2.1. Expression and purification of RdfS

The rdfS gene (msi109) encoding the 89-residue protein (UniProt ID Q7AL96) was amplified from M. japonicum R7A (GenBank accession CP051772) genomic DNA using PCR (5′-ATATCCATGGACGACGAAAACGACCGC-3′ and 5′-ATATGGATCCTTATCATGAGCGGGCTCCCTCG-3′; NcoI and BamHI sites in bold). The PCR product was cloned into the NcoI/BamHI sites of the pETM11 expression vector (European Molecular Biology Laboratory; Dümmler et al., 2005) using T4 DNA ligase (New England Biolabs; NEB) as per the manufacturer's instructions. Confirmation of the insert was performed using PCR and subsequent Sanger sequencing (Australian Genome Research Facility). The plasmid was transformed into electrocompetent Escherichia coli NiCo21(DE3) cells (NEB) using electroporation and was selected for on lysogeny broth (LB) agar medium containing kanamycin (50 µg ml⁻¹). Single colonies were inoculated into 5 ml LB (50 µg ml⁻¹ kanamycin) and incubated for 16 h at 310 K at 160 rev min⁻¹. The 5 ml culture was used to inoculate 1 l nonselective LB in a 5 l conical flask incubated at 310 K at 160 rev min⁻¹ until an optical density (600 nm) of ∼0.5 was reached. The cells were then induced using isopropyl β-D-1-thiogalactopyranoside at a final concentration of 0.1 mM and grown for an additional 16 h at 293 K with shaking at 160 rev min⁻¹. The cells were harvested at 4°C for 45 min at 20 000g. The cell pellets were resuspended in wash buffer [80 mM NaH₂PO₄, 500 mM NaCl, 80 mM imidazole, 5%(v/v) glycerol; pH 7.4] before being lysed using an Emulsiflex C5 high-pressure homogenizer (Avestin).

The lysate was centrifugated at 24 000g for 45 min at 4°C and the clarified soluble lysate was filtered using a 0.22 µm filter before being loaded onto a 5 ml HisTrap column (Cytiva) using an EP-1 peristaltic pump (Bio-Rad). Hexahistidine-tagged RdfS (6H-RdfS) was eluted from the column using a linearly increasing concentration of elution buffer [80 mM NaH₂PO₄, 500 mM NaCl, 850 mM imidazole, 5%(v/v) glycerol; pH 7.4] across a total of ten column volumes (50 ml) on an ÄKTApure chromatography system (GE Healthcare).

Fractions containing 6H-RdfS as determined by a 280 nm UV trace were pooled and diluted to approximately 2 mg ml⁻¹ in TEV digestion buffer [50 mM Tris–HCl pH 7.5, 300 mM NaCl, 1 mM EDTA, 5%(v/v) glycerol, 1 mM DTT]. In-house-prepared uncleavable 6H-tagged TEV protease (2.5 mg ml⁻¹) was added to 6H-RdfS at a ratio of 1:10(v:v) TEV:6H-RdfS before dialysing overnight in TEV digestion buffer at ambient temperature with gentle agitation. Post-digestion, the 6H-RdfS/TEV mixture was briefly centrifuged and filtered using a 0.22 µm filter before being reapplied onto the 5 ml HisTrap column pre-equilibrated with TEV digestion buffer. The flowthrough containing cleaved RdfS was pooled and concentrated to a final volume of 5 ml using a 3 kDa 15 ml centrifugal filter (Amicon) before being loaded onto a HiLoad 16/600 Superdex 200 column (GE Healthcare) pre-equilibrated with SEC buffer [50 mM Tris–HCl, 300 mM NaCl, 5%(v/v) glycerol; pH 7.4].

Peak fractions were pooled, concentrated and stored at room temperature for immediate use or flash-frozen in liquid nitrogen for long-term storage at −80°C.

2.2. Small-angle X-ray scattering

Small-angle X-ray scattering (SAXS) data were collected on the SAXS/WAXS beamline at the Australian Synchrotron (Kirby et al., 2013) with continuous data collection using a PILATUS 1M detector (Broennimann et al., 2006). All 6H-RdfS SAXS data were collected using size-exclusion chromatography-coupled synchrotron SAXS (SEC-SY-SAXS; Gully et al., 2015) with a Superdex 200 Increase 5/150 GL column (GE Healthcare) controlled by a Shimadzu HPLC system. All experiments were performed in SAXS buffer [150 mM Tris–HCl, 300 mM NaCl, 5%(v/v) glycerol; pH 7.4]. SAXS data-collection and analysis statistics are given in Table 1. Scattering data were background-corrected using linear interpolation of the background from averaged frames using scatterBrain (Stephen Mudie, Australian Synchrotron). The intensity at zero [I(0)], Guinier range and radius of gyration (R_g) were determined using the ATSAS package (Manalastas-Cantos et al., 2021) with PRIMUS (Konarev et al., 2003) and GNOM (Semenyuk & Svergun, 1991). SAXS ab initio modelling was performed using DAMMIN (Svergun, 1999) and DAMMIF (Franke & Svergun, 2009). Refinement of ab initio models was performed by the DAMAVER suite (Volkov & Svergun, 2003) using 11 individual DAMMIN models, and the solution scattering of 6H-RdfS was compared with the finalized X-ray structure using CORAL (Manalastas-Cantos et al., 2021) and EOM (Tria et al., 2015; Bernadó et al., 2007). The final SAXS data have been deposited in the SASBDB under entry SASDPK4.

2.3. Crystallization

For crystallization, the protein tags were removed. Crystallization trials were explored using a variety of sparse-matrix screens: Index HT (Hampton Research), Crystal Screen HT (Hampton Research), JCSG-plus (Molecular Dimensions; Newman et al., 2005), the LMB Crystallization Screen (Molecular Dimensions) and ProPlex (Molecular Dimensions). Each screen was set up in sitting-drop vapour-diffusion format in a three-drop 96-well ARI LVR Intelli-Plate (Hampton Research) at 293 ± 0.5 K using an Art Robbins Phoenix robot. Each 300 nl drop consisted of protein solution (9 mg ml⁻¹) and reservoir solution in a 1:1, 1:2 or 2:1 ratio equilibrated against 80 µl reservoir solution. While crystallization was observed in dozens of conditions across the entire plate, larger needle-shaped crystals that formed in condition No. 38 of the ProPlex screen [0.1 M MES pH 6.5, 10%(w/v) PEG 5000 MME, 12%(v/v) 1-propanol] appeared to be the most promising. Further optimization attempts varying the pH and the precipitant concentration in hanging drops in a 24-well VDX plate (Hampton Research) produced similar crystals with a larger size (∼50 × 1000 µm) which diffracted poorly (>10 Å). One variation of the initial condition was selected from a modified protocol of the Additive Screen matrix (Hampton Research) set up across four hanging-drop 24-well VDX plates, with each drop consisting of 2.5 µl protein (8.8 mg ml⁻¹), 2 µl crystallization condition [0.1 M MES pH 6.5, 8%(w/v) PEG 5000 MME, 10%(v/v) 1-propanol] and 0.5 µl additive condition equilibrated over a reservoir containing 100 µl of only the additive condition. This unusual setup was the result of an error which proved to be productive. In the presence of additive No. 23 (1 M sodium citrate tribasic dihydrate) RdfS formed large, multi-nuclear crystals of >1 mm in length. Replicate trials set up with identical conditions were conducted with four drops per well in a 24-well VDX hanging-drop tray (a total of 96 identical drops), with three individual drops producing plate-like rod crystal clusters [the final conditions in the drop were 0.05 M MES pH 6.5, 4%(w/v) PEG 5000 MME, 5%(v/v) 1-propanol, 0.1 M sodium citrate with RdfS protein at 4.3 mg ml⁻¹]. Crystal clusters were harvested and transferred to a cryoprotectant condition [0.08 M MES pH 6.5, 6.4%(w/v) PEG 5000 MME, 8%(v/v) 1-propanol, 20%(v/v) ethylene glycol] for 2 min. Micro-Tools (Hampton Research) were used to separate individual crystals from the clusters before harvesting and flash-cooling in liquid nitrogen (Haas & Rossmann, 1970; Henderson, 1990). Diffraction experiments were carried out on the MX2 beamline at the Australian Synchrotron, Melbourne, Victoria, Australia (Aragão et al., 2018) using remote access via the Blu-Ice software (McPhillips et al., 2002). The best data set was collected at 13.0 keV (λ = 0.953 Å) with a crystal-to-detector distance of 380 mm (2.49 Å at the detector top edge).

2.4. Diffraction data collection, processing and refinement

Data-collection and processing statistics are presented in Table 2. Data were collected at 100 K using a Dectris EIGER 16M detector (Casanas et al., 2016), with a total rotation range of 180° and an exposure time of 36 s at 60% attenuation of the beam. Data were integrated and reduced with XDS (Kabsch, 2010) and were scaled, merged and truncated in space group P2₁2₁2₁ using AIMLESS (Evans & Murshudov, 2013). Solvent-content analysis was performed using the Matthews coefficient (Matthews, 1968). The self-rotation function was calculated with MOLREP (Vagin & Teplyakov, 2010) using data between 42.87 and 2.65 Å resolution with an integration radius of 33.96 Å. Molecular-replacement calculations were carried out in space group P2₁2₁2₁ using MOLREP (Vagin & Teplyakov, 2010) from the CCP4 suite (Winn et al., 2011) with five individual versions of ab initio models of truncated RdfS generated from ColabFold (Mirdita et al., 2022) using the modelling algorithms from AlphaFold2 (Jumper et al., 2021; henceforth referred to as AlphaFold) and the sequence-alignment algorithms from HHsearch (Steinegger et al., 2019) and MMseqs2 (Steinegger & Söding, 2017). The structure was initially refined with REFMAC5 (Murshudov et al., 2011) using rigid-body refinement followed by restrained refinement with automatically generated local NCS restraints (Usón et al., 1999). Refinement was completed with phenix.refine (Afonine et al., 2012). NCS restraints were removed for the final stages of refinement. For refinement, 4.7% of reflections were used for cross-validation (Brünger, 1992). The fit of the structure to the electron density was manipulated with Coot (Emsley et al., 2010). The coordinates and structure factors of the final, fully refined model (validated by MolProbity; Chen et al., 2010) have been deposited in the Protein Data Bank (Berman et al., 2000; PDB entry 8dgl) and the accompanying structural and biochemical interpretations will be reported elsewhere.

3.1. Solution X-ray scattering of monomeric 6H-RdfS

Recombinant 6H-RdfS could be expressed and purified with a high yield (∼20 mg per litre of culture) suitable for biophysical analysis. Preliminary experiments were ambiguous with respect to the oligomerization state of RdfS in solution, so we used analytical SEC and SEC-SY-SAXS of 6H-RdfS to explore this in detail. 6H-RdfS elutes from the SEC column as a single peak with a long trailing edge and with an A_260 nm:A_280 nm ratio of 0.5, indicating pure protein (Fig. 1a). SAXS analysis of the peak yielded an experimental scattering curve exhibiting properties of a monodisperse sample (Fig. 1). Guinier analysis provided a radius of gyration (R_g) of 22 Å, and the pair-distribution function shows a maximal dimension (D_max) of approximately 92 Å, both of which are reasonable for a 6H-RdfS monomer with a prolate shape. SAXS-derived molecular-mass estimates of 12 046 Da (using a q_max of 0.300 Å⁻¹ and a V of 14 600 ų; Fischer et al., 2010) and 12 025 Da (Bayesian inference estimate; 96.22% credibility interval probability; Hajizadeh et al., 2018) also compare favourably with the expected molecular mass of 12 172 Da (as calculated by ProtParam; Wilkins et al., 1999). A dimensionless Kratky plot shows a peak slightly beyond 1.1 Å and a qR_g of 1.7 Å⁻¹, suggesting that 6H-RdfS is elongated with significant flexibility, which is also supported by the increase in intensity at qR_g > 5 indicating particle flexibility/disorder (Fig. 1d; Durand et al., 2010; Bizien et al., 2016; Trewhella et al., 2017). Porod volume estimates of 230 Å suggest extremely large, elongated particles in solution. These data support the hypothesis that a substantial proportion of the 6H-RdfS monomer is disordered in solution, as it contains an N-terminal His₆ tag, a flexible linker and a TEV cleavage site, and the final 31 residues of the native protein are highly disordered as predicted by MobiDB-lite (Necci et al., 2021). Given the propensity of the 6H-RdfS molecules to be disordered in solution, models were generated to visualize flexibility using the X-ray structure as a template. A filtered scattering envelope shows an elongated (80 Å) particle (Fig. 1e), which is slightly smaller than the idealized D_max calculated using the pair-distribution function (Supplementary Fig. S1). An ensemble of EOM models is shown in Fig. 1(f), highlighting the flexibility of the N-terminal region in solution with a reasonable fit (χ² = 0.27; two degrees of freedom). Further models of the RdfS structure fitted into the scattering of 6H-RdfS, including the addition of dummy residues for the additional N- and C-terminal regions that are not represented in the X-ray structure, can be found in Supplementary Fig. S2.

Figure 1 Characterization of 6H-RdfS in solution using small-angle X-ray scattering. (a) Size-exclusion chromatography profile of the 6H-RdfS monomer during the SAXS experiment. The absorbance at 260 and 280 nm is plotted against the elution volume from the Superdex 200 5/150 GL gel-filtration column. (b) Small-angle X-ray scattering profile of 6H-RdfS [log(I) versus log q]. (c) Guinier analysis of 6H-RdfS. Rg is shown adjacent to the plot line. (d) Normalized (dimensionless) Kratky plot of 6H-RdfS. The peak is shown as a dashed line. (e) Ab initio DAMFILT-filtered bead model (based on 11 DAMMIN models) representing the elongated 6H-RdfS envelope in (i) elongated and (ii) perpendicular views. The mean iterative closest point (ICP; Besl & McKay, 1992) metric was 14.7 (±2.5) for all 11 DAMMIN models. (f) EOM ensemble of six RdfS cartoon models fitted into the 6H-RdfS SAXS scattering data, with the wHTH domain (black) rigid and the N-terminal helix (coloured) disordered. The various colours demonstrate the flexibility of the N-terminal helix as fitted to the scattering data (red, green, yellow, blue, purple and pink).

3.2. Crystallization and X-ray data processing

RdfS crystallized readily across a broad range of screening conditions, with crystals consistently forming in approximately 17% of conditions in Index HT (Hampton Research), 10% of conditions in Crystal Screen HT (Hampton Research), 23% of conditions in JCSG-plus (Molecular Dimensions), 24% of conditions in the LMB Crystallization Screen (Molecular Dimensions) and 23% of conditions in ProPlex (Molecular Dimensions). Adjustments to the concentration of protein used and the volume of the drop appeared to have little impact on the number of crystals or of condition `hits', but instead the volume ratio of protein sample (in SEC buffer) to crystallization condition used had the largest discernible impact on the size and number of crystals within a single drop. Crystal-forming conditions containing either a 1:1 ratio of protein to crystallization condition (present in approximately 87% of all crystals formed) or a 1:2 ratio (∼73%) yielded the most crystals (a 2:1 ratio only appeared in ∼43% of all crystal-forming conditions).

Hundreds of crystals from a variety of conditions were tested for diffraction with no success, which was perhaps not surprising given their thin, uneven needle-like habit (Fig. 2a). Whilst these crystals varied in size, they typically formed very narrow (>10 µm width) highly elongated needles or prisms (Supplementary Fig. S3). No improvement in diffraction was seen with the MX2 mini beam (25 × 15 µm), compared with the larger MX1 beam (120 × 120 µm), for crystals with similar morphology. Condition No. 38 [0.1 M MES pH 6.5, 10%(w/v) PEG 5000 MME, 12%(v/v) 1-propanol] from the ProPlex screen yielded the most promising large (>500 µm) multi-nuclear crystals, which showed evidence of diffraction to 10 Å resolution (Supplementary Fig. S3). Optimization of the pH and the PEG and propanol concentrations [to 0.1 M MES pH 6.5, 8%(w/v) PEG 5000 MME, 10%(v/v) 1-propanol] was used to reproducibly obtain larger crystals.

Figure 2 Crystallization and diffraction of RdfS. (a) An example crystal morphology from sparse-matrix crystallization screens, with a thin, rod-like crystal shape observed. (b) Initial additive trial multi-nuclear crystal as described in Section 3.2. (c) Final crystal morphology of the RdfS crystals used to generate the solved data set prior to separation with tools and cryoprotection. (d) Diffraction pattern from the first ten frames (1°) of data with a resolution indicator (dashed circle). An image of a crystal from the solved data set mounted in a loop is shown in the bottom right corner.

To improve the diffraction properties, we screened additives and pursued a strategy capitalizing on an error where we screened for crystallization against reservoirs that contained only concentrated additive solution. Serendipitously, we found that this produced multiple crystal-forming conditions in initial trials with Hampton Research Additive Screen. Importantly, one of the conditions yielded a single large multi-nuclear crystal (>1 mm; Fig. 2b) which diffracted to 4 Å resolution (data not shown). We replicated this experimental condition [0.05 M MES pH 6.5, 4%(w/v) PEG 5000 MME, 5%(v/v) 1-propanol, 0.1 M sodium citrate tribasic dehydrate with 4.3 mg ml⁻¹ RdfS equilibrated against a reservoir consisting of 1 M sodium citrate tribasic dehydrate] 96 identical times, demonstrating low reproducibility (three successes out of 96 replicates; 3.1%), suggesting that variability in the process of setting up drops or uncontrolled nucleation events affected the outcome. Nevertheless, crystals from a single drop containing a typical large cluster of flat, rod-like crystals (Fig. 2c) were harvested, cryoprotected in mother liquor supplemented with 20% ethylene glycol and flash-cooled for storage. We suspect that the effectiveness and the overall increase in diffraction quality of the crystals produced from our additive trials are the result of a `pseudo-salting-out' technique. We assume that because of a decrease in water and 1-propanol in the drop over time via vapour diffusion due to the additive-only reservoir solution, idealized conditions fortuitously enabled RdfS to form crystals which diffracted well in a small percentage of replicate conditions.

RdfS crystals diffracted to 2.45 Å resolution on beamline MX2 at the Australian Synchrotron (Aragão et al., 2018; Fig. 2d). Data analysis clearly indicated space group P2₁2₁2₁, with unit-cell parameters a = 35.25, b = 119.20, c = 123.40 Å (Table 2). Solvent-content analysis indicated six molecules per asymmetric unit to be most likely (46% probability), while a self-rotation function suggested that four or eight molecules per asymmetric unit were possible. With such high Z′ values and no experimental model of a close homologue, molecular replacement was expected to be challenging.

3.3. Molecular replacement

Despite the lack of a close homologue to RdfS, the structure was solved by molecular replacement using MOLREP (Vagin & Teplyakov, 2010) from the CCP4 suite (Winn et al., 2011). In the absence of structures of close homologues, ab initio predictions from AlphaFold were used as search models both individually and as a cluster of five models (Fig. 3). Initial molecular-replacement attempts used fully intact models to maximize the scattering power of the model, but failed most probably due to structural variation and disorder at the termini of the models (Fig. 3c and Supplementary Table S1), an observation that was supported by disorder analysis with DisEMBL (version 1.5; Linding et al., 2003) and the pLDDT plot of each model (Fig. 3a). Manual investigation of the five individual ab initio models showed variability of the orientation of the N-terminal α-helix and the extended C-terminal tail, so a single truncated RdfS AlphaFold model (residues 16–64; RdfS_16–64) was utilized in all further molecular-replacement attempts (Fig. 3b). RdfS_16–64 yielded promising results, with three protomers located with strong rotation-function and translation-function scores. Refinement of this model stalled, so we manually inspected the structure and electron density in Coot, with two notable observations: (i) the three molecules were arranged in a repeating head-to-tail manner (i.e. the interface of A:B was replicated at B:C) and (ii) there was notable electron density adjacent to molecule C (Fig. 4a). Furthermore, structural alignment of the A:B:C `trimer' on itself (with A superimposed on C; Fig. 4b) placed molecule B in unmodelled electron density and molecule C directly on top of molecule A′ from an adjacent asymmetric unit. This was unlikely to be a coincidence and gave us confidence that the structure contains four molecules per asymmetric unit arranged in a head-to-tail fashion that continues throughout the crystal in one dimension, resulting in a protein polymer with eight molecules per helical turn. The refinement of four RdfS_16–64 molecules (Fig. 3d) proceeded as expected, with a substantial reduction of R_free, and each copy was highly similar to the others in the asymmetric unit [average r.m.s.d. of 0.32 Å calculated using PyMOL (version 1.8; Schrödinger) with default cycle parameters; Supplementary Table S2]. A finalized structure refined to an R_work of 19.9% and an R_free of 24.6% validated using MolProbity (Chen et al., 2010) has been deposited in the PDB (PDB entry 8dgl) and will be described in detail elsewhere.

Figure 3 Ab initio models used in molecular replacement. (a) Predicted local distance difference test (pLDDT) residue position plot as generated by ColabFold showing the confidence in each residue (y axis) and the relative residue location (x axis) for the RdfS amino-acid sequence. The predicted wHTH domain and additional C-terminal helix (positions 16–64) have the highest confidence scores for each model. (b) The RdfS16–64 truncated model used in molecular replacement as described in Section 3.3. (c) Superposition of all full AlphaFold-generated models [coloured to match (a): blue, orange, green, red and purple] with the finalized RdfS monomer (chain B) structure shown in black. (d) Overlaid backbone ribbon representation of RdfS16–64 for all AlphaFold models [coloured as in (c)] and each of the four RdfS chains (black). This region was highly similar between the models and each of the crystallographically determined RdfS chains (average r.m.s.d. between models of 1.0 Å: Supplementary Table S1).

Figure 4 Molecular replacement of the RdfS crystal structure. (a) Initial molecular replacement located three RdfS monomers and a patch of unmodelled electron density. (b) Superposition of molecule A of the molecular-replacement solution on molecule C demonstrated a repetitive pattern of head-to-tail interacting monomers, allowing the placement of a fourth monomer. (c) Three orthogonal views of the final molecular-replacement solution, with four molecules in the asymmetric unit, result in a continuous left-handed superhelix with eight molecules per helical turn running through the crystal (pink box, unit cell). (d) The self-rotation function of RdfS indicates eight equally spaced twofold NCS axes (χ = 180°; four nonredundant axes related by a crystallographic twofold axis) and a strong eightfold NCS axis (χ = 45°). (e) Left: the rotational symmetry axes relating a monomer in one molecular superhelix (black) and eight monomers in two other asymmetric units (red, orange, yellow, green and cyan; blue, indigo and violet). The black bar represents the eightfold symmetry axis (χ = 45°) and the coloured bars represent each of the twofold symmetry axes (χ = 180°), as indicated on the self-rotation function. Right: an orthogonal view of the same set of molecules viewed along the eightfold symmetry axis (black).