The minimal structure for iodotyrosine deiodinase function is defined by an outlier protein from the thermophilic bacterium Thermotoga neapolitana.

The nitroreductase superfamily of enzymes encompasses many flavin mononucleotide (FMN)-dependent catalysts promoting a wide range of reactions. All share a common core consisting of an FMN-binding domain, and individual subgroups additionally contain one to three sequence extensions radiating from defined positions within this core to support their unique catalytic properties. To identify the minimum structure required for activity in the iodotyrosine deiodinase subgroup of this superfamily, attention was directed to a representative from the thermophilic organism Thermotoga neapolitana (TnIYD). This representative was selected based on its status as an outlier of the subgroup arising from its deficiency in certain standard motifs evident in all homologues from mesophiles. We found that TnIYD lacked a typical N-terminal sequence and one of its two characteristic sequence extensions, neither of which was found to be necessary for activity. We also show that TnIYD efficiently promotes dehalogenation of iodo-, bromo-, and chlorotyrosine, analogous to related deiodinases (IYDs) from humans and other mesophiles. In addition, 2-iodophenol is a weak substrate for TnIYD as it was for all other IYDs characterized to date. Consistent with enzymes from thermophilic organisms, we observed that TnIYD adopts a compact fold and low surface area compared with IYDs from mesophilic organisms. The insights gained from our investigations on TnIYD demonstrate the advantages of focusing on sequences that diverge from conventional standards to uncover the minimum essentials for activity. We conclude that TnIYD now represents a superior starting structure for future efforts to engineer a stable dehalogenase targeting halophenols of environmental concern.

Enzymatic transformation of ginsenosides Re, Rg1, and Rf to ginsenosides Rg2 and aglycon PPT by using ß-glucosidase from Thermotoga neapolitana.

OBJECTIVES: To enzymatically transform protopanaxatriol by using ß-glucosidase from Thermotoga neapolitana (T. neapolitana) DSM 4359. RESULTS: Recombinant ß-glucosidase was purified, which molecular weight was about 79.5 kDa. High levels of ginsenoside were obtained using the follow reaction conditions: 2 mg ml-1 ginsenoside, 25 U ml-1 enzyme, 85 °C, and pH 5.0. ß-glucosidase converted ginsenoside Re to Rg2, Rf and Rg1 to APPT completely after 3 h under the given conditions, respectively. The enzyme created 1.66 mg ml-1 Rg2 from Re with 553 mg l-1 h-1, 0.85 mg ml-1, and 1.01 mg ml-1 APPT from Rg1 and Rf with 283 and 316 mg l-1 h-1 APPT. CONCLUSIONS: ß-glucosidase could be useful for the high-yield, rapid, and low-cost preparation of ginsenoside Rg2 from Re, and APPT from the ginsenosides Rg1 and Rf.

Crystal structure of ß-glucosidase 1A from Thermotoga neapolitana and comparison of active site mutants for hydrolysis of flavonoid glucosides.

The ß-glucosidase TnBgl1A catalyses hydrolysis of O-linked terminal ß-glycosidic bonds at the nonreducing end of glycosides/oligosaccharides. Enzymes with this specificity have potential in lignocellulose conversion (degrading cellobiose to glucose) and conversion of bioactive flavonoids (modification of glycosylation results in modulation of bioavailability). Previous work has shown TnBgl1A to hydrolyse 3, 4' and 7 glucosylation in flavonoids, and although conversion of 3-glucosylated substrate to aglycone was low, it was improved by mutagenesis of residue N220. To further explore structure-function relationships, the crystal structure of the nucleophile mutant TnBgl1A-E349G was determined at 1.9 Å resolution, and docking studies of flavonoid substrates were made to reveal substrate interacting residues. A series of single amino acid changes were introduced in the aglycone binding region [N220(S/F), N221(S/F), F224(I), F310(L/E), and W322(A)] of the wild type. Activity screening was made on eight glucosylated flavonoids, and kinetic parameters were monitored for the flavonoid quercetin-3-glucoside (Q3), as well as for the model substrate para-nitrophenyl-ß-d-glucopyranoside (pNPGlc). Substitution by Ser at N220 or N221 increased the catalytic efficiency on both pNPGlc and Q3. Residue W322 was proven important for substrate accomodation, as mutagenesis to W322A resulted in a large reduction of hydrolytic activity on 3-glucosylated flavonoids. Flavonoid glucoside hydrolysis was unaffected by mutations at positions 224 and 310. The mutations did not significantly affect thermal stability, and the variants kept an apparent unfolding temperature of 101°C. This work pinpoints positions in the aglycone region of TnBgl1A of importance for specificity on flavonoid-3-glucosides, improving the molecular understanding of activity in GH1 enzymes. Proteins 2017; 85:872-884. © 2016 Wiley Periodicals, Inc.

Rational design of a thermostable glycoside hydrolase from family 3 introduces ß-glycosynthase activity.

The thermostable ß-glucosidase from Thermotoga neapolitana, TnBgl3B, is a monomeric three-domain representative from glycoside hydrolase family 3. By using chemical reactivation with exogenous nucleophiles in previous studies with TnBg13B, the catalytic nucleophile (D242) and corresponding acid/base residue (E458) were determined. Identifying these residues led to the attempt of converting TnBgl3B into a ß-glucosynthase, where three nucleophilic variants were created (TnBgl3B_D242G, TnBgl3B_D242A, TnBgl3B_D242S) and all of them failed to exhibit glucosynthase activity. A deeper analysis of the TnBgl3B active site led to the generation of three additional variants, each of which received a single-point mutation. Two of these variants were altered at the -1 subsite (Y210F, W243F) and the third received a substitution near the binding site's aglycone region (N248R). Kinetic evaluation of these three variants revealed that W243F substitution reduced hydrolytic turnover while maintaining KM This key W243F mutation was then introduced into the original nucleophile variants and the resulting double mutants were successfully converted into ß-glucosynthases that were assayed using two separate biosynthetic methods. The first reaction used an α-glucosyl fluoride donor with a 4-nitrophenyl-ß-d-glucopyranoside (4NPGlc) acceptor, and the second used 4NPGlc as both the donor and acceptor in the presence of the exogenous nucleophile formate. The primary specificity observed was a ß-1,3-linked disaccharide product, while a secondary ß-1,4-linked disaccharide product was observed with increased incubation times. Additional analysis revealed that substituting quercetin-3-glycoside for the second reaction's acceptor molecule resulted in the successful production of quercetin-3,4'-diglycosides with yields up to 40%.

Eliminating hydrolytic activity without affecting the transglycosylation of a GH1 ß-glucosidase.

Unveiling the determinants for transferase and hydrolase activity in glycoside hydrolases would allow using their vast diversity for creating novel transglycosylases, thereby unlocking an extensive toolbox for carbohydrate chemists. Three different amino acid substitutions at position 220 of a GH1 ß-glucosidase from Thermotoga neapolitana caused an increase of the ratio of transglycosylation to hydrolysis (r s/r h) from 0.33 to 1.45-2.71. Further increase in r s/r h was achieved by modulation of pH of the reaction medium. The wild-type enzyme had a pH optimum for both hydrolysis and transglycosylation around 6 and reduced activity at higher pH. Interestingly, the mutants had constant transglycosylation activity over a broad pH range (5-10), while the hydrolytic activity was largely eliminated at pH 10. The results demonstrate that a combination of protein engineering and medium engineering can be used to eliminate the hydrolytic activity without affecting the transglycosylation activity of a glycoside hydrolase. The underlying factors for this success are pursued, and perturbations of the catalytic acid/base in combination with flexibility are shown to be important factors.

Substrate adaptabilities of Thermotogae mannan binding proteins as a function of their evolutionary histories.

The Thermotogae possess a large number of ATP-binding cassette (ABC) transporters, including two mannan binding proteins, ManD and CelE (previously called ManE). We show that a gene encoding an ancestor of these was acquired by the Thermotogae from the archaea followed by gene duplication. To address the functional evolution of these proteins as a consequence of their evolutionary histories, we measured the binding affinities of ManD and CelE orthologs from representative Thermotogae. Both proteins bind cellobiose, cellotriose, cellotetraose, ß-1,4-mannotriose, and ß-1,4-mannotetraose. The CelE orthologs additionally bind ß-1,4-mannobiose, laminaribiose, laminaritriose and sophorose while the ManD orthologs additionally only weakly bind ß-1,4-mannobiose. The CelE orthologs have higher unfolding temperatures than the ManD orthologs. An examination of codon sites under positive selection revealed that many of these encode residues located near or in the binding site, suggesting that the proteins experienced selective pressures in regions that might have changed their functions. The gene arrangement, phylogeny, binding properties, and putative regulatory networks suggest that the ancestral mannan binding protein was a CelE ortholog which gave rise to the ManD orthologs. This study provides a window on how one class of proteins adapted to new functions and temperatures to fit the physiologies of their new hosts.

Cloning, purification, and characterization of xylose isomerase from Thermotoga naphthophila RKU-10.

A 1.3 kb xyl-A gene encoding xylose isomerase from a hyperthermophilic eubacterium Thermotoga naphthophila RKU-10 (TnapXI) was cloned and over-expressed in Escherichia coli to produce the enzyme in mesophilic conditions that work at high temperature. The enzyme was concentrated by lyophilization and purified by heat treatment, fractional precipitation, and UNOsphere Q anion-exchange column chromatography to homogeneity level. The apparent molecular mass was estimated by SDS-PAGE to be 49.5 kDa. The active enzyme showed a clear zone on Native-PAGE when stained with 2, 3, 5-triphenyltetrazolium chloride. The optimum temperature and pH for D-glucose to D-fructose isomerization were 98 °C and 7.0, respectively. Xylose isomerase retains 85% of its activity at 50 °C (t1/2 1732 min) for 4 h and 32.5% at 90 °C (t1/2 58 min) for 2 h. It retains 90-95% of its activity at pH 6.5-7.5 for 30 min. The enzyme was highly activated (350%) with the addition of 0.5 mM Co(2+) and to a lesser extent about 180 and 80% with the addition of 5 and 10 mM Mn(2+) and Mg(2+) , respectively but it was inhibited (54-90%) in the presence of 0.5-10 mM Ca(2+) with respect to apo-enzyme. D-glucose isomerization product was also analyzed by Thin Layer Chromatography (Rf 0.65). The enzyme was very stable at neutral pH and sufficiently high temperature and required only a trace amount of Co(2+) for its optimal activity and stability. Overall, 52.2% conversion of D-glucose to D-fructose was achieved by TnapXI. Thus, it has a great potential for industrial applications.

Crystal structure of ß-N-acetylglucosaminidase CbsA from Thermotoga neapolitana.

CbsA from the thermophilic marine bacteria Thermotoga neapolitana is a chitinolyitc enzyme that can cleave a glycosidic bond of the polymer N-acetylglucosamine at the non-reducing end. This enzyme has particularly high activity on di-N-acetylchitobiose. CbsA consists of a family of 3 glycoside hydrolase (GH3)-type catalytic domains and a unique C-terminal domain. The C-terminal domain distinguishes CbsA from other GH3-type enzymes. Sequence analyses have suggested that CbsA has the Asp-His dyad as a general acid/base with the NagZ of Bacillus subtilis and the Salmonella enterica serovar Typhimurium. Here, we determined the crystal structure of CbsA from T. neapolitana at a resolution of 2.0 Å using the Zn-SAD method, revealing a unique homodimeric assembly facilitated by the C-terminal domains in the dimer. We observed that CbsA is strongly inhibited by ZnCl2, and two zinc ions were consistently bound in the active site. Our results can explain the zinc ion's inhibition mechanism in the subfamily of GH3 enzymes, and provide information on the structural diversity and substrate specificity of this hydrolase family.

A transposase strategy for creating libraries of circularly permuted proteins.

A simple approach for creating libraries of circularly permuted proteins is described that is called PERMutation Using Transposase Engineering (PERMUTE). In PERMUTE, the transposase MuA is used to randomly insert a minitransposon that can function as a protein expression vector into a plasmid that contains the open reading frame (ORF) being permuted. A library of vectors that express different permuted variants of the ORF-encoded protein is created by: (i) using bacteria to select for target vectors that acquire an integrated minitransposon; (ii) excising the ensemble of ORFs that contain an integrated minitransposon from the selected vectors; and (iii) circularizing the ensemble of ORFs containing integrated minitransposons using intramolecular ligation. Construction of a Thermotoga neapolitana adenylate kinase (AK) library using PERMUTE revealed that this approach produces vectors that express circularly permuted proteins with distinct sequence diversity from existing methods. In addition, selection of this library for variants that complement the growth of Escherichia coli with a temperature-sensitive AK identified functional proteins with novel architectures, suggesting that PERMUTE will be useful for the directed evolution of proteins with new functions.

Overexpression of a lethal methylase, M.TneDI, in E. coli BL21(DE3).

A pET-based vector pDH21 expressing the methylase, M.TneDI (recognizing CGCG) from Thermotoga was constructed, and transformed into E. coli BL21(DE3). Despite E. coli BL21(DE3) being McrBC positive, 30 transformants were isolated, which were suspected to be McrBC(-) mutants. The overexpression of M.TneDI was verified by SDS-PAGE analysis. Compared to the previously constructed pJC340 vector, a pACYC184 derivative expressing M.TneDI from a tet promotor, the newly constructed pDH21 vector improved the expression of the methylase about fourfold, allowing complete protection of DNA substrates. This study not only demonstrates a practical approach to overexpressing potential lethal proteins in E. coli but also delivers a production strain of M.TneDI that may be useful in various in vitro methylation applications.

The [4Fe-4S]-cluster coordination of [FeFe]-hydrogenase maturation protein HydF as revealed by EPR and HYSCORE spectroscopies.

[FeFe] hydrogenases are key enzymes for bio(photo)production of molecular hydrogen, and several efforts are underway to understand how their complex active site is assembled. This site contains a [4Fe-4S]-2Fe cluster and three conserved maturation proteins are required for its biosynthesis. Among them, HydF has a double task of scaffold, in which the dinuclear iron precursor is chemically modified by the two other maturases, and carrier to transfer this unit to a hydrogenase containing a preformed [4Fe-4S]-cluster. This dual role is associated with the capability of HydF to bind and dissociate an iron-sulfur center, due to the presence of the conserved FeS-cluster binding sequence CxHx(46-53)HCxxC. The recently solved three-dimensional structure of HydF from Thermotoga neapolitana described the domain containing the three cysteines which are supposed to bind the FeS cluster, and identified the position of two conserved histidines which could provide the fourth iron ligand. The functional role of two of these cysteines in the activation of [FeFe]-hydrogenases has been confirmed by site-specific mutagenesis. On the other hand, the contribution of the three cysteines to the FeS cluster coordination sphere is still to be demonstrated. Furthermore, the potential role of the two histidines in [FeFe]-hydrogenase maturation has never been addressed, and their involvement as fourth ligand for the cluster coordination is controversial. In this work we combined site-specific mutagenesis with EPR (electron paramagnetic resonance) and HYSCORE (hyperfine sublevel correlation spectroscopy) to assign a role to these conserved residues, in both cluster coordination and hydrogenase maturation/activation, in HydF proteins from different microorganisms.

Structure of a novel α-amylase AmyB from Thermotoga neapolitana that produces maltose from the nonreducing end of polysaccharides.

An intracellular α-amylase, AmyB, has been cloned from the hyperthermophilic bacterium Thermotoga neapolitana. AmyB belongs to glycoside hydrolase family 13 and liberates maltose from diverse substrates, including starch, amylose, amylopectin and glycogen. The final product of AmyB is similar to that of typical maltogenic amylases, but AmyB cleaves maltose units from the nonreducing end, which is a unique property of this α-amylase. In this study, the crystal structure of AmyB from T. neapolitana has been determined at 2.4 Šresolution, revealing that the monomeric AmyB comprises domains A, B and C like other α-amylases, but with structural variations. In the structure, a wider active site and a putative extra sugar-binding site at the top of the active site were found. Subsequent biochemical results suggest that the extra sugar-binding site is suitable for recognizing the nonreducing end of the substrates, explaining the unique activity of this enzyme. These findings provide a structural basis for the ability of an α-amylase that has the common α-amylase structure to show a diverse substrate specificity.

Improved transferase/hydrolase ratio through rational design of a family 1 ß-glucosidase from Thermotoga neapolitana.

Alkyl glycosides are attractive surfactants because of their high surface activity and good biodegradability and can be produced from renewable resources. Through enzymatic catalysis, one can obtain well-defined alkyl glycosides, something that is very difficult to do using conventional chemistry. However, there is a need for better enzymes to get a commercially feasible process. A thermostable ß-glucosidase from the well-studied glycoside hydrolase family 1 from Thermotoga neapolitana, TnBgl1A, was mutated in an attempt to improve its value for synthesis of alkyl glycosides. This was done by rational design using prior knowledge from structural homologues together with a recently generated model of the enzyme in question. Three out of four studied mutations increased the hydrolytic reaction rate in an aqueous environment, while none displayed this property in the presence of an alcohol acceptor. This shows that even if the enzyme resides in a separate aqueous phase, the presence of an organic solvent has a great influence. We could also show that a single amino acid replacement in a less studied part of the aglycone subsite, N220F, improves the specificity for transglycosylation 7-fold and thereby increases the potential yield of alkyl glycoside from 17% to 58%.

Biochemical characterization of a thermostable ß-1,3-xylanase from the hyperthermophilic eubacterium, Thermotoga neapolitana strain DSM 4359.

The biochemical properties of a putative ß-1,3-xylanase from the hyperthermophilic eubacterium Thermotoga neapolitana DSM 4359 were determined from a recombinant protein (TnXyn26A) expressed in Escherichia coli. This enzyme showed specific hydrolytic activity against ß-1,3-xylan and released ß-1,3-xylobiose and ß-1,3-xylotriose as main products. It displayed maximum activity at 85 °C during a 10-min incubation, and its activity half-life was 23.9 h at 85 °C. Enzyme activity was stable in the pH range 3-10, with pH 6.5 being optimal. Enzyme activity was significantly inhibited by the presence of N-bromosuccinimide (NBS). The insoluble ß-1,3-xylan K m value was 10.35 mg/ml and the k cat value was 588.24 s(-1). The observed high thermostability and catalytic efficiency of TnXyn26A is both industrially desirable and also aids an understanding of the chemistry of its hydrolytic reaction.

Crystallization and preliminary X-ray crystallographic analysis of the ß-N-acetylglucosaminidase CbsA from Thermotoga neapolitana.

The ß-N-acetylglucosaminidase CbsA was cloned from the thermophilic Gram-negative bacterium Thermotoga neapolitana. Although CbsA contains a family 3 glycoside hydrolase-type (GH3-type) catalytic domain, it can be distinguished from other GH3-type ß-N-acetylglucosaminidases by its high activity towards chitobiose. The homodimeric CbsA contains a unique domain at the C-terminus for which the three-dimensional structure is not yet known. In this study, CbsA was overexpressed and the recombinant protein was purified using Ni-NTA affinity and gel-filtration chromatography. The purified CbsA protein was crystallized using the vapour-diffusion method. A diffraction data set was collected to a resolution of 2.0 Å at 100 K. The crystal belonged to space group R32. To obtain initial phases, the crystallization of selenomethionyl-substituted protein and the production of heavy-atom derivative crystals are in progress.

Cloning and biochemical characterization of a glucosidase from a marine bacterium Aeromonas sp. HC11e-3.

By constructing the genomic library, a ß-glucosidase gene, with a length of 2,382 bp, encoding 793 amino acids, designated bgla, is cloned from a marine bacterium Aeromonas sp. HC11e-3. The enzyme is expressed successfully in the recombinant host Escherichia coli BL21 (DE3) and purified using glutathione affinity purification system. It shows the optimal activity at pH 6, 55 °C and hydrolyzes aryl-glucoside specially. Ca(2+), Mn(2+), Zn(2+), Ba(2+), Pb(2+), Sr(2+) can activate the enzyme activity, whereas SDS, EDTA, DTT show slight inhibition to the enzyme activity. Homologous comparing shows that the enzyme belongs to glycosyl hydrolase family 3, exhibiting 46 % identity with a fully characterized glucosidase from Thermotoga neapolitana DSM 4359. Such results provide useful references for investigating other glucosidases in the glycosyl family 3 as well as developing glucosidases using in suitable industrial area.

Crystal structure and thermostability of a putative α-glucosidase from Thermotoga neapolitana.

Glycoside hydrolase family 4 (GH4) represents an unusual group of glucosidases with a requirement for NAD(+), Mn(2+), and reducing conditions. We found a putative α-glucosidase belonging to GH4 in hyperthermophilic Gram-negative bacterium Thermotoga neapolitana. In this study, we recombinantly expressed the putative α-glycosidase from T. neapolitana, and determined the crystal structure of the protein at a resolution of 2.0Å in the presence of Mn(2+) but in the absence of NAD(+). The structure showed the dimeric assembly and the Mn(2+) coordination that other GH4 enzymes share. In comparison, we observed structural changes in T. neapolitana α-glucosidase by the binding of NAD(+), which also increased the thermostability. Numerous arginine-mediated salt-bridges were observed in the structure, and we confirmed that the salt bridges correlated with the thermostability of the proteins. Disruption of the salt bridge that linked N-terminal and C-terminal parts at the surface dramatically decreased the thermostability. A mutation that changed the internal salt bridge to a hydrogen bond also decreased the thermostability of the protein. This study will help us to understand the function of the putative glucosidase and the structural features that affect the thermostability of the protein.

Aglycone specificity of Thermotoga neapolitana ß-glucosidase 1A modified by mutagenesis, leading to increased catalytic efficiency in quercetin-3-glucoside hydrolysis.

BACKGROUND: The thermostable ß-glucosidase (TnBgl1A) from Thermotoga neapolitana is a promising biocatalyst for hydrolysis of glucosylated flavonoids and can be coupled to extraction methods using pressurized hot water. Hydrolysis has however been shown to be dependent on the position of the glucosylation on the flavonoid, and e.g. quercetin-3-glucoside (Q3) was hydrolysed slowly. A set of mutants of TnBgl1A were thus created to analyse the influence on the kinetic parameters using the model substrate para-nitrophenyl-ß-D-glucopyranoside (pNPGlc), and screened for hydrolysis of Q3. RESULTS: Structural analysis pinpointed an area in the active site pocket with non-conserved residues between specificity groups in glycoside hydrolase family 1 (GH1). Three residues in this area located on ß-strand 5 (F219, N221, and G222) close to sugar binding sub-site +2 were selected for mutagenesis and amplified in a protocol that introduced a few spontaneous mutations. Eight mutants (four triple: F219L/P165L/M278I, N221S/P165L/M278I, G222Q/P165L/M278I, G222Q/V203M/K214R, two double: F219L/K214R, N221S/P342L and two single: G222M and N221S) were produced in E. coli, and purified to apparent homogeneity. Thermostability, measured as Tm by differential scanning calorimetry (101.9°C for wt), was kept in the mutated variants and significant decrease (ΔT of 5-10°C) was only observed for the triple mutants. The exchanged residue(s) in the respective mutant resulted in variations in KM and turnover. The KM-value was only changed in variants mutated at position 221 (N221S) and was in all cases monitored as a 2-3 × increase for pNPGlc, while the KM decreased a corresponding extent for Q3.Turnover was only significantly changed using pNPGlc, and was decreased 2-3 × in variants mutated at position 222, while the single, double and triple mutated variants carrying a mutation at position 221 (N221S) increased turnover up to 3.5 × compared to the wild type. Modelling showed that the mutation at position 221, may alter the position of N291 resulting in increased hydrogen bonding of Q3 (at a position corresponding to the +1 subsite) which may explain the decrease in KM for this substrate. CONCLUSION: These results show that residues at the +2 subsite are interesting targets for mutagenesis and mutations at these positions can directly or indirectly affect both KM and turnover. An affinity change, leading to a decreased KM, can be explained by an altered position of N291, while the changes in turnover are more difficult to explain and may be the result of smaller conformational changes in the active site.

Cloning and characterization of the TneDI restriction: modification system of Thermotoga neapolitana.

A putative Type II restriction-modification system of Thermotoga neapolitana, TneDI, was cloned into Escherichia coli XL1-Blue MRF' and characterized. Gene CTN_0339 specifies the endonuclease R.TneDI, while CTN_0340 encodes the cognate DNA methyltransferase M.TneDI. Both enzymes were purified simply by heating the cell lysates of E. coli followed by centrifugation. The enzymes were active over a broad range of temperatures, from 42°C to at least 77°C, with the highest activities observed at 77°C. R.TneDI cleaved at the center of the recognition sequence (CG↓CG) and generated blunt-end cuts. Overexpression of R.TneDI in BL21(DE3) was confirmed by both SDS-PAGE and Western blotting.

Expression, crystallization and preliminary X-ray diffraction studies of thermostable ß-1,3-xylanase from Thermotoga neapolitana strain DSM†4359.

Crystals of ß-1,3-xylanase (1,3-ß-D-xylan xylanohydrolase; EC 3.2.1.32) from Thermotoga neapolitana strain DSM 4359 with maximum dimensions of 0.2×0.1×0.02 mm were grown using the sitting-drop vapour-diffusion method at 293 K over 24 h. The crystals diffracted to a resolution of 1.82 Å, allowing structure determination. The crystals belonged to space group P2(1), with unit-cell parameters a=39.061, b=75.828, c=52.140 Å; each asymmetric unit cell contained a single molecule.