Ultra-High Resolution Imaging by Fluorescence Photoactivation Localization Microscopy

doi:10.1529/biophysj.106.091116

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Ultra-High Resolution Imaging by Fluorescence Photoactivation Localization Microscopy

Samuel T. Hess^*, Thanu P. K. Girirajan and Michael D. Mason

^* Department of Physics and Astronomy, Institute for Molecular Biophysics, and Department of Chemical and Biological Engineering, University of Maine, Orono, Maine

Correspondence: Address reprint requests to Prof. Samuel T. Hess, Dept. of Physics and Astronomy, University of Maine, Orono, ME 04469. Tel.: 207-581-1036; Fax: 207 581-3410; E-mail: sam.hess{at}umit.maine.edu.

Biological structures span many orders of magnitude in size,but far-field visible light microscopy suffers from limitedresolution. A new method for fluorescence imaging has been developedthat can obtain spatial distributions of large numbers of fluorescentmolecules on length scales shorter than the classical diffractionlimit. Fluorescence photoactivation localization microscopy(FPALM) analyzes thousands of single fluorophores per acquisition,localizing small numbers of them at a time, at low excitationintensity. To control the number of visible fluorophores inthe field of view and ensure that optically active moleculesare separated by much more than the width of the point spreadfunction, photoactivatable fluorescent molecules are used, inthis case the photoactivatable green fluorescent protein (PA-GFP).For these photoactivatable molecules, the activation rate iscontrolled by the activation illumination intensity; nonfluorescentinactive molecules are activated by a high-frequency (405-nm)laser and are then fluorescent when excited at a lower frequency.The fluorescence is imaged by a CCD camera, and then the moleculesare either reversibly inactivated or irreversibly photobleachedto remove them from the field of view. The rate of photobleachingis controlled by the intensity of the laser used to excite thefluorescence, in this case an Ar+ ion laser. Because only asmall number of molecules are visible at a given time, theirpositions can be determined precisely; with only $~$ 100 detectedphotons per molecule, the localization precision can be as muchas 10-fold better than the resolution, depending on backgroundlevels. Heterogeneities on length scales of the order of tensof nanometers are observed by FPALM of PA-GFP on glass. FPALMimages are compared with images of the same molecules by widefieldfluorescence. FPALM images of PA-GFP on a terraced sapphirecrystal surface were compared with atomic force microscopy andshow that the full width at half-maximum of features $~$ 86 ±4 nm is significantly better than the expected diffraction-limitedoptical resolution. The number of fluorescent molecules andtheir brightness distribution have also been determined usingFPALM. This new method suggests a means to address a significantnumber of biological questions that had previously been limitedby microscope resolution.

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