2.1. Spherical-drift multiwire proportional chambers

The use of synchrotron radiation in the X-ray range became possible at the french synchrotron radiation facility LURE in 1976 when DCI, a 1.85 GeV electron–positron storage ring designed for high-energy physics, became operational. The exploitation of synchrotron radiation in a parasitic mode began immediately with six instruments installed on the first beamline D1. One of these instruments, on station D12, was dedicated to macromolecular crystallography. The set-up was equipped with a purposely modified Enraf–Nonius rotation camera. The monochromator introduced a crystal bender based on elastic properties of a triangular-shaped crystal (R. Fourme, unpublished; Lemonnier et al., 1978). The polarization correction to be applied with the highly polarized synchrotron radiation was derived (Kahn, Fourme, Gadet et al., 1982). This instrument was the first rotation camera used to collect diffraction data with synchrotron radiation (Fourme, 1978; Kahn, Fourme, Gadet et al., 1982; Wilson et al., 1983; Fourme & Kahn, 1985). A typical example of protein structure solved from data collected at D12 is deoxy hemoglobin at 1.74 Å resolution (Fermi et al., 1984). Modifications in the collimation system, suggested by P. B. Sigler, allowed recording of spatially resolved diffraction patterns from crystals with unit-cell parameters in the range 300–1000 Å (Usha et al., 1984). Experience obtained during these early years was essential for preparing a prospective report on the use of ESRF for protein crystallography (Helliwell & Fourme, 1983).

While D12 was under construction we realised that, in a set-up designed for protein crystallography with synchrotron radiation, the area detector was both the most crucial and the weakest component. Based on the pioneering work of G. Charpak at CERN (Charpak et al., 1968), a multiwire proportional chamber (MWPC) for X-ray diffraction applications had been developed by N. H. Xuong and co-workers at San Diego in collaboration with V. Perez-Mendez at Berkeley (Cork et al., 1974; Xuong et al., 1978). This device had attractive characteristics, especially the high accuracy inherent to photon counters and low instrumental noise. But it suffered from parallax effects (i.e. spot elongation observed for beams inclined with respect to the detector axis) and the count-rate capability of its delay-line position encoder was limited. During a meeting held in 1973 with G. Charpak, R. Mössbauer, W. Parak and R. Fourme, it was decided to build two detectors, one for Mössbauer experiments and the other for synchrotron radiation applications. This was the starting point of a long-term collaboration between G. Charpak and his collaborators at CERN (R. Bouclier, R. Benoit, G. Million, J. C. Santiard and F. Sauli) and the LURE team.

At LURE, R. Kahn, the main investigator of this project, and R. Fourme were joined by B. Caudron, then R. Bosshard and later by A. Bahri. Parallax was suppressed by coupling the MWPC to a drift space with radial field lines (Charpak et al., 1974). This drift space is defined by two spherical electrodes and a conical edge with ring-shaped electrodes. Due to the geometry of the drift space and the associated mapping function, the spherical drift MWPC performs a stereographic projection of the reciprocal space (Bricogne, 1987a); this projection is conformal, i.e. angle preserving, transforming circles on the Ewald sphere into circles on the detector plane. The position encoder was of the wire-by-wire type, with one amplifier per wire and priority encoders. These technical solutions were investigated on a prototype detector, called Mark I (Kahn et al., 1980; Kahn, Fourme, Bosshard et al., 1982), and equipped with a short-bending-radius Al entrance window. This detector was developed with a Cu X-ray tube, then installed on the D25 station. The software for data acquisition and partial on-line data reduction was written by R. Kahn, using the limited resources of a PDP 11/34 minicomputer with a 128 K 16-bit memory. An improved and completely redesigned version of this first detector, called Mark II, was built and installed at the D23 station of LURE-DCI. The Mark II was equipped with a wire-by-wire digital encoder allowing a total count rate in excess of 300 kHz. With a large disc-shaped sensitive area (diameter 0.486 m, 185500 1 × 1 mm pixels), a negligible instrumental noise, a detective quantum efficiency close to unity, and a very short dead time (∼1 s) obtained by double-buffering, this detector was a milestone in the development of gas chambers for macromolecular crystallography (Kahn, Fourme, Bosshard, Chiadmi et al., 1986).

At this stage it became clear that a new software package was needed both to drive data acquisition and to process diffraction images. This was provided by the EEC initiative described below, which resulted in the EEC MADNES software package. The implementation of EEC MADNES on the Mark II diffractometer was a crucial step forward, as it allowed the full exploitation of the intrinsic qualities of the detector [reviewed by Kahn & Fourme (1997)]. The final evolution of the spherical drift MWPC was the Mark III. With respect to the Mark II, the new feature was a position encoder designed for fast determination of the centroid of electron clusters resulting from the conversion of X-ray photons. This encoder improved both spatial resolution and uniformity (Bahri et al., 1992). The Mark II was installed on the D41 station at LURE-DCI and open to users under the supervision of A. Bentley. It was used for data collection at an essentially fixed wavelength (∼1.4 Å). Then, image-plate detectors which were simpler to operate and maintain became available, and the Mark III operation was stopped in 1993.

2.2. The EEC detector software initiative

The EEC MADNES software package was the product of an EEC initiative organized in 1986 by G. Bricogne (Bricogne, 1986a,b, 1987b) for the purpose of implementing, through a series of cooperative workshops, a single program structure providing device independence, computer independence without loss of efficiency, and method independence in the data reduction. This implementation was carried out starting from the MADNES package (Messerschmidt & Pflugrath, 1987) which was at the time specific for the Enraf–Nonius FAST system. Many specialists participated in the various workshops. This EEC initiative had a substantial and irreversible impact on the evolution of position-sensitive detector software: before the workshops, each package was tied to a particular combination of detector and goniometers; after the workshops, many of the packages were upgraded to process data from many different such combinations. Several original concepts emerged during these workshops, notably the idea of three-dimensional auto-indexing by Fourier transform methods (Bricogne, 1986b, p. 28) which was subsequently implemented in the DENZO package (Otwinowski & Minor, 1997).

The scientific manifesto of the workshops (Bricogne, 1986a) proposed a long-term approach to data acquisition in terms of Bayesian statistics, whose methods were invoked in particular to estimate and update three-dimensional reflection profiles and to carry out reflection integration itself. This Bayesian approach was viewed as seamlessly connected to the subsequent steps of phase determination and structure refinement which were later described under the name of `Bayesian programme' (Bricogne, 1988, 1993). This unified picture of the statistical underpinnings of crystal structure determination, from raw data acquisition through phasing to the final structure refinement, still holds much untapped potential.

2.3. First results on the MAD method

One of the goals of the MWPC project was the implementation of the multiwavelength anomalous diffraction method (MAD). A research project on MAD began at LURE in the late 1970s. This development was triggered by the pioneering work at SSRL (Stanford) in several fields, including EXAFS instrumentation; first experiments on anomalous diffraction performed with a precession camera (Phillips et al., 1977); the discovery of large resonances at the L-absorption edges of cesium and the associated large magnitudes and changes in f′ and f′′ which were potentially very attractive for phasing applications (Phillips et al., 1978); and the determination of MAD phases by a MIR-like approach (Phillips & Hodgson, 1980). We established a collaboration with O. Dideberg at Liege for the determination of the unknown structure of parvalbumin IIIf from the superfast swimbladder muscle of a fish, Opsanus tau. This protein was chosen for several reasons: it is a small molecule (10.1 kDa), which binds two Ca²⁺ ions which can be substituted by lanthanides; the space group is P2₁2₁2 with one molecule in the asymmetric unit and good crystals of the terbium complex, diffracting to at least 1.7 Å, were available. Diffraction experiments were performed at the terminal station, D15, of the bending-magnet beamline D1. The set-up included a Ge(220) channel-cut monochromator, a single-axis goniometer from an Enraf–Nonius camera and the Mark I detector. A crystal was accurately aligned along the b-axis in order to measure Bijvoet mates at the same time. Three data sets at a resolution of 2.3 Å were measured in 36 h at wavelengths close to the L_III-absorption edge of terbium. These wavelengths were selected in order to minimize average phase errors (Narayan & Ramaseshan, 1981): at the peak (f′′ maxi­mum), at the inflection point of the f′′ curve (|f′| maximum) and 0.0021 Å below the peak wavelength. Diffraction images were recorded over small angular intervals (20 images per degree), with the wavelength kept constant through 15° sectors. Coordinates of lanthanide ions were determined from Harker sections of an anomalous Patterson-difference map at the peak wavelength and refined against the strongest anomalous differences (Hendrickson & Teeter, 1981). One fully occupied and one minor site were found. Phasing of acentric reflections was performed in a pseudo-MIR mode with a program written by R. Fourme. The (hkl) set at the peak wavelength was selected as reference, and the total phase probability distribution P(φ) was taken as the product of distributions formed from the five pairings of the reference set with the remaining sets (hkl and h¯kl) at the various wavelengths. Centric reflections were determined by a method where the various data sets are treated on an equal footing and which considers phases and amplitudes of the wavelength-independent part of structure factors as random variables. This method was later extended to acentric reflections (Chiadmi et al., 1993). In a MAD experiment it is essential to derive accurate values for f′ and f′′ at the various wavelengths. In the parvalbumin study, initial f′′ values were determined by measuring, in the wavelength range of interest, the difference in intensities of mates in a selected Bijvoet pair; f′ values were obtained by numerical integration via the Kramers–Kronig dispersion relation. These values were refined by minimization of the total lack of closure over all reflections. The MAD electron density based on 2439 phased reflections was calculated for the two enantiomorphs and one of these maps allowed an unambiguous chain tracing. Independently, O. Dideberg solved the structure at 3.2 Å resolution by molecular replacement, using the carp parvalbumin molecule (Moews & Kretsinger, 1975) as model. The average phase discrepancy for reflections common to both determinations is 54°, prior to any refinement of either structure. The structure of Opsanus tau parvalbumin (Kahn et al., 1985; Kahn, Fourme, Bosshard, Chiadmi et al., 1986) is the first unknown ­structure determined by MAD phasing (Fourme & Hendrickson, 1990), although the folding was of a known type. The use of an electronic area detector with a short dead time allowing a fine slicing of reciprocal space was very innovative. Nevertheless, the accuracy and completeness of data collected during this experiment were not optimal, due to inhomogeneities in the response of the various detector channels and limitations in both detector hardware and data analysis software. These problems were essentially solved with the installation in 1984 of the Mark II detector, coupled to a multicircle diffractometer, on the D23 station (Kahn, Fourme, Bosshard, Chiadmi et al., 1986). After the implementation of EEC MADNES, the progress with respect to the pioneer parvalbumin experiments can be best appreciated with the solution by MAD of the structure of the carbohydrate recognition domain of a rat mannose-binding protein (Weis et al., 1991). The asym­metric unit contains a dimer in which the four native Ca²⁺ ions can be substituted by lanthanides. A crystal from the holmium complex was used for a three-wavelength MAD experiment at the Ho L_III-absorption edge. Values for the observed anomalous diffraction ratios 〈Δ|F|²〉/〈|F|²〉 (where Δ|F| is the Bijvoet difference at each wavelength) for centric reflections can serve as an estimate of the noise in the anomalous signals. These values (1.9, 2.1 and 1.7% at the remote, peak and edge wavelengths, respectively) as well as the merging Rsym value on intensities for the remote wavelength data set (3.1%) are very low, even according to current standards, especially as the whole data were obtained from a single sample kept at ∼277 K (not cryocooled) for several days. Monochromator instability during data collection produced a variability of edge and peak Ho³⁺ scattering factors. This problem was overcome by a least-squares refinement of scattering factors by blocks of data. It drew our attention to the fact that small changes in f′′ and f′ values due to wavelength drifts produced subtle non-isomorphism; accordingly, the refinement of f′′ and f′ values as parameters of the anomalous structure had to be included in a fully fledged treatment, which was achieved a few years later with the program SHARP as discussed in §5. Finally, a unique set of 7195 reflections (completeness 89.3%) was obtained. The phasing procedure was per­formed by the algebraic method (Karle, 1980; Hendrickson, 1985) using MADLSQ (Hendrickson, 1985). The |⁰F_A| Patterson map was extremely clear, and the quality of the MAD-phased electron density map allowed the construction of a molecular model with no significant deviations from the ideal geometry which was refined to a crystallographic R-factor of 0.176. This example demonstrated the feasibility of obtaining very accurate MAD phases.

W. Shepard and R. Fourme installed in 1994 a new MAD station, DW21, on the wiggler beamline of the storage ring DCI. The equipment includes double-focusing optics with a curved mirror and a sagittal-focusing monochromator, a commercial image-plate detector, a cryocooling system and a system for the detection of fluorescence based on an Si diode. With typical exposure times in the range 15–300 s per degree and the fairly long dead time of the image-plate detector, DW21 cannot compete with CCD-based instruments at third-generation synchrotron sources for data-collection rates. In contrast, the accuracy of data collected at DW21 may be excellent. This is due to the stability of the operating conditions of DCI (broad positron beam, beam lifetime in excess of 220 h) and to the care taken at the various steps of data collection and analysis, as illustrated in §6 (Schiltz et al., 1997a). Representative examples of structures solved by MAD using data collected at DW21 and which led to high-quality electron density maps are: a `zipper' DNA (Shepard et al., 1998), a double-stranded DNA containing a cisplatin interstrand cross-link at 1.63 Å resolution (Coste et al., 1999), and cytochrome 552 from Pseudomonas nautica with eight molecules in the asymmetric unit (Brown et al., 1999); the anomalous scattering species were Br, Pt and Fe, respectively.

4.1. Binding of xenon and krypton to proteins

Early experiments with xenon gas in protein crystallography go back to the work of Schoenborn et al. (1965) and Tilton et al. (1984) on myoglobin–xenon complexes. The general principles of xenon binding to proteins are reviewed by Schiltz et al. (1994) but a brief outline is given here. Xenon complexes with proteins are obtained by subjecting a native protein crystal to a xenon-gas atmosphere pressurized in the range 1 × 10⁵–50 × 10⁵  Pa. Xe atoms are able to diffuse rapidly towards potential interaction sites in protein molecules via the solvent channels that are always present in protein crystals. The number and the occupancies of xenon binding sites vary with the applied pressure. The interaction of xenon with proteins is the result of non-covalent weak-energy van der Waals forces and therefore the process of xenon binding is completely reversible. It also implies that xenon binding only induces very marginal perturbations to the surrounding molecular structure. As a consequence, these xenon complexes are almost always highly isomorphous to the native crystals. Xenon is able to bind to a large variety of sites in proteins (Prangé et al., 1998), including closed intramolecular hydrophobic cavities, accessible active sites, intermolecular cavities and channel-pores. Essentially the same interactions as for xenon also exist with krypton, and protein-krypton complexes can be prepared in the same way (Schiltz et al., 1997a).

4.2. A brief historical survey

The use of xenon as a heavy atom for phase determination was first suggested by Schoenborn & Featherstone (1967) who immediately realised its potential benefits by stating that “Xenon is a little `lighter' than desirable for a heavy atom, but this is counteracted by the fact that xenon protein complexes show a high degree of isomorphism with the native crystals – a fact often not true with most of the commonly used `heavy atoms' which are generally ionic groups capable of inducing some disorder into the native structure.” However, it was not until 1991 that Vitali et al. (1991) demonstrated that SIRAS-phases computed from the xenon complex of myoglobin yielded an interpretable electron density map for that protein. Following a suggestion by T. Prangé, a comprehensive research project on xenon derivatives was started at LURE in 1993 with three specific goals in mind: (i)  devising a simple and generally applicable method for the preparation and X-ray data collection of isomorphous xenon derivatives; (ii)  testing this method on proteins other than myoglobin and haemoglobin; and (iii) using xenon derivatives for determining phases of unknown protein structures. A first outcome of this work was the design of a high-pressure xenon cell and the setting up of a standard protocol for data collection under xenon gas pressure (Schiltz et al., 1994). Furthermore, it was shown that, apart from the well known cases of the haem-proteins, xenon is able to bind to a large number of different proteins (Schiltz et al., 1995; Prangé et al., 1998).

The first xenon derivative on a protein of unknown structure was obtained on urate oxidase in 1993 [the structural study was published in 1997 by Colloc'h et al. (1997)]. A highly substituted xenon derivative was obtained at a gas pressure of 8 × 10⁵  Pa. Mercury and lead derivatives had been obtained previously for this protein, but the binding sites in both derivatives are at almost identical locations, thus limiting their phasing power. The contribution of the xenon derivative was crucial for the successful determination of this structure by the MIR method: the single xenon binding site is at a large distance from the heavy-atom sites in the two classical derivatives. This emphasizes another advantage of xenon derivatives; because xenon tends to fix into hydrophobic cavities, these binding sites are very likely to be different from those of classical heavy-atom compounds which predominantly bind to specific functional groups.

The real breakthrough came in 1994, when the structure of the ligand-binding domain of the human nuclear receptor RXR-α was solved with a xenon derivative prepared at LURE at a gas pressure of 20 × 10⁵  Pa (Bourguet et al., 1995). This structure was solved with an initial 5 Å SIR map, based solely on the xenon derivative. The α-helices of the structure were clearly visible in this initial map and a discontinuous polyalanine model could be traced. Density modification via solvent-flattening and recombination with the SIR phases yielded an interpretable electron density map for the whole molecule. At a latter stage, a classical mercury derivative was obtained and these data were added to the SIR phases to improve the map. Because of its high isomorphism, the xenon derivative has a significantly better phasing power than the mercury derivative. This was the first published example where a xenon derivative had been used to determine the phases of an unknown protein structure. It established the credentials of the method and it immediately triggered the attention of the crystallographic community.

4.3. Recent developments and current status

Since then, xenon derivatives have been successfully used for the structure determination of a number of other proteins, including Photosystem I (Krauss et al., 1996), cartilage oligomeric matrix protein (Malashkevich et al., 1996), DMSO-reductase (Schindelin et al., 1996), the outer-surface antigen P64k from Neisseria meningitidis (Li de la Sierra et al., 1997), the CheY-binding domain of histidine kinase CheA (Welch et al., 1998), N-myristoyl transferase (Weston et al., 1998), Arcelin-1 (Mourey et al., 1998) and thermostable β-mannanase (Hilge et al., 1998).

Meanwhile, alternative designs for room-temperature pressure cells had been proposed (Stowell et al., 1996) and the problem of flash-freezing xenon derivatives was addressed by Sauer et al. (1997), Schiltz, Shepard et al. (1997) and Soltis et al. (1997) who showed that the pressurization and flash-freezing steps can be separated in time. Sauer et al. (1997) also developed two elegant devices for the production of freeze-trapped xenon derivatives. Alternative designs of such devices were presented by P. Mancia & R. P. Evans (unpublished), Soltis et al. (1997) and Djinovic-Carugo et al. (1998).

Xenon and krypton also display interesting anomalous scat­tering properties (Schiltz, Shepard et al., 1997; Schiltz, Kvick et al., 1997). The K-absorption edge of krypton is situated at a wavelength (0.866 Å) that is readily accessible on synchrotron radiation sources and that is near the selenium and bromine edges. The absorption edges of xenon are situated either at long or very short wavelengths (2.6 Å for the L_III edge and 0.36 Å for the K edge), which are more difficult to harness technically, but at the Cu Kα wave­length the residual anomalous signal from the L_III edge is still significant: f′′ = 7.4. Thus, SIRAS experiments on xenon derivatives with Cu Kα radiation were successfully carried out by Vitali et al. (1991) and Weston et al. (1998).

In two SIRAS test studies (Schiltz, Shepard et al., 1997; Schiltz, Kvick et al., 1997), carried out respectively on krypton and xenon derivatives of the protein porcine pancreatic elastase (PPE), the potentials of highly isomorphous noble-gas derivatives were evidenced. Perhaps even more significant, these studies strikingly demonstrated the crucial importance of the coupling between careful data-collection schemes designed to accurately harvest weak signals with the optimal statistical treatment of these data, as will be discussed in more detail in §6.

For many MIR projects, testing for xenon binding is now included as a routine part in the screening for derivatives. From the experience gathered at LURE and at SSRL (Stowell et al., 1996), one can estimate conservatively that the success rate for xenon binding is higher than 30%. Many protein crystallography groups have their own in-house pressurization apparatus and equipment for the preparation and X-ray data collection of xenon derivatives is provided to users on the crystallography beamlines at a number of synchrotron centres including LURE Orsay,² SRS Daresbury³ and SSRL Stanford.⁴ As a latest development in the field, xenon-derivatization flash-cooling devices are being commercialized by companies, including the Molecular Structure Corporation and Oxford Cryosystems (in collaboration with the University of Oxford).

Apart from their use in phase determination, xenon derivatives have also been used or proposed for other interesting applications such as the mapping of hydrophobic cavities in proteins (Tilton et al., 1984; Quillin et al., 1996; Prangé et al., 1998), the exploration of pathways for gas access in hydrogenases (Montet et al., 1997) or for X-ray contrast-variation imaging of lipids and detergents in crystals of membrane proteins (Sauer et al., 1997).

6.1. Test SIRAS phasing of a 26 kDa protein with half a krypton atom

X-ray diffraction data at the high-energy side of the krypton K-edge (0.86 Å) were collected on a crystal of pork pancreatic elastase (PPE) put under a krypton gas pressure of 56 × 10⁵  Pa (Schiltz, Shepard et al., 1997). The occupancy of the single krypton atom is approximately 0.5, giving isomorphous and anomalous scattering strengths of 15.2 and 1.9 electrons, respectively. This derivative was used successfully for phase determination with the SIRAS method. After phase improvement by solvent flattening, the resulting 1.87 Å electron density map is of exceptionally high quality, and has a correlation coefficient of 0.90 with a map calculated from the refined native structure. Over 50 water molecules appear as spherical peaks in this map, which is based purely on experimental data. That the equivalent of half a krypton atom is sufficient for the structure determination of a 26 kDa protein is in itself a remarkable outcome. Apart from the near-perfect isomorphism between the krypton derivative and the native structure, the key steps in the achievement of this result were as follows:

(i)  High-quality data. Data were collected on the DW21 beamline at LURE on an imaging plate. Parameters were carefully chosen so as to collect highly redundant data sets with minimal noise and without detector saturation effects, even at low resolution.

(ii)  Reducing systematic errors in the isomorphous differences. This was accomplished by collecting native and derivative data on the same crystal (before and after pressurization, respectively), in the same orientation. Residual systematic errors were reduced by parametrized local scaling of derivative to native data which also proved to enhance the accuracy of the anomalous differences.

(iii)  Optimization of the anomalous signal. This was achieved by tuning the energy of the X-rays to 14.361 keV, just past the krypton K-edge (on the high-energy side), to optimize the anomalous signal (i.e. to maximize f′′). Also, the crystal was pre-oriented in such a way that Bijvoet mates were collected on the same frame. Even though the anomalous signal is quite weak, the SIRAS phases are of significantly higher quality than phases computed in SIR mode (these give a final map correlation coefficient of 0.72).

(iv)  Optimal statistical treatment of isomorphous and anomalous differences. The use of the program SHARP for heavy-atom refinement and phasing played an essential role in the successful determination of the high-quality electron density map. Initial attempts to use the program MLPHARE gave rise to problems with the treatment of the weak anomalous signals. The final solvent-flattened SIRAS map which was calculated from MLPHARE phases is of lower quality and has a correlation coefficient of 0.69 with a map computed from the refined native structure. This study was one of the very first applications of SHARP to real data and it gave the first indications of the superiority of a complete implementation of the maximum-likelihood theory for heavy-atom refinement over previous approaches. Thus, the use of xenon and krypton derivatives, when they can be obtained, associated with statistical heavy-atom refinement allows one to overcome the major limitations of the isomorphous replacement method, i.e. non-isomorphism and the problem of optimal estimation of heavy-atom parameters.

A similar experiment, which was carried out at the ESRF, was also performed on a xenon derivative of PPE, with data collected at the high-energy side of the xenon K edge (λ = 0.36 Å) (Schiltz, Kvick et al., 1997). It essentially confirms the conclusions drawn in the study with krypton. This is the first fully documented report on a complete protein crystallography experiment, from data collection up to phase determination and calculation of an electron density map, carried out with data obtained at ultrashort (∼0.3 Å) wavelengths. Potential advantages of the use of very short (∼0.5 Å) or ultrashort wavelengths in macromolecular crystallography have already been addressed by Helliwell & Fourme (1983), Helliwell (1992) and Helliwell et al. (1993).

6.2. N-myristoyl transferase

In many respects the structure determination of N-myristoyl transferase (Weston et al., 1998) also proves to be a typical illustration of the advantages that highly isomorphous xenon derivatives, combined with mindful data-collection schemes and with a proper statistical heavy-atom refinement and phasing, can offer. A three-wavelength MAD dataset of standard quality was collected on an Se-Met protein at the ESRF, but the determination of the positions of the 12 Se atoms proved intractable. At a latter stage a flash-frozen xenon derivative (pressure 10⁶ Pa) was prepared and data were collected on an in-house X-ray generator with Cu Kα radiation. A second crystal was subjected to exactly the same treatment, but the xenon gas was allowed to diffuse out of the crystal before cryocooling, thus giving a native dataset. The authors report that the relative weakness of the isomorphous differences (R_iso  =  0.091) almost led them to discard the xenon derivative as being native. However, the isomorphous difference Patterson map showed clear cross-vectors and ten xenon sites could be refined in SHARP. The resulting SIRAS phases allowed for the straightforward detection of the positions of the 12 Se atoms by difference Fourier analysis. Most surprisingly, the SHARP-refined xenon SIRAS phases alone (after solvent-flattening) were of better quality than both the combined Xe/Se phases and the pure Se-MAD phases (after solvent-flattening). Eventually, the structure was solved from the solvent-flattened xenon SIRAS map. The authors also report that various attempts to derive SIRAS phases with the program MLPHARE (combined with solvent-flattening) failed to produce an interpretable electron density map.

6.3. SAD phasing with weak anomalous signals

The possibility of solving a protein structure from anomalous scattering at a single wavelength (SAD) was first achieved on crambin (Hendrickson & Teeter, 1981). Rusticyanin is the largest structure solved from SAD data to date (Harvey et al., 1998). The lack of information inherent to SAD alone was completed by information coming either from a Sim distribution (crambin) or direct methods (rusticyanin). A test SAD experiment on native tetragonal crystals of hen egg-white lysozyme (HEWL) was performed by Dauter et al. (1999). The data collection with an image-plate detector at the NSLS (Brookhaven) was standard, except for the high multiplicity and high completion of observations resulting mainly from multiple measurement passes with different limits and exposure times. The structure was solved from the weak anomalous signal of ten native S atoms and seven chlorine ions from the crystallization solution loosely bound to the protein surface (expected Bijvoet ratio at 1.54 Å, ∼1.5%). The partial structure of anomalous scatterers was solved by direct methods on the basis of Bijvoet differences with the program SHELXM (Sheldrick, 1998). From the initial bimodal phase distribution, the application of SHARP and SOLOMON produced an electron density map highly correlated (correlation factor 0.80) to the electron density of the refined structure.