Fluorescence perturbation techniques to study mobility and molecular dynamics of proteins in live cells: FRAP, photoactivation, photoconversion, and FLIP.

The technique of fluorescence recovery after photobleaching (FRAP) was introduced in the mid-1970s to study the diffusion of biomolecules in living cells. For several years, it was used mainly by a small number of biophysicists who had developed their own photobleaching systems. Since the mid-1990s, FRAP has gained increasing popularity because of the conjunction of two factors: First, photobleaching techniques are easily implemented on confocal laser-scanning microscopes (CLSMs), and so FRAP has become available to anyone who has access to such equipment. Second, the advent of green fluorescent protein (GFP) has allowed easy fluorescent tagging of proteins and their observation in living cells. Thanks both to the versatility of modern CLSMs, which allow control of laser intensity at any point of the image, and to the development of new fluorescent probes, additional photoperturbation techniques have emerged during the last few years. After the photoperturbation event, one observes and then analyzes how the fluorescence distribution relaxes toward the steady state. Because the photochemical perturbation of suitable fluorophores is essentially irreversible, changes of fluorescence intensity in the perturbed and unperturbed regions are due to the exchange of tagged molecules between those regions. This article first discusses the materials required for performing FRAP experiments on a CLSM and the software for data analysis. It then describes general considerations on how to perform FRAP experiments as well as the necessary controls. Finally, different possible ways to analyze the data are presented.

[1]  Sylvie Coscoy,et al.  Molecular analysis of microscopic ezrin dynamics by two-photon FRAP , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[2]  V. Verkhusha,et al.  Engineering of a monomeric green-to-red photoactivatable fluorescent protein induced by blue light , 2006, Nature Biotechnology.

[3]  Michael Unser,et al.  A pyramid approach to subpixel registration based on intensity , 1998, IEEE Trans. Image Process..

[4]  W. Webb,et al.  Photodamage to intact erythrocyte membranes at high laser intensities: methods of assay and suppression. , 1984, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[5]  J. Ellenberg,et al.  Automatic real‐time three‐dimensional cell tracking by fluorescence microscopy , 2004, Journal of microscopy.

[6]  E. R. Gavis,et al.  Localization of bicoid mRNA in late oocytes is maintained by continual active transport. , 2006, Developmental cell.

[7]  David A. Agard,et al.  Three-dimensional architecture of a polytene nucleus , 1983, Nature.

[8]  J. Swedlow,et al.  A workingperson's guide to deconvolution in light microscopy. , 2001, BioTechniques.

[9]  J. Lippincott-Schwartz,et al.  Fluorescent proteins for photoactivation experiments. , 2008, Methods in cell biology.

[10]  James G McNally,et al.  FRAP analysis of binding: proper and fitting. , 2005, Trends in cell biology.

[11]  A. Verkman,et al.  Translational Diffusion of Macromolecule-sized Solutes in Cytoplasm and Nucleus , 1997, The Journal of cell biology.

[12]  A. Diaspro,et al.  Spatial control of pa‐GFP photoactivation in living cells , 2008, Journal of microscopy.

[13]  Jan Ellenberg,et al.  Dissecting the contribution of diffusion and interactions to the mobility of nuclear proteins. , 2006, Biophysical journal.

[14]  E. Stelzer,et al.  Photobleaching GFP reveals protein dynamics inside live cells. , 1999, Trends in cell biology.

[15]  Mark Bates,et al.  Three-Dimensional Super-Resolution Imaging by Stochastic Optical Reconstruction Microscopy , 2008, Science.

[16]  Ram Dixit,et al.  Cell damage and reactive oxygen species production induced by fluorescence microscopy: effect on mitosis and guidelines for non-invasive fluorescence microscopy. , 2003, The Plant journal : for cell and molecular biology.

[17]  R. Tsien,et al.  green fluorescent protein , 2020, Catalysis from A to Z.

[18]  Suliana Manley,et al.  Photoactivatable mCherry for high-resolution two-color fluorescence microscopy , 2009, Nature Methods.

[19]  Petros Koumoutsakos,et al.  Effects of organelle shape on fluorescence recovery after photobleaching. , 2005, Biophysical journal.

[20]  M. Gustafsson,et al.  Subdiffraction Multicolor Imaging of the Nuclear Periphery with 3D Structured Illumination Microscopy , 2008, Science.

[21]  Ilan Davis,et al.  Lifting the Fog: Image Restoration by Deconvolution , 2006 .

[22]  R. Tsien,et al.  On/off blinking and switching behaviour of single molecules of green fluorescent protein , 1997, Nature.

[23]  L M Loew,et al.  A general computational framework for modeling cellular structure and function. , 1997, Biophysical journal.

[24]  Paul M Kulesa,et al.  Neural crest invasion is a spatially-ordered progression into the head with higher cell proliferation at the migratory front as revealed by the photoactivatable protein, KikGR. , 2008, Developmental biology.

[25]  James G McNally,et al.  Quantitative FRAP in analysis of molecular binding dynamics in vivo. , 2008, Methods in cell biology.

[26]  S. Hell Microscopy and its focal switch , 2008, Nature Methods.

[27]  D A Agard,et al.  Direct cell lineage analysis in Drosophila melanogaster by time-lapse, three-dimensional optical microscopy of living embryos , 1989, The Journal of cell biology.

[28]  Michael Schaefer,et al.  Reversible photobleaching of enhanced green fluorescent proteins. , 2005, Biochemistry.

[29]  J Langowski,et al.  Anomalous diffusion of fluorescent probes inside living cell nuclei investigated by spatially-resolved fluorescence correlation spectroscopy. , 2000, Journal of molecular biology.

[30]  J. Ellenberg,et al.  Mapping the dynamic organization of the nuclear pore complex inside single living cells , 2004, Nature Cell Biology.

[31]  L M Loew,et al.  Intracellular fluorescent probe concentrations by confocal microscopy. , 1998, Biophysical journal.

[32]  Florian Müller,et al.  Analysis of binding at a single spatially localized cluster of binding sites by fluorescence recovery after photobleaching. , 2006, Biophysical journal.

[33]  Peter Dedecker,et al.  Reversible single-molecule photoswitching in the GFP-like fluorescent protein Dronpa. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[34]  George H. Patterson,et al.  A Photoactivatable GFP for Selective Photolabeling of Proteins and Cells , 2002, Science.

[35]  G. Patterson,et al.  Quantitative imaging of the green fluorescent protein (GFP). , 1999, Methods in cell biology.

[36]  B. Herman,et al.  Analysis of simulated and experimental fluorescence recovery after photobleaching. Data for two diffusing components. , 1995, Biophysical journal.

[37]  M Edidin,et al.  Measurement of membrane protein lateral diffusion in single cells. , 2003, Science.

[38]  T. Terwilliger,et al.  Engineering and characterization of a superfolder green fluorescent protein , 2006, Nature Biotechnology.

[39]  J Greve,et al.  Real-time light-driven dynamics of the fluorescence emission in single green fluorescent protein molecules. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[40]  M. Gustafsson Surpassing the lateral resolution limit by a factor of two using structured illumination microscopy , 2000, Journal of microscopy.

[41]  Robert H Singer,et al.  Gene expression and the myth of the average cell. , 2003, Trends in cell biology.

[42]  Paul Wach,et al.  Evidence for a common mode of transcription factor interaction with chromatin as revealed by improved quantitative fluorescence recovery after photobleaching. , 2008, Biophysical journal.

[43]  W. Webb,et al.  Mobility measurement by analysis of fluorescence photobleaching recovery kinetics. , 1976, Biophysical journal.

[44]  M. Davidson,et al.  Advances in fluorescent protein technology , 2011, Journal of Cell Science.

[45]  J. Lippincott-Schwartz,et al.  Measuring Protein Mobility by Photobleaching GFP Chimeras in Living Cells , 2003, Current protocols in cell biology.

[46]  Bryant B. Chhun,et al.  Super-Resolution Video Microscopy of Live Cells by Structured Illumination , 2009, Nature Methods.

[47]  J. Lippincott-Schwartz,et al.  Imaging Intracellular Fluorescent Proteins at Nanometer Resolution , 2006, Science.

[48]  R. Pego,et al.  Analysis of binding reactions by fluorescence recovery after photobleaching. , 2004, Biophysical journal.

[49]  R. Vandenbroucke,et al.  Line FRAP with the confocal laser scanning microscope for diffusion measurements in small regions of 3-D samples. , 2007, Biophysical journal.

[50]  J. Lippincott-Schwartz,et al.  Diffusion in inhomogeneous media: theory and simulations applied to whole cell photobleach recovery. , 2000, Biophysical journal.

[51]  George H Patterson,et al.  Photobleaching and photoactivation: following protein dynamics in living cells. , 2003, Nature cell biology.

[52]  Ronald D. Vale,et al.  Imaging individual green fluorescent proteins , 1997, Nature.

[53]  M. Saxton,et al.  Anomalous subdiffusion in fluorescence photobleaching recovery: a Monte Carlo study. , 2001, Biophysical journal.

[54]  Ion I. Moraru,et al.  Morphological Control of Inositol-1,4,5-Trisphosphate–Dependent Signals , 1999, The Journal of cell biology.

[55]  Leann Tilley,et al.  Fluorescence photobleaching analysis for the study of cellular dynamics , 2002, European Biophysics Journal.

[56]  G. Phillips,et al.  The molecular structure of green fluorescent protein , 1996, Nature Biotechnology.

[57]  J. Wiedenmann,et al.  EosFP, a fluorescent marker protein with UV-inducible green-to-red fluorescence conversion. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[58]  L. Loew,et al.  An image-based model of calcium waves in differentiated neuroblastoma cells. , 2000, Biophysical journal.

[59]  Francesca Cella,et al.  A New FRAP/FRAPa Method for Three-Dimensional Diffusion Measurements Based on Multiphoton Excitation Microscopy , 2008, Biophysical journal.

[60]  G. Patterson Photoactivation and Imaging of Photoactivatable Fluorescent Proteins , 2008, Current protocols in cell biology.

[61]  T. Misteli,et al.  A Kinetic Framework for a Mammalian RNA Polymerase in Vivo , 2002, Science.

[62]  K. Jaqaman,et al.  Robust single particle tracking in live cell time-lapse sequences , 2008, Nature Methods.

[63]  R. Peters,et al.  A microfluorimetric study of translational diffusion in erythrocyte membranes. , 1974, Biochimica et biophysica acta.

[64]  W E Moerner,et al.  Fluorescence correlation spectroscopy reveals fast optical excitation-driven intramolecular dynamics of yellow fluorescent proteins. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[65]  J. Ellenberg,et al.  Four-dimensional imaging and quantitative reconstruction to analyse complex spatiotemporal processes in live cells , 2001, Nature Cell Biology.

[66]  S. Hess,et al.  Three-dimensional sub–100 nm resolution fluorescence microscopy of thick samples , 2008, Nature Methods.

[67]  J. Mathur,et al.  Visualizing the actin cytoskeleton in living plant cells using a photo-convertible mEos::FABD-mTn fluorescent fusion protein , 2008, Plant Methods.

[68]  D. Axelrod,et al.  Cell surface heating during fluorescence photobleaching recovery experiments. , 1977, Biophysical journal.

[69]  A. Diaspro,et al.  Photoactivation of pa-GFP in 3D: optical tools for spatial confinement , 2008, European Biophysics Journal.

[70]  Roland Eils,et al.  Nuclear Envelope Breakdown Proceeds by Microtubule-Induced Tearing of the Lamina , 2002, Cell.

[71]  Atsushi Miyawaki,et al.  mKikGR, a Monomeric Photoswitchable Fluorescent Protein , 2008, PloS one.

[72]  J. Swedlow,et al.  Deconvolution in optical microscopy , 1996 .

[73]  J. Swedlow,et al.  Evaluating performance in three-dimensional fluorescence microscopy , 2007, Journal of microscopy.