Transmission electron microscopy as a tool for nanocrystal characterization pre- and post-injector

Stevenson, Hilary P.; DePonte, Daniel P.; Makhov, Alexander M.; Conway, James F.; Zeldin, Oliver B.; Boutet, Sébastien; Calero, Guillermo; Cohen, Aina E.

doi:10.1098/rstb.2013.0322

Cited by 23 publications

(25 citation statements)

References 21 publications

(18 reference statements)

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“…Diffraction patterns of superior resolution (3.3 Å) were observed when using the microdiffractometer setup at LCLS XPP at 100 K than were previously measured at LCLS-CXI or at the synchrotron (Table S2). The lower diffraction resolution observed (4.0 Å) during screening experiments at LCLS CXI using smaller crystals and the GDVN injector suggests that a larger sample volume may be required to obtain higher resolution diffraction, or that the crystals were damaged during injection, potentially a consequence of their high solvent content (24). The best diffraction resolution (3.7 Å) observed at SSRL BL12-2 from these crystals (grown in same crystallization batch as used at LCLS XPP), suggests that Pol II-TFIIB-NAS crystals suffer significant radiation damage during the exposure time needed to deliver an equivalent dose at a synchrotron.…”

Section: Raster Data Collectionmentioning

confidence: 98%

“…However, there are different and often more complex optimization steps associated with specific injector technologies. Solutions containing a mixture of crystal sizes may require filtering to avoid clogging in the injector nozzle, and delicate crystals may be damaged from the pressures and shear forces of the delivery process itself (24). For experiments conducted in vacuo, stream formation may be disrupted by solution bubbling, drying, or freezing as it exits the injector and enters the vacuum chamber.…”

Section: Significancementioning

confidence: 99%

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Goniometer-based femtosecond crystallography with X-ray free electron lasers

Cohen

Soltis

González

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

126

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The emerging method of femtosecond crystallography (FX) may extend the diffraction resolution accessible from small radiationsensitive crystals and provides a means to determine catalytically accurate structures of acutely radiation-sensitive metalloenzymes. Automated goniometer-based instrumentation developed for use at the Linac Coherent Light Source enabled efficient and flexible FX experiments to be performed on a variety of sample types. In the case of rod-shaped Cpl hydrogenase crystals, only five crystals and about 30 min of beam time were used to obtain the 125 still diffraction patterns used to produce a 1.6-Å resolution electron density map. For smaller crystals, high-density grids were used to increase sample throughput; 930 myoglobin crystals mounted at random orientation inside 32 grids were exposed, demonstrating the utility of this approach. Screening results from cryocooled crystals of β 2 -adrenoreceptor and an RNA polymerase II complex indicate the potential to extend the diffraction resolution obtainable from very radiation-sensitive samples beyond that possible with undulator-based synchrotron sources.femtosecond diffraction | crystallography | XFEL | structural biology U sing extremely bright, short-timescale X-ray pulses produced by X-ray free-electron lasers (XFELs), femtosecond crystallography (FX) is an emerging method that expands the structural information accessible from very small or very radiation-sensitive macromolecular crystals. Central to this method is the "diffraction before destruction" (1) process in which a still diffraction image is produced by a single X-ray pulse before significant radiation-induced electronic and atomic rearrangements occur within the crystal (1-3). At the Linac Coherent Light Source (LCLS) at SLAC, a single ∼50-fs-long X-ray pulse can expose a crystal to as many X-ray photons as a typical synchrotron beam line produces in about a second. Exposing small crystals to these intense ultrashort pulses circumvents the dose limitations of conventional X-ray diffraction experiments (4) and may produce useful data to resolutions beyond what is achievable at synchrotrons (5). This innovation provides a pathway to obtain atomic information from proteins that only form micrometer-to nanometer-sized crystals, such as many membrane proteins and large multiprotein complexes. Moreover, XFELs enable "diffraction before reduction" data collection to address another major challenge in structural enzymology by providing a means to determine catalytically accurate structures of acutely radiation-sensitive metalloenzyme active sites (6), such as high-valency reaction intermediates that may be significantly photoreduced during a single X-ray exposure at a synchrotron, even at very small doses (7-11). Furthermore, the use of short (tens of femtoseconds) X-ray pulses further complements the structural characterization of biochemical reaction processes by providing access to a time domain two to three orders of magnitude faster (12, 13) than currently accessible using synchrotro...

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Section: Raster Data Collectionmentioning

confidence: 98%

Section: Significancementioning

confidence: 99%

Goniometer-based femtosecond crystallography with X-ray free electron lasers

Cohen

Soltis

González

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

126

View full text Add to dashboard Cite

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“…It was immediately realized that the high spatial coherence provided new approaches to the phase problem, for both SPs (Loh [7], Ourmazd and co-workers [8], Martin [9], Schwander et al [16]) and nanocrystals (Millane & Chen [17], Kirian et al [18], Spence et al [19] and Barty et al [20]). Atomic resolution has so far been obtained from unknown structures only using nanocrystals (and near-atomic resolution in the FSS when small changes in a known structure are studied), so that a crucial area for development of the BioXFEL field is the development of new methods for growing nanocrystals (Kupitz et al [21], Caffrey et al [22], Gallat et al [23] and Stevenson et al [24]). When the study of the evolving damage processes (reviewed by Chapman et al [3]), diffraction physics (White [25]), simultaneous emission spectroscopy (Kern et al [15]) and detector development (Denes [26]) is added to this list of subfields, it will be seen that structure and dynamics in biology with XFELs is an extremely rich interdisciplinary field, now undergoing rapid innovation and creative development.…”

mentioning

confidence: 99%

The birth of a new field

Spence

Chapman

2014

Phil. Trans. R. Soc. B

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“…The most important characteristics in this optimization are size distribution, density and, of course, diffraction quality. Size distribution for submicron crystals can be obtained using dynamic light scattering [29,45], Nanosight [33,46] or electron microscopy [47]. A new microfluidic technique even allows inert post crystallization sorting using dielectrophoresis [35].…”

Section: Growth and Biophysical Characterization Of Nanocrystalsmentioning

confidence: 99%

“…A new microfluidic technique even allows inert post crystallization sorting using dielectrophoresis [35]. Electron microscopy is an excellent characterization tool for nanocrystals, allowing predicted diffraction quality, analysis of size distribution and permitting comparison of samples at various stages in the sample preparation and subsequent experiment [47] (see Fig. 4).…”

Section: Growth and Biophysical Characterization Of Nanocrystalsmentioning

confidence: 99%

Serial femtosecond crystallography opens new avenues for Structural Biology

Coe¹,

Fromme

2016

PPL

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Free electron lasers (FELs) provide X-ray pulses in the femtosecond time domain with up to 1012 higher photon flux than synchrotrons and open new avenues for the determination of difficult to crystallize proteins, like large complexes and human membrane proteins. While the X-ray pulses are so strong that they destroy any solid material, the crystals diffract before they are destroyed. The most successful application of FELs for biology has been the method of serial femtosecond crystallography (SFX) where nano or microcrystals are delivered to the FEL beam in a stream of their mother liquid at room temperature, which ensures the replenishment of the sample before the next X-ray pulse arrives. New injector technology allows also for the delivery of crystal in lipidic cubic phases or agarose, which reduces the sample amounts for an SFX data set by two orders of magnitude. Time-resolved SFX also allows for analysis of the dynamics of biomolecules, the proof of principle being recently shown for light-induced reactions in photosystem II and photoactive yellow protein. An SFX data sets consist of thousands of single crystal snapshots in random orientations, which can be analyzed now “on the fly” by data analysis programs specifically developed for SFX, but de-novo phasing is still a challenge, that might be overcome by two-color experiments or phasing by shape transforms.

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Transmission electron microscopy as a tool for nanocrystal characterization pre- and post-injector

Cited by 23 publications

References 21 publications

Goniometer-based femtosecond crystallography with X-ray free electron lasers

Goniometer-based femtosecond crystallography with X-ray free electron lasers

The birth of a new field

Serial femtosecond crystallography opens new avenues for Structural Biology

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