Abstract
The emergence of X-ray free-electron lasers has led to the development of serial macromolecular crystallography techniques, making it possible to study smaller and more challenging crystal systems and to perform time-resolved studies on fast time scales. For most of these studies the desired crystal size is limited to afew micrometres, and the generation of large amounts of nanocrystals or microcrystals of defined size has become a bottleneck for the wider implementation of these techniques. Despite this, methods to reliably generate microcrystals and fine-tune their size have been poorly explored. Working with three different enzymes, L-aspartate α-decarboxylase, copper nitrite reductase and copper amine oxidase, the precipitating properties of ammonium sulfate were exploited to quickly transition from known vapour-diffusion conditions to reproducible, large-scale batch crystallization, circumventing the tedious determination of phase diagrams. Furthermore, the specific ammonium sulfate concentration was used to fine-tune the crystal size and size distribution. Ammonium sulfate is a common precipitant in protein crystallography, making these findings applicable to many crystallization systems to facilitate the production of large amounts of microcrystals for serial macromolecular crystallography experiments.
Highlights
X-ray crystallography is still the most prevalent technique for solving the structures of soluble proteins
Working with three different soluble enzymes, Escherichia coli l-aspartate -decarboxylase (ADC; a 60 kDa homotetramer), Achromobacter cycloclastes copper nitrite reductase (AcNiR; a 120 kDa homotrimer) and E. coli copper amine oxidase (ECAO; a 165 kDa homodimer), we show that when using ammonium sulfate the complexity of a crystallization experiment can be simplified by assuming that crystallization is mainly driven by the precipitant
We present a novel approach to produce large amounts of microcrystals quickly in batch starting from previously established vapour-diffusion conditions with ammonium sulfate
Summary
X-ray crystallography is still the most prevalent technique for solving the structures of soluble proteins This requires a large, well ordered, single crystal in order to collect a complete data set by rotating the crystal through the X-ray beam. It is important to note that the timeresolution defined by diffusion is dependent on the thinnest crystal dimension (Mehrabi et al, 2019; Schmidt, 2013; Makinen & Fink, 1977). This means that the generation of suitable nanocrystals or microcrystals of defined size can be a significant bottleneck for the wider implementation of these techniques
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