https://3demmethods.i2pc.es/index.php?action=history&feed=atom&title=2015Sachse_Review2015Sachse Review - Revision history2026-06-13T12:13:32ZRevision history for this page on the wikiMediaWiki 1.44.2https://3demmethods.i2pc.es/index.php?title=2015Sachse_Review&diff=3423&oldid=prevWikiSysop: Created page with "== Citation == Sachse, C. Single-particle based helical reconstruction-how to make the most of real and Fourier space. AIMS Biophysics, 2015, 2, 219-244 == Abstract == The..."2019-01-17T07:45:32Z<p>Created page with "== Citation == Sachse, C. Single-particle based helical reconstruction-how to make the most of real and Fourier space. AIMS Biophysics, 2015, 2, 219-244 == Abstract == The..."</p>
<p><b>New page</b></p><div>== Citation ==<br />
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Sachse, C. Single-particle based helical reconstruction-how to make the most of real and Fourier space. AIMS Biophysics, 2015, 2, 219-244<br />
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== Abstract ==<br />
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The helical assembly is a fundamental organization principle of biomacromolecules. To<br />
determine the structures of helical filaments or tubes has been helped by the fact that many different<br />
views of the helical unit are present to reconstruct a three-dimensional image from a single helix. In<br />
this review, I present the current state of helical image reconstruction from electron<br />
cryo-micrographs by introducing Fourier-based processing alongside real-space approaches. Based<br />
on this foundation, I describe how they can be applied to determine the symmetry and<br />
high-resolution structure of helical assemblies. In the past, the main structure determination approach<br />
of helical assemblies from electron micrographs was the Fourier-Bessel method, which is based on a<br />
comprehensive theory and has generated many successful applications in the last 40 years. The<br />
emergence of the single-particle technique allowed segmented helical specimens to be treated as<br />
single particles, thus rendering new specimens amenable to 3D helical reconstruction and facilitating<br />
high-resolution structure analysis. However, helical symmetry determination remains the crucial step<br />
for a successful 3D reconstruction. Depending on the helical specimen, Fourier and real-space<br />
approaches or a combination of both provide important clues to establish the correct helical<br />
symmetry. I discuss recent developments in combining traditional Fourier-Bessel procedures with<br />
single-particle algorithms to provide a versatile and comprehensive approach to structure<br />
determination of helical specimens. Upon introduction of direct electron detectors, a series of<br />
near-atomic resolution structures from helical assemblies have become available. As helical<br />
organization is fundamental to many structural assemblies of the cell, these approaches to structure<br />
elucidation open up promising capabilities to study the underlying structures at atomistic resolution.<br />
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== Keywords ==<br />
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== Links ==<br />
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http://www.aimspress.com/fileOther/PDF/biophysics/201502219.pdf<br />
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== Related software ==<br />
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== Related methods ==<br />
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== Comments ==</div>WikiSysop