2.1. Macromolecule production

The IMPase construct was as described by Kraft et al. (2018) and Escherichia coli Rosetta2 (DE3) cells were used for IMPase production. A starter culture (10 ml) of transformed E. coli cells was grown overnight and was used to inoculate 1 l LB medium containing 2.5 mM betaine, 660 mM sorbitol, 35 mg ml⁻¹ chloramphenicol and 50 mg ml⁻¹ ampicillin. The culture was grown at 37°C to an OD₆₀₀ of 0.8. IMPase expression was induced by the addition of 0.5 mM IPTG and the culture was grown overnight at 25°C.

The E. coli cells were pelleted by centrifugation at 9600g for 20 min at 4°C and were resuspended in 50 ml lysis buffer [20 mM Tris–HCl pH 7.8, 150 mM NaCl, 40 U ml⁻¹ DNAse and one EDTA-free protease-inhibitor tablet (Roche)]. The resuspended pellet was lysed by sonication and the debris was pelleted by centrifugation at 33 000g for 20 min at 4°C. The clarified sonicate was heat-treated at 68°C for 1 h and the precipitant was pelleted by centrifugation at 32 000g for 20 min at 4°C. The supernatant was then incubated with Co–NTA resin at 4°C for 1 h. After incubation, the resin was washed with seven resin volumes (RV) of wash buffer (20 mM Tris–HCl pH 7.8, 150 mM NaCl, 15 mM imidazole) and the IMPase was eluted with 5 RV of elution buffer (20 mM Tris–HCl pH 7.8, 150 mM NaCl, 250 mM imidazole).

The eluted fractions were pooled and incubated overnight at 4°C with Pierce HRV 3C protease solution. This removes the N-terminal tag (MHHHHHHLEVLFQ) by cleaving at LEVLFQ↓GP (the sequence is given in Table 1). Cleaved IMPase was purified initially by incubation with Glutathione Sepharose 4 Fast Flow Resin that had been pre-equilibrated with two column volumes of size-exclusion chromatography (SEC) buffer (20 mM Tris–HCl pH 7.8, 150 mM NaCl). The flowthrough from the column was collected, concentrated to 5 ml and loaded onto a HiLoad 26/600 Superdex 75 Prep-Grade SEC column pre-equilibrated with SEC buffer. The proteins were gel-filtered at a flow rate of 1 ml min⁻¹ and the fractions containing IMPase were pooled, buffer-exchanged into storage buffer [20 mM Tris–HCl pH 7.8, 150 mM NaCl, 1 mM EDTA, 10%(v/v) glycerol] and concentrated to 20 mg ml⁻¹ using 10 kDa cutoff protein concentrators at 4000g prior to storage at −20°C. This protocol gave a typical yield of 2 mg IMPase per litre of culture.

2.2. Crystallization

The crystallization of human IMPase was carried out using SWISSCI 3 Lens sitting-drop plates; the plates were set up using a Mosquito liquid-handling robot (TTP Labtech). To co-crystallize IMPase with ebselen, a 20 µl aliquot of IMPase at 20 mg ml⁻¹ in storage buffer [20 mM Tris–HCl pH 7.8, 150 mM NaCl, 1 mM EDTA, 10%(v/v) glycerol] was incubated with 50 mM ebselen (6 µl of 200 mM ebselen in DMSO). The sample was transferred to a 500 µl microcentrifuge tube, placed on a roller and incubated at room temperature for 30 min prior to setting up crystallization plates.

A reservoir solution consisting of 0.2 M MnSO₄, 0.1 M MES, 28% PEG 4000 pH 5.5 was added to the IMPase and ebselen solution in a 1:1 ratio and incubated at 20°C (see Table 2). Crystals appeared after seven days and continued to grow until they were harvestesd for data collection on day 14; they were cryoprotected by transfer into 20%(v/v) glycerol, 80%(v/v) reservoir solution and flash-cooled prior to data collection.

2.3. Data collection and processing

An X-ray diffraction data set was collected from a single cryocooled crystal on beamline I04-1 at Diamond Light Source (Table 3). The data (2000 images of 0.1°) were processed with the xia2 pipeline at Diamond Light Source (Winter, 2010; Winter et al., 2013) to give a 1.47 Å resolution data set in space group P3₁21, with unit-cell parameters a = b = 84.02, c = 150.22 Å, α = β = 90, γ = 120°.

There are nine crystal structures of human IMPase in the PDB with similar unit-cell parameters, all of which belong to space group P3₂21; thus, the data were re-indexed and remerged in P3₂21. The data were merged using AIMLESS version 0.7.4 (Evans & Murshudov, 2013). The Rcp statistic, which is used to estimate cumulative radiation damage in AIMLESS (Diederichs, 2006), did not increase significantly over the 2000 frames.

2.4. Structure solution and refinement

The structure was solved by rigid-body refinement using the 1.7 Å resolution crystal structure of IMPase with manganese (PDB entry 6gj0; Kraft et al., 2018). Initial structure solution used the DIMPLE pipeline; this pipeline provides the user with a quick method to identify data sets that have a bound ligand or drug candidate in the crystal (https://ccp4.github.io/dimple/; Wojdyr et al., 2013).

Initial maps showed clear electron density (Fig. 1) for a single ebselen molecule attached to Cys141 in both subunits A and B of the dimer (the P3₂21 cell has one dimer in the asymmetric unit). The ebselen was built onto Cys141A and Cys141B in Coot (Emsley et al., 2010; Emsley, 2017). Restraints for the covalently bound ebselen were generated in AceDRG (Long et al., 2017) and the structure was refined using REFMAC5 (Murshudov et al., 2011).

Figure 1 View of ebselen attached to Cys141 (PDB entry 6zk0). (a) Overview of two ebselen molecules attached to the A and A′ (symmetry-related) subunits around the crystallographic twofold axis. One subunit (A) has C atoms in orange and the second subunit (A′) has C atoms in slate blue (N atoms are blue, O atoms are red, Se atoms are orange and S atoms are yellow-orange). C atoms in one ebselen are yellow and those in the second ebselen are cyan. Hydrogen bonds near ebselen are indicated by dotted lines. (b) Chemical structures of ebselen and ring-opened ebselen on Cys141 (drawn with Marvin; https://www.chemaxon.com). (c) Final ebselen OMIT map (Fo − Fc; 3σ, green; 15σ, blue). Note that the peaks on the seleniums (blue mesh) are 20.5σ and 19.6σ in this ebselen OMIT map. (d) Original DIMPLE (Wojdyr et al., 2013) 2Fo − Fc map (1σ, light blue) and Fo − Fc difference map (3σ, orange). For subunit A the DIMPLE-refined structure with waters (small red spheres) refined into the density for the ebselen is shown. For the A′ subunit the `final' coordinates (including ebselen) are shown.

Although the electron density was very clear for the terminal phenyl ring of the compound (Figs. 1c and 1d) and the electron-density maps have a large peak for the Se atom (covalently bonded to the S atom of Cys141), the electron density suggests that some radiation damage has occurred to the sulfur–selenium bond (Weik et al., 2002; Garman, 2010). The data are consistent with a model in which some initial radiation damage occurred to the sulfur–selenium bond (within the first few degrees of data), after which a steady state occurred (the bond reforming after breaking owing to radiation; Gerstel et al., 2015).

Each active site contains three Mn²⁺ ions in PDB entry 6gj0 (Kraft et al., 2018), while in PDB entry 2bji (Gill et al., 2005) each active site contains three Mg²⁺ ions. In our structure, site 2 (Gill et al., 2005) does not have sufficient electron density for an Mn²⁺ ion (Mn²⁺ ions have 23 electrons). We modelled a similarly coordinated sodium ion at this site, because we had no Mg²⁺ ions in our crystallization experiment (the protein was provided in 150 mM NaCl and the crystallization buffer contained 200 mM MnSO₄). However, we cannot rule out the possibility that this is an Mg²⁺ ion, rather than an Na⁺ ion (both Na⁺ and Mg²⁺ ions have ten electrons). This `site 2' is the position in which lithium is postulated to bind with tetrahedral coordination geometry (Gill et al., 2005). However, the co­ordination geometry in our structure is consistent with two Mn<sup>2+</sup> ions and one Mg<sup>2+</sup> ion, each with `standard' octahedral coordination geometry. Most of the active-site metal atoms are modelled in two positions and have temperature factors similar to those of the surrounding residues (Masmaliyeva & Murshudov, 2019).

In the deposited structure (PDB entry 6zk0), the ebselens on Cys141 in subunits A and B each have an occupancy of 0.6, but the Se atoms are modelled in two positions (Supplementary Fig. S1). In the crystal, the selenium–sulfur bond has been modelled with an occupancy of 0.4 or 0.35 (see Supplementary Fig. S1). A second selenium position observed in the electron-density maps is some 1.3 Å further away from the S atom of Cys141 and this second position is likely to be caused by radiation-induced cleavage of the selenosulfide bond (Gerstel et al., 2015). Refinement statistics are summarized in Table 4.

3.1. Human IMPase structure with ebselen bound at Cys141

The 1.47 Å resolution crystal structure of human IMPase with ebselen (PDB entry 6zk0) was solved using a structure of human IMPase with the same unit cell and space group (PDB entry 6gj0; Kraft et al., 2018). Electron-density maps (Fig. 1) clearly showed ebselen attached only to a single cysteine, Cys141. The binding of ebselen to the Cys141 residue in each monomer does not lead to noticeable changes in conformation in the active site that would prevent the catalytic activity of IMPase. Additionally, the binding of ebselen to Cys141 does not appear to prevent dimer formation, as shown by the dimers (and tetramers) present in this structure (PDB entry 6zk0). However, whilst this structure clearly shows ebselen bound to Cys141 in each monomer of IMPase, our structure does not rule out the possibility that Cys218 could be modified in vivo.

IMPase contains seven cysteine residues, amino acids 8, 24, 125, 141, 184, 201 and 218; of these residues, only Cys218 is near the active site. Four of the cysteine residues are buried and would not be expected to be accessible to modification by ebselen (Cys8, Cys125, Cys201 and Cys218). Of the three cysteines that have some surface accessibility in the monomer, one of them, Cys184, is largely buried in the dimer interface, as shown in Fig. 2 (PDB entry 6zk0). The procedure used to co-crystallize ebselen with IMPase allowed partial oxidation to form a Cys141–ebselen selenosulfide bond (Fig. 1). In our structure Cys24 has some surface accessibility when reduced, but when oxidized forms a disulfide with Cys125 (Fig. 2). Cys125 has no surface accessibility whether oxidized or reduced. A partial Cys25–Cys125 disulfide is also observed in PDB entry 6gj0 (Kraft et al., 2018).

Figure 2 Cysteine residues in IMPase with ebselen bound to Cys141 (PDB entry 6zk0). IMPase is shown as a Cα ribbon trace and the side chains of the seven cysteines are shown as sticks on the `red' subunit. The second subunit in the dimer is shown in cyan. A semi-transparent surface is shown; note that where the S atoms of the cysteine residues are on the surface of the protein, the surface is yellow (Cys24 and Cys141). Cys184 also has some surface accessibility in the monomer, but is largely buried at the dimer interface, so no yellow is visible for Cys184 in this figure.

Previous research suggested that Cys218 is the primary reactive cysteine residue (Knowles et al., 1992), which is supported by the reduced inhibition of C218A mutant IMPase by ebselen (Singh et al., 2013). In the structure reported here (PDB entry 6zk0) and other human IMPase structures Cys218 is largely buried and therefore seems to be an unlikely target for modification, as it is unclear how ebselen would gain access. If the side chain of Cys218 is modified by ebselen it would be likely to lead to a substantial reorganization of the protein structure; Asp220 coordinates an active-site metal ion.

From our structure, it appears that Cys141 is likely to be the primary binding site of ebselen. The sulfur group of this residue is exposed on the surface of IMPase (Fig. 2), and this residue is not in close proximity to another cysteine residue in either the monomeric or the dimeric form, and thus is unlikely to form a disulfide bond (PDB entry 6zk0). Cys141 is conserved in mammals (Knowles et al., 1992; Singh et al., 2013), and an analogous cysteine residue (Cys138) is present in Staphylococcus aureus IMPase. Given this level of conservation, it is probable that Cys141 is a functionally important residue in IMPase (Dutta et al., 2014).

Cys141 has previously been shown to be a reactive cysteine residue, as demonstrated by its affinity for the thiol probes pyrenemaleimide (Greasley et al., 1994) and n-ethylmaleimide (Knowles et al., 1992). In this structure, ebselen is in an open-ring conformation, with the Se atom forming a selenosulfide bond to the sulfur group of Cys141, which is consistent with the known binding mechanism of ebselen (Capper et al., 2018). Each monomer of IMPase in this structure has a single ebselen molecule bound to Cys141 (PDB entry 6zk0).

Whilst the conservation of Cys141 would suggest a critical role of this residue, its exact function remains unclear. The residue is not in close proximity to the active site, and therefore the residue is unlikely to be involved in catalytic activity. One possibility is that the residue may undergo post-translational modification in vivo and may be redox-active (Marino & Gladyshev, 2012), linking ebselen to therapeutic effects as a known antioxidant.

3.2. Ebselen-bound IMPase is observed to form a tetramer with 222 symmetry in the solid state

Fig. 3 shows the position of Cys141 on subunits A and B of an IMPase dimer. The two ebselen molecules covalently bind to each dimer and localize with two other ebselen molecules on a second dimer. The two ebselen molecules on each dimer increase the contacts with a neighbouring dimer, which gives a tetramer with approximate 222 symmetry in the crystal. However, as shown in Figs. 3(g) and 3(h), the active site still appears to be accessible.

Figure 3 Orthogonal views of the IMPase dimer (and tetramer) showing ebselen on Cys141 and metal ions in the active sites based on the structure of PDB entry 6zk0. (a) The two subunits in the dimer are shown as green (subunit A) and cyan (subunit B) cartoons, with ebselen attached to Cys141A and Cys141B in space-filling representation. Metal ions (Mn2+/Na+) at each active site are shown as grey spheres. (b, c) Orthogonal views. (d, e, f) The same views as in (a, b, c) but also showing a second dimer related by a crystallographic twofold axis. Subunit A′ is in yellow and subunit B′ is in magenta. The view in (e) is along the crystallographic twofold that rotates the AB dimer (green/cyan) onto the A′B′ dimer (yellow/magenta). (g, h). Two views of the tetramer from underneath, showing that the three metal ions (grey/black spheres) at each active site are still accessible in the tetramer. In (h), a surface is shown for both dimers.

Interestingly, other members of the IMPase superfamily, including fructose-1,6-bisphosphate (FBPase), have been observed to have both dimer and tetramer forms (Hines et al., 2007). Tetrameric forms of IMPase have also been observed in the anaerobic hyperthermophilic eubacterium Thermotoga maritima (Stieglitz et al., 2007).