr-267 of the 9-kDa subunit. Furthermore, each heterodimer is folded into a single domain, generating a stacked αββα core structure. Amino acid mutations at subunit interfaces of the tetramer were observed to drastically alter the thermostability of the protein. In particular, four mutations (D122G/H130Y/D36A/E263Q) of wild-type NylC from Arthrobacter sp. (plasmid pOAD2-encoding enzyme), with a heat denaturation temperature of T_m = 52 °C, enhanced the protein thermostability by 36 °C (T_m = 88 °C), whereas a single mutation (G111S or L137A) decreased the stability by ∼10 °C. We examined the enzymatic hydrolysis of nylon-6 by the thermostable NylC mutant. Argon cluster secondary ion mass spectrometry analyses of the reaction products revealed that the major peak of nylon-6 (m/z 10,000–25,000) shifted to a smaller range, producing a new peak corresponding to m/z 1500–3000 after the enzyme treatment at 60 °C. In addition, smaller fragments in the soluble fraction were successively hydrolyzed to dimers and monomers. Based on these data, we propose that NylC should be designated as nylon hydrolase (or nylonase). Three potential uses of NylC for industrial and environmental applications are also discussed.