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Acta Cryst. (2014). A70, C112
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Small Angle X-ray Scattering (SAXS) is a powerful tool for the structural analysis of biological macromolecules in solution and has seen a surge in popularity amongst structural biologists in the past decade. In part, this is because SAXS benefits greatly from the sensitivity and throughput that can be achieved at modern high brightness synchrotron sources. However, the critical need for highly monodisperse samples in SAXS analysis can be a challenge, and as such a number of labs have moved to develop in-line Size Exclusion Chromatography (SEC) at the beamline. Real-time SAXS on elution profiles not only improves monodispersity of samples and provides information on possible oligomeric states, but it also offers new modes of data analysis that can take advantage of the inherent concentration profiles underlying elution peaks and distributions of partially resolved species. Efforts to extend the synergy between SEC and SAXS to other biophysical methods are ongoing. The newly commissioned G1 BioSAXS facility at MacCHESS now offers the option of combining real-time SEC-SAXS with multi-angle static (MALS) and dynamic (DLS) light scattering along with refractive index (RI) detection. In this talk we give a brief overview of the performance and capabilities of the new BioSAXS station at MacCHESS with emphasis on detection limits and signal quality. We then discuss how the complementary light scattering techniques can be combined to offer new insights for complex inhomogeneous samples in terms of biological information and data quality assessment. We also discuss the limitations and possible future developments of these approaches as biologists seek to investigate more dynamic systems as well as shorter time scales.

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Acta Cryst. (2014). A70, C408
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Small angle X-ray scattering (SAXS) is an increasingly popular technique for obtaining low resolution structural information from macromolecules and complexes in solution. Biomolecular SAXS signals can rapidly degrade due to radiation damage, so that flow or oscillating cells and large total sample volumes may be required. For particularly sensitive or hard to produce samples, such as of light sensitive proteins, metalloenzymes, and large complexes, and studies where multiple buffer conditions are probed sample consumption may be prohibitive. We describe cryo-cooling of samples to 100 K to prevent X-ray induced radiation damage. We identify SAXS-friendly cryoprotectant conditions that suppress ice formation upon cooling, and compare cryoSAXS profiles obtained in window-free variable-path-length cells with room temperature measurements for a variety of standard molecules. We obtain data sufficient for envelope reconstructions using scattering volumes as small as 20 nL, and find good agreement between cryoSAXS data and known atomic structures. We also discuss work on developing low-volume fixed path-length sample holders for cryoSAXS. Cryo-cooled samples can withstand doses that are 2-3 orders of magnitude higher than typically used for SAXS at room temperature, comparable to those used in cryo-crystallography. While practical challenges remain, cryoSAXS opens the possibility of studies exploiting high brightness X-ray sources and mail-in high-throughput SAXS. This work is funded by the NSF (DBI-1152348).
Keywords: SAXS; cryoSAXS.

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Acta Cryst. (2014). A70, C412
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Biological small angle x-ray solution scattering requires sufficient sample concentration to yield good signal while at the same time avoiding interparticle interference or the formation of unwanted oligomers or aggregates. The mere act of concentrating some samples risks rendering them unfit for SAXS measurements and the limit to which a sample may be concentrated before problems occur is often unknown a priori; aggregation is not generally regarded as a reversible process. At the same time, sample behavior at high concentrations is increasingly important not just for characterization of equilibria, or e.g. applications in the pharmaceutical industry, but also for understanding potential molecular crowding effects. We have constructed a microfluidic dialysis setup that permits on-demand concentration of protein samples at the beamline. Rather than generating dilution series to explore concentration effects, this approach produces true "concentration series", efficiently working from dilute sample upward. We experimentally demonstrate that useful concentrations can be achieved on practical timescales and that buffer exchange can be performed. Convection-diffusion modeling shows that the dialysis chip may actually retard aggregates, thus resulting in some degree of incidental sample purification. Based on model projections, the theoretical limits and potential of chip-dialysis will be described.

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Acta Cryst. (2014). A70, C787
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"MacCHESS (""Macromolecular diffraction at CHESS"") is an NIH funded facility at the Cornell High Energy Synchrotron Source; we provide a user facility with an exceptional level of support, as well as pursuing research to benefit the entire structural biology community. CRYSTALLOGRAPHY: High-flux monochromatic beamlines outfitted with state-of-the-art equipment are available. BSL-2 biohazards can be handled. Research activities include on-line confocal microscopy, working with multiple small crystals, use of graphene to reduce background, etc. BIOSAXS: A dedicated beamline features: a dual SAXS/WAXS setup using 2 Pilatus detectors; an integrated computer-controlled flow system including robotic sample loading from 96-well trays, custom-made disposable, transparent sample cells, and a convenient graphical interface; a well-equipped wet lab for sample monitoring and final preparation; an in-line SEC-MALS/DLS-SAXS option. Microfluidic "lab-on-a-chip" units are under development. Periodic workshops are held to educate users in the intricacies of BioSAXS. PRESSURE CRYOCOOLING: Cryocooling crystals under pressure reduces both cooling-induced degradation and the need for penetrating cryoprotectants, and can stabilize mobile ligands and possibly reaction intermediates. We offer pressure-cryocooling as a service to CHESS users, while continuing to develop the method. Several sample mounting techniques are now available, and the technique has promise for use with biological samples other than crystals. FMI: To request beamtime, fill out a simple on-line proposal form at http://www.chess.cornell.edu. Mail-in service is available, and remote data collection is supported for experienced crystallography users. We welcome a chance to collaborate on "non-standard" experiments. For more information, contact User Administrator Kathy Dedrick (kd73@cornell.edu)."
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