Cell-based and in vivo spectral analysis of fluorescent proteins for multiphoton microscopy

Abstract. Multiphoton microscopy of cells and subcellular structures labeled with fluorescent proteins is the state-of-the-art technology for longitudinal imaging studies in tissues and living animals. Successful analysis of separate cell populations or signaling events by intravital microscopy requires optimal pairing of multiphoton excitation wavelengths with spectrally distinct fluorescent proteins. While prior studies have analyzed two photon absorption properties of isolated fluorescent proteins, there is limited information about two photon excitation and fluorescence emission profiles of fluorescent proteins expressed in living cells and intact tissues. Multiphoton microscopy was used to analyze fluorescence outputs of multiple blue, green, and red fluorescent proteins in cultured cells and orthotopic tumor xenografts of human breast cancer cells. It is shown that commonly used orange and red fluorescent proteins are excited efficiently by 750 to 760 nm laser light in living cells, enabling dual color imaging studies with blue or cyan proteins without changing excitation wavelength. It is also shown that small incremental changes in excitation wavelength significantly affect emission intensities from fluorescent proteins, which can be used to optimize multi-color imaging using a single laser wavelength. These data will direct optimal selection of fluorescent proteins for multispectral two photon microscopy.

[1]  D. Shcherbo,et al.  Bright far-red fluorescent protein for whole-body imaging , 2007, Nature Methods.

[2]  Konstantin A Lukyanov,et al.  Near-infrared fluorescent proteins , 2010, Nature Methods.

[3]  J. Goedhart,et al.  Bright cyan fluorescent protein variants identified by fluorescence lifetime screening , 2010, Nature Methods.

[4]  Ralph Weissleder,et al.  Intravital Imaging , 2011, Cell.

[5]  M. Drobizhev,et al.  Resonance enhancement of two-photon absorption in fluorescent proteins. , 2007, The journal of physical chemistry. B.

[6]  J. Condeelis,et al.  Stretching the timescale of intravital imaging in tumors , 2009, Cell adhesion & migration.

[7]  Tri Giang Phan,et al.  Practical intravital two‐photon microscopy for immunological research: faster, brighter, deeper , 2010, Immunology and cell biology.

[8]  Kami Kim,et al.  Bright and stable near infra-red fluorescent protein for in vivo imaging , 2011, Nature Biotechnology.

[9]  Kristin L. Hazelwood,et al.  Far-red fluorescent tags for protein imaging in living tissues. , 2009, The Biochemical journal.

[10]  V. Verkhusha,et al.  Guide to red fluorescent proteins and biosensors for flow cytometry. , 2011, Methods in cell biology.

[11]  Watt W Webb,et al.  Two-photon fluorescence spectroscopy and microscopy of NAD(P)H and flavoprotein. , 2002, Biophysical journal.

[12]  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.

[13]  M. Drobizhev,et al.  Color hues in red fluorescent proteins are due to internal quadratic Stark effect. , 2009, The journal of physical chemistry. B.

[14]  Michael D. Cahalan,et al.  A Decade of Imaging Cellular Motility and Interaction Dynamics in the Immune System , 2012, Science.

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

[16]  Mark A Rizzo,et al.  An improved cyan fluorescent protein variant useful for FRET , 2004, Nature Biotechnology.

[17]  E. Sahai,et al.  Intravital imaging illuminates transforming growth factor beta signaling switches during metastasis. , 2010, Cancer research.

[18]  E. Sahai,et al.  In vivo fluorescence resonance energy transfer imaging reveals differential activation of Rho-family GTPases in glioblastoma cell invasion , 2012, Journal of Cell Science.

[19]  Dmitriy M Chudakov,et al.  Conversion of red fluorescent protein into a bright blue probe. , 2008, Chemistry & biology.

[20]  Erik Sahai,et al.  ROCK and JAK1 signaling cooperate to control actomyosin contractility in tumor cells and stroma. , 2011, Cancer cell.

[21]  Jacco van Rheenen,et al.  Intravital imaging of metastatic behavior through a mammary imaging window , 2008, Nature Methods.

[22]  S. Lukyanov,et al.  Fluorescent proteins and their applications in imaging living cells and tissues. , 2010, Physiological reviews.

[23]  Jianan Y Qu,et al.  Two-photon autofluorescence spectroscopy and second-harmonic generation of epithelial tissue. , 2005, Optics letters.

[24]  Mikhail Drobizhev,et al.  A new approach to dual-color two-photon microscopy with fluorescent proteins , 2010, BMC biotechnology.

[25]  Mudit Gupta,et al.  Imaging CXCR4 signaling with firefly luciferase complementation. , 2008, Analytical chemistry.

[26]  R. Tsien,et al.  Reducing the Environmental Sensitivity of Yellow Fluorescent Protein , 2001, The Journal of Biological Chemistry.

[27]  Michael Z. Lin,et al.  Improving the photostability of bright monomeric orange and red fluorescent proteins , 2008, Nature Methods.

[28]  R. Tsien,et al.  Evolution of new nonantibody proteins via iterative somatic hypermutation. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[29]  Brian Seed,et al.  Dynamic imaging of collagen and its modulation in tumors in vivo using second-harmonic generation , 2003, Nature Medicine.

[30]  D. Piwnica-Worms,et al.  CXCR4 Regulates Growth of Both Primary and Metastatic Breast Cancer , 2004, Cancer Research.

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

[32]  V. Verkhusha,et al.  Modern fluorescent proteins: from chromophore formation to novel intracellular applications. , 2011, BioTechniques.

[33]  W. Webb,et al.  Live tissue intrinsic emission microscopy using multiphoton-excited native fluorescence and second harmonic generation , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[34]  Erik Sahai,et al.  Localised and reversible TGFβ signalling switches breast cancer cells from cohesive to single cell motility , 2009, Nature Cell Biology.

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

[36]  David W Piston,et al.  Fluorescent proteins at a glance , 2011, Journal of Cell Science.

[37]  G. Luker,et al.  Imaging ligand-dependent activation of CXCR7. , 2009, Neoplasia.

[38]  G. Luker,et al.  Applications of bioluminescence imaging to antiviral research and therapy: multiple luciferase enzymes and quantitation. , 2008, Antiviral research.

[39]  Mikala Egeblad,et al.  Visualizing stromal cell dynamics in different tumor microenvironments by spinning disk confocal microscopy , 2008, Disease Models & Mechanisms.

[40]  G. Patterson,et al.  Use of the green fluorescent protein and its mutants in quantitative fluorescence microscopy. , 1997, Biophysical journal.

[41]  D. Piwnica-Worms,et al.  Characterization of phosphine complexes of technetium(III) as transport substrates of the multidrug resistance P-glycoprotein and functional markers of P-glycoprotein at the blood-brain barrier. , 1997, Biochemistry.

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

[43]  Dai Fukumura,et al.  Tumor Microvasculature and Microenvironment: Novel Insights Through Intravital Imaging in Pre‐Clinical Models , 2010, Microcirculation.