In vivo fluorescence lifetime tomography of a FRET probe expressed in mouse

Förster resonance energy transfer (FRET) is a powerful biological tool for reading out cell signaling processes. In vivo use of FRET is challenging because of the scattering properties of bulk tissue. By combining diffuse fluorescence tomography with fluorescence lifetime imaging (FLIM), implemented using wide-field time-gated detection of fluorescence excited by ultrashort laser pulses in a tomographic imaging system and applying inverse scattering algorithms, we can reconstruct the three dimensional spatial localization of fluorescence quantum efficiency and lifetime. We demonstrate in vivo spatial mapping of FRET between genetically expressed fluorescent proteins in live mice read out using FLIM. Following transfection by electroporation, mouse hind leg muscles were imaged in vivo and the emission of free donor (eGFP) in the presence of free acceptor (mCherry) could be clearly distinguished from the fluorescence of the donor when directly linked to the acceptor in a tandem (eGFP-mCherry) FRET construct.

[1]  D K Smith,et al.  Numerical Optimization , 2001, J. Oper. Res. Soc..

[2]  D. Delpy,et al.  Optical Imaging in Medicine , 1998, CLEO/Europe Conference on Lasers and Electro-Optics.

[3]  Ilya V Turchin,et al.  Lifetime imaging of FRET between red fluorescent proteins , 2010, Journal of biophotonics.

[4]  S R Arridge,et al.  Optical imaging in medicine: I. Experimental techniques , 1997, Physics in medicine and biology.

[5]  Michael Knop,et al.  Spatial regulation of Fus3 MAP kinase activity through a reaction-diffusion mechanism in yeast pheromone signalling , 2007, Nature Cell Biology.

[6]  E. Signori,et al.  Optimisation of electrotransfer of plasmid into skeletal muscle by pretreatment with hyaluronidase – increased expression with reduced muscle damage , 2001, Gene Therapy.

[7]  D. Scherman,et al.  A versatile vector for gene and oligonucleotide transfer into cells in culture and in vivo: polyethylenimine. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[8]  S. Arridge,et al.  Fluorescence lifetime optical tomography with Discontinuous Galerkin discretisation scheme , 2010, Biomedical optics express.

[9]  M. Neil,et al.  A compact, multidimensional spectrofluorometer exploiting supercontinuum generation , 2008, Journal of biophotonics.

[10]  Elizabeth A Jares-Erijman,et al.  Imaging molecular interactions in living cells by FRET microscopy. , 2006, Current opinion in chemical biology.

[11]  Simon R. Arridge,et al.  Tomographic imaging of flourescence resonance energy transfer in highly light scattering media , 2010, BiOS.

[12]  S. Achilefu,et al.  In vivo fluorescence lifetime tomography. , 2009, Journal of biomedical optics.

[13]  Vasilis Ntziachristos,et al.  In vivo tomographic imaging of red-shifted fluorescent proteins , 2011, Biomedical optics express.

[14]  V. Ntziachristos Fluorescence molecular imaging. , 2006, Annual review of biomedical engineering.

[15]  Alessandro Sardini,et al.  Three-dimensional imaging of Förster resonance energy transfer in heterogeneous turbid media by tomographic fluorescent lifetime imaging. , 2009, Optics letters.

[16]  Amy E Palmer,et al.  Fluorescent biosensors of protein function. , 2008, Current opinion in chemical biology.

[17]  Jin Zhang,et al.  Chapter 2: Molecular sensors based on fluorescence resonance energy transfer to visualize cellular dynamics. , 2008, Methods in cell biology.

[18]  Philip S Low,et al.  Deep-tissue imaging of intramolecular fluorescence resonance energy-transfer parameters. , 2010, Optics letters.