Abstract
BackgroundSynchrotron radiation facilities are pillars of modern structural biology. Small-Angle X-ray scattering performed at synchrotron sources is often used to characterize the shape of biological macromolecules. A major challenge with high-energy X-ray beam on such macromolecules is the perturbation of sample due to radiation damage.ResultsBy employing atomic force microscopy, another common technique to determine the shape of biological macromolecules when deposited on flat substrates, we present a protocol to evaluate and characterize consequences of radiation damage. It requires the acquisition of images of irradiated samples at the single molecule level in a timely manner while using minimal amounts of protein. The protocol has been tested on two different molecular systems: a large globular tetremeric enzyme (β-Amylase) and a rod-shape plant virus (tobacco mosaic virus). Radiation damage on the globular enzyme leads to an apparent increase in molecular sizes whereas the effect on the long virus is a breakage into smaller pieces resulting in a decrease of the average long-axis radius.ConclusionsThese results show that radiation damage can appear in different forms and strongly support the need to check the effect of radiation damage at synchrotron sources using the presented protocol.
Highlights
Synchrotron radiation facilities are pillars of modern structural biology
According to the reconstituted tetrameric structure of β-Amylase, the computed maximum bounding box of Cα atoms has a size of 12.4 × 12.4 × 7.5 nm3 and a radius of gyration of 4.14 nm
Atomic force microscopy (AFM) images were obtained with β-Amylase adsorbed on hydrophilic mica in liquid environment using the amplitude modulation mode
Summary
Small-Angle X-ray scattering performed at synchrotron sources is often used to characterize the shape of biological macromolecules. The most recent step forward in structural biology for characterizing large molecular assemblies is the integration of several complementary techniques to reach the goal of determining structures at atomic level. In this frame, it is essential to combine information from a variety of physical and chemical origins providing a solid basis to understanding molecular function. SAXS applied to dilute solutions of proteins is a long established technique in structural biology It gives ensemble reciprocal space information on the size and shape of macromolecules [2,3,4,5]. Radiation-induced aggregation has been observed with SAXS data for lysozyme, but
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