2.1. Expression, purification and crystallization of TtLMCO1

Recombinant TtLMCO1 was expressed in Pichia pastoris X33 and deglycosylated as described previously (Zerva et al., 2019). The copper-loaded enzyme was purified from the culture supernatant after supplementation of the culture with 0.025 mM copper(II) sulfate (Zerva et al., 2019). Immobilized metal-affinity chromatography (IMAC) with Co²⁺ resin was applied to separate endoglycosidase H from the deglycosylated enzyme. A final polishing step was performed by size-exclusion chromatography on a 16/60 Sephacryl column. The purified enzyme was concentrated to 16 mg ml⁻¹ in 20 mM Tris–HCl pH 8.0 and was submitted to crystallization trials using the JCSG-plus and PACT premier screening kits (Molecular Dimensions). Equal volumes (0.7 µl) of enzyme solution and reservoir solution were mixed in each well of a 96-well plate (SWISSCI) implementing the sitting-drop vapour-diffusion method. After 10–12 days, protein crystals with an irregular rod-like shape and a characteristic light blue colour appeared in several crystallization conditions, such as 0.2 M ammonium chloride, 0.1 M 2-(N-morpholino)ethanesulfonic acid (MES) pH 6.0, 20%(w/v) PEG 6000 (Supplementary Fig. S1a). In an effort to obtain larger crystals, optimization was performed for this condition by adjusting the pH to 5.5 (Supplementary Fig. S1b). For X-ray data collection, crystals were mounted on litholoops and transferred into mother liquor containing 20% glycerol as a cryoprotectant before being flash-cooled in liquid nitrogen. X-ray data were collected on beamline P13 at the PETRA III storage ring, DESY, Hamburg, Germany operated by EMBL Hamburg (Cianci et al., 2017).

2.2. Structure determination

X-ray data were processed with XDS (Kabsch, 2010) and scaled with AIMLESS (Evans & Murshudov, 2013), which is included in the CCP4 suite (Agirre et al., 2023). Although the TtLMCO1 crystals diffracted to 1.3 Å resolution, data beyond 1.9 Å resolution were excluded to improve the data-processing statistics (the data-resolution cutoff criteria were 〈I/σ(I)〉 > 1.5 and CC_1/2 > 0.5). The crystal was assigned to space group P4₃, with unit-cell parameters a = b = 74.85, c = 118.99 Å and one molecule in the asymmetric unit. Data-collection statistics are shown in Table 1.

The closest homologue with an experimentally determined structure displayed low sequence identity to TtLMCO1 (PDB entry 1aoz, with 28% sequence identity over 85% coverage; Messerschmidt et al., 1992). Initial attempts to use it as a template for molecular replacement (MR) in Phaser (McCoy et al., 2007) provided a solution with R_work and R_free values of 0.46 and 0.49, respectively (LLG = 56.09, TFZ = 6.8), while the resulting electron-density maps indicated several chain breaks and clashes with symmetry-related molecules. Further attempts to autobuild the protein model using Buccaneer (Cowtan, 2012) led to an improved model and decreased R_work and R_free to 0.38 and 0.39, respectively. However, subsequent rounds of manual model building and real-space and reciprocal-space refinement failed to further decrease the R factors. To address this, an AlphaFold2 (Jumper et al., 2021) prediction was generated and was instead used as a model for MR. The predicted model was assessed according to the predicted aligned error plot and the confidence measure (pLDDT) for each residue (Supplementary Fig. S2). Regions of the predicted model with poor pLDDT score (pLDDT < 50) were omitted from the MR model; specifically, residues 1–15 and 179–251 as well as the C-terminal residues 601–630. Using this model for MR, Phaser (McCoy et al., 2007) found a unique solution with high LLG (14139) and TFZ (107.5) scores. Manual model building and N-glycan addition were performed with Coot (Emsley et al., 2010). Structure refinement was performed with REFMAC (Murshudov et al., 2011). For cross-validation, 5% of the data were excluded from the refinement for R_free calculations (Brünger, 1992). Solvent molecules were added using REFMAC and inspected manually using Coot. H atoms were added at riding positions in the final step of the refinement. The quality of the final model was evaluated using MolProbity (Chen, Arendall et al., 2010). Refinement statistics are shown in Table 2. The coordinates and structure factors have been deposited in the PDB with accession code 7zn6. Graphical display of the structure and analysis were performed with PyMOL 2.0 (Schrödinger).

2.3. Solvent-channel characterization

The CAVER 3.0 PyMOL plugin (Pavelka et al., 2016) was used for solvent-channel identification. The starting position for each tunnel estimation was defined using the coordinates of the T2 Cu or the coordinates of the O1 atom of dioxygen as input for the T2 and T3 tunnels, respectively. Default values were used for tunnel estimation. The results for each tunnel were evaluated in terms of average tunnel bottleneck, average tunnel length and average tunnel throughput. The tunnels with the minimum tunnel length and the highest values for tunnel throughput were selected and presented.

2.4. Substrate screening

All substrates for investigation of the substrate scope of TtLMCO1 were purchased from Merck KGaA (Darmstadt, Germany) or Thermo Fisher Scientific (Waltham, Massachusetts, USA) and were of the highest purity available. The ability of TtLMCO1 to oxidize different substrates was explored in 24 h reactions. The tested substrates (2 mM) were mixed with the enzyme (0.1 U, measured using ABTS as a substrate, corresponding to 16 µg protein) in 50 mM phosphate–citrate buffer pH 5.0 and incubated for 24 h at 40°C and 800 rev min⁻¹ in an Eppendorf thermomixer. The final volume of the reaction was 250 µl. The reaction parameters (i.e. substrate concentration and temperature) had already been optimized, as described in a previous publication (Zerva et al., 2019). The UV–Vis spectra (250–750 nm) of the reactions and their respective controls with heat-inactivated enzyme were recorded after 15 min and 24 h of reaction using a polystyrene flat-bottom Greiner CELLSTAR 96-well plate (Greiner Bio-One GmbH, Austria) in a SpectraMax 250 microplate reader (Molecular Devices, California, USA) to determine differences in absorbance maxima. 1 U is defined as the amount of enzyme that oxidizes 1 µmol of substrate per minute.

2.5. Molecular-docking simulations

Docking simulations were performed in YASARA Structure (Krieger & Vriend, 2014). The ligand structures were retrieved from PubChem (Kim et al., 2021). Ligand structures were cleaned and their hydrogen-bonding network was optimized (Krieger & Vriend, 2014). Their geometries were also optimized using semi-empirical quantum-mechanics calculations. The structure of TtLMCO1 (PDB entry 7zn6) was used after removing all heteroatoms and waters. Polar H atoms were added and the hydrogen network was optimized before proceeding with docking simulations (Krieger et al., 2012). All structures were curated with AutoSMILES (Jakalian et al., 2002) before docking simulations. The charge assignment for ligands was calculated at pH 4.5, at which TtLMCO1 displays the highest activity (Zerva et al., 2019). The charge assignment for ferulic acid that was used in docking simulations for ascorbate oxidase from C. pepo was calculated at pH 6.0, at which the enzyme displays the highest activity (Itoh et al., 1995). Global docking in a 10³ Å simulation cell defined around the binding site was performed employing AutoDock Vina, completing 25 runs per simulation (the default settings; Trott & Olson, 2010).

The results were clustered and evaluated based on binding energies, dissociation constants and ligand orientation. Ligand-docking poses away from the binding site or with inappropriate orientation were rejected. The results with the highest YASARA scores (binding energy) and the lowest K_d (in the micromolar range) were selected and discussed.

3.1. Overall crystal structure of TtLMCO1

The refined crystal structure of TtLMCO1 (Fig. 1) contains 576 residues arranged in three cupredoxin-like domains. Domain A includes residues 11–134, domain B includes residues 135–372 and domain C includes residues 373–602. Residues 209–224 were not included in the final model due to insufficient electron density, similarly to the first ten N-terminal and the last 20 C-terminal residues. A disulfide bond is formed between Cys28 and Cys236, stabilizing the relative orientation of domains A and B.

Figure 1 Cartoon representation of the TtLMCO1 crystal structure. Each domain (A, B and C) is coloured differently: in cyan, raspberry and green, respectively. The disulfide bond between Cys28 and Cys236 is shown in stick representation. Copper ions and a dioxygen molecule located at the TNC are shown as brown and red spheres, respectively. Glycans are depicted as cyan sticks. (a) A NAG molecule is modelled into a 2Fo − Fc electron-density map contoured at 1σ. A hydrogen bond is formed by the main-chain carbonyl O atom of Ile16 and the N2 atom of NAG (yellow dotted line). (b) Two NAG molecules are modelled into a 2Fo − Fc electron-density map contoured at 1σ. A hydrogen bond is formed between the OD1 atom of Asp420 and the N2 atom of NAG (yellow dotted line). A CH–π interaction is formed between the phenyl group of Tyr595 and the D-glycopyranose ring of NAG (red dotted line).

A preliminary search using the NetNGlyc server proposed that TtLMCO1 has three putative N-glycosylation sites (Asn37, Asn65 and Asn602; Gupta & Brunak, 2002). In accordance with the bioinformatic analysis, the crystal structure revealed two N-glycosylation sites, including Asn37 [one N-acetylglucosamine (NAG) molecule] and Asn65 (two NAG molecules). The N atom of the NAG residue on Asn37 forms a hydrogen bond to the backbone-carbonyl O atom of Ile16 (Fig. 1a). In addition, the glycosylation on Asn65 seems to fix the relative positioning of domains A and C in the crystal lattice through the formation of a hydrogen bond between the N2 atom of the second NAG molecule and the OD2 atom of Asp420. Finally, a CH–π interaction between Tyr595 and the first NAG molecule leads to the stabilization of the C-terminus of the enzyme (Fig. 1b).

The implications of N-glycosylation for the folding, stability and activity of laccases have been revealed in previous reports (Ernst et al., 2018; Arregui et al., 2019; Bento et al., 2010). A recent crystallographic study of another asco-laccase from T. thermophila (MtL) identified several glycosylation sites which are rather conserved in all known asco-laccase structures and suggested that N-glycans should contribute to the relative stabilization of protein domains A, B and C (Ernst et al., 2018). Moreover, the study suggests that the solvent-exposed glycans could mediate the interaction of the laccase with large biopolymers or carbohydrate-rich substrates such as lignocellulose. TtLMCO1 has considerably fewer N-glycosyl­ation sites compared with other asco-laccases; however, they still seem to contribute to conformational stability as discussed above. As shown in Supplementary Table S1, N-glycosylation on Asn37 is only conserved in MtL (Asn61) and Botrytis aclada laccase (BaL; Asn55), despite the fact that the asparagine residue is conserved in all asco-laccases, while Asn65 is not conserved in other asco-laccases.

A common feature of several MCOs is the development of a multimeric arrangement, as mentioned in several studies (Hakulinen & Rouvinen, 2015). Asco-laccases regularly form dimeric assemblies in a head-to-head arrangement of the T1 pockets of the enzyme (Ernst et al., 2018). Moreover, a dodecameric arrangement of a bacterial MCO in its active form has recently been reported (Paavola et al., 2021). Analysis of the TtLMCO1 structure by the Protein Interfaces, Surfaces and Assemblies (PISA) server (Krissinel & Henrick, 2007) did not suggest dimer formation, while the interactions between TtLMCO1 monomers are a result of crystal packing. The monomeric state of TtLMCO1 was also corroborated by gel-filtration chromatography (data not shown).

To date, one MCO structure and four laccase structures from the Ascomycota family have been deposited in the PDB (Hakulinen & Rouvinen, 2015; Ernst et al., 2018). These are laccases from Thielavia arenaria (TaL; PDB entry 3pps), Botrytis aclada (BaL; PDB entry 3sqr), Melanocarpus albomyces (MaL; PDB entry 1gw0) and Myceliopthora thermo­phila (MtL; PDB entry 6f5k) and an MCO from Aspergillus niger (AnMCO; PDB entry 5lm8). Among these, the DALI server (Holm, 2020) only identified TaL asco-laccase as a structural homologue, while all other hits displayed low sequence identity to TtLMCO1 (Supplementary Fig. S3). The closest structural homologue, an ascorbate oxidase from C. pepo (PDB entry 1aoz), shares only 30% sequence identity with TtLMCO1. Other structural homologues of TtLMCO1 include five laccases from Basidiomycota species (Metuloidea murashkinskyi, Trametes hirsuta, T. versicolor, Coprinus cinereus and Cerrena sp.), a plant laccase from Zea mays and two bacterial laccases (from Pediococcus acidilactici and a marine bacterium of unknown classification) (Supplementary Table S2).

As mentioned in Section 2, the closest structural homologue (PDB entry 1aoz) failed to generate a robust MR model. Post analysis involving the superposition of the two experimentally determined structures revealed several differences, mainly in loop regions such as loop 382–426 in C. pepo ascorbate oxidase, which is much more elongated than the corresponding TtLMCO1 loop, and further clashes in TtLMCO1 loop 529–539. However, the most pronounced difference that could account for the unsuccessful MR attempts is located at the C-terminus of the two enzymes (Supplementary Fig. S4), a region of interest in TtLMCO1 that is further analysed in Section 3.3. The TtLMCO1 structure was thus solved using an AlphaFold2 prediction, which when superimposed with the final refined experimental TtLMCO1 model exhibits an r.m.s.d. on C^α atoms of 1.3 Å, in contrast to C. pepo oxidase, which has an r.m.s.d. on C^α atoms of 2.5 Å. Superposition of the AlphaFold2 prediction with the final refined structure of TtLMCO1 did not indicate any significant structural differences between the main-chain conformations of the two models, with the exception of the C-terminal region (Supplementary Fig. S4).

3.2. Copper sites

3.2.1. T1 copper site

In the T1 site, the copper ion is coordinated by the ND1 atoms of His564 (2.1 Å distance) and His483 (2.0 Å distance) and by the thiolate group of Cys559 (2.2 Å distance), forming a trigonal plane. Also, a methionine residue (Met569) is positioned axially to the T1 copper at a distance of 3.15 Å (Fig. 2a). The nature of the axially positioned residue has been correlated with the redox potential (E^o) of the enzyme in some studies (Rodgers et al., 2010). The methionine residue identified in the TtLMCO1 structure is typically found in laccases with low E^o (<+460 mV) from plants and bacteria (Pardo & Camarero, 2015). However, reports of the redox potentials of other laccases do not support a conclusive correlation of redox potential and the nature of the axial T1 copper ligand (Ernst et al., 2018). It is interesting to note that among the closest structural homologues, the only MCO with a methionine in the axial position is the ascorbate oxidase from C. pepo. The two enzymes share a low redox potential (Murata et al., 2006), but they present significantly different biochemical properties and substrate specificity, supporting the idea that the biochemical properties of LMCOs and their substrate scopes are defined by multiple structural attributes.

Figure 2 Representation of the substrate-binding site of TtLMCO1. (a) T1 copper (sphere) with coordinating His483, Cys559 and His564 (sticks). Coordination bonds are shown as grey dashed lines. Met569 is axially positioned to the T1 copper. (b) Semi-transparent surface representation of the binding site in TtLMCO1. The side chains of amino acids forming the substrate-binding site are shown as wheat sticks.

According to known crystal structures of MCOs complexed with ligands, the substrate-binding pocket, where oxidation occurs, is adjacent to the T1 copper site (Hakulinen & Rouvinen, 2015). TtLMCO1 was superposed onto the structure of 2,6-dimethoxyphenol (2,6-DMP)-bound MaL (PDB entry 3fu7), which is the first reported structure of a ligand-bound asco-laccase (Kallio et al., 2009). The TtLMCO1 residues potentially forming the substrate-binding site include several hydrophobic residues (Phe169, Trp171, Leu405, Trp407, Tyr473 and Met567) and also charged amino acids (Glu481, Arg329 and Glu174 along with His564) (Fig. 2b). According to the structure of 2,6-DMP-bound MaL, His564 that is implicated in T1 copper coordination should contribute to substrate binding and is considered to be the primary electron acceptor of the oxidized substrate (Kallio et al., 2009). In other asco-laccases, a carboxylate residue (Glu or Asp), perpendicular to the trigonal plane of the T1 copper, contributes to the polar recognition of the substrate (Hakulinen & Rouvinen, 2015; Supplementary Fig. S5). There is also one reported case of an asco-laccase in which the carboxylate residue is replaced by a histidine (Ernst et al., 2018). In TtLMCO1, a hydrophobic leucine residue (Leu259) is instead identified, similar to C. pepo and in contrast to other asco-laccases.

3.2.2. Trinuclear copper site (TNC)

Similarly to other laccases, the trinuclear copper site (TNC) of TtLMCO1 is formed by two T3 coppers along with one T2 copper coordinated by histidine residues. The electrons abstracted from the oxidized substrate at the T1 site are transferred to the TNC through a highly conserved His-Cys-His motif (His558-Cys559-His560 in TtLMCO1) that is considered to act as an electron shuttle (Jones & Solomon, 2015; Fig. 3). A dioxygen molecule is modelled between the T3a and T3b coppers rather than a water molecule or a hydroxyl anion, since it fits more accurately into the ellipsoid shape of the electron density (Supplementary Fig. S6), while the peaks in the difference electron-density map disappear. The presence of a dioxygen molecule between the T3 coppers corresponds to the fully reduced state of the enzyme according to Polyakov et al. (2019). In addition to this oxygen molecule, the coordination sphere of the T3 coppers includes the N atoms of His117, His488 and His558 for the T3a copper and the N atoms of His71, His115 and His560 for the T3b copper. The T2 copper is linearly coordinated by the N atoms of His69 and His486 and forms charge–dipole interactions with W1 (Fig. 3). Interatomic distances between the T2 and T3 Cu atoms and the dioxygen molecule are shown in Supplementary Table S3. Extensive serial crystallography studies on basidio-laccase from Steccherinum murashkinskyi highlight that the reduction of copper ions can be induced by increasing the radiation dose on a protein crystal (Polyakov et al., 2017, 2019). The linear coordination of the T2 copper by the N atoms of His69 and His486 is a strong indication that the T2 copper is present in the reduced state. Analysis of the metal-binding sites using the CheckMyMetal server verified the coordination geometry of the T2 copper ion (Gucwa et al., 2023).

Figure 3 TtLMCO1 copper sites. Copper ions in the TNC (left) are shown as brown spheres and are coordinated by histidine residues shown as wheat and magenta sticks. A dioxygen molecule is located between the T3 coppers, and a water molecule (W1) is modelled next to the T2 copper ion. Coordination bonds are shown as grey dashed lines, while the electrostatic interaction of W1 with T2 is shown as a marine dashed line. His558, Cys559 and His560, which form the `histidine bridge' that enables electron transfer from the T1 copper site to the TNC, are shown as magenta sticks.

3.3. Solvent tunnels

Apart from electron transfer between the two copper sites, transportation of protons is also necessary to complete the reduction of the dioxygen molecule to two water molecules in the TNC. Solvent tunnels or channels have been reported both for basidiomycete laccases and asco-laccases, assisting proton transfer to the TNC of MCOs either by delivering protons to the T2 copper (T2 copper channels; Quintanar et al., 2005) or by the direct dispatch of protons to the dioxygen molecule between the T3 coppers (T3 copper channels). The latter channels are commonly found in basidiomycete laccases (Wu et al., 2018; Polyakov et al., 2017). Residues with carboxylate side chains exposed on the surface of the solvent channels are considered to be involved in the mechanism of proton transfer (Enguita et al., 2003; Chen, Durão et al., 2010).

The crystal structure of TtLMCO1 was thus used to trace the solvent tunnels providing access to the trinuclear site. The predominant results from CAVER 3.0 analysis of the pathway of the T2 and T3 tunnels are shown in Fig. 4. The average length of the T2 tunnel is estimated at 8.2 Å, while the lowest bottleneck radius is calculated at 1.03 Å (Table 3). Asp82 and Asp552 form the inner part of the T2 tunnel, while His491 and Ser74 are located at the entrance to the tunnel. The average length of the T3 tunnel is estimated at 8.1 Å, while the lowest bottleneck radius is calculated as 0.98 Å (Table 3). The side chains of His117, Met565, Glu570 and Asp416 are exposed to the solvent inside the T3 tunnel.

Figure 4 Graphical representation of TtLMCO1 tunnels estimated by the CAVER 3.0 PyMOL plugin. The T2 and T3 tunnels are shown as red and blue spheres, respectively. Copper ions are shown as brown spheres and the side chains of the residues forming the tunnels are shown as wheat sticks.

The T2 tunnel has previously been suggested to participate in proton transfer to the TNC (Quintanar et al., 2005), as well as in copper ion restoration in T2-depleted enzyme (Osipov et al., 2015). In TtLMCO1, the entrance to the T2 tunnel is partially blocked by His491, which potentially acts as a gate residue (Fig. 4). The low bottleneck radius of the T2 tunnel compared with the radius of a water molecule (1.03 Å) indicates that conformational changes are necessary for molecule transfer. Furthermore, inside the T2 tunnel a water molecule (W1) forms hydrogen bonds to the N atom of the backbone of Gly72 and water molecules W2 and W3 (Fig. 5). The side chain of Asp82 contributes to the stabilization of this network by interacting with W3 and the ND1 atom of His488 (Fig. 5). Polyakov and coworkers suggest that this aspartic acid residue is present in many laccase structures, contributing to the coordination of the water molecule that interacts with the T2 copper. W1 is 2.77 Å away from the T2 copper, which is too far for a coordination bond to occur. In the oxidized state of the enzyme, however, this water is assumed to form a coordination bond with the T2 copper, enabling planar four-coordination of the copper, which leads to subsequent cleavage of the O—O bond (Polyakov et al., 2017).

Figure 5 Detailed view of the TNC. Water molecules are shown as red spheres, hydrogen bonds as yellow dashed lines and coordination bonds as grey dashed lines. A water network (W4, W5 and W6) in the T3 channel is formed with the assistance of the hydrophilic side chain of Glu570 and Asp416. A methionine residue (Met565) is shown in place of Glu498 that is present in the CotA laccase from Bacillus subtilis (grey sticks).

Oxygen and water molecules are transferred through the T3 tunnel to the TNC. Several studies, mostly on basidiomycete laccases, support the presence of a carboxylate residue in the T3 channel that aids the transfer of protons to the dioxygen molecule between the T3 coppers. Mutational studies on the CotA laccase from Bacillus subtilis indicate a major impact of Glu498 on the catalytic mechanism of the enzyme, implying involvement of this residue in the direct transfer of a proton at the dioxygen molecule (Chen, Durão et al., 2010). A glutamate residue is generally conserved in this position in other basidio-laccases (Bento et al., 2010). In TtLMCO1, a methionine (Met565) is present at this position instead of glutamate (Fig. 5). However, another glutamate (Glu570) is located at the entrance to the T3 tunnel next to an aspartic acid residue (Asp416). A water molecule (W6) is coordinated by the O atoms of the two side chains and participates in a network of water molecules penetrating the T3 channel (W4, W5 and W6). This supports the statement of Polyakov and coworkers that the nature of the negatively charged hydrophilic groups (Glu or Asp) assists the formation of the T3 water channel through the coordination of water molecules that penetrate deeply into the TNC (Polyakov et al., 2017, 2019).

3.4. Role of the C-terminus in TtLMCO1

A common feature of reported asco-laccase structures is that the C-terminus blocks the T3 tunnel that gives access to the TNC of the enzyme (Kallio et al., 2009; Ernst et al., 2018; Hakulinen et al., 2002; Ferraroni et al., 2017; Osipov et al., 2014). Indeed, superposition of the BaL, TaL, MaL, MtL and AnL structures reveals a conserved four-amino-acid sequence (DSGL/I) that penetrates the T3 tunnel and is referred to as the C-plug. Multiple sequence alignment of TtLMCO1 with asco-laccases reveals a similar motif at its C-terminus (DSGH; Supplementary Fig. S7). The most important difference compared with other asco-laccases is that the final amino acid is a hydrophilic histidine and not an aliphatic leucine or isoleucine. Mutation of the terminal leucine to an alanine in MaL resulted in breakage of the hydrogen bond between the C-terminus of the enzyme and the T3 copper-coordinating His140 (Andberg et al., 2009). Despite the slightly altered conformation of the TNC, the activity of the enzyme towards 2,6-DMP did not change significantly and the redox potential of the enzyme also remained unaffected. Given that the terminal leucine is conserved among asco-laccases, TtLMCO1 could represent a naturally occurring mutant with a modified C-terminus, resulting in a modified, but still functional, TNC.

Furthermore, since the last 20 amino acids of TtLMCO1 were not included in the final structure due to a lack of electron density, there is no indication that the C-terminus of TtLMCO1 penetrates the T3 tunnel. However, superposition of the TtLMCO1 structure with those of the aforementioned asco-laccases highlights some interesting structural differences. A disulfide bridge stabilizes the position of an α-helix of the third domain with respect to the first domain of asco-laccases (Fig. 6b). In TtLMCO1 the cysteine residues are replaced by a tryptophan (Trp90, domain A) and a threonine (Thr594, domain C) (Fig. 6). Moreover, the C-terminal loop makes a β-turn after Tyr595, possibly forced by the two NAG molecules from glycosylation on Asn65 that interact with Tyr595 and that are absent in other asco-laccases. This may affect the ability of the C-terminus to act as a plug for the T3 channel, as opposed to the other asco-laccases, in which the C-terminus is oriented towards the T3 tunnel (Fig. 6b).

Figure 6 (a) Cartoon representation of the C-terminus of TtLMCO1. The side chains of Trp90, Thr594 and Tyr595 are shown as wheat sticks. Two NAG molecules linked to Asn65 are shown as cyan sticks. (b) Superposition of the C-terminus of TtLMCO1 with the C-termini of other asco-laccases (BaL, TaL, MaL, MtL and AnL) shown in cartoon representation. TtLMCO1 is coloured wheat, while the other asco-laccases are coloured shades of green. A cysteine bridge shown as sticks fixes the position of an α-helix at the C-terminus, allowing the formation of the C-plug.

3.5. Activity of TtLMCO1 against a variety of laccase substrates

Although the substrate specificity of TtLMCO1 for various common laccase substrates was determined in a previous study (Zerva et al., 2019), a more thorough exploration of the substrate scope of the enzyme was performed in this work. Due to a lack of available data on the molar absorptivities of the oxidized species for many LMCO substrates, their oxidation was only assessed based on absorbance differences before and after incubation with TtLMCO1, and the results are shown in Table 4. It has to be noted that since the oxidized products of each tested compound might have significantly variable absorbance properties, the results should be treated as qualitative. The substrate scope of TtLMCO1 verifies our previous results and confirms that the promiscuity of the enzyme clearly distinguishes it from ascorbate oxidases, since these enzymes are not able to oxidize phenolic compounds. It is also shown that the existence of an ortho-hydroxy group is crucial for oxidation: pyrogallol and catechol, which contain ortho-hydroxy groups, are readily oxidized, but this is not the case for resorcinol and hydroquinone, which contain meta- and para-hydroxy groups, respectively. The same is also true for the existence of a methoxy group in an ortho-position, since 2,6-DMP, guaiacol and ferulic and caffeic acids are also rather easily oxidized compared with the corresponding unsubstituted compounds. This is in accordance with the rather low E⁰ of the enzyme: the presence of electron-donating groups, such as hydroxy and methoxy groups, on the phenol ring decreases the E⁰ of the compound [for example, the E⁰ of catechol is 0.53 V versus the normal hydrogen electrode (NHE), compared with an E⁰ of >0.8 V versus the NHE for phenol] and thus makes it more readily oxidized (Subrahmanyam et al., 1991). Moreover, aromatic amines are easily oxidized by TtLMCO1, similarly to most laccases. In the case of L-DOPA oxidation, a precipitate was formed after 24 h reaction, indicating polymerization of the substrate. This is common for most ascomycete laccases, since they are naturally implicated in melanin biosynthesis and in pigment formation in general (Janusz et al., 2020; Sapmak et al., 2015).

3.6. Molecular docking reveals residues that are involved in substrate recognition

Structural data on laccases or MCOs complexed with ligands are scarce; therefore, little is known about the residues involved in substrate recognition and conformational changes of the binding site. As shown above, TtLMCO1 not only oxidizes ascorbic acid and its derivatives, but also phenolic substrates, with a higher activity towards those that bear methoxy or hydroxyl substituents at the ortho position of the phenol ring (Zerva et al., 2019). Therefore, in addition to ascorbic acid, two further TtLMCO1 substrates were selected for docking simulations: one with a single methoxy substitution at the ortho position (ferulic acid) and one with methoxy substitutions at both ortho positions (2,6-DMP). Global docking of the selected ligands around the residues that form the substrate site was performed using YASARA (Land & Humble, 2018). Docking results, in terms of calculated binding energy (kcal mol⁻¹), dissociation constant (K_d) and contact receptor residues, are presented in Supplementary Table S4.

Simulations for all ligands were initially performed with all protein atoms fixed. This strategy provided acceptable docking results for L-ascorbic acid, while docking simulations for the phenolic compounds resulted in high dissociation constants (over 200 µM) and low binding energies. Therefore, several docking simulations were repeated for 2,6-DMP and ferulic acid enabling free movement of residue side chains that form the substrate-binding site. Eventually, after allowing free movement of only the side chains of Arg329 and Glu481, 2,6-DMP and ferulic acid were docked at catalytically relevant positions with acceptable scores. A more detailed outline of the docking poses and clustered results is presented in Appendix A.

Ligand-binding positions in all examined cases indicate the placement of the O2 atom of ascorbic acid and 2,6-DMP, as well as the O3 atom of ferulic acid, within electron-transfer distance of the NE2 atom of His564 (Figs. 7a, 7b and 7c), which is considered to be the direct acceptor of electrons from the oxidized substrate (Kallio et al., 2009; Mehra et al., 2018). This agrees with other known structures of three-domain laccases complexed with ligands [MaL (PDB entry 3fu7), Trametes trogii laccase (PDB entry 2hrg) and T. versicolor laccase (PDB entry 1kya)]. A hydrophobic cavity of the binding pocket composed of Phe169, Trp171, Leu405, Trp407, Tyr473 and Met567 contributes to substrate binding via hydrophobic or π–π interactions in all three cases (Figs. 7a, 7b and 7c). Docking of L-ascorbic acid into the substrate-binding site is further mediated by three hydrogen bonds to Arg329, Trp405 and Glu481, in addition to His564 which is common to all substrates (Fig. 7a). Binding of 2,6-DMP is assisted by the formation of two hydrogen bonds, one to Gln396 and one to His564 (Fig. 7b), while ferulic acid only forms a hydrogen bond to His564 (Fig. 7c).

Figure 7 Graphical representation of docking-simulation results for TtLMCO1 with L-ascorbic acid (a, d), 2,6-DMP (b, e) and ferulic acid (c, f). (a, b, c) Stick representations of the substrate-binding pocket of TtLMCO1 with L-ascorbic acid, 2,6-DMP and ferulic acid, respectively. Hydrogen bonds are shown as yellow, hydrophobic interactions as cyan and π–π interactions as red dashed lines. (d, e, f) Surface representation of the substrate-binding pocket of TtLMCO1 with L-ascorbic acid, 2,6-DMP and ferulic acid, respectively. Surface colouring of TtLMCO1 varies from hydrophobic regions (red) to hydrophilic regions (white).

The interaction of methoxy groups of phenolic compounds with the NE2 atom of His564 is important for the electron-transfer pathway in laccases and agrees with other computational studies on laccases (Mehra et al., 2018). Mehra and coworkers showed that in the absence of an ortho-positioned hydroxyl or methoxy group, the hydrogen bond to His458 (His564 in TtLMCO1) is disrupted and therefore the phenolic hydroxy group of the substrate is located too far away to interact with His458. This is also in accordance with the biochemical data for TtLMCO1 and also for most laccases, which are unable to oxidize substrates with a phenolic structure (Table 4) but readily oxidize compounds with a catecholic structure.

Moreover, the dissociation constant and binding energy for ferulic acid (Supplementary Table S4) indicate a higher affinity for this ligand compared with 2,6-DMP. This preference could be attributed to the architecture of the binding site: the single methoxy group of ferulic acid is more easily accommodated in the substrate cavity compared with the bulkier 2,6-DMP, which contains two opposing methoxy groups. Also, one side of the cavity is rather hydrophilic and is able to interact with hydroxy-bearing compounds, but the other side is lined with hydrophobic residues which, as shown from our docking results, are more likely to interact with the phenolic ring of the substrate through π–π stacking or hydrophobic interactions.

Conformational changes of the residues forming the binding site seem to be necessary to achieve phenolic ligand docking with favourable scoring. The side chains of Arg329 and Glu481 shift from their initial conformation, allowing enlargement of the binding pocket to fit catecholic or even pyrogallolic substrates with substitutions at the ortho positions (Figs. 7b and 7c). Indeed, initial attempts to dock 2,6-DMP and ferulic acid into the substrate-binding site while setting all residues at fixed positions did not result in an energetically and catalytically favourable solution. Since TtLMCO1 readily oxidizes ortho-substituted phenolic compounds, it might be safe to assume that this conformation could be close to the actual positioning of these residues during catalysis.

The conformational flexibility of Arg329 and Glu481 could be related to the ability of TtLMCO1 to act as a laccase rather than as an ascorbate oxidase. TtLMCO1 shares a similar substrate-binding site architecture with ascorbate oxidase from C. pepo (Supplementary Fig. S8) as well as sharing a similar redox potential with plant oxidases; however, as a fungal LMCO it is able to oxidize a wide spectrum of phenolic compounds. Attempts to perform docking of ferulic acid to the structure of ascorbate oxidase from C. pepo implementing the same strategy as used for TtLMCO1 did not provide favourable results (Supplementary Table S5). It could be possible that steric hindrance does not favour a shift of the side-chain conformations of Arg285 and Glu443 in ascorbate oxidase and thus hampers ligand binding to the substrate site.

TtLMCO1 is the second laccase-like enzyme to be reported from T. thermophila and shows significantly different properties to the first laccase described from this organism (Berka et al., 1997). Although many LMCOs have been found in fungal genomes and secretomes, this group of enzymes has not been studied in detail and thus the biological role of such enzymes in their natural hosts remains largely unexplained. Many enzymes with different kinetic and electrochemical properties, and the ability to oxidize different compounds, may participate in biological processes such as pigment synthesis and the decomposition of xenobiotics or even lignin in natural habitats. TtLMCO1 closely resembles C. pepo ascorbate oxidase, but its biochemical properties mostly correlate with those of laccases. Thus, the present analysis leads to the hypothesis that TtLMCO1 might correspond to an intermediate between plant ascorbate oxidases and microbial laccases, which are largely different from plant laccases. One such enzyme is an MCO from Aspergillus terreus, named TerA (Zaehle et al., 2014), that shares high sequence similarity with TtLMCO1. TerA belongs to the metabolic gene cluster of this organism for the biosynthesis of terrein, a molecule with diverse biological activities, but the exact role of this MCO in terrein biosynthesis has not been experimentally elucidated. Combined with the potential of TtLMCO1 to oxidize natural compounds, such as epinephrine, L-DOPA and others, this could be an indication that these enzymes are involved in the production of pigments and other bioactive compounds in their natural hosts.