Progress towards imaging biological filaments using X-ray free-electron lasers

2020 35th International Conference on Image and Vision Computing New Zealand (IVCNZ) Pub Date : 2020-11-25 DOI:10.1109/IVCNZ51579.2020.9290623

R. D. Arnal, David H. Wojtas, R. Millane

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Abstract

X-ray free-electron lasers (XFELs) are opening new frontiers in structural biology. The extreme brilliance of these highly coherent X-ray sources allows for ever smaller crystals to be used while still being able to diffract enough photons to provide sufficient data for structure determination. Biomolecules arranged into filaments are an important class of targets that are expected to greatly benefit from the continuous improvements in XFEL capabilities. Here we first review some of the state-of the-art research in using XFELs for the imaging of biological filaments. Extrapolating current trends towards single particle imaging, we consider an intermediate case where diffraction patterns from single filaments can be measured and oriented to form a 3D dataset. Prospects for using iterative projection algorithms (IPAs) for ab initio phase retrieval with such data collected from single filaments are illustrated by the reconstruction of the electron density of a B-DNA structure from simulated, noisy XFEL data.

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利用x射线自由电子激光器成像生物细丝的研究进展

x射线自由电子激光器(XFELs)为结构生物学开辟了新的领域。这些高相干x射线源的极端亮度允许使用更小的晶体，同时仍然能够衍射足够的光子，为结构确定提供足够的数据。排列成细丝的生物分子是一类重要的靶标，有望从XFEL能力的不断改进中受益匪浅。在这里，我们首先回顾了一些使用XFELs进行生物细丝成像的最新研究。外推单粒子成像的当前趋势，我们考虑了一种中间情况，其中单细丝的衍射图案可以测量和定向形成3D数据集。利用模拟的、有噪声的XFEL数据重建B-DNA结构的电子密度，说明了利用迭代投影算法(IPAs)对从单丝收集的数据进行从头算相位检索的前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 35th International Conference on Image and Vision Computing New Zealand (IVCNZ)

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