Abstract
Single-particle electron microscopy has now reached maturity, becoming a commonly used method in the examination of macromolecular structure. Using a small amount of purified protein, isolated molecules are observed under the electron microscope and the data collected can be averaged into a 3D reconstruction. Single-particle electron microscopy is an appropriate tool for the analysis of proteins that can only be obtained in modest quantities, like many of the large complexes currently of interest in biomedicine. Whilst the use of electron microscopy expands, new methods are being developed and improved to deal with further challenges, such as reaching higher resolutions and the combination of information at different levels of structural detail. More importantly, present methodology is still not robust enough when studying certain “tricky” proteins like those displaying extensive conformational flexibility and a great deal of user expertise is required, posing a threat to the consistency of the final structure. This mini review describes a brief outline of the methods currently used in the 3D analysis of macromolecules using single-particle electron microscopy, intended for those first approaching this field. A summary of methods, techniques, software, and some recent work is presented. The spectacular improvements to the technique in recent years, its advantages and limitations compared to other structural methods, and its future developments are discussed.
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Project supported by projects SAF2002-01715 and GEN2003-20239-C06-06 from the Spanish Ministry of Education to OL.
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Llorca, O. Introduction to 3D reconstruction of macromolecules using single particle electron microscopy. Acta Pharmacol Sin 26, 1153–1164 (2005). https://doi.org/10.1111/j.1745-7254.2005.00203.x
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DOI: https://doi.org/10.1111/j.1745-7254.2005.00203.x
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