2.1. Expression, purification and crystallization

Expression, purification and crystallization of the modified human UCK2 utilized in this study have been previously reported (Suzuki et al., 2003). Briefly, UCK2 with a deleted C-­terminus (residues 251–260) was expressed with glutathione-S-transferase fused at the N-terminus. A sequence of affinity, gel-filtration and ion-exchange chromatography steps yielded highly purified UCK2. The protein was concentrated to approximately 12 mg ml⁻¹ and was stored at 193 K. Diffraction-quality crystals were grown using the sitting-drop vapor-diffusion technique. Drops (3 µl) were formed by mixing 1 µl protein solution with 1 µl ligand solution (20 mM cytidine, 10 mM MgCl₂, 5 mM ATP) and 1 µl reservoir solution (17–18% PEG 8000, 0.2–0.3 M calcium acetate, 100 mM Tris–HCl pH 7.0). The drops were equilibrated against 0.5 ml reservoir solution. Although UCK2 was crystallized in the presence of substrates (ATP and cytidine), the structure actually revealed an enzyme–product complex (UCK2–ADP–CMP), indicating that the reaction had occurred during the crystallization process. Block-shaped UCK2–ADP–CMP crystals generally appear in 3 d and grow for approximately one week, reaching dimensions of 0.2 × 0.2 × 0.15 mm. The UCK2–ADP–CMP crystals belong to the monoclinic space group C2, with unit-cell parameters a = 88.6, b = 109.3, c = 64.5 Å, β = 95.0°. The Matthews coefficient (V_M; Matthews, 1968) is 2.75 ų Da⁻¹ assuming two monomers of approximately 28 300 Da each in the asymmetric unit, which corresponds to a solvent content of approximately 54%.

2.2. Derivative preparation

Native UCK2 crystals were harvested from the mother liquor and transferred to the heavy-atom solution (19–20% PEG 8000, 0.15 M samarium acetate, 100 mM Tris–HCl pH 7.0). After 1 h, these crystals were transferred briefly to a cryosolution consisting of the heavy-atom solution supplemented with 20% glycerol and then frozen directly in a stream of nitrogen at 100 K. The Sm-derivative crystals also belong to the monoclinic space group C2, with unit-cell parameters a = 88.5, b = 108.9, c = 64.4 Å, β = 94.7°, and are isomorphous with respect to the native UCK2–ADP–CMP crystals.

2.3. Data collection

All diffraction data were collected using an in-house RUH3R copper rotating anode producing Cu Kα radiation and equipped with an R-AXIS IV⁺⁺ image-plate area detector mounted on a 2θ stage (Rigaku MSC, The Woodlands, TX, USA). The X-ray beam was focused by an Osmic Blue confocal optic and a collimator with a 0.6 mm rear aperture and a 0.3 mm front aperture (Rigaku MSC). The generator power settings were 50 kV and 100 mA for all diffraction experiments. The experimental setup contained a single vertical spindle axis (φ axis). Owing to the reasonable unit-cell parameters of the UCK2–ADP–CMP crystals and the large-area format of the image-plate detector, all diffraction data were measured with the direct beam centered on the detector. Analyzing the initial images collected on the native crystal using the STRATEGY module of the software program CrystalClear (Rigaku MSC), it was determined that the unique crystallographic axis (b axis) was 30° from the φ axis and that ∼98% of a complete 2.0 Å resolution data set could be collected using a continuous φ-axis scan of 150° (1° per image) with a crystal-to-detector distance of 150 mm without reorienting the crystal. The exposure time selected to give strong signal out to the full range of resolution was 60 min per image. CrystalClear analysis of initial images collected on the Sm derivative crystal revealed that the b axis was nearly perpendicular to (86° from) the φ axis, while the a and c axes were more than 10° off of the spindle axis. Thus, 97% of a complete 2.5 Å resolution data set could be collected using a continuous φ-axis scan. In order to collect Bijvoet pairs and to maximize redundancy, the SAD data were collected on the Sm derivative using 1° oscillations per image for a total of 360° with a crystal-to-detector distance of 180 mm and exposure times of 25 min per image. All data were integrated and scaled using DENZO and SCALEPACK (Otwinowski & Minor, 1997) (Table 1). For the Sm-derivative data, anomalous pairs were treated as non-equivalent reflections and were kept separate during scaling and merging steps by using the `SCALE ANOMALOUS' flag in the program SCALEPACK. The refined mosaicity and average data redundancy were 0.46° and 3.0, respectively, for the native crystal and 0.61° and 3.9 (for Bijvoet measurements), respectively, for the Sm-derivative crystal.

Table 1 Structure determination and model refinement statistics (a) Crystal characteristics and data-collection statistics. Values for the outer resolution shell are given in parentheses.   Native Sm derivative Unit-cell parameters (Å,°) a = 88.6, b = 109.3, c = 64.5, β = 95.0 a = 88.5, b = 108.9, c = 64.4, β = 94.7 Space group C2 C2 Molecules per AU 2 2 X-ray source Rigaku RUH3R Rigaku RUH3R Wavelength (Å) 1.5418 1.5418 Resolution (Å) 100.0–2.0 (2.07–2.00) 100.0–2.5 (2. 59–2.50) No. of observations 120872 156169 No. of unique reflections 40772 40316† Completeness (%) 98.8 (96.2) 97.9 (96.4) Mean I/σ(I) 22.0 (6.5) 21.1 (4.7) Rmerge‡ 0.046 (0.165) 0.062 (0.295) (b) Crystallographic data and refinement statistics. The FOM from the CCP4 programs MLPHARE and DM is the average figure-of-merit ≃ 〈cos(phase error)〉. MLPHARE FOM 0.344 (50.0–2.5 Å resolution)for 21067 reflections DM FOM 0.747 (50.0–2.5 Å resolution) for 21067 reflections Resolution range (Å) 50.0–2.0 No. of reflections 45293 (40732 working set, 4561 test set) Completeness (%) 94.1 No. of protein residues/atoms 424/3395 No. of ligand atoms 98 No. of water atoms 315 Rcryst 0.209 Rfree 0.237 Root-mean-square deviations    Bond lengths (Å) 0.006  Bond angles (°) 1.00 Ramachandran plot statistics: residues in    Most favored regions 367 (94.8%)  Additional allowed regions 18 (4.7%)  Generously allowed regions 2 (0.5%)  Disallowed regions 0 (0.0%) †Bijvoet pairs are treated as unique reflections for the Sm-derivative data. ‡Rmerge = .

2.4. Heavy atom and structure determination

The anomalous signal present in the diffraction data is represented graphically in Fig. 1, where the Bijvoet ratio 〈ΔF^anom〉/〈F〉 is plotted as a function of resolution. The anomalous differences from the Sm-derivative data were used to determine the heavy-atom positions in the crystal. Normalized structure-factor magnitude differences (diffEs) were generated from the Bijvoet pairs using the DREAR package (Blessing & Smith, 1999). The anomalously scattering substructure was determined by the dual-space direct-methods (Shake-and-Bake) procedure (Weeks et al., 1994) using the computer program SnB (v.2.2; Weeks & Miller, 1999). 4000 triple invariants were generated from the largest 400 diffE values. A total of 1000 trials were processed, each starting with ten random atoms and each run for 20 cycles of phase refinement. A trace of the minimal function (R_min) revealed a bimodal distribution. The density values of the top four peaks from the best solution were 20.2, 16.9, 15.4 and 13.9, respectively. The next six density peaks in the list range in height from 7.8 to 6.1. These results suggested that the top four density peaks represented four major Sm-atom positions in the asymmetric unit. These four sites were visualized graphically. An approximate twofold non-crystallographic symmetry (NCS) axis was identified by generating several symmetry-related sites for the four Sm atoms and then grouping specific atoms into NCS pairs based on visual inspection using the interactive molecular-graphics program O (Jones et al., 1991). NCS pairs were then superimposed using the LSQ_EXPLICIT routine in O. This program generates a transformation matrix that can later be used directly in density-modification programs for the purpose of NCS averaging. Heavy-atom parameter refinement and phasing were performed with the MLPHARE program (Otwinowski, 1991) from the CCP4 software suite (Collaborative Computational Project, Number 4, 1994) and the phases were improved by solvent flattening using the program DM (Cowtan & Zhang, 1999). The correct hand for the Sm-atom model was determined by inspecting the resulting electron-density maps. The initial average figure-of-merit (FOM) for all reflections to 2.5 Å resolution is 0.344 and improves to 0.735 after density modification (Table 1). Utilizing the available twofold NCS averaging in conjunction with solvent flattening resulted in a final FOM of 0.747. This averaged experimental map was of excellent quality, showing clear main-chain and side-chain density (Fig. 2) as well as several solvent molecules. On the basis of this map, a C^α trace for the first molecule (molecule A) was generated manually, followed by the addition of main-chain and side-chain atoms using the molecular-graphics program O (Jones et al., 1991). Molecule B was then generated by the NCS transformation obtained from the Sm sites. After rigid-body refinement and one round of torsion-angle molecular-dynamics refinement (Rice & Brünger, 1994) using the program CNX (Accelrys, San Diego, CA, USA), the R factor dropped to 28% with a free R factor of 32% using data to 2.5 Å resolution. The model was further improved by iterative cycles of torsion-angle annealing using the 2.0 Å resolution native data set and manual adjustment to the model. In later rounds of refinement, ADP, CMP, a magnesium ion and several water molecules were added to both molecules in the asymmetric unit on the basis of difference density and reasonable hydrogen-bonding distances and geometries.

Figure 1 The presence of anomalous signal in the diffraction data. The Bijvoet ratio 〈ΔFanom〉/〈F〉 is plotted as a function of resolution for the data collected on the UCK2–ADP–CMP samarium-derivative crystal.

Figure 2 A stereo diagram of the averaged solvent-flattened electron-density map calculated from SIRAS phases to 2.5 Å resolution. The map is superimposed on coordinates of the final model in the region of the core β-sheet.

3.1. Structure of human UCK2

Our UCK2 structure is nearly identical to that of the product-bound structure determined previously by Suzuki and coworkers (PDB code bad locator type ; Suzuki et al., 2004). Both structures crystallize in space group C2 with similar unit-cell parameters that vary by less than 0.6%. Superposition of the two structures reveals an r.m.s.d. of 0.15 Ų for 1696 protein backbone atoms in the asymmetric unit (ASU). In contrast, the r.m.s.d. for 844 backbone atoms of molecule A is 0.54 Ų when superimposed with molecule B within the ASU of our structure. A tetramer is formed by the two molecules in the ASU and two additional molecules generated by crystallographic symmetry. The UCK2 monomer contains a core five-stranded parallel β-sheet flanked on both sides by a pair of α-­helices (Fig. 3). Three additional α-helices sit above the core-sheet structure and together with a large β-hairpin loop complete the active site. The enzyme active site contains the products of the phosphate-transfer reaction, ADP and CMP. Since the reaction substrates were added to the crystallization drops, we assume that the reaction proceeded during crystallization. The β-hairpin loop of UCK2 forms an extensive portion of the deep nucleoside-binding pocket. The positions of this loop in our ligand-bound structure and in the structure of the apo enzyme (PDB code 1ufq ; Suzuki et al., 2004) suggest that this unique structural element might act as a flap that modulates substrate binding and product release. A total of 12 hydrogen bonds are formed between side chains of UCK2 and the CMP molecule, accounting for much of the enzyme's specificity. His117 and Tyr112 allow UCK2 to select for nucleosides with both cytosine and uracil bases by either accepting hydrogen bonds from or donating hydrogen bonds to the 4-amino group of cytidine or the 6-oxo group of uridine, respectively. The 2′- and 3′-hydroxyl groups of the ribose moiety are involved in hydrogen bonding to both the acidic side chain of Asp84 and the guanidinium group of Arg166. These four hydrogen bonds most likely explain why UCK2 selects for ribonucleoside over deoxyribonucleoside substrates (Van Rompay et al., 2001). As previously reported (Suzuki et al., 2004), the carboxylate of Asp62 is positioned near the 5′-O atom of the nucleoside monophosphate product and most likely acts as a general base to activate the 5′-­hydroxyl group of the nucleoside substrate, thus facilitating attack of the γ-phosphate of ATP. A similar role for an acidic residue acting as a catalytic base has also been proposed for other sugar and nucleoside kinases, including Asp255 in ribokinase (Sigrell et al., 1998), Asp300 in adenosine kinase (Mathews et al., 1998) and, more recently, Glu53 in deoxycytidine kinase (Sabini et al., 2003).

Figure 3 The overall structure of the human UCK2 monomer. Strands (green) and helices (blue) are represented by arrows and coils, respectively. The reaction products ADP and CMP are shown as sticks, while the magnesium ion is denoted by a cyan sphere. N- and C-termini are labeled accordingly.

In addition to the presence of nucleotides, the active sites of both UCK2 molecules in the asymmetric unit also contain one magnesium ion. In molecule A, the magnesium ion is coordinated by the 5′-­phosphate of CMP and the β-phosphate of ADP in addition to Ser34 and two water molecules. The relatively weaker electron density in this region of the active site of molecule B suggests a lower occupancy for magnesium and ADP. Interestingly, the magnesium ion in molecule B appears to be slightly removed from the active site (∼3 Å) and is coordinated by the side chains of Glu135 and Ser34 as well as the side chain of the catalytic base Asp62, which displays an alternate side-chain conformation compared with that in molecule A (Fig. 4). It is possible that after phosphate transfer the solvent-exposed ADP molecule diffuses out of the active site, while the acidic side chain of Asp62 flips away from the 5′-phosphate of the newly formed CMP molecule. The magnesium ion may remain associated with the Asp62 carboxylate during this process. If this is the case, molecule B may represent an intermediate conformation of the enzyme that occurs during the product-release stage of the reaction. In fact, we have observed that the longer the UCK2–ADP–CMP crystals are allowed to sit in the mother liquor before harvesting the weaker the density for ADP becomes, while the difference density indicating the conformation change of Asp62 becomes stronger (data not shown).

Figure 4 A stereoview comparing the active sites of the two molecules in the asymmetric unit. Asp62 and Ser60 with alternate side-chain conformations together with the magnesium ion from molecule B (magenta) are superimposed on the protein side chains and the magnesium ion from molecule A (cyan). Stick models for the reaction products ATP and CMP from molecule A are also displayed.

3.2. Heavy-atom positions

The brief high-concentration samarium acetate soak resulted in the addition of four well ordered Sm atoms per asymmetric unit of the UCK2–ADP–CMP crystals (Fig. 5). Two of the four samarium sites lie at the interfaces between crystallographically related molecules (one between A and A_symm, one between B and B_symm) near the center of the UCK2 tetramer. The positively charged samarium ion is positioned between Asp158 of one molecule and Glu194 of its crystallographic symmetry mate. The remaining two Sm-atom positions are located within the active sites of the UCK2 molecules, where they appear to have displaced the magnesium ions which are required for crystallization. The Sm atoms are coordinated by the 5′-monophosphate of CMP and the side chain of Asp62. Of the remaining six peaks found by SnB, four also correlate with peaks in the anomalous difference Fourier map calculated using amplitudes of ΔF^anom and phases calculated from the four major Sm sites. These four peaks are probably minor Sm sites and are near surface exposed acidic residues of UCK2 in the crystals. Including the four additional sites does allow a slight improvement in the phasing statistics, with the averaged solvent-flattened FOM improving from 0.747 to 0.765. The quality of the new map, however, reveals no major improvements over the initial map calculated using the four major sites.

Figure 5 A stereoview indicating the location of the four major samarium sites (red spheres). Positions for the magnesium ions in the native UCK2–ADP–CMP crystals are shown as green spheres. ADP, CMP and Asp158 are shown as ball-and-stick models. Molecules A and B are labeled accordingly.

3.3. Conclusions

Soaking native UCK2 crystals in 0.15 M samarium acetate for 1 h resulted in a heavy-atom derivative with four major Sm sites in the asymmetric unit. As with any heavy-atom soaking experiment, the type of salt, the concentration of the compound and the duration of soaking will require some optimization for each unique structure-determination project. The fact that magnesium was required for crystallization and was subsequently present in the product complex may have improved the chances that ordered Sm sites would result from the heavy-atom soaking procedure. The presence of additional well ordered sites on the surface of the UCK2 molecules does indicate that samarium ions have the potential to generate useful heavy-atom derivatives for a diverse set of protein crystals. Further studies are required to substantiate the general application of this technique.

Owing to their large values, the lanthanide metals are a useful class of heavy atoms for anomalous diffraction studies. Gadolinium (Gd), another lanthanide metal, has already shown great utility in macromolecular structure determination by SAD techniques using conventional laboratory X-ray sources (Girard et al., 2003). The anomalous signal at the Cu Kα wavelength arising from the presence of the Sm atoms in our study was sufficient to determine the heavy-atom substructure by direct methods and provided sufficient phasing power to generate an interpretable electron-density map. These results suggest that the use of samarium may represent a general strategy for obtaining a useful heavy-atom derivative for in-house structure determination using SAD and SIRAS phasing techniques. This strategy should definitely be considered when working with metal-binding proteins or proteins that require the presence of metal ions for crystallization.