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A U.S. Department of Energy laboratory managed by The University of Chicago X-Ray Damage to Biological Crystalline Samples Gerd Rosenbaum Structural Biology.

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Presentation on theme: "A U.S. Department of Energy laboratory managed by The University of Chicago X-Ray Damage to Biological Crystalline Samples Gerd Rosenbaum Structural Biology."— Presentation transcript:

1 A U.S. Department of Energy laboratory managed by The University of Chicago X-Ray Damage to Biological Crystalline Samples Gerd Rosenbaum Structural Biology Center, ANL and Dept. of Biochemistry, UGA ACA Summer School IIT, 18 July 2006

2 2 First Workshop (RD1) 1999 at ESRF Second Workshop (RD2) 2001 at APS http://www.aps.anl.gov/News/Conferences/2001/damage/home.html 8 papers in Journal of Synchrotron Radiation (2002) 9, 327 - 382 Third Workshop (RD3) 2003 at ESRF 9 papers in Journal of Synchrotron Radiation (2005) 12, 257 - 329 Fourth Workshop (RD4) 2006 at SPring8 http://www.spring8.or.jp/en/users/meeting/rd4 several presentations will be published International Workshops on X-Ray Damage to Biological Crystalline Samples Organizers: Elspeth Garman, Collin Nave, Gerd Rosenbaum, Raimond Ravelli, Seam McSweeney

3 3 Radiation Damage - An Unavoidable Byproduct Of Crystallographic Data Acquisition Radiation damage is proportional to dose on sample. dose = absorbed energy / mass( unit: 1 Gy = 1 J/kg ) dose = µ/  I t  phot I = flux density, t = exp. time Number of photons in diffraction peak N phot ~ I t V 2 V = sample volume Dose on sample / number of photons in diffraction peak dose / N phot ~ 1/V Almost all deposited energy is by photoelectric absorption. (µ/  photo ~ 3 => dose / N phot ~ 2 / 2 Radiation damage to cryo-cooled samples is not a particular property of 3 rd gen. sources. Lavish use of available flux is characteristic for users of 3 rd gen. sources: over-exposure Detector read-out units should be calibrated in photons to help guide level of exposure.

4 4 Primary and Secondary Radiation Damage and Cryo-cooling Primary radiation damage: Direct hit of protein by absorbed photon or by ejected photo-electron Secondary radiation damage:| Damage of protein by action of non-protein molecules activated by absorbed photon or by photo-electron (mostly hydroxyl radicals) Data Collection at Room Temperature: Early observation of radiation damage on home sources. More than 1 sample per data set needed. Cryo-cooling of samples: Radicals immobilized at 100 K; secondary damage stopped; ~50-100-times increase in sample life (dose tolerance); I 1/2 dose = 4*10 7 Gy Cooling to 15 K: improvement not clearly demonstrated; B-factor reduced (mostly)

5 5 Radiation Damage Observed at 3rd Generation Sources Renewed Attention to Radiation Damage at 3rd Generation Sources: - observed higher radiation damage attributed to high flux density -no significant dose rate effect observed in carefully designed studies -photons from 3rd gen. sources are not different from photons from other sources - high flux allows much higher exposure in available beam time allotment -concern about beam heating: not the cause of increased damage, even at max. flux from APS undulator temperature increase <10 K X-Ray Damage is Not Local -photo-electrons carry ~95% of energy of absorbed photon (12 keV) -photo-electrons from 12 keV photons travel ~2.8 µm -transfer damage energy of 20 eV average per hit -only 5% of energy (binding energy of C, N, O) of absorbed photon stays within 5 Å

6 6 Effects of Radiation Damage Breaking bonds => loss of occupancy, increased temp. factor S-S bonds first, then carboxyl, then other charged residues, then … (It's the chemistry, not the local absorption cross-section.) Changing charge state Reduction of metal centers Ironically, cryo-protectant among worst promoters. Increase in unit cell volume and lattice constants General decrease of intensity of diffraction peaks Increase in B-factor Non-Isomorphism Increased R merge between initial and later frames Problem for SAD/MAD phasing, especially sulfur SAD (Byfoet pairs suffered different amount of radiation damage)

7 7 Blake and Phillips [1] suggest the following model for radiation damage : 1.Blake, C.C. & Phillips, D.C. (1962). Effects of X-irradiation on single crystals of myoglobin. In Biological Effects of Ionizing Radiation at the Molecular Level. (Vienna: International Atomic Energy Agency), pp. 183-191. 2.Hendrickson, W.A. (1976). Radiation damage in protein crystallography. J. Mol. Biol. 106, 889-893. 3.Sliz, P., Harrison, S.C. & Rosenbaum, G. (2003).How does Radiation Damage in Protein Crystals Depend on X-Ray Dose. Structure 11, 13-19 The “disordered” unit cells have elevated temperature factors; the amorphous regions do not give Bragg diffraction at all. Hendrickson [2] concluded from data collected from myoglobin at room temperature that k 3 =0. Sliz et al. [3] concluded from data collected from several samples at 100 K at much higher exposure that k 3 =0. The process of radiation damage is sequential: A 1 => A 2 => A 3 Process of Radiation Damage

8 8 Studies of damage vs. dose and limiting sample sizes by Teng & Moffat (2000, 2002), Glaser et al. (2000) and Sliz, Harrison, Rosenbaum (2003) Radiation damage proportional to dose up to a certain limit; then fast collapse of structure (non-linear dose effect, not dose rate effect) No dose rate effect noticeable for flux densities up to 3*10 15 ph/s/mm 2 T&M and S,H,R conclude damage in cryo-cooled samples is primary damage, i.e. radicals are immobilized. Limit of crystal volume for full data set: Glaser et al.: ~ 35µm Teng&Moffat: ~30 µm Sliz, Harrison, Rosenbaum: ~15 µm (different resolutions, different criteria for damage limit.) Damage vs. Dose, Dose Rate Minimum Sample Size

9 9 Typical Effects of Radiation Damage on Diffraction Intensities, R merge, Unit Cell Volume, B-factor

10 10 Preventing, mitigating the effects of radiation damage Minimize dose - avoid high Z atoms in buffer - calculate dose using program RADDOSE [1] - reduce exposure to level necessary for accuracy as determined by photon statistics - reduce scatter by - minimizing beam on non-crystal volume - minimizing path length of primary beam through air - clean freeze, no ice - avoid high Z atoms in buffer (e.g. arsenic) or other high mol. weight stuff Radio-protectants (Garman, others) Scavengers: effectiveness not clear; concern about chemistry 1.Murray et al., J.Appl.Cryst. 37, 513-522 (to get program contact Elspeth Garman elspeth@biop.ox.ac.uk)

11 11 Mitigating or make use of the effects of radiation damage Correction of diffraction peak intensities for radiation damage (Otwinowsky, others) Akin to dead time loss correction. Extrapolate back to zero exposure Use non-isomorphism for phasing (Ravelli, others) Technology developments that can help reducing dose -detectors with low read noise / signal per photon) -ratio (read noise / signal per photon) should be <1 -detectors with large dynamic range (max. no. of photons per pixel / read noise in photons)

12 12 SBC Upgrades – Hardware and Electronics Upgrades

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