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Improved Cryo-EM Pose Estimation and 3D Classification through Latent-Space Disentanglement

Published 9 Aug 2023 in eess.IV, cs.CV, q-bio.BM, and q-bio.QM | (2308.04956v3)

Abstract: Due to the extremely low signal-to-noise ratio (SNR) and unknown poses (projection angles and image shifts) in cryo-electron microscopy (cryo-EM) experiments, reconstructing 3D volumes from 2D images is very challenging. In addition to these challenges, heterogeneous cryo-EM reconstruction requires conformational classification. In popular cryo-EM reconstruction algorithms, poses and conformation classification labels must be predicted for every input cryo-EM image, which can be computationally costly for large datasets. An emerging class of methods adopted the amortized inference approach. In these methods, only a subset of the input dataset is needed to train neural networks for the estimation of poses and conformations. Once trained, these neural networks can make pose/conformation predictions and 3D reconstructions at low cost for the entire dataset during inference. Unfortunately, when facing heterogeneous reconstruction tasks, it is hard for current amortized-inference-based methods to effectively estimate the conformational distribution and poses from entangled latent variables. Here, we propose a self-supervised variational autoencoder architecture called "HetACUMN" based on amortized inference. We employed an auxiliary conditional pose prediction task by inverting the order of encoder-decoder to explicitly enforce the disentanglement of conformation and pose predictions. Results on simulated datasets show that HetACUMN generated more accurate conformational classifications than other amortized or non-amortized methods. Furthermore, we show that HetACUMN is capable of performing heterogeneous 3D reconstructions of a real experimental dataset.

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References (33)
  1. Deep generative modeling for volume reconstruction in cryo-electron microscopy. Journal of Structural Biology, 214:107920, 2022.
  2. Rational design of asct2 inhibitors using an integrated experimental-computational approach. Proceedings of the National Academy of Sciences (USA), 118(37):e2104093118, 2021.
  3. Cryogan: A new reconstruction paradigm for single-particle cryo-em via deep adversarial learning. IEEE Transactions on Computational Imaging, 7:759–774, 2021.
  4. Hemnma-3d: Cryo electron tomography method based on normal mode analysis to study continuous conformational variability of macromolecular complexes. Frontiers in Molecular Biosciences, 8, 2021.
  5. Deep residual learning for image recognition. In Proceedings of the IEEE conference on computer vision and pattern recognition, pages 770–778, 2016.
  6. Approximating deformation fields for the analysis of continuous heterogeneity of biological macromolecules by 3D Zernike polynomials. IUCrJ, 8:992–1005, 2021.
  7. Hyper-molecules: on the representation and recovery of dynamical structures for applications in flexible macro-molecules in cryo-em. Inverse Problems, 36:044005, 2020.
  8. CryoAI: Amortized Inference of Poses for Ab Initio Reconstruction of 3D Molecular Volumes from Real Cryo-EM Images. In European Conference on Computer Vision (ECCV), 2022.
  9. Amortized inference for heterogeneous reconstruction in cryo-em. In S. Koyejo, S. Mohamed, A. Agarwal, D. Belgrave, K. Cho, and A. Oh, editors, Advances in Neural Information Processing Systems, volume 35, pages 13038–13049, 2022.
  10. The electron microscopy exchange (emx) initiative. Journal of structural biology, 194(2):156–163, 2016.
  11. Cryoposenet: End-to-end simultaneous learning of single-particle orientation and 3d map reconstruction from cryo-electron microscopy data. In Proceedings of the IEEE/CVF International Conference on Computer Vision (ICCV) Workshops, pages 4066–4076, October 2021.
  12. Nobel. The Nobel Prize in Chemistry 2017, 2017.
  13. EMPIAR-10180. https://www.ebi.ac.uk/empiar/EMPIAR-10180, 2018.
  14. Structure of a pre-catalytic spliceosome. Nature, 546:617–—621, 2017.
  15. 3d flexible refinement: Structure and motion of flexible proteins from cryo-em. Microscopy and Microanalysis, 28:1218––1218, 2022.
  16. 3D variability analysis: Resolving continuous flexibility and discrete heterogeneity from single particle cryo-em. Journal of structural biology, 213:107702, 2021.
  17. cryosparc: algorithms for rapid unsupervised cryo-em structure determination. Nature Methods, 14(3):290–296, 2017.
  18. Random features for large-scale kernel machines. Advances in neural information processing systems, 20, 2007.
  19. Inferring a continuous distribution of atom coordinates from cryo-em images using vaes. CoRR, abs/2106.14108, 2021.
  20. Sjors H.W. Scheres. Relion: Implementation of a bayesian approach to cryo-em structure determination. Journal of Structural Biology, 180:519–530, 2012.
  21. Sjors HW Scheres. Relion: implementation of a bayesian approach to cryo-em structure determination. Journal of structural biology, 180(3):519–530, 2012.
  22. Cryofold: Ab-initio structure determination from electron density maps using molecular dynamics. Cold Spring Harbor Laboratory, 2019.
  23. Computational methods for single-particle electron cryomicroscopy. Annual Review of Biomedical Data Science, 3(1):163–190, 2020.
  24. Fourier features let networks learn high frequency functions in low dimensional domains. Advances in Neural Information Processing Systems, 33:7537–7547, 2020.
  25. Differentiable probabilistic models of scientific imaging with the Fourier slice theorem. In Proceedings of The 35th Uncertainty in Artificial Intelligence Conference, PMLR, 2020.
  26. Image formation modeling in cryo-electron microscopy. Journal of structural biology, 183(1):19–32, 2013.
  27. Cryo-em structure of the plasmodium falciparum 80s ribosome bound to the anti-protozoan drug emetine. Elife, 3:e03080, 2014.
  28. Boosted ab initio cryo-em 3d reconstruction with ace-em, 2023.
  29. Cryo-em structure of a sars-cov-2 omicron spike protein ectodomain. Nature communications, 13:1214, 2022.
  30. Cryodrgn: reconstruction of heterogeneous cryo-em structures using neural networks. Nature methods, 18(2):176–185, 2021.
  31. Data for "CryoDRGN: Reconstruction of heterogeneous cryo-EM structures using neural networks" doi: 10.5281/zenodo.4355284, Jan. 2021.
  32. Reconstructing continuous distributions of 3d protein structure from cryo-em images. In International Conference on Learning Representations, 2019.
  33. Cryodrgn2: Ab initio neural reconstruction of 3d protein structures from real cryo-em images. In 2021 IEEE/CVF International Conference on Computer Vision (ICCV), pages 4046–4055, 2021.
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Authors (3)

  1. Weijie Chen 
  2. Yuhang Wang 
  3. Lin Yao 

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