Small angle X-ray Scattering (SAXS) is a method for determining basic structural characteristics such as size, shape, and surface of particles. SAXS can generate low resolution models of biomolecules faster than any other conventional structural biology tools. SAXS data is mostly collected in synchrotron facilities to obtain the best scattering data possible however home source SAXS devices can also generate valuable data when optimized properly. Here, we examined sample data collection and optimization at home source SAXS beamline in terms of concentration, purity, and the duration of data acquisition. We validated that high concentration, monodisperse and ultra pure protein samples obtained by size exclusion chromatography are necessary for generating viable SAXS data using home source beamline. Longer data collection time does not always generate higher resolutions but at least one hour is required for generating a feasible model from SAXS data. Furthermore, with small optimizations both during data collection and later data analysis SAXS can determine properties such as oligomerization, molecular mass, and overall shape of particles in solution under physiological conditions.
Small angle X-ray Scattering (SAXS) is a method for determining basic structural characteristics such as size, shape, and surface of particles. SAXS can generate low resolution models of biomolecules faster than any other conventional experimental structural biology tools. SAXS data is mostly collected in synchrotron facilities to obtain the best scattering data possible however home source SAXS devices can also generate valuable data when optimized properly. Here, we examined sample data collection and optimization at home source SAXS beamline in terms of concentration, purity, and the duration of data acquisition. We validated that high concentration, monodisperse and ultra pure protein samples obtained by size exclusion chromatography are necessary for generating viable SAXS data using home source beamline. Longer data collection time does not always generate higher resolutions but at least one hour is required for generating a feasible model from SAXS data. Furthermore, with small optimizations both during data collection and later data analysis SAXS can determine properties such as oligomerization, molecular mass, and overall shape of particles in solution under physiological conditions.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8′s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein′s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
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