A FRET-facilitated photoswitching using an orange fluorescent protein with the fast photoconversion kinetics.

Fluorescent proteins photoswitchable with noncytotoxic light irradiation and spectrally distinct from multiple available photoconvertible green-to-red probes are in high demand. We have developed a monomeric fluorescent protein, called PSmOrange2, which is photoswitchable with blue light from an orange (ex./em. at 546 nm/561 nm) to a far-red (ex./em. at 619 nm/651 nm) form. Compared to another orange-to-far-red photoconvertable variant, PSmOrange2 has blue-shifted photoswitching action spectrum, 9-fold higher photoconversion contrast, and up to 10-fold faster photoswitching kinetics. This results in the 4-fold more PSmOrange2 molecules being photoconverted in mammalian cells. Compared to common orange fluorescent proteins, such as mOrange, the orange form of PSmOrange has substantially higher photostability allowing its use in multicolor imaging applications to track dynamics of multiple populations of intracellular objects. The PSmOrange2 photochemical properties allow its efficient photoswitching with common two-photon lasers and, moreover, via Förster resonance energy transfer (FRET) from green fluorescent donors. We have termed the latter effect a FRET-facilitated photoswitching and demonstrated it using several sets of interacting proteins. The enhanced photoswitching properties of PSmOrange2 make it a superior photoconvertable protein tag for flow cytometry, conventional microscopy, and two-photon imaging of live cells.

[1]  Atsushi Miyawaki,et al.  Proteins on the move: insights gained from fluorescent protein technologies , 2011, Nature Reviews Molecular Cell Biology.

[2]  V. Verkhusha,et al.  Setup and use of a two-laser multiphoton microscope for multichannel intravital fluorescence imaging , 2011, Nature Protocols.

[3]  John S. Condeelis,et al.  A photoswitchable orange-to-far-red fluorescent protein, PSmOrange , 2011, Nature Methods.

[4]  Atsushi Miyawaki,et al.  Development of probes for cellular functions using fluorescent proteins and fluorescence resonance energy transfer. , 2011, Annual review of biochemistry.

[5]  Bin Wu,et al.  Modern fluorescent proteins and imaging technologies to study gene expression, nuclear localization, and dynamics. , 2011, Current opinion in cell biology.

[6]  M. Drobizhev,et al.  Two-photon absorption properties of fluorescent proteins , 2011, Nature Methods.

[7]  M. Davidson,et al.  A monomeric photoconvertible fluorescent protein for imaging of dynamic protein localization. , 2010, Journal of molecular biology.

[8]  V. Verkhusha,et al.  Red fluorescent protein with reversibly photoswitchable absorbance for photochromic FRET. , 2010, Chemistry & biology.

[9]  Michael Z. Lin,et al.  Autofluorescent proteins with excitation in the optical window for intravital imaging in mammals. , 2009, Chemistry & biology.

[10]  J. Lippincott-Schwartz,et al.  Photoactivatable fluorescent proteins for diffraction-limited and super-resolution imaging. , 2009, Trends in cell biology.

[11]  J. Lippincott-Schwartz,et al.  Interferometric fluorescent super-resolution microscopy resolves 3D cellular ultrastructure , 2009, Proceedings of the National Academy of Sciences.

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

[13]  M. Drobizhev,et al.  Absolute two-photon absorption spectra and two-photon brightness of orange and red fluorescent proteins. , 2009, The journal of physical chemistry. B.

[14]  Kristin L. Hazelwood,et al.  A bright and photostable photoconvertible fluorescent protein for fusion tags , 2009, Nature Methods.

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

[16]  D. Piston,et al.  Fluorescent protein FRET: the good, the bad and the ugly. , 2007, Trends in biochemical sciences.

[17]  S. Lukyanov,et al.  Tracking intracellular protein movements using photoswitchable fluorescent proteins PS-CFP2 and Dendra2 , 2007, Nature Protocols.

[18]  J. Wiedenmann,et al.  Two-photon excitation and photoconversion of EosFP in dual-color 4Pi confocal microscopy. , 2007, Biophysical journal.

[19]  Jerry March,et al.  March's Advanced Organic Chemistry , 2006 .

[20]  Nathan C Shaner,et al.  Novel chromophores and buried charges control color in mFruits. , 2006, Biochemistry.

[21]  D. Chudakov,et al.  Photoswitchable cyan fluorescent protein as a FRET donor , 2006, Microscopy research and technique.

[22]  Nathan C Shaner,et al.  A guide to choosing fluorescent proteins , 2005, Nature Methods.

[23]  Alberto Diaspro,et al.  Two-photon activation and excitation properties of PA-GFP in the 720-920-nm region. , 2005, Biophysical journal.

[24]  Vladislav V Verkhusha,et al.  Conversion of the monomeric red fluorescent protein into a photoactivatable probe. , 2005, Chemistry & biology.

[25]  Atsushi Miyawaki,et al.  Semi‐rational engineering of a coral fluorescent protein into an efficient highlighter , 2005, EMBO reports.

[26]  R. Tsien,et al.  Improved monomeric red, orange and yellow fluorescent proteins derived from Discosoma sp. red fluorescent protein , 2004, Nature Biotechnology.

[27]  Konstantin A Lukyanov,et al.  Photoswitchable cyan fluorescent protein for protein tracking , 2004, Nature Biotechnology.

[28]  Jennifer J. Kohler,et al.  Regulating cell surface glycosylation by small molecule control of enzyme localization. , 2003, Chemistry & biology.

[29]  J. Post,et al.  Imaging molecular interactions in cells by dynamic and static fluorescence anisotropy (rFLIM and emFRET). , 2003, Biochemical Society transactions.

[30]  Tom W Muir,et al.  Conditional protein splicing: a new tool to control protein structure and function in vitro and in vivo. , 2003, Journal of the American Chemical Society.

[31]  A. Miyawaki,et al.  An optical marker based on the UV-induced green-to-red photoconversion of a fluorescent protein , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[32]  J. Lippincott-Schwartz,et al.  Role of Grb2 in EGF-stimulated EGFR internalization. , 2002, Journal of cell science.

[33]  Jerry March,et al.  March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure , 2001 .

[34]  A. Sorkin,et al.  Interaction of EGF receptor and Grb2 in living cells visualized by fluorescence resonance energy transfer (FRET) microscopy , 2000, Current Biology.

[35]  T M Jovin,et al.  FRET microscopy demonstrates molecular association of non‐specific lipid transfer protein (nsL‐TP) with fatty acid oxidation enzymes in peroxisomes , 1998, The EMBO journal.

[36]  A. Kenworthy,et al.  Distribution of a Glycosylphosphatidylinositol-anchored Protein at the Apical Surface of MDCK Cells Examined at a Resolution of <100 Å Using Imaging Fluorescence Resonance Energy Transfer , 1998, The Journal of cell biology.

[37]  B. Herman,et al.  Quantitative fluorescence resonance energy transfer measurements using fluorescence microscopy. , 1998, Biophysical journal.

[38]  V. Mekler,et al.  Fluorescence energy transfer-sensitized photobleaching of a fluorescent label as a tool to study donor-acceptor distance distributions and dynamics in protein assemblies: studies of a complex of biotinylated IgM with streptavidin and aggregates of concanavalin A. , 1997, Journal of photochemistry and photobiology. B, Biology.

[39]  Shannon R. Magari,et al.  A humanized system for pharmacologic control of gene expression , 1996, Nature Medicine.

[40]  S. Schreiber,et al.  Dimeric ligands define a role for transcriptional activation domains in reinitiation , 1996, Nature.

[41]  S. Schreiber,et al.  Identification of an 11-kDa FKBP12-rapamycin-binding domain within the 289-kDa FKBP12-rapamycin-associated protein and characterization of a critical serine residue. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[42]  V. Mekler A PHOTOCHEMICAL TECHNIQUE TO ENHANCE SENSITIVITY OF DETECTION OF FLUORESCENCE RESONANCE ENERGY TRANSFER , 1994 .

[43]  Robert M. Clegg,et al.  Fluorescence lifetime imaging microscopy (FLIM): Spatial resolution of microstructures on the nanosecond time scale , 1993 .

[44]  S. Ho,et al.  Site-directed mutagenesis by overlap extension using the polymerase chain reaction. , 1989, Gene.