Overcoming the preferred-orientation problem in cryo-EM with self-supervised deep learning.

IF 36.1 1区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS Nature Methods Pub Date : 2024-11-18 DOI:10.1038/s41592-024-02505-1
Yun-Tao Liu, Hongcheng Fan, Jason J Hu, Z Hong Zhou
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Abstract

While advances in single-particle cryo-EM have enabled the structural determination of macromolecular complexes at atomic resolution, particle orientation bias (the 'preferred' orientation problem) remains a complication for most specimens. Existing solutions have relied on biochemical and physical strategies applied to the specimen and are often complex and challenging. Here, we develop spIsoNet, an end-to-end self-supervised deep learning-based software to address map anisotropy and particle misalignment caused by the preferred-orientation problem. Using preferred-orientation views to recover molecular information in under-sampled views, spIsoNet improves both angular isotropy and particle alignment accuracy during 3D reconstruction. We demonstrate spIsoNet's ability to generate near-isotropic reconstructions from representative biological systems with limited views, including ribosomes, β-galactosidases and a previously intractable hemagglutinin trimer dataset. spIsoNet can also be generalized to improve map isotropy and particle alignment of preferentially oriented molecules in subtomogram averaging. Therefore, without additional specimen-preparation procedures, spIsoNet provides a general computational solution to the preferred-orientation problem.

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利用自我监督深度学习克服低温电子显微镜中的首选方向问题。
虽然单颗粒低温电子显微镜技术的进步使大分子复合物的结构测定达到了原子分辨率,但颗粒定向偏差("优先 "定向问题)仍然是大多数标本的一个复杂问题。现有的解决方案依赖于应用于标本的生化和物理策略,通常非常复杂且具有挑战性。在此,我们开发了基于深度学习的端到端自监督软件 spIsoNet,以解决首选取向问题造成的图谱各向异性和粒子错位问题。利用首选方向视图恢复采样不足视图中的分子信息,spIsoNet 在三维重建过程中提高了角度各向同性和粒子对准精度。我们展示了 spIsoNet 从有限视图的代表性生物系统(包括核糖体、β-半乳糖苷酶和以前难以解决的血凝素三聚体数据集)生成接近各向同性重建的能力。因此,无需额外的标本制备程序,spIsoNet 就能为优先取向问题提供通用的计算解决方案。
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来源期刊
Nature Methods
Nature Methods 生物-生化研究方法
CiteScore
58.70
自引率
1.70%
发文量
326
审稿时长
1 months
期刊介绍: Nature Methods is a monthly journal that focuses on publishing innovative methods and substantial enhancements to fundamental life sciences research techniques. Geared towards a diverse, interdisciplinary readership of researchers in academia and industry engaged in laboratory work, the journal offers new tools for research and emphasizes the immediate practical significance of the featured work. It publishes primary research papers and reviews recent technical and methodological advancements, with a particular interest in primary methods papers relevant to the biological and biomedical sciences. This includes methods rooted in chemistry with practical applications for studying biological problems.
期刊最新文献
A foundation model for joint segmentation, detection and recognition of biomedical objects across nine modalities. Content-aware motion correction for multi-shot imaging. Nanopore approaches for single-molecule temporal omics: promises and challenges. A foundation model unlocks unified biomedical image analysis. Overcoming the preferred-orientation problem in cryo-EM with self-supervised deep learning.
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