Anna J Warren, Adam D Crawshaw, Jose Trincao, Pierre Aller, Simon Alcock, Ioana Nistea, Paula S Salgado, Gwyndaf Evans
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引用次数: 0
Abstract
The measurement of diffraction data from macromolecular crystal samples held in vacuo holds the promise of a very low X-ray background and zero absorption of incident and scattered beams, leading to better data and the potential for accessing very long X-ray wavelengths (>3 Å) for native sulfur phasing. Maintaining the hydration of protein crystals under vacuum is achieved by the use of liquid jets, as with serial data collection at free-electron lasers, or is side-stepped by cryocooling the samples, as implemented at new synchrotron beamlines. Graphene has been shown to protect crystals from dehydration by creating an extremely thin layer that is impermeable to any exchanges with the environment. Furthermore, owing to its hydrophobicity, most of the aqueous solution surrounding the crystal is excluded during sample preparation, thus eliminating most of the background caused by liquid. Here, it is shown that high-quality data can be recorded at room temperature from graphene-wrapped protein crystals in a rough vacuum. Furthermore, it was observed that graphene protects crystals exposed to different relative humidities and a chemically harsh environment.
在真空中测量大分子晶体样品的衍射数据,有望获得极低的 X 射线背景以及零入射和散射光束吸收,从而获得更好的数据,并有可能获得超长 X 射线波长(>3 Å)的原生硫相位。在真空条件下保持蛋白质晶体的水合状态,可通过使用液体喷射器来实现,如在自由电子激光器上进行串行数据采集,或通过低温冷却样品来实现,如在新的同步辐射光束线上实现。事实证明,石墨烯可以保护晶体不脱水,因为石墨烯形成的极薄层不会与环境发生任何交换。此外,由于石墨烯的疏水性,在样品制备过程中,晶体周围的大部分水溶液都被排除在外,从而消除了由液体引起的大部分背景。研究表明,在室温下,石墨烯包裹的蛋白质晶体可在粗糙真空中记录高质量数据。此外,还观察到石墨烯能保护暴露在不同相对湿度和化学性质恶劣环境中的晶体。
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