Electronic damage in S atoms in a native protein crystal induced by an intense X-ray free-electron laser pulse

Current hard X-ray free-electron laser (XFEL) sources can deliver doses to biological macromolecules well exceeding 1 GGy, in timescales of a few tens of femtoseconds. During the pulse, photoionization can reach the point of saturation in which certain atomic species in the sample lose most of their electrons. This electronic radiation damage causes the atomic scattering factors to change, affecting, in particular, the heavy atoms, due to their higher photoabsorption cross sections. Here, it is shown that experimental serial femtosecond crystallography data collected with an extremely bright XFEL source exhibit a reduction of the effective scattering power of the sulfur atoms in a native protein. Quantitative methods are developed to retrieve information on the effective ionization of the damaged atomic species from experimental data, and the implications of utilizing new phasing methods which can take advantage of this localized radiation damage are discussed.

[1]  Anton Barty,et al.  Indications of radiation damage in ferredoxin microcrystals using high-intensity X-FEL beams. , 2014, Journal of synchrotron radiation.

[2]  P. Howell,et al.  Identification of heavy‐atom derivatives by normal probability methods , 1992 .

[3]  Anton Barty,et al.  Cheetah: software for high-throughput reduction and analysis of serial femtosecond X-ray diffraction data , 2014, Journal of applied crystallography.

[4]  U Weierstall,et al.  Injector for scattering measurements on fully solvated biospecies. , 2012, The Review of scientific instruments.

[5]  Sang-Kil Son,et al.  Multiwavelength anomalous diffraction at high x-ray intensity. , 2011, Physical review letters.

[6]  Anton Barty,et al.  CrystFEL: a software suite for snapshot serial crystallography , 2012 .

[7]  Anton Barty,et al.  Ultrafast self-gating Bragg diffraction of exploding nanocrystals in an X-ray laser. , 2015, Optics express.

[8]  Sébastien Boutet,et al.  De novo protein crystal structure determination from X-ray free-electron laser data , 2013, Nature.

[9]  H. Chapman,et al.  Femtosecond protein nanocrystallography-data analysis methods. , 2010, Optics express.

[10]  Sébastien Boutet,et al.  The Coherent X-ray Imaging (CXI) instrument at the Linac Coherent Light Source (LCLS) , 2010 .

[11]  Nicholas K. Sauter,et al.  XFEL diffraction: developing processing methods to optimize data quality , 2015, Journal of synchrotron radiation.

[12]  G. Murshudov,et al.  Refinement of macromolecular structures by the maximum-likelihood method. , 1997, Acta crystallographica. Section D, Biological crystallography.

[13]  Sang-Kil Son,et al.  Impact of hollow-atom formation on coherent x-ray scattering at high intensity , 2011, 1101.4932.

[14]  Anton Barty,et al.  Natively Inhibited Trypanosoma brucei Cathepsin B Structure Determined by Using an X-ray Laser , 2013, Science.

[15]  Sean McSweeney,et al.  Specific radiation damage can be used to solve macromolecular crystal structures. , 2003, Structure.

[16]  K. Schmidt,et al.  Gas dynamic virtual nozzle for generation of microscopic droplet streams , 2008, 0803.4181.

[17]  Anton Barty,et al.  Towards phasing using high X-ray intensity , 2015, IUCrJ.

[18]  Georg Weidenspointner,et al.  Self-terminating diffraction gates femtosecond X-ray nanocrystallography measurements , 2011, Nature Photonics.

[19]  Randy J. Read,et al.  Phaser crystallographic software , 2007, Journal of applied crystallography.

[20]  Anton Barty,et al.  Crystallographic data processing for free-electron laser sources , 2013, Acta crystallographica. Section D, Biological crystallography.

[21]  Max H Nanao,et al.  Towards RIP using free-electron laser SFX data. , 2015, Journal of synchrotron radiation.