1. Introduction

The enzyme dehydroquinate synthase (DHQS) catalyses the conversion of 3-deoxy-D-arabino-heptulosonate-7-phosphate (DAHP) to dehydroquinate (DHQ), an intermediate in the biosynthesis of shikimate. The shikimate pathway is present in bacteria and microbial eukaryotes, but is absent in higher eukaryotes (Bentley, 1990). Pathogenic bacteria mutants in this pathway are attenuated for virulence (Gunel-Ozcan et al., 1997). Enzymes such as DHQS thus represent attractive targets for the development of novel antimicrobial drugs.

DHQS has been thoroughly characterized biochemically (Bender et al., 1989; Moore et al., 1994; Knowles, 1989; Widlanski et al., 1989). More recently, X-ray crystal structures of Aspergillus nidulans DHQS (AnDHQS) have led to proposals for the mechanisms of catalysis (Carpenter et al., 1998) and domain closure (Nichols et al., 2003).

We previously reported the identification of nine different crystal forms of AnDHQS (forms A–I; Nichols et al., 2001). Structure determination indicated that in the absence of the substrate analogue carbaphosphonate (CBP), DHQS was in an open form with a domain rotation of ∼12° (Brown et al., 2003; Nichols et al., 2003) compared with the closed ternary complex (Carpenter et al., 1998). The mechanisms involved in the domain closure are complex: there are changes in three proximal elements that have substrate-contacting residues in the closed form (PE1–PE3) which propagate to five distal elements having no direct contact with the substrate (DE1–DE5). These two sets of changes then act concertedly to cause the large-scale closure of the hinge, leading to the exclusion of bulk solvent and the formation of a tightly defined active-site pocket. The maximum resolution of the earlier crystals of the AnDHQS open form was ∼2.5 Å, thus limiting the accuracy of the final models. The availability of a higher resolution AnDHQS open structure will benefit both the design of novel inhibitors as well as detailed analysis of domain movements of the protein. The current work describes the generation of a new crystal form (form J) of the open conformation of AnDHQS diffracting to 1.7 Å resolution, which grew after the addition of an excess of substrate to allow enzyme turnover. Determination of the structure of AnDHQS in this new crystal form, refinement to 1.7 Å and comparison with the earlier open-form structures are described.

2. Materials and methods

The cloning, expression and isolation of AnDHQS took place as described previously (Moore et al., 1994; van den Hombergh et al., 1992). For crystallization, aliquots of purified protein were concentrated and buffer-exchanged into 10 mM Tris pH 7.4, 40 mM KCl using Vivascience Vivaspin 2 centrifugal concentrators with polyethersulfone membranes. Pooled concentrates were filtered through Amersham NAP 25 columns, re-concentrated to 30 mg ml⁻¹ and pre-incubated at 277 K with 1 mM ZnCl₂ for 20 min; 50 mM DAHP was then added. Hampton Research sparse-matrix and grid screens were then set up (i.e. Crystal Screen I, Crystal Screen II, Crystal Screen Cryo, PEG/Ion, Natrix, MembFac, PEG/LiCl Grid, NaCl Grid, PEG 6000 Grid and A/S Grid Screens). All crystallizations were carried out at 277 K and set up as sitting-drop vapour-diffusion experiments utilizing microbridges.

Single frames of X-ray data were collected from the crystals that grew from the screens and the unit-cell parameters were characterized. A full X-ray diffraction data set was then collected for the new form J turnover-related crystal form. Data collection was carried out at the ESRF on beamline ID-14 EH4 (λ = 0.933 Å) at 100 K, with cryoprotection being provided by the displacement of aqueous media with perfluoroether PFO-X125/03 (supplied by Lancaster). Indexing, integration and merging of data images were carried out with DENZO and SCALEPACK (Otwinowski & Minor, 1996). Rotation-function and translation searches together with initial rigid-body Patterson correlation refinement were carried out using CNS (Brünger et al., 1998). Molecular-replacement solutions were checked by displaying the transformed coordinates in O (Jones et al., 1991). Rigid-body, positional and B-factor refinement, simulated annealing and initial water picking were carried out in CNS. Manual rebuilding, including insertion of ions, ligands and extra water molecules, was carried out with O. The final model was overlaid with previously released AnDHQS structures using Top3D (Collaborative Computational Project, Number 4, 1994); the results were compared visually in VMD (Humphrey et al., 1996) and final figures prepared using Corel11.

3. Results and discussion

Characterization of crystals deriving from screens set up with AnDHQS and 50 mM DAHP revealed a new crystal form (form J) that was obtained under conditions that had not previously been seen to yield crystals with either NAD binary or NAD/CBP ternary setups. Data were therefore collected to determine the structure of the complex involved and compare it with other structures to assess any differences and see if it represented the crystallization of an intermediate stage in the domain-closure cycle. Although the crystals were extremely small (50 × 20 × 5 µm), they proved to be very well ordered, diffracting to 1.7 Å resolution.

Autoindexing with DENZO indicated C-centred orthorhombic symmetry and analysis of systematic absences then allowed the final assignment of space group as C222₁. The C chain of PDB model 1nve (NAD binary complex) was used as an initial molecular-replacement search model and the first cross-rotation peak gave a good translation search result with an E2E2 correlation of 0.383, yielding chain A of the new form. However, it was not so clear which of the other 22 peaks was the correct solution for the second moiety within the asymmetric unit. The monomeric initial solution was therefore subjected to rigid-body, positional and B-factor refinement, which lowered R_free from 0.52 to 0.46, and was then used for a second cross-rotation search. The monomeric model was then copied to give chains A and B overlaid on one another and was used for a second translation search with chain A fixed for translation but allowed to move in the final rigid-body stage of the CNS translation-search script. The first peak (excluding the origin) of the new cross-rotation search was thus revealed as the correct peak for chain B, with the resultant dimer showing an E2E2 correlation of 0.734. Structural refinement from this solution was then trivial, with only minor modifications being required after cyclic application of simulated annealing, positional/B-factor refinement and automated water-picking/deleting options. Representative electron density is shown in Figs. 1(a) and 1(b) and final refinement statistics are given in Table 1.

Table 1 Data-collection and refinement statistics for AnDHQS crystal form J Values in parentheses are for the outer shell. Ligands NAD, Zn2+ Space group C2221 Unit-cell parameters (Å)    a 90.0  b 104.5  c 177.4 Subunits in AU 2 Crystal form J Resolution range 30.00–1.70 (1.73–1.70) No. observations 91002 (4311) Data redundancy 7.2 (4.7) Completeness (%) 99.6 (94.6) Rmerge† 0.123 (0.735) I/σ(I) 18.89 (2.69) Rwork‡ (%) 19.5 Rfree‡ (%) 25.0 Residues in§ (%)    Most favoured regions 92.9  Additionally allowed regions 7.1 Mean B factors (Å2)    All atoms 24.4  Main chain 18.5  Side chains 25.2  Water 26.6  Ligands 14.1 R.m.s.d. bond lengths (Å) 0.005 R.m.s.d. bond angles (°) 1.19 PDB code 1sg6 †Rmerge = . ‡R = − . §Ramachandran plot results from PROCHECK.

Figure 1 Electron-density map at 1. 7 Å resolution for AnDHQS showing (a) the active-site region and (b) the presence of extended hydration shells.

With d_min = 1.7 Å, the final structure is of substantially higher resolution than the best extant open form of AnDHQS (PDB code 1nve ; d_min = 2.58 Å) and the model contains in excess of 1300 waters, which is between two and four times greater than the number discernible previously. Second-order and even third-order hydration shells can be unambiguously discerned (Fig. 1b), which may be because of the greater order of this crystal form but could also be the result of the use of the cryoprotectant perfluoroether, which stabilizes hydration shells more effectively than, for example, glycerol.

Analysis of 2F_o − F_c and F_o − F_c maps shows no sign of electron density consistent with the presence of either substrate or product (Fig. 1a), although as expected the tightly bound cofactor NAD is present. Comparison of the refined model with those previously reported for NAD binary and NAD/CBP ternary complexes (PDB models 1nve and 1nr5 , respectively) also clearly shows the DHQS is `open form', with the N- and C-terminal domains counter-rotated by ∼12° compared with the `closed-form' model (Fig. 2a). However, whilst the bulk state of the protein is clearly `open', the A-­chain PE1 structural element is bent slightly towards the active site (Fig. 2a) and in both the A and B chains structural elements DE1, DE4 and DE5 all show conformations closer to those previously observed with `closed' rather than `open-form' structures (Figs. 2a and 2b). This in turn affects crystal packing, with the semi-disordered DE4 and DE5 regions now making contacts with rigid regions of adjacent moieties in the crystal lattice rather than each other as observed with previous open-form data.

Figure 2 Cartoon-format Cα-trace superpositions comparing `open' AnDHQSs (NAD complex, crystal form E; PDB code 1nve ) in green and the structure after turnover (crystal form J): chain A in yellow, chain B in red. (a) Full-chain overlap, proximal view. (b) Close up of distal hinge-point.

One explanation of the observed conformation of AnDHQS in crystal form J is that as the enzyme relaxes back to the open form after the completion of its reaction cycle, it transiently passes through a conformation that can be trapped to yield this new crystal form. Uncertainty remains as to whether this is truly the final-stage intermediate of domain opening, as the substantial changes in crystal packing may also induce structural changes in the surface contacts relative to their equivalent in vivo state. However, it is hoped that the availability of higher resolution open-form AnDHQS structures will facilitate the future design of inhibitors of this enzyme. In particular, the new structure may aid in the development of compounds which act by stabilizing the open form, an alternative design strategy compared with inhibitors occupying the substrate site. The general utility of enzyme turnover prior to crystallization is difficult to estimate but may be worth using, particularly if other methods fail to give good-quality crystals. We have successfully used this method to crystallize Varicella zoster virus thymidine kinase, although in this latter case both products remain bound to the active site following crystallization (Bird et al., 2003).