2.1. Case study 1: the structure of SCRs 6, 7 and 8 from the complement regulator factor H

Although the structures of several fH SCR domains were already known, we were interested in the structure and arrangement of domains in the region of SCR domain 7, since this region is implicated in recognition of surface glycosaminoglycans, thus conferring on fH the selectivity that enables it to protect self-tissues against complement-mediated lysis. In order to obtain structural insight into the fH–glycosamino­glycan recognition event, crystals were grown of a three SCR-domain construct comprising domains 6, 7 and 8 (fH678) in complex with sucrose octasulfate (SOS; Prosser, Johnson, Roversi, Herbert et al., 2007), a highly sulfated analogue of glycosaminoglycans.

Crystals of fH678–SOS were obtained and native data were collected to 2.4 Å resolution; the crystals belonged to space group C222₁ and had a likely content of one copy of fH per asymmetric unit (Prosser, Johnson, Roversi, Clark et al., 2007). We then sought to use all possible SCR domains from the PDB to determine the structure by three different molecular-replacement protocols: three sequential searches for single SCR search models, a search for a pair of SCR domains followed by an additional single one or a single search for a triple SCR-domain search model. The molecular-replacement computer programs used were MOLREP, Phaser and AMoRe from CCP4. Various modifications of the models, including the use of CHAINSAW (Stein, 2008), reducing to the backbone and forming ensembles, were tried. None of these attempts proved successful. This was rationalized as arising from the fact that whilst it was clear that the three domains we were searching for were SCR domains (each with a pair of conserved disulfides and a buried tryptophan), the level of sequence identity was low (20–30%). When different SCR models are overlaid, it is clear that these domains pack a lot of structural variation into a small and fairly constrained structure. SCR interdomain angles also vary widely and cannot be predicted. These orthorhombic crystals suffered rapid radiation damage, thus hindering attempts at phasing by sulfur-SAD (which needs high-redundancy data sets, preferably collected from a single crystal) or phasing by radiation damage-induced phasing (RIP; Ravelli et al., 2003) (which needs a relatively radiation-damage-free data set before the non-isomorphism is introduced by a heavy X-ray dose and still requires measurable diffraction from the same crystal afterwards). As FH₆₇₈ con­tains two methionines (one in SCR domain 6 and one in SCR domain 7), SeMet labelling of the recombinant protein was performed. Multiple data sets were collected (for details of data quality, see Prosser, Johnson, Roversi, Clark et al., 2007) and autoSHARP–SHELXD could interpret both the anomalous and the isomorphous difference Patterson maps with a model containing two Se atoms. SHARP was used to refine the heavy-atom model against a 2.4 Å resolution native data set and a three-wavelength 2.5 Å resolution SeMet MAD data set and SOLOMON was used to solvent-flatten the resultant phases, but the correct hand could not be distinguished. The Patterson peak heights and the heavy-atom parameters refined for these two sites in SHARP suggested that one of the methionines was significantly more ordered than the other and even the more ordered methionine was undergoing a large thermal motion: the SHARP B factor for one Se refined to around 100 Ų and the B factor for the other Se refined to around 170 Ų. These B-factor values were obtained consistently against isomorphous and anomalous differences from a number of different SeMet MAD data sets and irrespective of the treatment of heavy-atom site occupancies during the refinement protocol; both letting individual Se occupancies vary while keeping f′ and f′′ at the experimentally measured values and keeping the occupancies fixed to unity while refining f′ and f′′ instead produced the same result. The final refined B factors for the S atoms of these Met residues in the deposited crystal structure are 52 and 90 Ų (the average B factor for the side chain was 50 Ų). The lack of hand discrimination power of this set of experimental phases was therefore not unexpected, since attempting to phase a 186-residue structure with essentially one poorly ordered Se atom was rather beyond the realms of the possible. Attempts to use heavy-atom soaks to generate additional phasing information also failed.

At this point new phase information was needed and it was provided in the form of the structure of SCR 7 (hereafter known as fH7), which was determined by Paul Barlow and colleagues using NMR (Herbert et al., 2007). A single copy of a search model from the NMR ensemble could unambiguously be found using each of the molecular-replacement programs: the MR hit (as became obvious with hindsight after structure completion) was always to the fH7-domain placement and repeating the search with the same fH7 model (or any of the other SCR domains from the PDB in the presence of the fH7 first partial model) did not reveal the position and orientations of the flanking SCR domains. Refinement of the fH7 model (consisting of less than a third of the structure) against the fH678–SOS data using BUSTER-TNT led to maps which were not readily interpretable outside of the modelled domain.

At this point we were therefore in possession of two sets of poor phases and so it became an obvious strategy to attempt to combine these phase distributions to generate improved phase estimates (Read, 1986). Various methods for combining the experimental and molecular-replacement phases were con­sidered, but for ease of resolution of hand/origin issues and also to help the conditioning of the heavy-atom refinement we decided to use the DM solvent-flattened BUSTER-TNT phases as input to SHARP and to use them for heavy-atom location, heavy-atom refinement and to generate the final phase distributions. These phases were good enough to con­firm the location of both Se atoms in the isomorphous and anomalous log-likelihood gradient (LLG) maps in SHARP; more importantly, refinement of the two-Se heavy-atom model conditioned by the BUSTER-TNT phases and solvent flattening of the internally combined phase distributions (using SOLOMON as driven from the SUSHI interface) produced a new `phase-combined and solvent-flattened' map that began to show sensible electron density outside the fH7 model and allowed the building of some residues at the N- and C-termini of the central domain. It is worth noting the phase combination with the model phases prior to solvent flattening had the additional advantage that the solvent-flattening masks included the parts of structure modelled thus far. Fig. 1 shows the phase errors between both the uncombined and combined phases compared with the reference phases generated from the final refined model. Fig. 2 shows the quality of the corresponding maps. Whilst it is clear that the combined phases were not magically `correct' (and they certainly did not allow automatic model building), they were sufficiently improved that manual rebuilding could begin. Indeed, we followed a iterative phasing protocol, each cycle of which comprised (i) building of a small additional portion of the model, (ii) refinement in BUSTER-TNT using the solvent-flattened combined phases from the previous cycle to define the missing-atoms envelope during refinement and (iii) calculation of a new set of combined phases within SHARP to help refinement of the heavy-atom model and guide the solvent flattening of maps for the next round of model building. This process eventually allowed the construction of the complete model for the fH SCR domains 6, 7 and 8 and location of the bound SOS (Prosser, Johnson, Roversi, Herbert et al., 2007).

Figure 1 Mean phase error across the resolution range for fH678 phase sets at various stages of structure solution compared with calculated phases from the final complete model.

Figure 2 Electron-density maps calculated at various stages of the fH678 structure solution with the final coordinates displayed as stick models. The inset shows a close-up of a typical portion of the map in a region for which no molecular model existed at the point of calculating the map. (a) A SOLOMON solvent-flattened map derived from SHARP phase distributions generated from SeMet anomalous data. (b) BUSTER-TNT phases generated by refining fH7 against the fH678 data with missing atoms modelled. (c) SOLOMON solvent-flattened map using SHARP phase distributions generated from SeMet anomalous data in which BUSTER-TNT phase distributions (as in b) were used within the SHARP refinement and for calculation of SHARP output phase distributions.

2.2. Case study 2: the crystal structure of a complex between SCR domains 6 and 7 from complement regulator factor H and the factor H-binding neisserial protein fHbp

The next example will also show the power of phases from a highly incomplete model to locate and aid refinement of heavy-atom sites. This example also involves a fragment of the crystal structure discussed in the previous section: the sixth and seventh SCR domains of fH were crystallized in complex with a Neisseria meningitidis protein whose biological function is to scavenge fH onto the bacterial surface (Schneider et al., 2009). The neisserial protein fHbp is approximately twice the size of the two-domain construct fH67 and consists of a C-­terminal half (the NMR structure of which was available; Cantini et al., 2006) and an N-terminal half of unknown structure. As such, this project seemed another obvious case where molecular replacement was likely to be successful: one third of the structure was known from a crystal structure (Prosser, Johnson, Roversi, Herbert et al., 2007), one third was known from an NMR solution structure (Cantini et al., 2006) and the final third was unknown. The crystals belonged to space group C2 and the unit-cell volume (Matthews, 1968) and the self-rotation function suggested that there were likely to be three copies of the complex per asymmetric unit. Initially, three copies of the fH domains could be located using each of the abovementioned CCP4 molecular-replacement programs; however, despite extensive searching with the NMR ensemble and models, the known portion of the fHbp structure could not be found. Even with missing-atom modelling switched on in BUSTER-TNT and with threefold averaging applied, it was not surprising that refinement of the fH domains alone did not yield an interpretable map for the missing fHbp components, as the partial structure only accounted for one third of the asymmetric unit.

Pt- and Hg-soaked crystals yielded diffraction data sets to a resolution of 3.2 Å; a SAD experiment collected at a wavelength of 1.8 Å gave a 3 Å resolution 28-fold redundant data set to exploit the anomalous signal from the 33 S atoms in the asymmetric unit. None of the data/signals were of sufficient quality to allow heavy-atom finding de novo, but using the partial model BUSTER-TNT phases in SHARP allowed the detection of six Pt sites and one Hg site, and also confirmed (with peaks higher than 3σ in SHARP anomalous LLG residual maps) the location of 11 of the 12 disulfides present in the fH portion of the asymmetric unit, providing a good independent corroboration of the molecular-replacement solution. SOLOMON solvent flattening and DM threefold averaging produced a map in which the majority of the fHbp C-terminal domain could be traced. Once this model had been refined (the model now being about two-thirds com­plete), additional S sites added and the phases again com­bined, the rest of fHbp could be traced: it turned out that the N-terminal domain was also a β-barrel, although differing in topology from the C-terminal one. At the end, 31 of the 33 sulfur sites were visible in the anomalous LLG maps of the long-wavelength SAD data set. Fig. 3 shows the mean phase errors of the phases derived from the third of the model before and after combination with the heavy-atom phases from the sites located using the same partial model. Post factum com­parison of the final structure of fHbp with the earlier NMR structure of the C-terminal barrel suggests that molecular replacement failed owing to small but significant distortions of the β-strands: the strands in the NMR structure could not all be aligned along the lengths of the crystal structure strands, so that any placement that aligned any one strand misplaced the others.

Figure 3 fH67–fHbp. Mean phase errors across the resolution range of the data for the BUSTER-TNT phases derived from the one-third model (fH67 alone) and for these phases combined with the heavy-atom phases compared with calculated phases derived from the fully refined final model.