Electron Tomography of Ice-Embedded Prokaryotic Cells

Whole cells of archaea were embedded in vitreous ice by plunge freezing and investigated by automated energy-filtered electron tomography at 120 kV. The embedded cells were between 300 and 750 nm thick, and their structures were reconstructed to a resolution of 20–40 nm from tilt series comprising 5...

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Bibliographic Details
Published in:Biophysical journal 1998-02, Vol.74 (2), p.1031-1042
Main Authors: Grimm, Rudo, Singh, Hapreet, Rachel, Reinhard, Typke, Dieter, Zillig, Wolfram, Baumeister, Wolfgang
Format: Article
Language:English
Subjects:
Automation
Freezing
Ice
Image Processing, Computer-Assisted
Microscopy, Electron - methods
Models, Structural
Sensitivity and Specificity
Sulfolobus - ultrastructure
Thermoproteaceae - ultrastructure
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Summary:Whole cells of archaea were embedded in vitreous ice by plunge freezing and investigated by automated energy-filtered electron tomography at 120 kV. The embedded cells were between 300 and 750 nm thick, and their structures were reconstructed to a resolution of 20–40 nm from tilt series comprising 50–140 images. The dose was kept within tolerable limits. A resolution of 20 nm allowed visualization of the individual stalks of the S-layer of Pyrobaculum aerophilum cells, which had undergone partial lysis, in three dimensions. The attainable resolution for low-dose electron tomography under different experimental conditions was theoretically investigated in terms of the specimen thickness. To obtain 2-nm resolution at 120 kV (300 kV), the specimen must not be thicker than 100 nm (150 nm). For a resolution of 10 nm, the maximum thickness is 450 nm (700 nm). An accelerating voltage of 300 kV is advantageous, mainly for specimens thicker than 100 nm. Experimental investigations so far have resulted in a resolution that is worse by a factor of 2–5 as compared to theory.
ISSN:0006-3495
1542-0086
DOI:10.1016/S0006-3495(98)74028-7