1. Introduction

Type III secretion systems (T3SSs) are essential virulence determinants of many Gram-negative bacterial pathogens. The T3SS is required to translocate virulence effectors into the host cell. The T3SS consists of a `needle complex' composed of an external hollow needle held within a basal body that traverses both bacterial membranes. Secretion is activated by contact of the tip of the needle with host cells, resulting in the formation of a pore in the host-cell membrane that is contiguous with the needle. Other effector proteins are injected via this apparatus directly into the host-cell cytoplasm (for a review, see Johnson et al., 2005).

Among Gram-negative bacteria that possess a T3SS, the Burkholderia species are highly pathogenic to humans. They have been listed as biological risk category B agents and as a consequence of their infectivity by the respiratory route are considered potential bioterror agents (Rotz et al., 2002). B. pseudomallei causes melioid­osis in humans, a disease endemic in Southeast Asia and Northern Australia. This disease presents in a variety of ways from subacute and chronic suppurative infections to a rapidly fatal septicaemia (White, 2003). B. mallei causes the zoonotic disease glanders, mainly in horses. B. mallei can also infect humans, an infection that is almost invariably fatal if untreated (Wilkinson, 1981).

The B. pseudomallei needle is composed of the ∼9 kDa protein BsaL, the structure of which has been determined by NMR (Zhang et al., 2006) and is homologous both in sequence and structure to the Shigella flexneri needle component MxiH. We have recently determined the crystal structure of MxiH and assembled a molecular model of the T3SS needle, docking its crystal structure into a 16 Å EM reconstruction of the S. flexneri needle (Cordes et al., 2005; Deane, Cordes et al., 2006; Deane, Roversi et al., 2006). As part of our ongoing structural effort to further characterize the T3SS needle machinery, we have now endeavoured to express, purify and crystallize the B. pseudomallei BipD protein, a key component of the translocation apparatus in this bacterium. BipD is required for full virulence in murine models of melioidosis and mutation of the B. pseudomallei bipD gene impairs invasion of epithelial cells in vitro (Stevens & Galyov, 2004; Stevens et al., 2004).

There are no close BipD sequence homologues of known structure, the closest (13% sequence identity) being LcrV (Derewenda et al., 2004), a T3SS component of Yersinia pestis, which has been shown to be located at the tip of the T3SS needle and is similarly needed for cell invasion (Mota, 2006). The closest sequence homologues of BipD are Shigella IpaD and Salmonella SipD (36% and 33% sequence identity to BipD, respectively); together with some enteropathogenic Escherichia coli and Chromobacterium violaceum proteins, they form the T3SS protein family called `invasion plasmid antigen IpaD proteins' (Bateman et al., 2004). A three-dimensional structure of Burkholderia BipD, together with the structure of Yersinia LcrV (Derewenda et al., 2004), should increase our understanding of their role in T3SS pathogenesis.

2. Experimental procedures

2.2. Crystallization

Initial crystallization conditions were obtained by sparse-matrix screening (Jancarik & Kim, 1991) using the sitting-drop vapour-diffusion technique. Drops were prepared by mixing 0.2 µl protein solution (10 mg ml⁻¹, 20 mM Tris pH 6.6, 20 mM NaCl) with 0.2 µl reservoir solution and were equilibrated against 100 µl reservoir solution at 293 K. Initial crystals of BipD grew in two weeks in condition No. 22 of Molecular Dimensions Stura Footprint Screen 1 (1 M trisodium citrate, 10 mM sodium borate pH 8.5). Subsequent optimization yielded diffraction-quality crystals of BipD (Fig. 1) at citrate concentrations in the range 1.0–1.17 M and at pH values between 8.4 and 8.5. Crystals of SeMet-labelled BipD were grown as described above from SeMet-labelled sample. The Pt derivative was obtained by addition of 1 µl reservoir solution saturated with K₂PtCl₄ to the 0.4 µl crystallization drop; crystals were soaked for 1 d at 293 K prior to data collection.

Figure 1 Orthorhombic crystals of native BipD. The largest crystal has dimensions of approximately 20 × 20 × 300 µm.

2.3. Data collection and processing

Crystals of native and SeMet BipD were cryoprotected in reservoir solution containing 20% glycerol and flash-cryocooled in liquid nitrogen for data collection. The crystal of the Pt derivative of BipD was mounted and flash-cryocooled directly in the cryostream.

Diffraction data were recorded at 100 K (Table 1). Data were indexed and integrated in MOSFLM (Leslie, 1992) and scaled with SCALA (Evans, 1997) within the CCP4 program suite (Collaborative Computational Project, Number 4, 1994). A fluorescence scan measured on the SeMet crystal across the Se edge yielded values of  = −8.0 and = 6.4 using the program CHOOCH (Evans & Pettifer, 2001).

Table 1 BipD X-ray diffraction data-collection statistics Value in parentheses are for the highest resolution shells.   Native 1 Native 2 SeMet K2PtCl4 soak X-ray source ESRF ID29 ESRF ID14-2 ESRF ID29 ESRF ID14-2 Detector ADSC scanner ADSC scanner ADSC scanner ADSC scanner Space group C222 P21212 P21212 P21212 Z 8 8 8 8 Unit-cell parameters          a (Å) 103.98 136.47 135.90 136.52  b (Å) 122.79 89.84 89.50 89.55  c (Å) 49.17 50.15 49.97 49.29 Wavelength (Å) 0.9778 0.9330 0.9794 0.9330 Resolution limits (Å) 54–2.6 (2.74–2.6) 54–2.7 (2.85–2.7) 43–3.2 (3.37–3.2) 33–2.7 (2.85–2.7) Completeness (%) 99.8 (99.8) 99.8 (99.8) 100.0 (100.0) 95.2 (95.2) Anomalous completeness (%) — — 99.9 (99.9) 95.0 (73.4) Measured reflections 48047 (6998) 114952 (8942) 67849 (10074) 106839 (9603) Unique reflections 10006 17569 10590 16408 I/σ(I) 6.1 (1.6) 7.4 (2.4) 3.9 (1.8) 7.7 (2.2) Multiplicity 4.8 (4.9) 6.5 (3.6) 6.4 (6.7) 6.5 (5.3) Rmerge† 9.4 (42.7) 8.7 (31.8) 16.9 (41.5) 8.0 (33.1) Ranom‡ — — 8.3 (3.6) 4.5 (19.8) †Rmerge = 100 × , where I(h)i is the ith observation of reflection h and 〈I(h)〉 is the mean intensity of all observations of h. ‡Ranom = 100 × , where 〈I+〉 and 〈I−〉 are the mean intensities of the Bijvoet pairs for observation h.

3. Results and discussion

Of all the BipD crystals analysed, all of which were grown under the same conditions and all of which had a similar rod shape, only one belonged to space group C222 (labelled Native 1), while all other crystals examined belonged to space group P2₁2₁2.

The C222 crystal contains one molecule per asymmetric unit, with a Matthews coefficient of 2.4 ų Da⁻¹, corresponding to a solvent content of 47% (Matthews, 1968). The P2₁2₁2 crystals are likely to contain two molecules per asymmetric unit, based on the frequency distribution of Matthews coefficients among the PDB entries at comparable resolution (Kantardjieff & Rupp, 2003); this is confirmed by the P2₁2₁2 self-rotation function peak at ω = 90, φ = 27, κ = 180°, which has an intensity equal to 46% of the crystallographic peaks (Fig. 2).

Figure 2 The κ = 180° section of the self-rotation function calculated for the P21212 native data set using MOLREP (Collaborative Computational Project, Number 4, 1994) with an integration radius of 27.6 Å and data in the resolution range 37–5 Å. The peak (marked with an X) at (ω, φ) = (90, 27°) represents 46% of the peaks for the crystallographic twofold axes.

The c unit-cell parameter is equal to about 49 Å in both BipD crystal forms; the estimated solvent content and unit-cell volumes are very similar (V = 627 744 and 613 596 ų for C222 and P2₁2₁2, respectively), making it possible that the two lattices are equivalent. Indeed, the cross-crystal rotation function [computed between the C222 and P2₁2₁2 forms with the program ALMN (Collaborative Computational Project, Number 4, 1994) using data in the resolution range 15–5 Å] has a 5σ peak at ω = 0, φ = 0, κ = 26.7° (data not shown), suggesting that the two lattices are related by a simple rotation around the direction of the c axis. Moreover, this cross-crystal rotation approximately aligns the direction of the a axis of C222 with the NCS twofold in P2₁2₁2. Thus, the P2₁2₁2 form is likely to be the result of a change in symmetry that causes one of the twofold axes in C222 to become an NCS twofold in P2₁2₁2.

Anomalous difference Patterson maps for the Pt and SeMet derivatives were calculated within autoSHARP (Vonrhein et al., 2005) using (E² − 1) coefficients and strict outlier rejection. The Pt anomalous difference Patterson Harker sections suggest the presence of two sites (Fig. 3), while the SeMet anomalous difference Pattersons for the expected 2 × 6 = 12 Se sites are not easily interpretable (data not shown), nor have they yielded a reliable set of Se sites, despite attempts using the available Patterson-solving computer programs. The current phasing strategy is therefore based on initial SIRAS phasing with the Pt sites only, which should enable the location of the subset of ordered Se sites in the SeMet derivative and allow MIRAS phasing with the full BipD native data set and Pt- and SeMet-derivative data sets.

Figure 3 Harker section (u = 0.5) of the anomalous difference Patterson maps of the K2PtCl4 soak of BipD (space group P21212) calculated at 3.3 Å resolution with data collected at λ = 0.9330 Å (see Table 1) by autoSHARP. Maps are drawn with a minimum contour level of 1.5σ with 0.3σ increments. The two main peaks are labelled.