2.1. Crystal preparation

Crystals of thermolysin from Bacillus thermoproteolyticus (Sigma-Aldrich, catalog #P1512) were grown using hanging-drop vapor diffusion (Hausrath & Matthews, 2002). The purchased protein was used without further preparation and dissolved at 100 mg ml⁻¹ in 45% (v/v) DMSO. Drops were made by mixing 5 µL of this protein solution with 5 µL 35% (v/v) DMSO, and set up over 5% (v/v) saturated ammonium sulfate. Crystals in space group P6₁22 grew in a few days. Approximately 1 d prior to data collection the crystals were transferred to sitting drops composed of 30% (v/v) ethylene glycol over a well solution of 30% ethylene glycol. The crystals were washed with 30% ethylene glycol a few times over a few hours to eliminate any residual DMSO.

2.2. X-ray data collection and processing

X-ray data were collected at beamline ID14-EH4 (McCarthy et al., 2009) at the European Synchrotron Radiation Facility. The aperture was set to give a beam with a rectangular cross section of 40 µm (horizontal) × 100 µm (vertical). The energy was set to 13.20 keV (0.9393 Å). A single crystal (a 250 µm-long hexagonal rod of diameter 100 µm with a uniform visual appearance along its length) was used for data collection. At each temperature four data sets were collected at 10% transmittance (i.e. the beam intensity was attenuated by 90% before interacting with the crystal). During a data set, composed of 50 frames (1° oscillation, exposure time 1 s per frame), a dose of 0.25 MGy was absorbed as calculated using the program RADDOSE (Paithankar et al., 2009). Between data sets, the crystal was exposed over the same total oscillation range but with 100% transmittance (i.e. the beam was unattenuated), corresponding to a dose of ∼2 MGy. After the exposures at 100 K the temperature was increased at a rate of 0.1 K s⁻¹ to 160 K, the crystal was translated by 80 µm leaving a 40 µm gap of unexposed crystal material; the procedure was then repeated. The purpose of the 40 µm gap was to limit the diffusion of damaging species created during the 100 K exposures into the zone of the crystal used for the 160 K exposures. At 100 K the penumbral radiation damage is limited to a few micrometers surrounding the area directly exposed to the X-ray beam (Holton, 2009). Since the experiment was carried out at 160 K, a gap considerably larger than a few micrometers was considered to be potentially necessary. After the data collection at 160 K, the temperature was increased to 240 K and the crystal was again translated by 80 µm. However, at 240 K the scattering pattern showed no Bragg diffraction spots. The temperature was controlled with an Oxford Cryosystems 700 system, and the warming rate was 0.1 K s⁻¹. MOSFLM (Leslie, 1992) and SCALA (Evans, 2006) were used to process all data to 2.2 Å resolution, with the resolution limit of the fourth data set at 160 K. Truncate was used to determine the Wilson B-factor (French & Wilson, 1978) and SCALEIT (Howell & Smith, 1992) to determine the relative isotropic B-factor between data sets.

The intensity decay was determined by calculating the total diffracted intensity (I_tot) for the data set from 〈I〉 and the total number of reflections as output from SCALA (Table 1; all data from 34 to 2.2 Å were used), and normalizing this to the first data set at each temperature. A plot of I_tot versus dose yields D_1/2, the dose at which I_tot drops by 1/2 (Owen et al., 2006). The B-factor decay was determined by calculating the B-factor relative to the first data set at each temperature (B_rel) using SCALEIT. The slope of a linear fit to B_rel versus D yields the coefficient of sensitivity, (Kmetko et al., 2006).

2.3. Structure refinement and analysis

For structure determination and refinement, rigid-body refinement was first performed on Protein Data Bank (PDB) entry 8tln against the first 100 K data set (hereafter called data set 100a) using REFMAC (Murshudov et al., 1997). Restrained positional and B-factor refinement followed using all data (less 5% reserved for R-free calculations), alternating with rounds of map inspection, model building, and water removal and addition using Coot (Emsley et al., 2010). This refined 100 K structure (structure 100a) was then used as the initial model for refinement against the seven other data sets, which were refined as above. The coordinates have been deposited in the PDB with accession codes 3p7p , 3p7q , 3p7r , 3p7s , 3p7t , 3p7u , 3p7v and 3p7w .

Structure analysis was carried out with EDPDB (Zhang & Matthews, 1995), Coot, UCSF Chimera (Pettersen et al., 2004), MSMS (Sanner et al., 1996) and programs written by one of the authors (DHJ). EDPDB was used to calculate B-factor changes, coordinate manipulations and structure overlays. Coot, UCSF Chimera and PyMOL (Schrödinger, San Diego, CA) were used for structure visualization and mapping atom properties (e.g. ΔB and d_nc) to coordinate positions. MSMS was used to calculate solvent-accessible surface areas and molecular volumes. The distance from each atom to the nearest solvent channel (d_nc) was determined as follows. First, the unit cell was divided into a three-dimensional rectangular grid with spacings of 1 Å. Grid points were assigned to `solvent channels' based on a cut-off distance (4.5 Å): if a grid point was greater than the cut-off distance from every protein atom, it was assigned to `solvent channels'. Second, distances between the atom of interest and all solvent channel grid points were calculated. The smallest such distance was assigned as the parameter d_nc for that atom. The basic result of the present work, which is that the change in refined atomic B-factor, ΔB, owing to radiation exposure is negatively correlated with d_nc at 160 K, was robust to this cut-off distance with values between 3 and 6 Å giving the same qualitative result. Correlation coefficients were calculated using StatPlus and Microsoft Excel.

Comparisons of our results with previously reported radiation damage experiments were carried out. The structures used were thermolysin (PDB codes 3do1 /3do0 ), acetyl­cholinesterase (1qid /1qie ), malate dehydrogenase (2j5k /2j5q ) and human aldose reductase (3ghr /3ghs ) at 100 K, and acetylcholinesterase (2vja /2vjb and 2vjc /2vjd ) at 100 and 150 K.

3.1. Global indicators

Global indicators (total diffracted intensity, Wilson B-factor, mosaicity and unit-cell volume) provide evidence for increased radiation damage at 160 K compared with 100 K (Table 1 and Fig. 1). Two global metrics for radiation sensitivity have been suggested, one based on the diffracted intensity (D_1/2 = the dose at which the total diffracting power of the crystal is reduced by 1/2; Owen et al., 2006) and the other based on the change in B-factor with dose (Kmetko et al., 2006). Here, at 100 K we find D_1/2 = 14 MGy and s_AD = 0.033 Ų MGy⁻¹, while at 160 K we find D_1/2 = 8.5 MGy and s_AD = 0.060 Ų MGy⁻¹.

Figure 1 Progression of normalized average intensity (upper) and B-factor (lower) with dose. Lines connect successive points.

The mosaicity increased with dose at both temperatures studied (Fig. 2). Both the unit-cell volume and protein volume also increased with dose, at about the same rate for both temperatures (Fig. 2). However, the unit-cell volume increase at 160 K was anisotropic: one cell edge (a) increased while the other (c) decreased (Table 1).

Figure 2 Dependence of mosaicity (upper), unit cell and molecular volumes (lower) on dose. Lines connect successive points. Mosaicity values are from MOSFLM. The molecular volume was determined using MSMS.

3.2. Specific radiation damage

Specific radiation damage was initially investigated with difference Fourier maps, which showed some of the greatest susceptibility at sites normally expected to show specific damage. For example, of the top ten negative F_o^100b - F_o^100a peaks (5 to 8σ; phases from the refined 100a structure) resulting from the first exposure at 100 K, two occur at the S_δ atoms of the two methionines in the structure and five occur at carboxylate O atoms (four aspartates and the carboxy terminus). Additionally, the four calcium ions and the active-site zinc ions showed negative features in the F_o^100b - F_o^100a map.

The difference Fourier maps for the 160 K series and between the 100 and 160 K series were less easily interpreted, owing to non-isomorphism (Table 1). Many of the strongest map features were associated with shifts of atom positions. Consequently we turned to the refined structures to assess the effects of X-ray exposure.

Fig. 3 shows the relative susceptibility of different residue types in the structure by comparing the effect of radiation exposure on the refined B-factors to the overall B-factor change. At 100 K the most sensitive residues by this measure when comparing data sets a and b are Met, Asp, Glu and Lys in decreasing order (Fig. 3). Note that there are no cysteines and thus no disulfide bonds in thermolysin. At 160 K these residues are still susceptible, but others show similar susceptibilities (in decreasing order of B-factor change with exposure when comparing data sets a and b: Lys, Asp, Gln, Pro, Thr, Met, Asn). The metals sites have susceptibilities above average at 100 K. At 160 K the zinc has about average susceptibility, while the calcium ions become much more susceptible than average.

Figure 3 ΔB by residue type at 100 K (upper) and 160 K (lower). Positive values indicate that on average the residue undergoes a greater B-factor increase from radiation exposure than the rest of the structure. In the 160 K plot of data sets b–a, the value for tryptophan (−2.2 Å2) is off the scale.

4.1. Global damage indicators

The thermolysin crystals are radiation-sensitive at both 100 and 160 K. Using either the intensity decay (D_1/2) or B-factor decay (s_AD) the sensitivity is two to three times higher at 100 K than for apoferritin at 100 K (Owen et al., 2006; Kmetko et al., 2006). Also, using either measure, the thermolysin crystals roughly double in radiation sensitivity between 100 and 160 K, an increase similar to that reported for crystals of insulin (Meents et al., 2010), glucose isomerase (Borek et al., 2007) and thaumatin (Warkentin & Thorne, 2010) over the same temperature range.

We also examined unit-cell volume and mosaicity changes. Both the cell volume and protein volume show a comparable response to radiation exposure: an expansion of 0.4–0.5% for 7 MGy, which is also similar at the two temperatures (Fig. 2). This contrasts with the response to only a change in temperature, in which the cell volume expands approximately three times more than protein volume between 100 and 160 K (i.e. comparing data sets 100a and 160a). The differential temperature response has been discussed and is related to differences between the thermal properties of the two types of materials comprising the crystal (protein versus bulk solvent; Juers & Matthews, 2001; Kriminski et al., 2002).

The cause of the radiation-induced unit-cell volume expansion has been a matter of some debate (Ravelli et al., 2002; Meents et al., 2010; Warkentin & Thorne, 2010). Recently it has been proposed that the production of molecular hydrogen gas via the X-ray exposure of aliphatic groups expands the unit cell (Meents et al., 2010). The similar magnitude of cell and protein volume expansion as a function of dose observed here suggests either (a) the production of hydrogen in equal concentrations in the two regions of the cell or (b) the rapid diffusion of hydrogen gas uniformly throughout the unit cell after its production. Although there are aliphatic groups in the bulk solvent [which is composed of 30% (v/v) ethylene glycol], their concentration should be higher in the protein. Therefore, the rapid diffusion model is favored here. Warkentin & Thorne, however, have noted that the diffusion of H₂ gas through amorphous ice at 100 K may be quite slow (i.e. ∼100 s to travel a distance of ∼25 water molecules; Warkentin & Thorne, 2010).

4.2. Specificity of damage: OH radicals versus electrons at 160 and 100 K

Previous observations of protein crystals at 100 K have shown radiation-susceptible sites to include disulfide bonds, carboxylate groups, tyrosine hydroxyls and methionine carbon–sulfur bonds (Weik et al., 2000; Ravelli & McSweeney, 2000; Burmeister, 2000). The thermolysin crystals behave similarly, with methionine, aspartate and glutamate residues showing the highest radiation susceptibilities at 100 K. Note the absence of cysteine residues in thermolysin.

The detailed mechanisms of radical reactions as they relate to protein crystals have been investigated mainly using electron spin resonance (ESR) on model compounds, but are also now being studied with single-crystal spectrophotometry (Carpentier et al., 2010). At the most basic level, X-ray radiation causes damage by ejecting electrons from atoms via the photoelectric effect or Compton scattering (primary damage; von Sonntag, 1987; Southworth-Davies et al., 2007). These high-energy electrons then cause further ionizations (secondary damage). Possible species involved in secondary damage processes include electrons and holes, as well as other radicals that are produced in both the protein and solvent regions of the crystal. Radicals produced in the latter include radicals originating from water (solvated and aqueous electrons, and

At 77 K electrons appear to be mobile in proteins, travelling until they are trapped at electron sinks (Jones et al., 1987), such as disulfide bonds (Symons, 1995) or, in their absence, side-chains with high electron affinity. Holes, however, are trapped prior to migrating long distances at peptide bonds via the loss of amide protons (Symons, 1995). Electrons and holes, as well as primary damage events, are likely to be responsible for the specific radiation damage observed at 100 K, which has been discussed previously (Ravelli & McSweeney, 2000; Burmeister, 2000). For example, disulfide breakage is thought to occur via electron capture, while decarboxylation of acidic side-chains is thought to proceed upon hole capture either from primary events or hole transfer. Some events at 100 K may be triggered by other species, for example thioether loss by methionine may occur via H-atom capture (Shimazu et al., 1964).

At 160 K the irradiated thermolysin crystal has different characteristics than at 100 K. Approximately 98% of the protein atoms in the crystal were more radiation sensitive at 160 K than at 100 K. While the methionine sulfurs and carboxylate O atoms are still more sensitive than average, other sites (e.g. lysine, glutamine and proline, see Fig. 3) show equal or greater sensitivity. It appears, therefore, that the specificity of damage has changed somewhat between 100 and 160 K. One possible source of this new damage specificity is OH radicals produced in the solvent region of the crystal.

At 77 K the ESR spectrum of aqueous polethylene oxide is stable for several days and includes signals from OH radicals, which disappear upon warming to 115 K (Zakurdaeva et al., 2005). Other experiments show the disappearance of radiation-induced OH radicals in ice in the range 90–130 K (Kroh et al., 1961; Zakurdaeva et al., 2005; Plonka et al., 1984). The short lifetime of OH radicals at ∼130 K has been used to implement annealing processes for quenching OH radical signals in various low-temperature ESR experiments (Boon et al., 1984). Other observations suggest that H radicals become mobile above 115 K (Fisher & Devlin, 1995; Southworth-Davies et al., 2007; Garman & Nave, 2009). Therefore, we may expect that increasing the temperature of the thermolysin crystal to 160 K should significantly increase the damage activity of both OH and H radicals.

Hydroxyl radicals are powerful oxidizing agents, responsible for a variety of amino acid modifications (Xu & Chance, 2007; Davies & Dean, 1997), including deletions (e.g. decarboxylation of acidic side-chains) as well as, following subsequent reactions, additions of other moieties to the radical centers formed by H-atom abstraction. Also, the hydroxyl radical can itself add to aromatic rings and sulfur centers. Here, our metric for radiation damage is the increase in atomic B-factor, which will obviously be sensitive to deletion events. Addition events would be less likely produce B-factor increases unless, for example, they caused greater conformational disorder.

There are several known processes involving OH radicals consistent with our results at 160 K. Generally these are multi-step processes involving first the creation of a radical somewhere on the side-chain via reaction with , subsequent reaction of this side-chain radical with molecular oxygen, and in some cases the breakdown of an unstable product (e.g. Arg, His, Cys; Xu & Chance, 2007). Owing to its hydrophobic nature, molecular oxygen should be available in the protein fraction of the crystal. These oxidation reactions result in guanidinium group loss by arginine (Ayala & Cutler, 1996; Xu et al., 2003), decarboxylation of aspartate and glutamate (Davies et al., 1995; Xu & Chance, 2004), main-chain breaks at proline residues (Dean et al., 1989; Uchida et al., 1990), loss of thioether from methionine (Hiller et al., 1981; Xu & Chance, 2007), loss of the side-chain primary amine by lysine (Hawkins & Davies, 2001; Davies & Dean, 1997), and breakdown of acetamide (a model compound for asparagine and glutamine side-chain amides; Leitner et al., 2002). These are all possible reactions that could become more active at higher temperatures, explaining the altered radiation susceptibility at 160 versus 100 K.

OH radicals are also indirectly responsible for addition reactions with most amino acids (see above), resulting in hydroxylation or carbonylation at many different sites on the side-chains (Xu & Chance, 2007). If a hydroxylation event were directed sterically to the same site on a particular side-chain on every protein molecule in the crystal, we would expect to see it as a positive peak in a difference map. Map inspection, however, showed no such peaks, suggesting low occupancy if such addition reactions are occurring. Addition reactions may be inhibited by steric constraints in the protein matrix, especially since the residues most sensitive to hydroxylation (e.g. Tyr, Phe) are among those most deeply buried in the protein. To the best of our knowledge, the current literature on radiation damage in protein X-ray crystallography does not contain evidence for radiation-induced additions in electron density maps.

4.3. The role of residue depth in protection from radiation damage

Previous investigations have demonstrated that there is no correlation between the solvent-accessibile surface of an atom and its radiation sensitivity at 100 K (Fig. 4) (Ravelli & McSweeney, 2000; Burmeister, 2000; Fioravanti et al., 2007). The influence on radiation sensitivity of a related, yet distinct, parameter has not yet been addressed, i.e. of the distance of an atom to the nearest interphase between protein and solvent (referred to as depth hereafter). Since we are interested in the depth in the context of the crystalline protein, we determined the distance from the atom to the nearest solvent channel (d_nc), rather than to the surface of the protein in isolation. We then considered the correlation between the atom's dose-dependent ΔB and d_nc as a measure of the dependence of the radiation sensitivity on the proximity to the crystal solvent.

Figure 4 Backbone trace of the thermolysin molecule with the 130 atoms with the greatest B-factor increases shown with spheres (corresponding to ∼5% of the atoms in the protein; oxygen = red, nitrogen = blue, carbon = wheat, sulfur = yellow, calcium = cyan). At 100 K (upper; two orthogonal views of the molecule are shown) the 130 greatest B-factor increases are distributed evenly throughout the molecule, and include the two methionine Sδ atoms (yellow). In contrast, at 160 K (lower) they are biased towards the surface, and include a surface-exposed calcium ion (cyan). Figure prepared using PYMOL.

Fig. 5(a) shows ΔB versus d_nc for all atoms in the structure. The slopes of linear fits suggest the dependence of ΔB on d_nc is ten times greater at 160 K than 100 K for the first exposure (−0.31 versus −0.03 Å, Table 1). For the second and third exposures the slopes are −0.19 and −0.12 Å for 160 K, and −0.06 and −0.03 Å for 100 K, respectively. Thus, the effect persists but is less dramatic with later exposures.

Figure 5 Dependence of ΔB for the first radiation exposure on proximity to solvent channels. (a) Plots of ΔB versus dnc for each atom in the structure for 100 K (top) and 160 K (bottom). Linear fits to the data are in black. For the 100 K plot the correlation between ΔB and dnc is −0.13 and the slope of the linear fit is −0.03 Å. At 160 K the correlation and slope become −0.44 and −0.31 Å, respectively. (b) ΔB versus dnc averaged over each residue type. Between 100 K (top) and 160 K (bottom) the correlation between ΔB and dnc improves significantly, from −0.23 to −0.81 (excluding methionine).

The slopes of ΔB versus d_nc for thermolysin were compared with those for previously published radiation damage studies. There are several sets of refined protein structures in the PDB at increasing doses, most at 100 K. In one case, two structures of thermolysin before and after exposure at 100 K are given, although details of the work are unpublished and no dose information is given in the corresponding PDB entries (3do1 /3do0 ). The slope of ΔB versus d_nc for this pair of structures is −0.09 Å, similar to our 100 K value of −0.03 Å. Other 100 K structures, i.e. acetylcholinesterase (Weik, Ravelli et al., 2001; PDB codes 2vja /2vjb ), malate dehydrogenase (Fioravanti et al., 2007; PDB codes 2j5k /2j5q ) and human aldose reductase (Petrova et al., 2009; PDB codes 3ghr /3ghs ) give slopes of −0.09, −0.12 and −0.19 Å for doses of 1, 3.3 and 2.0 MGy, respectively. In only one case, for acetylcholinesterase, are there data at both 100 K and a higher temperature. In this case the slope of ΔB versus d_nc was −0.10 Å at 100 K (dose = 7.0 MGy) and −0.26 Å at 150 K (dose = 6.5 MGy), an increase of 2.6× over a similar temperature range to the experiment reported here, which is of the same order as our results, as follows. Using similar doses we calculate slopes of −0.12 Å at 100 K (100d versus 100a; dose of 7.2 MGy) and −0.62 Å at 160 K (160d versus 160a, dose of 7.1 MGy), a 5× increase in the rate of change.

ΔB versus d_nc was considered on a residue basis. Fig. 5(b) shows graphs of ΔB versus d_nc averaged over all of the atoms in the crystal for each residue type. Excluding methionine, there is a much greater correlation at 160 K (correlation coefficient = −0.80) than at 100 K (correlation coefficient = −0.23). (Note that because deeper residues show smaller ΔB, correlation coefficients between ΔB and d_nc are negative.) In sum, the data show that on average the proximity of a residue to a solvent channel can predict ΔB at 160 K, but not at 100 K.

One way to explain the negative correlation of ΔB with d_nc at 160 K but not at 100 K is that at 160 K OH radicals produced in the solvent region of the crystal are no longer trapped, but free to diffuse and cause damage. The first residues they come into contact with should be those residues lining the solvent channels, so residues buried deeper inside the protein suffer less damage than those closer to the surface. That the slope of ΔB with d_nc moves closer to zero with successive exposures would then indicate that this depth-dependent protection becomes less effective with greater doses. That is, the damage from the prior exposure diminishes the protective effect of the outer residues.

At 100 K both the zinc and calcium ions show greater than average susceptibility. At 160 K the Zn atoms show little change in their susceptibility, while the calcium ions display dramatically increased susceptibility. The zinc ion is ligated by two histidines and one glutamate; histidines tend to suffer less radiation damage than other residues and since they are ligating the zinc may offer this ion some protection. Both histidine and a zinc–alanyl–histidine complex (zinc carnosine) are known hydroxyl radical scavengers (Chan et al., 1994; Yoshikawa et al., 1991). Therefore, this active-site metal center may be naturally protected from OH radical damage. The calcium ions, on the other hand, are all ligated by O atoms from carboxylates, carbonyls or waters, groups known to be susceptible to damage. Damage to the calcium ligands could release the calcium from the protein, an event more likely to occur with greater solvent mobility that probably exists at 160 K (see below), since the calcium must be released to the bulk solvent.

4.4. Solvent mobility and rotational static disorder

The negative correlation between ΔB and d_nc can also be explained simply via the creation of greater static disorder at 160 K, as opposed to being due to depth-dependent damage promoted by OH radicals released at a temperature between 100 and 160 K. Diffraction degradation from radiation exposure must involve the gradual misalignment of neighboring molecules. Random translational misalignments would cause increases in the B-factor which are uniform over all atoms. Random rotational misalignments would cause greater B-factor increases in atoms further from the average center of rotation. This could be more relevant at 160 K, where greater solvent mobility could allow for such movements more easily. The slope of ΔB versus d_nc at 160 K is approximately −0.3 Å. Given that the average radius of thermolysin is ∼25 Å, this means atoms on the surface show ΔB about 7.5 Ų greater than atoms in the center, which corresponds to 0.1 Ų in atomic mean square displacement ( using ). This corresponds to ∼0.012 rad or 0.7° of greater angular disorder after radiation exposure than before. The decrease in slope of ΔB versus d_nc with successive exposures would then suggest that rotational misalignments contribute less to the static disorder as the exposures continue.

The solvent fraction of the crystal shows evidence of greater mobility at 160 K. The anisotropy in the cell volume changes at 160 K (Fig. 1), indicating that there is some reorientation of the molecule in the unit cell at 160 K (see also Table 1) which would require some redistribution of the bulk solvent molecules. Additionally, at 160 K, but not at 100 K, powder diffraction rings can be seen which are indicative of cubic ice formation, implying at least some of the bulk solvent has gone through the glass transition (Weik, Kryger et al., 2001; Juers & Matthews, 2004; Kim et al., 2009). The mosaicity showed considerable improvement in the region of the crystal used for the 160 K measurement, suggesting the initial cooling process produced some strain which was relieved with warming to 160 K, and produced a data set of slightly higher quality than at 100 K. (We cannot, however, exclude the possibility that this region of the crystal simply had lower intrinsic mosaicity than the region of the crystal used for the 100 K measurements.) This greater solvent mobility could facilitate the build-up of rotational disorder triggered by the degradation of crystal contacts by radical species, including newly available solvent-based radicals at 160 K.

At this point, neither of the above models can be eliminated. Both processes could be occurring. Distinguishing between them could be approached with higher-resolution data to permit simultaneous refinement of occupancy and B-factor, since the rotational disorder model would affect the B-factors but the solvent-produced radical model would affect mainly the occupancies. Another possibility might be to carry out mass spectrometric analysis after radiation exposure to identify the locations and types of damage events.