2.1. OH1 configuration

The common OH1 houses standard ESRF high-powered primary slits (Marion & Zhang, 2004), a standard ESRF high-vacuum white beam viewer (WBV), and a photon absorber. The WBV contains a water-cooled optical-grade chemical vapour deposition (CVD) diamond that can be inserted into the X-ray beam using a pneumatic actuator. A Basler acA1300-30gm GigE monochrome camera (Basler AG, Ahrensburg, Germany) is used for visualization via a web browser and can also be configured as a counter or X-ray beam position monitor (XBPM) via the LIMA generic library (Homs et al., 2011). In addition, the CVD diamond can act as a scattering element for an integrated diode, with adjustable gain settings, which is used to optimally align the primary slits.

2.2. OH3 configuration

OH3 is equipped with a standard ESRF liquid-nitro­gen-cooled Si (111 reflection) channel-cut monochromator for energy selection and a transfocator for the vertical focusing of the X-ray beam. A number of ancillary devices are also installed to facilitate the alignment of the beamline and for X-ray beam diagnostic purposes. These include a WBV, as described above for OH1, installed just before the monochromator about 60 m downstream of the source; a carousel containing two empty slots and a number of calibration foils (Fe, Cu, Pt, Mo and Zr) with a pneumatic activated direct diode read via a Keithley picoammeter for monochromator calibration and diagnostic purposes; and a monochromatic beam viewer (MBV) containing a cerium-doped YAG that can be inserted into the X-ray beam using a pneumatic actuator. For the latter device a Basler acA1300-30gm GigE camera is again used for visualization and can again be configured either as a counter or XBPM via the LIMA generic library (Homs et al., 2011). This MBV element contains an additional pneumatic actuator containing a foil, the scattering from which is monitored via a Keithley picoammeter. This MBV diode is used to optimally align the transfocator.

2.3. EH3 configuration

The ID30B experimental hutch, EH3, is situated in the Chartreuse Hall extension of the ESRF and accommodates both the horizontal focusing element and the beamline end-station. EH3 is large as it accommodates a long (1 m) horizontal focusing mirror close to the sample measurement area in order to achieve the required horizontal beam size (20–200 µm). Installation of an ESRF standard X-ray phase-plate setup is foreseen to facilitate the use of polarized resonant scattering in MX anomalous phasing experiments (Schiltz & Bricogne, 2008). Several other ancillary devices, including beam viewers, slits and X-ray beam conditioning elements (slit box) were also installed to facilitate X-ray beam optimization and alignment procedures.

2.4. EH3 sample environment

The ID30B sample environment is composed of a MD2S diffractometer (Arinax, Moirans, France), a PILATUS3 6M detector with a 1 mm-thick Si sensor [Dectris, Baden-Dättwil, Switzerland (Broennimann et al., 2006)] mounted on a fast translation table, and a FlexHCD robotic sample changer (Fig. 2). In addition, a 700 series cryo-stream (Oxford Cryostreams, Oxford, UK) with annealing device (Giraud et al., 2009) is mounted on a REX rapid nozzle exchanger (Arinax, Moirans, France). Similar to the other MX beamlines at the ESRF the whole experimental setup is fixed on a large granite table to facilitate the simultaneous alignment of all elements to the X-ray beam position. The table is mounted on three motorized vertical supports and can be translated in the horizontal direction using two additional motors. These motors are in a closed loop and can be moved independently, or as a series of pseudo motors for controlling the table height, translation, roll, pitch and yaw. This setup facilitates an easy alignment of the experimental setup with the X-ray beam, especially after energy changes as channel-cut monochromators displace the X-ray beam vertically during this procedure.

Figure 2 Photograph of the ID30B experimental hutch highlighting the MD2S diffractometer, REX rapid nozzle exchanger and FlexHCD sample changer. The beam path is highlighted as a red arrow.

The first element on the experimental table is a high-vacuum slit box containing a single set of beam-defining/cleaning slits (JJ-XRAY, Lyngby, Denmark) followed by two beam diagnostic elements separated by a fast (∼70 ms per 90°) rotary shutter containing a large opening. The fast shutter is connected to the MD2S diffractometer to allow synchronization with its goniometer axis. Both beam diagnostic elements are comprised of a cerium-doped YAG screen with a Basler acA1300-30gm GigE camera for visualization of the X-ray beam and a 125 µm-thick Kapton scattering foil diode mounted on a rotary table for easy insertion or retraction in the X-ray beam. During user operation, the diodes remain in the X-ray beam and are read using a Keithley picoammeter. The readings from these diodes are regularly calibrated at different energies and aperture settings against a standardized control diode placed at the sample position. These readings provide continuous real-time flux measurements during experiments and are relatively constant across the energy range (6–20 keV) available on ID30B (Fig. 3).

Figure 3 Photon flux (photons s−1) at the sample position as a function of photon energy and beam-defining aperture used at 200 mA storage ring curent.

2.4.1. The MD2S diffractometer

The MD2S diffractometer, the first device of this type installed on an MX beamline, has a maximum goniometer axis rotation speed of 720° s⁻¹, and a Mini-Kappa goniometer head (MK3) (Cipriani et al., 2007; Brockhauser et al., 2011, 2013) is mounted to provide crystal realignment with a sphere of confusion of <1.5 µm (Fig. 4a). An AXAS-A X-ray fluorescence detector (KETEK, Munich, Germany) on a retractable pneumatic table has also been fully integrated into the MD2S. An additional digital I/O card was installed in the MD2S control electronics rack for direct detector control thus allowing a gated triggering of the PILATUS3 6M detector. This has enabled the development of fast continuous mesh scanning data collection protocols (see movie S1 of the supporting information). The MD2S control software runs on a Windows PC and is based on the JLib library (EMBLEM Technology Transfer GmbH, Heidelberg, Germany; https://software.embl-em.de). The MD2S can be controlled using a graphical user interface (GUI) or remotely by a socket server using the Exporter protocol of JLib. The Prosilica GC655C GigE on-axis video camera of the MD2S is read using the LIMA generic library for high-throughput image acquisition (Homs et al., 2011).

Figure 4 The MD2S on ID30B in (a) Mini-kappa (MK3) and (b) in situ plate holder goniometer head configuration.

The MD2S diffractometer is currently equipped with a penta-aperture (75, 50, 30, 20 and 10 µm in diameter) that can be easily inserted to adjust the beam size as experimentally required. A second penta-aperture set primarily for larger beam sizes (150, 100, 75, 50 and 20 µm in diameter) is available on request. The MD2S is an evolution of the standard MD2 diffractometers installed on other ESRF MX beamlines such as ID29 (de Sanctis et al., 2012). It combines a large-range goniometer axis translation stage with a new beam-conditioning device originally developed for the MD3 on the EMBL P14 beamline at PETRA-III. This allows the diffractometer's beam-cleaning capillary and beamstop to move independently. The current beamstop is 400 µm in diameter and its distance from the crystal can be varied from 9 to 60 mm with the larger distances facilitating the collection of very low resolution reflections. A larger beamstop, 800 µm in diameter, is available when required.

2.4.2. In situ data collection

The MD2S was specially designed to allow in situ data collection from crystallization plates. For this, the cryo-stream is first moved away from the sample environment using the REX rapid nozzle changer (Fig. 2). The cleaning capillary is also removed and disabled, while the beam-defining aperture is replaced with a 20 µm canon aperture (a combined aperture and beam-cleaning capillary). The MK3 goniometer head (Cipriani et al., 2007, Brockhauser et al., 2011, 2013) can then be unmounted and replaced by a new type of crystal plate holder incorporating a novel `quick lock' mechanism to facilitate the swap between MK3 and plate holder goniometer heads that was specially developed for ID30B (Fig. 4b). The plate holder can accommodate low-profile SBS footprint plates (127.76 × 85.48 × 8.0 mm) and is currently configured to accommodate CrystalDirect™ (Cipriani et al., 2012; Zander et al., 2016), CrystalQuick™X and In Situ-1™ crystallization plates. Due to space constraints induced when measuring samples in crystallization plates a number of interlocks have also been configured to prevent potential collisions. Using this set-up, oscillation data (±20^o) can successfully be collected from in situ crystals and this functionality has now been implemented in MxCuBE (Fig. 5). It takes ∼40 min to exchange goniometer heads and configure the MD2S for in situ data collection. The plates are manually mounted on the beamline and we currently schedule one shift (8 h) every other week for in situ experiments, but remote experiments can be carried out upon request.

Figure 5 In situ data collection on ID30B as implemented in MxCuBE.

2.5. X-ray fluorescence measurements

A Ketek AXAS-A X-ray fluorescence detector (Ketek, Munich, Germany) connected to a Bruker MultiMax signal processing unit (Bruker AXS, Karlsruhe, Germany) is used for X-ray absorption near-edge structure (XANES) measurements. The X-ray fluorescence region of interest (ROI) for a particular element's absorption edge is calculated and programmed via an RS-232 serial line connection. As for all energy-tuneable MX beamlines (ID23-1, ID29 and ID30B) at the ESRF, the ROI signal, using the MultiMax TTL output, is registered synchronously with the energy, during a continuous motion of the monochromator by the multipurpose unit for synchronization, sequencing and triggering (MUSST) module developed at the ESRF. Thus, a complete XANES scan, 100 eV around the theoretical absorption edge, is typically recorded in 20–30 s. As previously described (Leonard et al., 2009), this setup also allows a complete X-ray fluorescence (XRF) spectrum to be recorded via the serial line connection and to be subsequently analysed using PyMCA (Solé et al., 2007).

2.6. The FlexHCD sample changer

ID30B started user operation in June 2015 with a SC3 sample changer (Cipriani et al., 2006) installed. However, a new generation sample changer was clearly required to overcome the limited sample capacity of the SC3, to allow the use of sample holders formats used elsewhere (i.e. Uni-Puck; https://smb.slac.stanford.edu/robosync/Universal_Puck/) and to accommodate new sample holding formats being developed, such as miniSPINE (Papp, Rossi et al., 2017). A decision was therefore taken to combine the Flex robotic technology developed by the EMBL-Grenoble instrumentation team (Papp, Felisaz et al., 2017) with the ESRF HCD developed as part of the MASSIF-1 (ID30A-1) project (Nurizzo et al., 2016). This new sample changer, the FlexHCD, combines the versatility and reliability of a Stäubli TX60L six-axis industrial robot (Stäubli Faverges SCA, Faverges, France) with a robust, large-capacity storage dewar, a fundamental requirement for modern MX beamlines.

The robotic arm of the FlexHCD is equipped with a tool changer and tool storage rack that can accommodate five gripper types. The robot on ID30B is currently equipped with a calibration tool for automatic robot alignments (Papp, Felisaz et al., 2017), an IRELEC flipping gripper (Jacquamet et al., 2009) for samples stored in SC3 format pucks (Cipriani et al., 2006), and EMBL-designed single and double SPINEplus grippers (Papp, Felisaz et al., 2017) for samples stored in Uni-Puck format (Figs. 6a, 6b and 6c). Only SPINE standard sample holders (Cipriani et al., 2006) are compatible with the SPINEplus grippers.

Figure 6 Three types of FlexHCD grippers are currently available on ID30B: (a) a modified IRELEC flipping gripper; EMBL-designed single (b) and double (c) SPINEplus grippers. The HCD was modified to allow storage of samples in (d) SC3 or (e) Uni-Puck storage formats. Orientation and positioning aids help facilitate puck loading by users. ProxiSense puck detection sensors are used for puck type recognition, and to ensure the pucks are correctly positioned and are not inadvertently removed during sample loading.

In order to integrate both SC3 and Uni-Puck format pucks on ID30B, the HCD was significantly modified compared with the version installed on MASSIF-1 (Nurizzo et al., 2016). First, two types of segment plates were designed. For SC3 format pucks a ring-shaped plastic plug with magnetic disks pushes the vials up about 15 mm to ensure that the IRELEC gripper has access to the vials (Fig. 6d). The magnetic disks guarantee that the vials are held in position and are refilled with liquid nitro­gen after sample loading. To facilitate loading of the pucks an orienting finger that fits in the SC3 puck groove, coupled with a positioning aid, help to align the pucks correctly in the HCD. The second type of segment plate has a Uni-Puck footprint (Fig. 6e). Again, an orienting/pressing finger and positioning stops facilitate the precise loading of Uni-Pucks by users. Each puck position (SC3 and Uni-Puck) is equipped with a ProxiSense puck sensor and readout electronics (Papp, Felisaz et al., 2017), allowing detection of the presence and correct positioning of pucks in the HCD. Secondly, the positional accuracy of the HCD rotation axis was improved and migrated to a Modbus electronic module (WAGO Contact SAS, Roissy, France) control system. These modifications were carried out to ensure the reliable robotic handling of samples in Uni-Puck format and to facilitate the potential use of high-density sample holders in the future (Papp, Rossi et al., 2017). On ID30B the HCD is configured to accommodate 12 SC3 pucks and 11 Uni-pucks, but this layout can be adapted by changing segment plates. The dewar filling and exhaust ports of the HCD have been modified such that the filling port is now used for both liquid-nitro­gen filling and venting. The original venting port was equipped with a pneumatic port and is now used to cool the SPINEplus grippers between operations. The liquid nitro­gen in the HCD is maintained at a constant level using detection monitors coupled to valves for refilling by an external reserve tank.

The HCD contains two large ports, one for manual user loading of sample containers (SC3 or Uni-Puck), the second for robot access. A GigE connected UI-5240CP-M-GL camera (IDS Imaging Development Systems GmbH, Obersulm, Germany) and two MS-4Xi (Omron Microscan Systems Inc, Renton, WA, USA) have been integrated for robotic diagnostics and sample bar code reading, respectively. During sample loading, or unloading, a series of images are taken and processed to determine whether a sample has been properly handled. The image processing algorithm was further developed to detect and correct for small variations in the sample positioning in the grippers. If a sample is detected as too far from predefined specifications, the sample transfer can be refused and returned to the dewar or placed in a special receptacle in the HCD for later recovery.

The high-level software control of the FlexHCD system on ID30B runs on a Windows PC and is based on the JLib library software suite (EMBLEM Technology Transfer GmbH, Heidelberg, Germany; https://software.embl-em.de), encompassing a StaubCom server for robotic movements, a WAGO controller for HCD carousel rotations, a pr­oxy sense card for sample holder detection, and all image acquisition and processing software. The FlexHCD software can be controlled using a dedicated GUI or remotely by a socket server using the Exporter protocol of JLib.

2.7. Beamline control software

The individual motors required to align the optical elements, move the experimental table and detector translation table as well as open and close the millisecond fast shutter are all controlled at the lowest level by ESRF-developed IcePAP electronics (Janvier et al., 2013). All pneumatic devices on ID30B are driven via WAGO-I/O-System 750 control modules (WAGO Contact SAS, Roissy, France), which are also used to monitor thermocouples. The scattering foil diodes on ID30B are read via Keithley picoammeters.

All XBPM Basler acA1300-30gm GigE cameras and the MD2S sample camera on ID30B can be accessed via the LIMA generic library (Homs et al., 2011) and viewed in a web browser. All motors, apart from those of the MD2S diffractometer and FlexHCD sample changer, are controlled on a higher level using BeamLine Instrumentation Support Software (BLISS), the new ESRF system for experiment control, which is a Python-based open source project [https://gitlab.esrf.fr/bliss/bliss (Guijarro et al., 2017)]. A number of pseudo motors, such as slit gaps and offsets, table height, translation, roll, pitch and tilt are configured in BLISS, which also provides procedures for the automatic alignment of the experimental environment to the X-ray beam. All the beamline thermocouples and diodes are configured to be read using BLISS, which additionally provides, via a unified web-based application shell, a graphical scanning functionality to facilitate beamline alignment, develop automated alignment routines, and diagnose beamline-specific problems.

As for all the ESRF MX beamlines, MxCuBE, the Macromolecular Crystallography Customized Beamline Environment software [https://mxcube.github.io/mxcube (Gabadinho et al., 2010)], provides the user interface to control instruments and procedures required for a diffraction experiment. These include calls to the underlying BLISS control system for the execution of procedures such as energy changes, alignments and various scans; loading and unloading of samples by the FlexHCD; and MD2S data collection protocols using the Exporter protocol of JLib. The PILATUS3 6M detector control software runs on a dedicated Linux computer and is triggered for data collection via the LIMA generic library PILATUS implementation, sending commands to the Dectris camserver. For automated data acquisition protocols, as already described for MASSIF-1 (Svensson et al., 2015), we use the Beamline Expert System (BES), a customized version of Passerelle EDM (https://supportsquare.io/portfolio/products/) running on a central computing cluster. Meanwhile, all experimental planning and final data collection parameters are stored in the ISPyB database for MX with results of automatic data processing (Monaco et al., 2013) and analyses of characterization and BES workflows displayed in ExiMX (https://exi.esrf.fr/), the ESRF user interface to ISPyB (Delagenière et al., 2011).

3.1. Data collection at cryogenic temperature

On ID30B, diffraction data are routinely collected at 100 K from samples mounted in SPINE standard pins [see https://www.spineurope.org for details (Cipriani et al., 2006)]. For example, Thaumatococcus daniellii thaumatin was crystallized and cryoprotected as previously described (Nanao et al., 2005). Diffraction data were subsequently collected from a single crystal using a radiation damage optimized strategy calculated by BEST (Bourenkov & Popov, 2010) as implemented in EDNA (Incardona et al., 2009). This data set was processed with XDS (Kabsch, 2010) and AIMLESS (Evans et al., 2011) using an automatic data processing pipeline (Monaco et al., 2013) and the results downloaded from ExiMX. The structure was further refined using REFMAC (Murshudov et al., 2011), waters added using ARPwarp (Lamzin et al., 2012) and the results visually inspected with Coot (Emsley et al., 2010), all as implemented in CCP4 (Winn et al., 2011). A summary of the crystallographic information is shown in Table 2.

Table 2 Data collection and refinement statistics of thaumatin collected at 100 and 293 K (in situ) Statistics for the highest-resolution shell are shown in parentheses. Data collection Energy (keV) 12.67 12.7 17.5 Temperature (K) 100 293 (in situ) 293 (in situ) Resolution range (Å) 50–1.08 (1.12–1.08) 50–1.5 (1.53–1.5) 50–1.5 (1.53–1.5) Space group P41212 P41212 P41212 Unit cell (Å, °) 58.0, 58.0, 150.7, 90, 90, 90 58.6, 58.6, 151.6, 90, 90, 90 58.6, 58.6, 151.5 90, 90, 90 Unique reflections 99222 (6841) 42124 (2031) 39794 (1988) Multiplicity 3.6 (1.6) 3.6 (3.5) 3.4 (3.4) Completeness (%) 89.8 (63.5) 98.2 (98.4) 92.6 (96.7) Mean 〈I/σ(I)〉 11.8 (0.8) 5.7 (1.0) 7.2 (1.3) Wilson B factor (Å2) 11.4 15.2 12.4 (I/σ)asymptotic† 13.3 8.2 12.3 Rp.i.m. (%)‡ 2.9 (54.4) 7.1 (71.2) 5.7 (51.8) CC* 0.996 (0.857) 0.99 (0.39) 0.99 (0.6)   Structure refinement Rwork (%) 14.8 (47.0) 13.0 (29.6) 13.8 (26.4) Rfree (%) 16.6 (45.4) 16.7 (35.3) 16.7 (29.0) No. of non-H atoms 1806 1724 1725  Macromolecule 1600 1594 1594  Tartrate/glycerol 34 10 10  Water 172 120 121 R.m.s.d. (bonds, Å) 0.017 0.014 0.01 R.m.s.d. (angles, o) 1.8 1.6 1.4 Ramachandran plot (%)        Favored 98.6 98.6 98.6  Allowed 1.4 1.4 1.4 Average B factor (Å2)        Macromolecules 16.8 21.7 19.5  Tartrate/glycerol 29.0 19.7 17.5  Solvent 33.0 22.4 30.7 Diffraction data https://doi.org/10.15785/SBGRID/544 https://doi.org/10.15785/SBGRID/546 https://doi.org/10.15785/SBGRID/547 PDB code 6fj6 6fj8 6fj9 †(I/σ)asymptotic: as reported in XDS (Diederichs, 2010). ‡Rpim: precision-weighted merging R-factor (Weiss, 2001).

To further illustrate the capabilities of the beamline, several single-wavelength anomalous diffraction (SAD) experimental phasing measurements were carried out on three test proteins. Firstly, Bacillus thermoproteolyticus thermolysin was crystallized and cryoprotected as previously described (Zander et al., 2015). Diffraction data from a single flash-frozen crystal were collected at 100 K using an X-ray beam size of 30 µm² with a flux of 2.3 × 10¹¹ photons s⁻¹ at the peak of the Zn K absorption edge (λ = 1.282 Å). Next, a seleno­methione-derivative of the feruloyl esterase module of xylanase 10B from Clostridium thermocellum (FAE) was crystallized and cryoprotected as previously described (Prates et al., 2001). Diffraction data from a single flash-frozen crystal were collected at 100 K using an X-ray beam size of 30 µm² with a flux of 3.3 × 10¹¹ photons s⁻¹ at the peak of the Se K absorption edge (λ = 0.9792 Å). Lastly, porcine trypsin was crystallized and cryoprotected as previously described (Nanao et al., 2005). Diffraction data from a single flash-frozen crystal were collected at 100 K using an X-ray beam size of 30 µm² with a flux of ∼7 × 10¹⁰ photons s⁻¹. Here, a longer wavelength of 6 keV (λ = 2.066 Å) and the Si-stripe of the horizontal mirror were used to optimize the anomalous signal from the intrinsic sulfur atoms present in the crystal and two consecutive low-dose data sets of 360^o total rotation were collected; for the first data set the crystal was aligned along c* using the MK3 goniometer head to ensure that Bijvoet pairs were collected simultaneously, while for the second the crystal was in a random orientation. This strategy is particularly recommended for S-SAD phasing experiments (Brockhauser et al., 2013).

All data were processed and scaled using the XDS suite (Kabsch, 2010) and AIMLESS (Evans et al., 2011), and are of very high quality (Table 3). Structure solution was carried out using the SAD phasing technique as implemented in the CRANK2 pipeline (Skubák & Pannu, 2013; Skubák et al., 2018), resulting in clearly interpretable electron density maps: for thermolysin, 306 residues out of a total of 315 were automatically built (R/R_free = 28.6/30.3%); for FAE, 284 residues out of a total of 297 were automatically built (R/R_free = 25.5/28.1%); for trypsin, 224 residues out of a total of 246 were automatically built (R/R_free = 30.7/35.6%). All three structures were then refined using the PDB_redo server (Joosten et al., 2014) and model building carried out in Coot (Emsley et al., 2010). A summary of all crystallographic information is shown in Table 3.

Table 3 Data collection and phasing of trypsin by S-SAD, thermolysin by Zn-SAD and FAE by Se-SAD Statistics for the highest-resolution shell are shown in parentheses. Protein Trypsin Thermolysin FAE Data collection Energy (keV) 6 9.672 12.662 Resolution range (Å) 50.0–2.2 (2.27–2.2) 50–1.43 (1.45–1.43) 50–1.7 (1.73–1.71) Space group P212121 P6122 P41212 Unit cell (Å, °) 60.0, 64.1, 69.7 90, 90, 90 92.7, 92.7, 128.6 90, 90, 120 112.0, 112.0, 65.9 90, 90, 90 Unique reflections 13845 (1057) 60230 (2 379) 207445 (11053) Anom. multiplicity 11.8 (6.5) 2.8 (2.0) 2.4 (2.3) Anom. completeness (%) 97.2 (85.8) 96.7 (60.6) 96.3 (96.1) Mean 〈I/σ(I)〉 24.9 (10.4) 13.6 (3.7) 11.2 (0.9) Wilson B factor (Å2) 15.1 11.3 24.2 (I/σ)asymptotic† 12.1 9.8 19.0 Rp.i.m. (%)‡ 2.4 (7.4) 4.2 (13.7) 4.1 (84.1) CC* 0.997 (0.98) 0.99 (0.93) 0.997 (0.318) Anom. mid-slope§ 1.136 1.224 1.293 SigAno 1.23 (0.76) 1.48 (1.57) 1.44 (0.7)   Structure refinement Rwork (%) 17.6 (19.7) 14.5 (19.0) 18.3 (36.4) Rfree (%) 22.0 (27.5) 16.4 (19.6) 20.1 (37.1) No. of non-H atoms 1830 2948 2358  Macromolecules 1636 2561 2232  Water 170 362 50  Ligand/ion/glycerol 24     R.m.s.d. (bonds, Å) 0.008 0.017 0.02 R.m.s.d. (angles, o) 1.3 1.7 1.7 Ramachandran plot (%)        Favored 97.3 97.3 97.9  Allowed 2.7 2.7 2.1 Average B factor (Å2)        Macromolecules 10.2 8.7 20.7  Ligand/ion/glycerol 36.0 32.6    Solvent 26.6 27.6 23.5 Diffraction images https://doi.org/10.15785/SBGRID/541 https://doi.org/10.15785/SBGRID/542 https://doi.org/10.15785/SBGRID/543 PDB code 6fid 6fj2 6fj4 †(I/σ)asymptotic: as reported in XDS (Diederichs, 2010). ‡Rpim: precision-weighted merging R-factor (Weiss, 2001). §Anom. mid-slope: mid-slope of anomalous normal probability in AIMLESS (Evans et al., 2011).

More complex experiments such as `MeshAndCollect' (Zander et al., 2015) have benefitted from the development of the rapid mesh scanning protocol (see movie S1 of the supporting information) on ID30B. As an example this method was recently used to determine the structure of an important human hormone receptor, Adinonectin receptor 2 (Vasiliauskaité-Brooks et al., 2017). The fast mesh scanning option combined with the reliability of the FlexHCD has allowed the implementation of fully automatic MXPress workflows (Svensson et al., 2015) on ID30B. For such workflows, processing time per sample currently varies from less than 4 to around 8 min depending on the complexity of the workflow executed.

3.2. In situ diffraction experiments

The ID30B in situ data collection setup (§2.4.2) is compatible both with standard and raster-based data collections between 6 and 20 keV. While the total rotation range is limited due to the restricted sample environment, complete data sets can be collected from large single crystals with high-symmetry space groups lying in favourable orientations. In the case of smaller, lower-symmetry crystals the most successful approach is to create a complete data set from multiple partial data sets collected from different crystals. To validate our in situ setup a number of data sets of thaumatin crystals grown in CrystalDirect™ (Cipriani et al., 2012; Zander et al., 2016) (using a flux of ∼8 × 10¹⁰ photons s⁻¹ with a 20 µm² cannon aperture; 20 ms exposure per 0.1^o oscillation; total oscillation range of 50°) were collected at 12.7 and 17.5 keV with an ESRF storage ring current of 4 × 10 mA. The most complete data set from the automatic data processing pipeline (Monaco et al., 2013) at each energy was downloaded from ExiMX and the crystal structures refined to 1.5 Å resolution. Crystallographic information is shown in Table 2.