1. Introduction

There is a high demand for beam time on macromolecular crystallography stations at synchrotron radiation sources. At CHESS the stations that support this field, as part of the MacCHESS facility, are heavily oversubscribed. Efforts are being made to develop systems that allow users to achieve their experimental goals more rapidly. The use of CCD detectors for macromolecular crystallography has been pioneered at CHESS (Walter et al., 1995; Thiel et al., 1995, 1996). They offer efficient detection of X-rays, coupled with a very short readout time. Recently, user-friendly graphical interfaces (GUIs) have been developed to allow users to quickly and intuitively run experiments (Szebenyi, Deacon et al., 1997; Szebenyi, Arvai et al., 1997) using these state-of-the-art detectors. For many projects the exposure time is now the rate-limiting step in the data-collection process.

Macromolecular X-ray diffraction data are generally collected in one of two modes: using either a stationary crystal with a polychromatic X-ray beam (the Laue method) (Helliwell, 1992), or a rotating crystal with a monochromatic X-ray beam (Arndt & Wonacott, 1977). The former is used primarily for time-resolved experiments (Ren & Moffat, 1994), while the latter is the standard for most other types of measurement. The oscillation method (Rossmann & Erickson, 1983) is the most commonly adopted experimental geometry, incorporating a single rotation-axis (the spindle) and an area detector. A highly monochromatic X-ray beam, provided by a silicon or germanium monochromator, is normally used. Multilayer technology can be used to provide a wider band-pass X-ray beam, although this has not previously been applied to protein crystallography. In this paper the possibility of reducing exposure times by using a wide-band-pass monochromatic X-ray beam from a multilayer in standard oscillation geometry is investigated and suitable macromolecular crystallography experiments are identified.

2. Experimental

2.1. Data collection

A multilayer (No. XRO-673-6) was purchased from ECD (now Osmic Inc.). It consisted of 200 layer-pairs of tungsten and silicon, with a d-spacing of 24 Å, deposited on an optically polished electro-less nickel–aluminium substrate. It was installed on the bending-magnet station D1 at CHESS and was operated with no focusing, in a single-bounce geometry at a glancing angle of 1.2°. At one time the reflectivity of the multilayer was measured to be 50% at 8 keV. The energy band-pass of the multilayer was measured to be ∼240 eV at 13.89 keV (ΔE/E = 1.7%), by scanning a silicon crystal. No significant Fresnel structure was observed. The higher-order harmonics were expected to be very small, since the multilayer was manufactured in 1983 and the substrate had a 10 Å r.m.s. roughness. The X-ray intensity was 7 × 10¹⁰ photons s⁻¹ at 100 mA through a 0.3 mm collimator. A standard single-rotation-axis oscillation camera and the Princeton 1K CCD detector (Tate et al., 1994) were used to collect X-ray diffraction data from protein crystals.

A dataset was collected at room temperature from a single-crystal of tetragonal hen egg-white (HEW) lysozyme mounted in a glass capillary (Table 1). Radiation damage soon became apparent and the data collection was stopped after 23 exposures. The images consisted of radially streaked diffraction spots (Fig. 1a), due to a convolution of the crystal mosaicity, the beam divergence and the δλ (wavelength spread) contribution in Braggs law (λ = 2dsinθ). The δλ contribution to this streaking can be calculated from δλ = λcotθδθ. It may be possible to reduce the streaking by collecting stills in a narrow-band-pass Laue geometry, although this was not attempted. Nevertheless, the diffraction peaks appeared to be clearly resolved. A dataset was then collected from a single crystal of human methylthioadenosine phosphorylase (MTAP). The crystal was frozen in a fibre loop at 100 K (see Rodgers, 1994, for a review of cryocrystallography techniques). The detector was moved back and offset with respect to the direct beam to allow for the larger cell dimensions and yet still collect data to 2.6 Å resolution (Table 1). Again the images consisted of clearly resolved diffraction maxima (Fig. 1b), despite the increased mosaicity usually associated with frozen crystals and the significantly larger cell dimensions of this particular protein. The spot size is increased here because of the larger mosaicity.

Table 1 Data-collection information for HEW lysozyme and human MTAP   HEW lysosome Human MTAP Space group P43212 P321 Cell dimensions a = 79.0, b = 79.0, c = 38.0 Å a = 122.5, b = 122.5, c = 45.2 Å Mosaicity used 0.5° 0.75° Crystal to detector distance 72.0 mm 117.0 mm Exposure time 20 s 15 s Oscillation angle 1° 1° Redundancy 1.7 3.1 Number of images 23 162

Figure 1 Oscillation images collected on the Princeton 1K CCD detector from (a) a crystal of tetragonal HEW lysozyme at room temperature (1° oscillation in 20 s), (b) a crystal of human MTAP at 100 K (1° oscillation in 15 s).

3. Discussion

The observed X-ray intensity of 7 × 10¹⁰ photons s⁻¹ at 100 mA, through a 0.3 mm collimator, compares well with the value of 4 × 10¹¹ photons s⁻¹ at 100 mA on the multipole wiggler station F1 at CHESS. This is reflected in the longer exposure times required using the multilayer for a crystal size of about 0.3–0.4 mm³ (15–20 s). Data from the same proteins and to similar resolution have previously been collected on station F1 using 5 s exposures. The multilayer used in these tests was purchased several years ago and was not optimized for this application. More suitable optics are currently available, offering higher efficiency. These results suggest that a multilayer with an energy bandwidth of 100 eV would be useful for structural studies on proteins with cell dimensions of at least 250 Å on the beamlines at CHESS. It may also be possible to manufacture a multilayer offering a selectable bandwidth. Such a device would then offer the crystallographer the possibility of minimizing the exposure time for a protein of given cell dimensions, by using the maximum tolerable bandwidth. The gain in intensity for perfect optics should approximately scale as the bandwidth. When compared with a symmetric Si(111) monochromator, with an intrinsic bandwidth of 1.4 × 10⁻⁴, a 1% bandwidth multilayer offers a 70-fold increase (140-fold for a 2% bandwidth etc.) on a broad-band X-ray radiation source, such as a bending or wiggler magnet. A further intensity increase of anywhere from 20–1000 may be possible if the multilayer is used in conjunction with some focusing optics (either a mirror or by bending the multilayer).

The application of multilayers most likely will not be suitable for wavelength-optimized measurements, often used in the initial structure determination of a particular protein (e.g. by MAD experiments), where accurate measurement of an often weak anomalous signal is essential. However, there are a host of other studies where fine wavelength resolution is not required. For example, as part of a structural-based drug design project it is often desirable to study a large number of different protein mutants and a variety of protein–inhibitor complexes. The structural information can then be combined with data from other disciplines to provide a more complete picture of an enzyme reaction or ligand-binding mechanism. In these cases the structure of the native protein has usually been determined previously. A dedicated multilayer-based data-collection facility, coupled with high-speed computing and automated refinement procedures, would allow these structures to be determined both rapidly and routinely.

4. Conclusions

A multilayer monochromator has been tested at CHESS, which shows promise for speeding up the rapid structure determination of macromolecules, with cell dimensions of ∼250 Å, on bending-magnet synchrotron X-ray sources. Further development by both simulation and testing of a new more perfect optic, as well as developing software to deal precisely with the energy bandwidth, will hopefully improve the data quality and lead to such a device being incorporated on either an existing or new macromolecular crystallography beamline at CHESS.