1. Introduction

Circular dichroism (CD) spectroscopy is a technique that can be used to determine the secondary structure content of proteins; to observe and quantify structural changes that result from the binding of small molecules to proteins; and to follow the folding of proteins to their native conformations (Wallace, 2000a,b). Conventional CD (cCD) measurements on laboratory-based machines have an accurate lower wavelength limit at best of ∼185 nm, primarily because of limitations imposed by the drop in the flux from the source xenon arc lamps beyond this point. With this lower flux the signal from the sample becomes lost in the background noise levels. Much lower wavelength limits can be reached by switching to a synchrotron radiation light source where the flux is maintained at workable levels to wavelengths well below cCD machines (Sutherland et al., 1980). This extended range provides more data resulting in higher information content (Wallace & Janes, 2001), thus more types of secondary structure can be identified and with greater resolution, more subtle changes can be observed in binding studies, and more can be determined about the nature of protein folding. Particularly for this last feature, this is due to the pronounced differences in the spectral characteristics displayed by the diverse types of secondary structure in the extended wavelength range, when compared with that seen in the range for cCD data (Wallace & Janes, 2001). Synchrotron radiation CD (SRCD) therefore offers data with considerably greater potential for analyses over data collected from cCD machines.

CD12 is a new high-flux beamline on the SRS at Daresbury, UK, designed for collection of ultraviolet and vacuum-ultraviolet circular dichroism spectra over the extended range available from synchrotron radiation sources (Clarke & Jones, 2004). The spectral characteristics of this beamline allow for SRCD data to be collected from 300 nm down to as low as 120 nm (Clarke & Jones, 2004). During SRCD data collection on this beamline, we, and others (Wien et al., 2005; Clarke & Jones, 2004), have observed notable changes in repeat spectra produced by protein samples that are clearly from some kind of irradiation effect. The suggestion from Clarke & Jones (2004) is that this is a degradation process and may reflect the formation of radicals from the water solute in the sample cell, which in turn degrades the protein through free-radical damage. However, this irradiation effect has now been thoroughly investigated and the probable causes identified in an accompanying paper to this article (Wien et al., 2005). Our work has also shed light on the causes of the irradiation effect where we believe this to be denaturation of the protein. However, we primarily report on methods of circumnavigating this problem to allow SRCD data to be collected on CD12 without any unexpected loss of the CD signal throughout the collection procedure.

2. Materials and methodology

The lysozyme and human serum albumin (HSA) used were purchased from Sigma Aldrich (UK). SRCD spectra were collected using different set-ups both to examine some of the properties of, and to try to prevent the effects of, irradiation on the protein sample. A stock solution of lysozyme was prepared at a concentration of approximately 20 mg ml⁻¹, unless otherwise indicated. HSA at approximately 20 mg ml⁻¹, the irradiation sensitivity of which is described in the accompanying paper (Wien et al., 2005), was used to show the significant improvement in spectral data collection that resulted when using attenuation. The protein samples were dialysed against water using Slide-A-Lyzer MINI dialysis units (Pierce, USA) and degassed under vacuum prior to data collection, as were the baseline solutions where used. Protein samples were mounted in a Hellma Quartz Suprasil demountable circular cell of pathlength 0.014 mm. A second cell of pathlength 0.015 mm was also used, as described in subsequent sections [the pathlengths for each having been measured by interferometery techniques (Miles et al., 2005)]. All data were collected with the temperature for the sample set at 277 K. All spectra were processed using CDTool (Lees et al., 2004).

2.1. Overcoming irradiation effects with a water attenuator cell

For all the spectra collected as reported in this section, a step size of 1 nm and a dwell time of 1 s were used. Three repeat scans were recorded on a lysozyme sample from stock using the 0.014 mm cell (Fig. 1a) over a wavelength range 300–170 nm. All spectra were zeroed over the range 263–267 nm. Using a fresh protein sample from the stock solution, an initial spectrum was recorded over the wavelength range 300–185 nm; then the wavelength was set to 170 nm and the sample left exposed to the SRCD beam for 30 min. This exposure duration was equivalent to approximately five times that of a standard 300–185 nm scan. Following this, a further spectrum was recorded, repeating the protocol of the initial spectrum. The set-up for the attenuation procedure involved using a second cell (Fig. 1b). A water-filled cell, of pathlength 0.015 mm, was placed into the sample holder, beam-side of the sample cell. Again an initial spectrum was recorded using a fresh protein sample from the stock. Here, however, the time scan at wavelength 170 nm was of 60 min duration, to counter-balance the presence of the attenuator cell. A further wavelength scan was then recorded. To test the validity of this attenuation procedure, and to clarify features of the irradiation effect, a control experiment was undertaken (Fig. 1c). Here, the two cell cover plates were placed prior to the sample holders. The protein sample was diluted to half its concentration (∼10 mg ml⁻¹), then added to the 0.014 mm cell with sufficient volume that the 0.015 mm cell could be placed onto it (thereby creating almost exactly double the volume of sample in the beam), as shown in the Fig. 1(c). Spectra were then recorded in an identical fashion to that described for the water-cell attenuation experiment, the duration of the exposure again being 60 min because of the pathlength now being doubled. To test this attenuation procedure under more severe conditions, three spectra were collected with a step size of 0.5 nm over the wavelength range 300–170 nm using a 0.02 mm-pathlength water-filled attenuator cell placed beam-side of the 0.014 mm sample cell.

Figure 1 Arrangements of the cells for the experiments conducted. The arrow pointing to the right indicates the direction from the beam source. (a) Initial set-up for the sample cell, directly in the SRCD beam. (b) Set-up for the water-filled beam-attenuated procedure. A water-filled cell is placed in the path of the beam prior to the sample. (c) Control set-up. Here the two glass cover plates are placed prior to the sample well plates which are now placed together creating one container, approximately double the size, as explained in the accompanying text.

3. Results and discussion

Fig. 2 shows three sequential spectra of lysozyme collected on CD12 using a 1 nm step size and 1 s dwell time. When using a `standard' set-up for collecting the SRCD data (Fig. 1a) there are substantial differences in these repeat spectra. These differences themselves are reproducible (data not shown), and indicate that the protein is undergoing some sort of alteration from the native state during the data collection as a result of being exposed to the SRCD beam. That a central cause of this irradiation effect is the high flux associated with CD12 is attested by the fact that this phenomenon was not seen in SRCD spectra of proteins collected on the lower-flux station 3.1, the now-decommissioned predecessor to CD12 (Orry et al., 2001). Nor is it seen on station UV1 on the ASTRID ring at Aarhus, Denmark (data not shown). There is a loss of magnitude in the signal between the first and second spectrum in the series, and between the second and third. This problem with the high flux means that in the set-up of the beamline used currently it has generally not been possible to collect reproducible spectra from a single sample. The most likely explanation for this is that some of the protein sample exposed to the SRCD beam is being affected by localized heating, but this is fully discussed in the accompanying paper (Wien et al., 2005).

Figure 2 All spectra shown in this and subsequent figures were recorded over the wavelength range 300–170 nm unless otherwise stated. Three repeat spectra of lysozyme recorded under the initial set-up conditions (as in Fig. 1a and described in §2.1). This clearly shows the effects of irradiation on the SRCD signal over the repeats from the first (blue) to the second (green) to the third (red).

Prior experiments had established that the irradiation problem was most severe after exposure to the flux from CD12 at wavelengths from ∼185 nm and lower (data not shown, and Wien et al., 2005; Clarke & Jones, 2004). Fig. 3 shows spectra recorded before and after 30 min of exposure to the SRCD beam at 170 nm using the set-up shown in Fig. 1(b). Being approximately five times the duration taken to complete a single scan run, the 30 min exposure was significantly beyond the time necessary for a `standard' three-scan experiment. Not only are there differences in the signal magnitude between the two spectra, but there are also peak shape and position differences as well. Fig. 4 shows the difference spectrum of the data in Fig. 3. This was created by scaling the CD spectral data of the `after exposure' spectrum to be identical to the `before exposure' spectrum at a wavelength of 222 nm (where no signal is seen for unordered structure), then subtracting the `before exposure' data. This clearly demonstrates that being exposed to the high flux at 170 nm for 30 min results in the sample being denatured as shown by the spectrum in Fig. 4, characteristic of unordered protein.

Figure 3 Spectra of lysozyme taken prior to exposure at 170 nm for 30 min in the SRCD beam under the initial set-up conditions (blue), and after exposure (red) (using the set-up as in Fig. 1a and described in §2.1). The recording range for these spectra was 300–185 nm.

Figure 4 Difference spectrum of the spectra shown in Fig. 3, with the `after exposure' spectrum first scaled to be identical to the `before exposure' value at 222 nm, then the `before exposure' subtracted from it.

By lowering the flux on the sample through attenuation, it was in turn expected that the irradiation effect would also be reduced, as the sample would not be so subjected to the localized heating during the data collection. Owing to the attenuation cell placed before the sample cell, both of approximately the same pathlength, the duration of exposure to the beam at 170 nm was doubled to provide a comparable total flux to that where no attenuation was used. Fig. 5 shows the results of this attenuation experiment. As can be seen, the difference in spectra before and after exposure to the beam at 170 nm is substantially smaller than that without attenuation. Attenuation of the beam in this manner therefore does appear to have significantly reduced the irradiation effect caused by the SRCD beam. It seems that the attenuation cell appears to have acted as a heat sink, absorbing the energy normally gained by the sample imparted to it by the high-flux beam. As the sample cell now receives lower flux, there is a significant reduction in the denaturation of the protein that results from the localized heating.

Figure 5 Spectra of lysozyme taken prior to exposure at 170 nm for 60 min in the SRCD beam under the attenuation conditions (blue) and after exposure (red) (using the set-up as in Fig. 1b and described in §2.1). The recording range for these spectra was 300–185 nm.

The spectra from the control experiment, conducted to ascertain whether the attenuation observed using the water cell was only because of an overall change in the pathlength and was thus nothing to do with heating, are given in Fig. 6, the set-up being shown in Fig. 1(c). Once again, exposure to the beam at 170 nm was doubled in time as the pathlength was also now double with the sample and attenuator cells being placed together. It is clear that there is no attenuation, and that increasing the pathlength alone has not overcome the irradiation effect. Indeed, the spectra shown in Fig. 6 are very similar to those in Fig. 3, where no attenuation was present, and are comparable with those observed from thermal de­naturation experiments on lysozyme (Takesada et al., 1973). In addition, Fig. 4 agrees with this observation.

Figure 6 Spectra of lysozyme taken prior to exposure at 170 nm for 60 min in the SRCD beam under the control conditions (blue) and after exposure (red) (using the set-up as in Fig. 1c and described in §2.1). The recording range for these spectra was 300–185 nm.

Fig. 7 shows three spectra of lysozyme now with a step size of 0.5 nm and using a 0.02 mm-pathlength water-filled attenuator cell beam-side of the sample, since the reduced step size led to longer data-collection times and an increased exposure to the beam. There is substantial improvement in the comparability of the spectral shapes of the three spectra compared with those of Fig. 2.

Figure 7 Three repeat spectra of lysozyme recorded with an attenuator in place and with a step size of 0.5 nm (blue, green and red being the first, second and third, respectively) (using the set-up as in Fig. 1c and described in §2.1).

The water-cell attenuation approach greatly reduces the irradiation effect, even under the more severe conditions of data collection using a 0.5 nm scan step. However, there is still a slight loss of signal over the period of time and wavelength range of such a scanning protocol. Additionally, the water in the attenuator cell increases the absorption in the lower wavelength range to the detriment of measuring an accurate CD signal in this region, restricting the data collection as a result. Other liquids [ethylene glycol/water (30/70 v/v) and fomblin oil (perfluoropolyether)] were examined for their suitability to act as the attenuator, but none have been identified so far to be any better in absorption properties at the lower wavelengths than the water itself (data not shown).

As collecting data in the lower wavelength range represents the major advantage of SRCD over cCD, other methods of attenuation to reduce the beam flux hitting the sample cell were explored. One such method used was to close the `pre-monochromator' baffles on the beamline, the aim being to reduce the flux of the beam hitting the monochromator and thus reduce the overall flux reaching the sample. This approach, however, did not prove to be of use. Substantial reductions to one quarter of the initial voltages recorded on the detector (with no sample present, and used purely as a guide to the flux from the beamline) did not lessen the differences between spectra when a sample was irradiated (data not shown). A second approach was to close the vertical slits on the beamline adjacent to the sample chamber, hence limiting the cross-sectional area of the beam hitting the sample. Fig. 8 shows four spectra of the lysozyme stock protein recorded with a 0.5 nm step size, without attenuation and thus with the irradiation problem. With a duration of about 7 min for a scan, this equates to a radiation dose of around 4.4 kJ m⁻² (Clarke & Jones, 2004). The cross-sectional area of the full beam hitting the sample when measured photographically without the slits in place was found to be ∼5 mm × ∼12 mm. The slits were then closed as described in §2.2, the cross-sectional area of the beam being reduced to ∼5 mm × ∼9 mm, and four spectra were again recorded. The resultant spectra in Fig. 9 show that the differences between them are now within the overall noise of the spectra themselves. In this slit configuration, three repeat spectra with a 0.5 nm step size can be recorded under good practice conditions without apparent denaturation of the protein sample. In order to test this set-up to the extreme, HSA was used. HSA has currently been found to be the protein most susceptible to the denatur­ation processes observed on CD12. With the slits closed as for the lysozyme spectra shown in Fig. 9, recording of HSA repeat spectra still gave rise to some denaturation, albeit to a very limited extent (data not shown). The slit width was thus reduced again to create a beam of ∼5 mm × ∼8 mm, and the four spectra for HSA in Fig. 10 are the results from this position of the slits. For these four repeats there is no measurable denaturation, the differences between them remaining in the noise level. The signal-to-noise ratio for the spectra recorded using the non-attenuated, water-cell-attenuated and slit-attenuated procedures remained comparable in each case when examined over the wavelength range used for zeroing the spectra (263–267 nm).

Figure 8 Four repeat spectra (blue, green, orange and red, respectively) of lysozyme unattenuated with a step size of 0.5 nm. The trend observed in these spectra is similar to that seen in the spectra in Fig. 2 (using the set-up as in Fig. 1a and described in §2.2).

Figure 9 Four repeat spectra (blue, green, orange and red, respectively) of lysozyme with the beam slits closed to 5.10 and 22.90 on the vernier scales, and a step size of 0.5 nm (using the set-up as in Fig. 1a and described in §2.2).

Figure 10 Four repeat spectra (blue, green, orange and red, respectively) of HSA with the beam slits closed to 4.75 and 23.25 on the vernier scales, and a step size of 0.5 nm (using the set-up as in Fig. 1a and described in §2.3).

Decreasing the slit width in this way from fully open to ∼5 mm × ∼8 mm represents a reduction from ∼60 mm² to ∼40 mm², approximately a decrease of one third in the cross-sectional area of the source beam on the sample. The possibility exists that these attenuation experiments have in fact cut out stray light from hitting the sample, and that this is the root cause of why spectra are subsequently reproducible. This cannot be excluded given the experiments conducted here; however, this is unlikely to be the case as numerous experiments have been conducted on this beamline which have concluded that any stray light is minimal to non-existent (D. Clarke, personal communication). In fact, closing the slits has probably introduced many beneficial effects for data collection. Less protein sample is being irradiated, and therefore there is less opportunity for the protein to be denatured. Additionally, and of significance, there is a greater area not being irradiated into which protein sample can diffuse away from the irradiation area. This would be a localized diffusion event induced by the localized heating in the sample by the high-flux intensity of the synchrotron beam, and not an overall bulk effect. Sample that is exposed to the beam therefore has a greater chance of diffusing out, and even if `slightly denatured' it has the opportunity to refold in the cooler conditions of the surrounding sample area. Likewise, `fresh sample' from the surrounding pool has had an opportunity to diffuse in replenishing the sample being irradiated with fully folded protein. Diffusion is therefore probably providing the stabilization of conditions necessary to ensure that, over the period of time it takes to record repeat spectra (here under the more severe data-collection protocol of a 0.5 nm scan step and four repeats), there is no appreciable loss of signal through denaturation. Therefore, collecting three repeat spectra under these conditions, as a good practice protocol, will not compromise the state of a protein sample to any significantly measurable extent. Additionally, this set-up now enables productive protein-melting studies to be undertaken on CD12 (F. Wien & A. Miles, personal communications).

4. Conclusions

With CD12 at Daresbury there exists a state-of-the-art SRCD beamline capable of recording data to wavelengths substantially lower than for conventional laboratory-based CD machines. In the set-up of the beamline that has been running to date there has been a problem associated with recording repeat scans causing apparent denaturation of protein samples throughout the course of the experiment. Clarke & Jones (2004) suggested this to be a degradation process caused by radical formation, which from the accompanying paper seems not to be the primary cause. They also advise that for most measurements the high flux of the CD12 beamline allows for the collection of good signal-to-noise data from only a single rapid scan which would therefore avoid the degradation problem. Whilst substantially reducing this problem, this is not a solution as no statistical analyses can be conducted on a single scan, and fresh, possibly precious, samples would have to be used to carry out `repeat' scans to provide any validation for the CD spectra recorded. The work reported here shows that the denaturation problem can readily be overcome by reducing the cross-sectional area of the source beam hitting the sample. Our results show that four spectra of HSA, a protein highly sensitive to this de­naturation, can be recorded with differences between the spectra being within the noise. With the slits closed, limiting the cross-sectional area of the source beam hitting the sample, this new set-up for the CD12 beamline enables a typical good practice protocol of collecting three repeat spectra to be adopted, thus ensuring that statistically valid data can be collected.