2.1. Production of recombinant AcNiR crystals

The nirK gene from A. cycloclastes with codon optimization for expression in Escherichia coli was acquired from GenScript and cloned into a pET-26b(+) plasmid. The plasmid was transformed into E. coli BL21 (DE3) cells via heat shock and the transformant was cultured on Kan^R lysogeny broth (LB) agar to isolate individual colonies. 500 ml LB supplemented with 30 µg ml⁻¹ kanamycin was inoculated with a single colony and was incubated with shaking at 37°C. Protein overexpression was induced with 2 mM isopropyl β-D-1-thiogalactopyranoside (IPTG) and 1 mM CuSO₄. Incubation continued for 24 h, after which the cells were harvested by centrifugation and resuspended in 20 mM Tris–HCl pH 7.5, 0.1 mg ml⁻¹ lysozyme before being disrupted by sonication. The lysate was collected by centrifugation and dialyzed against 20 mM Tris–HCl pH 7.5, 2 mM CuSO₄, followed by dialysis against water. The lysate was loaded onto a DEAE-Cellulose column equilibrated with 20 mM Tris–HCl pH 7.5, which was subsequently washed with 20 mM Tris–HCl pH 7.5 followed by 100 mM Tris–HCl pH 7.5. AcNiR was eluted from the column using an NaCl gradient from 100 to 250 mM in 20 mM Tris–HCl pH 7.5. 4 M ammonium sulfate was used to completely precipitate the AcNiR, which was dissolved in 10 mM HEPES–NaOH pH 6.5. The AcNiR was concentrated to 50 mg ml⁻¹ and was crystallized by hanging-drop vapour diffusion against a 1:1 ratio of 1.2 M ammonium sulfate and 100 mM citrate buffer pH 5.0. Crystals with a pyramidal shape grew to ∼0.7 × 0.7 × 0.7 mm in size.

2.2. SF-ROX crystal treatment, data collection and processing

The harvested crystals of AcNiR were soaked in cryoprotectant, cryocooled by plunging into liquid nitrogen and maintained at 77 K after cooling. SF-ROX^OX crystals were soaked in 3.4 M ammonium sulfate, 100 mM citrate buffer pH 5.0 for 10 s. SF-ROX^NIT crystals were soaked in 3.4 M sodium malonate pH 5.0, 100 mM sodium nitrite for 10 s. SF-ROX^RED crystals were soaked in 3.4 M sodium malonate pH 5.0, 100 mM sodium ascorbate for 30 min, after which their colour changed from green to colourless. SF-ROX data collection was carried out on BL2 EH3/4b at SACLA at 100 K as described previously (Hirata et al., 2014; Halsted et al., 2018). The X-ray energy was set to 10 keV and the pulses were of <10 fs in duration. The sample was positioned 10 mm downstream of the XFEL focal point, which gave a beam size at the sample position of 2.2 × 4.5 µm. The XFEL beam was atten­uated to 5.7 × 10¹⁰ photons per pulse using a 100 µm thick aluminium X-ray attenuator. The crystals were rotated 0.1° and translated 50 µm between each snapshot. X-ray diffraction images were collected on an MX225-HS CCD detector (Rayonix) with a camera length of 110 mm. The same data-collection and processing procedure was used for all three data sets. Hit finding, indexing and integration were performed using CrystFEL (v.0.6.3; White et al., 2016), with the inner, middle and outer integration radii set to four, five and seven pixels, respectively. After the resolution of the indexing ambiguity, Bragg intensities were merged using the Monte Carlo method with frame scaling. Refinement was carried out in REFMAC5 (Murshudov et al., 2011) using the resting-state AcNiR structure (PDB entry 2bw4; Antonyuk et al., 2005) as the starting model with riding H atoms and isotropic B factors. Coot (Emsley et al., 2010) was used for manual model building between rounds of refinement. Double conformations of the side chains were assigned where 2F_o − F_c electron-density maps showed them clearly. The occupancies of the different conformers were chosen by examining the levels of the OMIT (F_o − F_c) electron-density maps and refined B factors. The final quality of the models was assessed using MolProbity (Chen et al., 2010). Data-processing and refinement statistics are given in Table 1.

Table 1 SF-ROX data-processing and refinement statistics Values in parentheses are for the highest resolution shell.   SF-ROXOX SF-ROXNIT SF-ROXRED No. of crystals 75 62 33 Images collected 1867 1257 581 Images merged 1377 1039 410 Data collection  Space group P213 P213 P213  a = b = c (Å) 94.95 94.92 94.61  α = β = γ (°) 90 90 90  Resolution (Å) 54.82–1.50 (1.54–1.50) 54.80–1.50 (1.54–1.50) 54.62–1.60 (1.64–1.60)  Rsplit† (%) 11.5 (90.4) 10.6 (85.3) 15.8 (70.8)  〈I/σ(I)〉 6.3 (2.0) 6.6 (2.3) 5.4 (2.7)  CC1/2‡ 0.980 (0.157) 0.984 (0.288) 0.957 (0.384)  Completeness (%) 100.0 (100.0) 100.0 (100.0) 100.0 (100.0)  Multiplicity 220.9 (77.2) 154.7 (50.8) 66.1 (44.3)  Wilson B factor (Å2) 14.9 14.5 17.5 Refinement  No. of unique reflections 45883 (2276) 45846 (2275) 37489 (1858)  Rwork/Rfree (%) 14.4/17.7 14.3/17.1 16.7/19.9  No. of atoms   Protein 2608 2595 2580   Ligand/ion 37 34 59   Water 425 418 279  B factors (Å2)   Protein 18.9 18.7 21.9   Cu 16.5 16.2 19.5   SO42− 33.2 41.5     NO2−   18.5     Malonate   37.2 30.1   Water 30.0 30.0 32.7  R.m.s. deviations   Bond lengths (Å) 0.013 0.013 0.015   Bond angles (°) 1.612 1.594 1.534  PDB code 6gsq 6gt0 6gt2 †Rsplit is as defined by White et al. (2013). ‡The correlation coefficient between half data sets is as defined by Karplus & Diederichs (2015).

2.3. In-house laboratory-source data collection and processing

Data sets for the resting state at a variety of pH values were obtained at the Barkla X-ray Laboratory of Biophysics using a Rigaku FR-E+ SuperBright rotating-anode generator with an EIGER R 4M detector. The same experimental setup was used to obtain a room-temperature structure from a perdeuterated crystal. For room-temperature data collection, the crystal was mounted in the cryoloop and protected from drying using MicroRT Tubing (MiTeGen) containing reservoir solution. Crystals of AcNiR were soaked for 15 min in 3.1 M sodium malonate, 100 mM NaNO₂ at pH 5.0, 5.5, 6.0 and 6.5. For each pH value, data sets were collected with 15 s exposure time and a 1.0° oscillation step per image, with a total of 60 images per data set. The images were processed using XDS (Kabsch, 2010) and AIMLESS (Evans & Murshudov, 2013), and refinement, model building and validation were carried out in the same manner as for the SF-ROX structures. Data-processing and refinement statistics can be found in Supplementary Table S1.

2.4. Production of perdeuterated AcNiR crystals

An E. coli cell pellet containing AcNiR expressed under perdeuterated conditions was produced by the Deuteration Laboratory at the Institut Laue–Langevin (Haertlein et al., 2016). 5 g of the pellet was resuspended in lysis buffer consisting of 20 mM Tris–HCl pH 7.5, 150 mM NaCl, 0.1 mg ml⁻¹ lysozyme, 1 µg ml⁻¹ protease inhibitors, 0.1 µg ml⁻¹ DNAse and stirred on ice for 30 min. The cells were subsequently disrupted by sonication and the lysate was collected by centrifugation. The cell lysate was dialyzed against 20 mM Tris–HCl pH 7.5, 1 mM CuSO₄ followed by the addition of 2 µl H₂O₂ and further dialysis against the same buffer without any additives. The lysate was loaded onto a hydroxyapatite column equilibrated with 100 mM Tris–HCl pH 7.5 and washed with a mixture of 6 mM Tris–HCl pH 7.5 and 2 mM potassium phosphate buffer pH 7.5 before being eluted using a potassium phosphate buffer gradient from 10 to 150 mM. The eluted fraction was applied onto a DEAE-Sepharose column pre-equilibrated with 20 mM Tris–HCl pH 7.5 and was eluted using an NaCl gradient from 50 to 250 mM. The eluted fraction was subsequently applied onto a HiLoad 16/600 Superdex 200 size-exclusion chromatography column (GE Life Sciences) pre-equilibrated with 150 mM NaCl in 20 mM Tris–HCl pH 7.5. In the final stage, AcNiR was precipitated using 4 M ammonium sulfate and the pellet was resuspended in 50 mM MES–NaOH pD 6.9. The pH values were determined using a conventional pH meter and the pH_obs reading was corrected as described in Schowen & Schowen (1982). AcNiR was crystallized by hanging-drop vapour diffusion against a 1:1 ratio of 1.1 M ammonium sulfate and 100 mM sodium acetate pD 5.4. For crystallization, 5 µl protein solution at a concentration of 20 mg ml⁻¹ was mixed with 5 µl reservoir solution; crystallization was initiated by adding microcrystals 2 h after the crystallization was set up. Two additional drops of equivalent size were added in one week and were merged with the nucleated drop after equilibration. It took three weeks for the crystal to reach its final size. A large single pyramid-shaped crystal of ∼0.9 × 0.4 × 1.0 mm was mounted in a 2 mm diameter capillary and stored for neutron data collection.

2.5. Neutron data collection and structural refinement

Neutron diffraction data were collected at RT to 1.8 Å resolution from a perdeuterated crystal of AcNiR (∼0.36 mm³ in volume) using the quasi-Laue neutron diffractometer LADI-III (Blakeley et al., 2010) at the Institut Laue–Langevin. A total of 20 images of 18 h exposure time each were collected from four different crystal orientations. These data were indexed and integrated using LAUEGEN (Campbell et al., 1998), wavelength-normalized using LSCALE (Arzt et al., 1999) and scaled and merged using the CCP4 program SCALA (Winn et al., 2011). Previously, D-exchanged crystals of similar volume had been used to collect diffraction data that extended to only 2.3 Å resolution (Blakeley et al., 2015), illustrating the benefits of using perdeuterated samples.

A 1.9 Å resolution X-ray data set collected at RT from a perdeuterated crystal was used as the starting model for neutron structural refinement. Using Ready_Set! from the PHENIX software suite (Adams et al., 2010), D atoms were added to the residues at calculated positions in preparation for structural refinement using phenix.refine. After initial rigid-body refinement, several rounds of maximum-likelihood-based refinement of individual coordinates and individual B factors against the neutron data were performed while applying restraints from the X-ray structure of the perdeuterated crystal, the data for which were collected at room temperature using an in-house X-ray generator, to maintain the geometry of the copper sites. After every round the model was visually inspected and manipulated in Coot (Emsley & Cowtan, 2010) using both positive and negative F_o − F_c and 2F_o − F_c nuclear scattering-length density maps to guide the modelling of solvent and protein D atoms. The final model contained 179 water molecules that were observed as full D₂O molecules, along with ten water molecules that were rotationally disordered and thus were included as O atoms only. Data-processing and refinement statistics can be found in Table 2.

3.1. Resting-state structures of AcNiR determined by SF-ROX and neutron crystallography

Resting-state structures of AcNiR were obtained using both SF-ROX at 100 K and neutron crystallography at RT and were refined to 1.5 and 1.8 Å resolution, respectively (Tables 1 and 2). The SF-ROX^OX structure was compared with the 0.90 Å resolution synchrotron-radiation (SR) structure of AcNiR (Antonyuk et al., 2005), revealing conservation of the overall structure with an all-protein-atom r.m.s.d. of 0.29 Å. The T2Cu is ligated by a single, highly ordered water molecule (W1) bound in a distorted tetrahedral geometry relative to the histidine plane. The active-pocket residues His_CAT and Ile257 (Ile_CAT) were in similar positions; however, there were marked differences in the positioning of the Asp_CAT residue and its hydrogen-bonding network. In the SF-ROX^OX structure the proximal conformation of the Asp_CAT side chain has two variants of the proximal conformation compared with a single proximal conformation in the synchrotron structure (Figs. 1 and 2). The additional conformation is formed by a 34° rotation around the O^δ1 atom, with the carboxyl O^δ2 atom forming a hydrogen bond to W1 at 3 Å, while the O^δ2 atom of the original conformation makes two hydrogen bonds to two water molecules, W3 and W4, one of which, W3, subsequently hydrogen-bonds to the T2Cu-ligated W1. These water molecules are part of the ordered water network in the substrate-entry channel. Both conformations are hydrogen-bonded via the O^δ1 atom to water W2, linking His255 to Asp98 (Fig. 2).

Figure 1 The T2Cu site of AcNiR determined by SF-ROX and neutron crystallography. (a) The T2Cu in SF-ROXOX is ligated by a single water molecule (W1) hydrogen-bonded to the Asp98 residue. Asp98 (AspCAT) is visible in two conformations in the proximal position, with the residue rotating around the fixed Oδ1 atom. AspCAT is subsequently hydrogen-bonded to the linking water (W2), which is hydrogen-bonded to His255. Water molecules are shown as red spheres. (b) The T2Cu catalytic site determined by neutron crystallography. The protonation states of the T2Cu site residues are clearly seen, along with the orientations of the catalytic D2O molecule (D1) and the proton-sharing D2O molecule D2. There is no expected protonation of His255 and Asp98, while a D2 molecule connects His255 and Asp98. The 2Fo − Fc electron-density map is contoured at the 1σ level and is shown as a grey mesh. The 2Fo − Fc nuclear scattering-length density map is contoured at the 1σ level and is shown as a cyan mesh. Atoms are coloured by element, with different colour schemes used for the different chains. The T2Cu is shown as a cyan sphere and D2O water molecules are shown as red and white sticks. Metal-coordinating bonds are shown as red dotted lines. Selected hydrogen bonds are shown as black dotted lines.

Figure 2 Water structure in the catalytic pocket and substrate-entry channel. (a) In the structure of oxidized AcNiR determined by SF-ROX, Asp98 (AspCAT) has a dual conformation; the usual proximal conformation hydrogen-bonds to two waters (W3 and W4), while the distorted proximal position, which is observed for the first time, hydrogen-bonds directly to the T2Cu water ligand. The waters (W3 and W4) are part of the ordered water network in the substrate-entry channel. Both proximal conformations of AspCAT are hydrogen-bonded via Oδ1, with the water W2 linking His255 (HisCAT) to AspCAT. 2Fo − Fc electron density is contoured at the 1σ level and is shown as a grey mesh. (b) In the atomic resolution crystal structure (PDB entry 2bw4) the proximal conformation is hydrogen-bonded to the ligated water W1A with an occupancy of 0.8. Water W1B with an occupancy of 0.2 is not shown for simplicity. (c) In the neutronOX structure, AspCAT is in a single proximal conformation. The 2Fo − Fc nuclear scattering-length density map is contoured around selected heavy waters at the 1σ level and is shown as a teal mesh. Atoms are coloured by element, with different colour schemes used for the different chains. The T2Cu is shown as a cyan sphere, D2O water molecules are shown as red and white sticks and water molecules are shown as small red spheres. Metal-coordinating bonds are shown as red dotted lines. Selected hydrogen bonds are shown as black dotted lines.

The neutron structure was modelled using the 1.9 Å resolution room-temperature X-ray structure of the perdeuterated protein obtained in this study. Subsequently, the structure was refined against the neutron data only, with restraints from the starting model to compensate for the weaker nuclear scattering length from Cu and S atoms. In contrast, the deuterons of the deuterated enzyme and the water molecules have neutron scattering lengths that are similar to those of C atoms. This makes the deuterons of histidine and water, for example, very visible in the neutron map. A water molecule appears as three atoms with similar densities. In contrast, H/D atoms are essentially invisible at the typical resolutions of X-ray structures. Even the subatomic resolution structure of AcNiR at better than 0.9 Å resolution was unable to provide the positions of many of the key H atoms in the catalytic pocket (Blakeley et al., 2015). Furthermore, the information in these very high-resolution SR structures is compromised as a significantly high X-ray dose is required that results in changes from the dose-dependent solvated electrons. The neutron structure determined here to 1.8 Å resolution provides the location of deuterons in the catalytic core and its associated water network for the first time (Figs. 1 and 2). The T2Cu is coordinated by a neutral D₂O molecule similar to W1 in the distorted tetrahedral position observed in the SF-ROX^OX structure.

In the atomic resolution SR structure the T2Cu has a tetrahedral coordination, with W1 hydrogen-bonded to the O^δ2 atom of the proximal Asp_CAT at a distance of 2.8 Å. The position of W1 in the SR structure differs from that in damage-free structures (Fig. 2). The neutron structure clearly shows W1 to be a D₂O molecule rather than a D₃O⁺ or OD⁻ ion, which have previously been suggested as possible alternatives. The Asp_CAT residue in the neutron^OX structure adopts a single proximal conformation and is bonded to a neutral heavy water D₂O, which is also hydrogen-bonded to His_CAT. Compared with the SF-ROX^OX structure, the His255 plane undergoes a 20° rotation. The neutron data revealed an ordered network of heavy water molecules around His_CAT, and also revealed hydrogen-bonding of the deuterated His255 N^∊1 atom to the carbonyl O atom of Glu279 only [Fig. 2(b)]. An unresolved question in mechanistic studies of CuNiRs is the origin of the protons that are required for the reduction of NO₂⁻. Several studies involving intramolecular electron-transfer rates and pH-dependent activity, together with computational studies, have suggested the involvement of protonated Asp_CAT and His_CAT in providing the two protons during catalysis (Ghosh et al., 2009). Our neutron structure provides unequivocal data on the protonation states of active-site residues in the resting state of the CuNiR enzymes for the first time. The nuclear density maps clearly reveal that neither of these residues are protonated at pD 5.4, where the activity of the enzyme is at a maximum, while the bridging D₂O has its two O—D bonds directed towards Asp_CAT and His_CAT. There is a chain of fully deuterated waters within hydrogen-bonding distance of each other, close to the liganded water at the T2Cu (Fig. 2).

The T1Cu site in the neutron structure shows no change in its copper geometry compared with the SF-ROX structure, but the second-sphere amino acid Met141 adopts a single conformation in the neutron^OX structure as opposed to a dual conformation in the SF-ROX^OX structure. Most of the differences in backbone structural alignment are found in an area of surface loop adjacent to Met141 consisting of residues 187–206, with an all-protein-atom r.m.s.d. of 1.02 Å (Supplementary Fig. S1). The loop is fully occupied and ordered in the neutron structure compared with the partially disordered loop in the SF-ROX^OX structure. This loop is associated with the binding of the cognate partner protein cytochrome c₅₅₁ (Nojiri et al., 2009).

3.2. SF-ROX structures of the NO₂⁻-bound form of AcNiR

Upon NO₂⁻ soaking of crystals of the oxidized enzyme, no changes in the geometry of the T1Cu site were observed in the SF-ROX^NIT structure determined at 1.5 Å resolution (Table 1). Met141 is stabilized in a single conformation, covering His145 [Figs. 3(a) and 3(c)]. A large patch of positive electron density was observed at the T2Cu site, and NO₂⁻ was initially assigned with full occupancy with a `side-on' binding mode in view of the recent MSOX results (Horrell et al., 2018). This, however, did not fully satisfy the electron density, and the density was finally assigned as NO<sub>2</sub><sup>−</sup> bound in both `side-on' and `top-hat' conformations in almost equal proportions (Supplementary Fig. S2). The O<sub>1</sub> atoms of `top-hat' and `side-on' NO<sub>2</sub><sup>−</sup> are separated by 1.3 Å. A partial-occupancy water (W4) is present at the position of the proximal Asp98 O<sup>δ1</sup> when in the gatekeeper conformation and is hydrogen-bonded to the bridging water W2. The observation of both conformations of nitrite in the damage-free SF-ROX structure raises an important question regarding the origin of the conformational changes observed during enzyme turnover in the initial frames of MSOX structures. Consistent with the occupancy of the two conformations observed in SF-ROX<sup>NIT</sup>, Asp<sub>CAT</sub> adopts the proximal and gatekeeper conformations with equal occupancy [Fig. 4(a)]. Based on the possibility of steric interaction, the proximal Asp<sub>CAT</sub> conformation coincides with `side-on' NO₂⁻, while the gatekeeper conformation matches the `top-hat' mode. The distorted proximal conformation seen in the SF-ROX^OX structure is not visible here. In the atomic resolution SR structure of nitrite-bound AcNiR (PDB entry 2bwi; Antonyuk et al., 2005), where significant radiolysis would be expected to have occurred, the NO₂⁻ ion takes up an intermediate position between the dual conformations observed here in the SF-ROX structure.

Figure 3 The damage-free T1Cu site in the SF-ROX structures of AcNiR in (a) oxidized, (b) reduced and (c) nitrite-bound forms. 2Fo − Fc electron density is contoured at the 1σ level and is shown as a grey mesh. Atoms are coloured by element. The T1Cu is shown as a dark blue sphere and water molecules are shown as small red spheres. Metal-coordinating bonds are shown as red dotted lines. Selected hydrogen bonds are shown as black dotted lines.

Figure 4 NO2−-bound T2Cu site of AcNiR. (a) NO2− is bound to the T2Cu in two conformations in the SF-ROXNIT structure: top-hat and side-on conformations with equal occupancy (50% each). Asp98 is visible in both proximal and gatekeeper conformations, with the gatekeeper conformation corresponding to the top-hat NO2− in the SF-ROXNIT structure. (b) Conformation of nitrite at pH 5.0 obtained using a low-dose home source. (c) At pH 6.5 only a single side-on conformation is visible corresponding to a single Asp98 (AspCAT) proximal position. The half-occupancy water molecule is also bound to T2Cu in the same conformation as in the SF-ROXOX structure. 2Fo − Fc electron density is contoured at the 1σ level and is shown as a grey mesh. Atoms are coloured by element, with different colour schemes used for the different chains. The T2Cu is shown as a cyan sphere and water molecules are shown as small red spheres. Metal-coordinating bonds are shown as red dotted lines. Selected hydrogen bonds are shown as black dotted lines.

3.3. SF-ROX structures of chemically reduced AcNiR

Despite the wealth of structures of CuNiRs, there are very few structures of the reduced form of the enzyme. The best resolution structure available for a reduced copper nitrite reductase is that from A. faecalis, which was determined to 1.85 Å resolution some ten years ago (Wijma et al., 2007). There is no XFEL structure of the reduced form of the enzyme from any species.

The structure of AcNiR in the chemically reduced state (SF-ROX^RED) obtained using 33 large colourless crystals was refined to a resolution of 1.6 Å (Table 1). The SF-ROX^RED T1Cu site showed a marked difference from the SF-ROX^OX structure, with two positions of the copper refined with occupancies of 0.7 and 0.3, respectively [Fig. 3(b)]. As the T2Cu site is fully reduced (as indicated by the absence of liganded water), both positions of T1Cu represent the reduced status of copper. Met141 is positioned in a single conformation away from His145, allowing a water molecule to fill the free space, making strong hydrogen bonds to both Met141 and His145. The loop (residues 187–206) undergoes a significant movement compared with that in the SF-ROX^OX structure (Supplementary Fig. S1).

W1 is lost from the T2Cu site on chemical reduction, producing a tricoordinate T2Cu site with three histidine residues ligating the copper. The T2Cu also drops 0.5 Å into the histidine plane upon reduction. The electron density of the side chain of Ile257 revealed that the CD₁ side chain flips down to partially occupy the active-site cavity space vacated by the water ligand [Fig. 5(b)]. The Ile257 CD₁–T2Cu distance decreases from 5.2 to 3.6 Å, reducing the volume of and increasing the steric restraints on the active-site cavity. The distorted proximal Asp98 conformation seen in the SF-ROX^OX structure is not visible here, with the residue adopting the original proximal conformation. The bridging water connecting Asp_CAT to His_CAT is positioned as in the SF-ROX^OX structure [Fig. 5(a)]. The loss of water at the T2Cu in the SF-ROX^RED structure and the colourless nature of the crystals confirm that this structure represents the damage-free structure of the chemically reduced enzyme. In X-ray radio­lysis experiments T1Cu is reduced but T2Cu remains four-coordinate with the ligated water ligand intact (Hough et al., 2008); however, movement of the the T1Cu loop (residues 187–206) is again observed (PDB entry 2vm4).

Figure 5 The T2Cu sites of oxidized and reduced AcNiR determined by SF-ROX. (a) Oxidized T2Cu site with two conformations of Asp98, water W1 bound to T2Cu, and Ile257 allowing space for this water. (b) Reduced T2Cu site (SF-ROXRED). The T2Cu water ligand is lost upon reduction. Only a single Asp98 (AspCAT) conformation is present. The Ile257 side chain flips down to partially fill the space vacated by the water ligand. 2Fo − Fc electron density is contoured at the 1σ level and is shown as a grey mesh. Atoms are coloured by element, with different colour schemes used for the different chains. The T2Cu is shown as a cyan sphere and water molecules are shown as small red spheres. Metal-coordinating bonds are shown as red dotted lines. Selected hydrogen bonds are shown as black dotted lines.

3.4. pH-dependence of nitrite conformation

Given the different binding modes of nitrite in the MSOX and SF-ROX^NIT structures, we investigated the pH dependence of the nitrite conformation using the in-house copper-anode X-ray generator at the Barkla Laboratory equipped with an EIGER R 4M detector. The highly efficient photon-counting detector together with low-dose data collection allows complete data collection without the conversion of nitrite to NO, thus allowing the determination of NO₂⁻-bound AcNiR structures at a variety of pH values. The resolution limit of these data sets was restricted to 1.5 Å owing to the geometrical constraints of the in-house experimental setup (Supplementary Table S1). The structure at pH 5.0 was comparable to the SF-ROX^NIT structure, with both `top-hat' and `side-on' conformations of NO₂⁻ with 0.5 occupancy each. The Asp_CAT residue has two conformations, with the gatekeeper conformation corresponding to the `top-hat' binding mode of NO₂⁻ [Figs. 4(a) and 4(b)]. At pH 5.5 both the NO₂⁻ and Asp_CAT conformations are present in equal proportions, but several changes are noticeable in the structure. The Met141 residue protecting His145 from water binding at the short distance has a single conformation [Supplementary Fig. S3(a)]. At pH 5.5 Met141 adopts two conformations with half occupancy each. This allows a partial water molecule to hydrogen-bond directly to His145 and create a water network to the protein surface which ends close to the low-density loop region. At pH 6.0 the original conformation of Met141 is lost, the water hydrogen-bonded to His145 is fully occupied and the side chain of Trp144 flips 180°. A major movement occurs in the external loop [residues 192–207; Supplementary Figs. S4(a) and 4(c)], with residues 195–201 regaining almost full occupancy. The crystal structure of AxNiR complexed with cytochrome c₅₅₁ (PDB entry 2zon) shows the AxNiR–Cyt c₅₅₁ interface aligned directly on top of the equivalent loop [Supplementary Fig. S4(d); Nojiri et al., 2009]. No changes are visible in the T2Cu geometry. Finally, at pH 6.5 few differences are observed around the T1Cu apart from both conformations of Trp144 being present. The outer loop is fully stabilized in its new conformation. The T2Cu site is changed significantly, with a single conformation of Asp_CAT, and NO₂⁻ is in a side-on conformation [Fig. 4(c)].

3.5. Protonation of the active-site residues in CuNiR

The consensus view of the resting state of CuNiRs at pH values close to the optimum for activity is that Asp_CAT is not protonated and His_CAT is fully protonated, with the two residues bridged by a hydrogen-bonded water molecule (Ghosh et al., 2009). In our AcNiR neutron^OX structure the O^δ1 and O^δ2 atoms of Asp_CAT were not deuterated, as expected (Figs. 1 and 2), but, contrary to expectation, His_CAT lacked a deuteron at the N^∊2 position as well. The linking water (D2) is positioned with one deuteron directed towards Asp98 O^δ1 and one directed towards His_CAT N^∊2. Moreover, the T2Cu-ligated water (D1) can clearly be modelled as a D₂O molecule (as opposed to a D₃O⁺ or an OD⁻ ion, which have been suggested previously as possible alternatives). The water (D2) linking His_CAT to O^δ1 of Asp_CAT restricts the movement of the unprotonated Asp_CAT. The bridging water is too distant to form a hydrogen bond to the O atom of the bound nitrite that interacts with Asp_CAT. We suggest that when NO₂⁻ binds, a proton is transferred from this water to the O^δ2 atom of Asp_CAT, resulting in an increase in the reduction potential to facilitate electron transfer from T1Cu to T2Cu (Fig. 6). In the complex with the reduced T2Cu, the proton is transferred from Asp_CAT to bound nitrite and the second proton is donated from the bridging water of His_CAT. This residue has been shown to rotate on reduction of the T2Cu site and has a proposed role as a redox-coupled switch for proton transfer (Brenner et al., 2009; Leferink et al., 2011, 2012; Fukuda, Tse, Nakane et al., 2016). The structure also shows that the fourth ligand of the T2Cu is D₂O, which is consistent with proton-uptake studies, which established that two protons coupled to electron transfer are required for turnover (Brenner et al., 2009). Synthetic copper complexes are able to carry out efficient NO₂⁻ reduction with the addition of a proximal carboxylate group, analogous to Asp_CAT, to form part of the copper(II) coordination sphere (Cioncoloni et al., 2018). From a mechanistic viewpoint, our data are consistent with the binding of NO₂⁻ to the oxidized T2Cu, resulting in displacement of the coordinated water ligand and triggering the protonation of Asp_CAT via the bridging water to initiate a proton-coupled electron-transfer (PCET) reaction and subsequent catalysis (Brenner et al., 2009; Ghosh et al., 2009).

Figure 6 Structure-based mechanism.