Guidelines for de novo phasing using multiple small-wedge data collection.

Seiki Baba,Nobuhiro Mizuno,Kunio Hirata,Naoki Sakai,Yuki Nakamura,Takashi Kawamura,Takashi Kumasaka,Yoshiaki Kawano,Masaki Yamamoto,Hiroaki Matsuura

doi:10.1107/s1600577521008067

Abstract

Intense micro-focus X-ray beamlines available at synchrotron facilities have achieved high-quality data collection even from the microcrystals of membrane proteins. The automatic data collection system developed at SPring-8, named ZOO, has contributed to many structure determinations of membrane proteins using small-wedge synchrotron crystallography (SWSX) datasets. The `small-wedge' (5-20°) datasets are collected from multiple crystals and then merged to obtain the final structure factors. To our knowledge, no systematic investigation on the dose dependence of data accuracy has so far been reported for SWSX, which is between `serial crystallography' and `rotation crystallography'. Thus, herein, we investigated the optimal dose conditions for experimental phasing with SWSX. Phase determination using anomalous scattering signals was found to be more difficult at higher doses. Furthermore, merging more homogeneous datasets grouped by hierarchical clustering with controlled doses mildly reduced the negative factors in data collection, such as `lack of signal' and `radiation damage'. In turn, as more datasets were merged, more probable phases could be obtained across a wider range of doses. Therefore, our findings show that it is essential to choose a lower dose than 10 MGy for de novo structure determination by SWSX. In particular, data collection using a dose of 5 MGy proved to be optimal in balancing the amount of signal available while reducing the amount of damage as much as possible.

Highlights

It has become possible to accomplish structural analysis even from small crystals with weak diffracting power, such as membrane proteins
Experimental phases were successfully determined for all dose conditions for data obtained at a wavelength of 1.7 A, and the automated chain tracing function of SHELXE built more than 76% of the main chain model of the lysozyme
For the datasets obtained at 1.4 Awavelength, the phases were successfully determined and the autotracing function built more than 76% of the main chain model, except for the data at a dose of 40 MGy

Summary

Introduction

It has become possible to accomplish structural analysis even from small crystals with weak diffracting power, such as membrane proteins. High-brilliance and small X-ray beams available at synchrotron radiation facilities enable reduced scattering from the noncrystalline volume and measurement of weak diffraction intensities from tiny crystals with high signal-to-noise ratio (Smith et al, 2012; Owen et al, 2017; Yamamoto et al, 2017). Radiation damage is still a limitation for data collection from tiny protein crystals since the amount of signal per absorbed dose is reduced as the crystal volume diminishes (Holton & Frankel, 2010).

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