Clustering and variance maps for cryo-electron tomography using wedge-masked differences

Heumann, John M.; Hoenger, Andreas; Mastronarde, David N.

doi:10.1016/j.jsb.2011.05.011

Cited by 229 publications

(238 citation statements)

References 20 publications

(38 reference statements)

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“…Visual inspection of the M and RNP tomograms were carried out to investigate if there was any order in the data to justify subvolume averaging. All subvolume processing was carried out using 3dmod and PEET from the IMOD package (32)(33)(34). Bsoft was used for generating masks for subvolume processing and estimation of the subvolume average resolutions (35).…”

Section: Methodsmentioning

confidence: 99%

Architecture of respiratory syncytial virus revealed by electron cryotomography

Liljeroos

Krzyzaniak²,

Helenius³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

174

173

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Human respiratory syncytial virus is a human pathogen that causes severe infection of the respiratory tract. Current information about the structure of the virus and its interaction with host cells is limited. We carried out an electron cryotomographic characterization of cell culture-grown human respiratory syncytial virus to determine the architecture of the virion. The particles ranged from 100 nm to 1,000 nm in diameter and were spherical, filamentous, or a combination of the two. The filamentous morphology correlated with the presence of a cylindrical matrix protein layer linked to the inner leaflet of the viral envelope and with local ordering of the glycoprotein spikes. Recombinant viruses with only the fusion protein in their envelope showed that these glycoproteins were predominantly in the postfusion conformation, but some were also in the prefusion form. The ribonucleocapsids were left-handed, randomly oriented, and curved inside the virions. In filamentous particles, they were often adjacent to an intermediate layer of protein assigned to M2-1 (an envelopeassociated protein known to mediate association of ribonucleocapsids with the matrix protein). Our results indicate important differences in structure between the Paramyxovirinae and Pneumovirinae subfamilies within the Paramyxoviridae, and provide fresh insights into host cell exit of a serious pathogen.cryo-ET | paramyxovirus | virus structure H uman respiratory syncytial virus (HRSV) causes severe disease, especially in children and the elderly (1, 2). In a study covering data from 2005, it was found that HRSV was responsible for 22% of acute lower respiratory infections worldwide and 66,000-199,000 deaths in children under the age of 5 y (2). Treatment is currently limited to purine analogs (Ribavirin) and passive immune-prophylaxis with humanized monoclonal antibodies (Palivizumab) (3).RSV belongs to the Paramyxoviridae, a large family of enveloped, negative-sense RNA viruses with many members from humans and animals. Together with human metapneumovirus, it constitutes the Pneumovirinae subfamily. Like other paramyxoviruses, it has a plasma-membrane-derived lipid envelope and a helical ribonucleocapsid (RNP) that contains a single viral RNA molecule associated with nucleoproteins (N), and an RNA-dependent RNA polymerase. The virion contains, in addition, a matrix protein (M) (4-7) and a transcription antiterminator, M2-1 (an envelopeassociated protein known to mediate association of RNPs with the M protein) (8-11). The lipid envelope contains two transmembrane glycoproteins: the fusion protein, F, and a glycoprotein, G, used for attachment to host cells. In addition, HRSV contains a small hydrophobic protein, SH, of unclear function and proteins of cellular origin, such as actin and chaperones (12). The RNP and F have been analyzed using 3D-EM and X-ray crystallography (13,14).HRSV particles are pleomorphic with both spherical and filamentous particles of different sizes (15). Early electron microscopy studies showed the presence of a helical p...

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Section: Methodsmentioning

confidence: 99%

Architecture of respiratory syncytial virus revealed by electron cryotomography

Liljeroos

Krzyzaniak²,

Helenius³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

174

173

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“…Subtomograms, each containing a 96-nm axonemal repeat, were extracted, aligned, and averaged with missing-wedge compensation using PEET software (3). An unsupervised classification approach incorporated in PEET (38) was used to analyze the presence or absence of strep-Au label in the axonemal repeats of WT, DRC4-SNAP, DRC3-SNAP, and SNAP-DRC3. During the classification analysis, the examined three-dimensional volume was limited to the targeted region with a mask.…”

Section: Methodsmentioning

confidence: 99%

In Situ Localization of N and C Termini of Subunits of the Flagellar Nexin-Dynein Regulatory Complex (N-DRC) Using SNAP Tag and Cryo-electron Tomography

Song

Awata

Tritschler

et al. 2015

Journal of Biological Chemistry

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Background: Techniques to localize proteins in situ at high resolution are important but limited. Results: Combining SNAP tag technology with cryo-electron tomography, we precisely localized proteins within the N-DRC that are important for ciliary motility. Conclusion: The developed method was applied to localize proteins with ϳ3 nm resolution without interfering with the complex function. Significance: The method is a powerful tool for studies of proteins in situ.

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“…This dataset has been used in various studies of subtomogram alignment and classification and thus serves as a quasi-standard in the field (Förster et al, 2008;Heumann et al, 2011;Scheres et al, 2009;Yu and Frangakis, 2011). The 786 subtomograms were aligned using the average of the unaligned subtomograms as the initial reference.…”

Section: Classification Of Groel/esmentioning

confidence: 99%

“…Furthermore, classification techniques can be used to sort subtomograms according to their intrinsic variations, which yields an increase in resolution for the different classes compared to the overall average. Different software tools have been proposed for subtomogram localization (Förster et al, 2010;Frangakis and Forster, 2004;Rath et al, 2003;Renken et al, 2009;Xu et al, 2011), alignment (Amat et al, 2010;Bartesaghi et al, 2008;Förster et al, 2005;Schmid and Booth, 2008;Walz et al, 1997;Winkler, 2007) and classification (Bartesaghi et al, 2008;Förster et al, 2008;Heumann et al, 2011;Scheres et al, 2009;Stolken et al, 2010;Winkler et al, 2009;Yu et al, 2010;Yu and Frangakis, 2011), but a unified platform that covers the whole workflow from subtomogram localization to averaging and classification is not available to date. Here, we present the open-source toolbox PyTom, which covers a workflow comprising localization of macromolecules based on template matching, correlation-based alignment of subtomograms, and their classification by a novel stochastic method.…”

Section: Introductionmentioning

confidence: 99%