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 αßßα 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.

Crystallization and X-ray diffraction analysis of nylon hydrolase (NylC) from Arthrobacter sp. KI72.

Nylon hydrolase (NylC) encoded by Arthrobacter plasmid pOAD2 (NylCp2) was expressed in Escherichia coli JM109 and purified by ammonium sulfate fractionation, anion-exchange column chromatography and gel-filtration chromatography. NylCp2 was crystallized by the sitting-drop vapour-diffusion method with ammonium sulfate as a precipitant in 0.1 M HEPES buffer pH 7.5 containing 0.2 M NaCl and 25% glycerol. Diffraction data were collected from the native crystal to a resolution of 1.60 Å. The obtained crystal was spindle shaped and belonged to the C-centred orthorhombic space group C2221, with unit-cell parameters a=70.84, b=144.90, c=129.05 Å. A rotation and translation search gave one clear solution containing two molecules per asymmetric unit.

X-ray crystallographic and mutational analysis of the NylC precursor: catalytic mechanism of autocleavage and substrate hydrolysis of nylon hydrolase.

Nylon hydrolase (NylC), a member of the N-terminal nucleophile (Ntn) hydrolase superfamily, is responsible for the degradation of various aliphatic nylons, including nylon-6 and nylon-66. NylC is initially expressed as an inactive precursor (36 kDa), but the precursor is autocatalytically cleaved at Asn266/Thr267 to generate an active enzyme composed of 27 and 9 kDa subunits. We isolated various mutants with amino acid changes at the catalytic centre. X-ray crystallographic analysis revealed that the NylC precursor forms a doughnut-shaped quaternary structure composed of four monomers (molecules A-D) with D2 symmetry. Catalytic residues in the precursor are covered by loop regions at the A/B interface (equivalent to the C/D interface). However, the catalytic residues are exposed to the solvent environment through autocleavage followed by movements of the loop regions. T267A, D306A and D308A mutations resulted in a complete loss of autocleavage. By contrast, in the T267S mutant, autocleavage proceeded slowly at a constant reaction rate (k = 2.8 × 10-5  s-1 ) until complete conversion, but the reaction was inhibited by K189A and N219A mutations. Based on the crystallographic and molecular dynamic simulation analyses, we concluded that the Asp308-Asp306-Thr267 triad, resembling the Glu-Ser-Ser triad conserved in Ntn-hydrolase family enzymes, is responsible for autocleavage and that hydrogen-bonding networks connecting Thr267 with Lys189 and Asn219 are required for increasing the nucleophilicity of Thr267-OH in both the water accessible and water inaccessible systems. Furthermore, we determined that NylC employs the Asp308-Asp306-Thr267 triad as catalytic residues for substrate hydrolysis, but the reaction requires Lys189 and Tyr146 as additional catalytic/substrate-binding residues specific for nylon hydrolysis.

X-ray crystallographic analysis of the 6-aminohexanoate cyclic dimer hydrolase: catalytic mechanism and evolution of an enzyme responsible for nylon-6 byproduct degradation.

We performed x-ray crystallographic analyses of the 6-aminohexanoate cyclic dimer (Acd) hydrolase (NylA) from Arthrobacter sp., an enzyme responsible for the degradation of the nylon-6 industry byproduct. The fold adopted by the 472-amino acid polypeptide generated a compact mixed alpha/beta fold, typically found in the amidase signature superfamily; this fold was especially similar to the fold of glutamyl-tRNA(Gln) amidotransferase subunit A (z score, 49.4) and malonamidase E2 (z score, 44.8). Irrespective of the high degree of structural similarity to the typical amidase signature superfamily enzymes, the specific activity of NylA for glutamine, malonamide, and indoleacetamide was found to be lower than 0.5% of that for Acd. However, NylA possessed carboxylesterase activity nearly equivalent to the Acd hydrolytic activity. Structural analysis of the inactive complex between the activity-deficient S174A mutant of NylA and Acd, performed at 1.8 A resolution, suggested the following enzyme/substrate interactions: a Ser(174)-cis-Ser(150)-Lys(72) triad constitutes the catalytic center; the backbone N in Ala(171) and Ala(172) are involved in oxyanion stabilization; Cys(316)-S(gamma) forms a hydrogen bond with nitrogen (Acd-N(7)) at the uncleaved amide bond in two equivalent amide bonds of Acd. A single S174A, S150A, or K72A substitution in NylA by site-directed mutagenesis decreased the Acd hydrolytic and esterolytic activities to undetectable levels, indicating that Ser(174)-cis-Ser(150)-Lys(72) is essential for catalysis. In contrast, substitutions at position 316 specifically affected Acd hydrolytic activity, suggesting that Cys(316) is responsible for Acd binding. On the basis of the structure and functional analysis, we discussed the catalytic mechanisms and evolution of NylA in comparison with other Ser-reactive hydrolases.

Crystallization and X-ray diffraction analysis of nylon-oligomer hydrolase (NylC) from Agromyces sp. KY5R.

6-Aminohexanoate-oligomer hydrolase (NylC) from Agromyces sp. KY5R was expressed in Escherichia coli JM109 and purified by ammonium sulfate fractionation, anion-exchange column chromatography and gel-filtration chromatography. NylC was crystallized by the sitting-drop vapour-diffusion method with sodium citrate as a precipitant in 0.1 M HEPES buffer pH 7.5 containing 0.2 M NaCl. Diffraction data were collected from native and K(2)PtCl(4)-derivative crystals to resolutions of 2.00 and 2.20 Å, respectively. The obtained crystal was plate-shaped, with an I-centred orthorhombic space group and unit-cell parameters a = 155.86, b = 214.45, c = 478.80 Å. The anomalous difference Patterson map of the K(2)PtCl(4)-derivative crystal suggested that the space group was I222 rather than I2(1)2(1)2(1).

Structural and functional characterization of nylon hydrolases.

Biodegradation of synthetic polymers is recognized as a useful way to reduce their environmental load and pollution, loss of natural resources, extensive energy consumption, and generation of greenhouse gases. The potential use of enzymes responsible for the degradation of the targeted polymers is an effective approach which enables the conversion of the used polymers to original monomers and/or other useful compounds. In addition, the enzymes are expected to be applicable in industrial processes such as improving the surface structures of the polymers. Especially, conversion of the solid polymers to soluble oligomers/monomers is a key step for the biodegradation of the polymers. Regarding the hydrolysis of polyamides, three enzymes, 6-aminohexanoate-cyclic-dimer hydrolase (NylA), 6-aminohexanoate-dimer hydrolase (NylB), and 6-aminohexanoate-oligomer endo-hydrolase (nylon hydrolase, NylC), are found in several bacterial strains. In this chapter, we describe our approach for the screening of microorganisms which degrade nylons and related compounds; preparation of substrates; assay of hydrolytic activity for soluble and insoluble substrates; and X-ray crystallographic and computational approaches for analysis of structure and catalytic mechanisms of the nylon-degrading enzymes.

Nylon-oligomer degrading enzyme/substrate complex: catalytic mechanism of 6-aminohexanoate-dimer hydrolase.

We performed X-ray crystallographic analyses of 6-aminohexanoate-dimer hydrolase (Hyb-24DN), an enzyme responsible for the degradation of nylon-6, an industry by-product, and of a complex between Hyb-24DN-A(112) (S112A-mutant of Hyb-24DN) and 6-aminohexanoate-linear dimer (Ald) at 1.58 A and 1.4 A resolution, respectively. In Hyb-24DN, Asp181-O(delta) forms hydrogen bonds with Tyr170-O(eta), -two of the catalytic and binding amino acids, and a loop between Asn167 and Val177. This state is the so-called open form, allowing its substrate to bind in the space between the loop and catalytic residues. Upon substrate binding (in Hyb-24DN-A(112)/Ald complex), the loop is shifted 4.3 A at Tyr170-C(alpha), and the side-chain of Tyr170 is rotated. By the combined effect, Tyr170-O(eta) moves a total of 10.5 A, resulting in the formation of hydrogen bonds with the nitrogen of amide linkage in Ald (closed form). In addition, electrostatic interaction between Asp181-O(delta) and the amino group in Ald stabilizes the substrate binding. We propose here that the enzyme catalysis proceeds according to the following steps: (i) Ald-induced transition from open to closed form, (ii) nucleophilic attack of Ser112 to Ald and formation of a tetrahedral intermediate, (iii) formation of acyl enzyme and transition to open form, (iv) deacylation. Amino acid substitutions reducing the enzyme/Ald interaction at positions 181 or 170 drastically decreased the Ald-hydrolytic activity, but had very little effect on esterolytic activity, suggesting that esterolytic reaction proceeds regardless of conversion. Present models illustrate why new activity against the nylon oligomer has evolved in an esterase with beta-lactamase folds, while retaining the original esterolytic functions.

Genetic organization of nylon-oligomer-degrading enzymes from alkalophilic bacterium, Agromyces sp. KY5R.

A 15-kb gene locus including nylon-oligomer-degrading genes from the chromosome of an alkalophilic bacterium, Agromyces sp. KY5R, was cloned and sequenced. The genetic organization was similar to the DNA region flanked by directly repeated IS6100 sequences on the nylon-oligomer-degradative plasmid pOAD2. However, we found several genetic rearrangements between the two DNA regions. Here, we discuss the possible mechanisms underlying the genetic rearrangements.

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.

Crystallization and X-ray diffraction analysis of 6-aminohexanoate-cyclic-dimer hydrolase from Arthrobacter sp. KI72.

6-Aminohexanoate-cyclic-dimer hydrolase (EI) from Arthrobacter sp. KI72 was expressed in Escherichia coli and purified by anion-exchange chromatography. EI was crystallized by the sitting-drop vapour-diffusion method with sodium citrate as precipitant in imidazole buffer pH 8.0. The crystal is hexagonal, with unit-cell parameters a = b = 130.75, c = 58.23 A. Diffraction data were collected from native and mercury(II) dichloride-derivative crystals to resolutions of 1.90 and 2.06 A, respectively.

6-Aminohexanoate oligomer hydrolases from the alkalophilic bacteria Agromyces sp. strain KY5R and Kocuria sp. strain KY2.

Alkalophilic, nylon oligomer-degrading strains, Agromyces sp. and Kocuria sp., were isolated from the wastewater of a nylon-6 factory and from activated sludge from a sewage disposal plant. The 6-aminohexanoate oligomer hydrolases (NylC) from the alkalophilic strains had 95.8 to 98.6% similarity to the enzyme in neutrophilic Arthrobacter sp. but had superior thermostability, activity under alkaline conditions, and affinity for nylon-related substrates, which would be advantageous for biotechnological applications.