We present the application of a redox-sensitive mutant of the yellow fluorescent protein (rxYFP) to image, with elevated sensitivity and high temporal and spatial resolution, oxidative responses of eukaryotic cells to pathophysiological stimuli. The method presented, based on the ratiometric quantitation of the distribution of fluorescence by confocal microscopy, allows us to draw real-time "redox maps" of adherent cells and to score subtle changes in the intracellular redox state, such as those induced by overexpression of redox-active proteins. This strategy for in vivo imaging of redox signaling circumvents many of the technical limitations currently encountered in the study of complex redox-based phenomena and promises to contribute substantially to this expanding area of signal transduction.
Maulucci, G., Labate, V., Mele, M., Panieri, E., Arcovito, G., Galeotti, T., Ostergaard, H., Winther, J. R., De Spirito, M., Pani, G., High-resolution imaging of redox signaling in live cells through an oxidation-sensitive yellow fluorescent protein., <<SCIENCE SIGNALING>>, 2008; (Ottobre): 75-88. [doi:10.1126/scisignal.143pl3] [http://hdl.handle.net/10807/3893]
High-resolution imaging of redox signaling in live cells through an oxidation-sensitive yellow fluorescent protein.
Maulucci, Giuseppe;Labate, Valentina;Mele, Marina;Panieri, Emiliano;Arcovito, Giuseppe;Galeotti, Tommaso;De Spirito, Marco;Pani, Giovambattista
2008
Abstract
We present the application of a redox-sensitive mutant of the yellow fluorescent protein (rxYFP) to image, with elevated sensitivity and high temporal and spatial resolution, oxidative responses of eukaryotic cells to pathophysiological stimuli. The method presented, based on the ratiometric quantitation of the distribution of fluorescence by confocal microscopy, allows us to draw real-time "redox maps" of adherent cells and to score subtle changes in the intracellular redox state, such as those induced by overexpression of redox-active proteins. This strategy for in vivo imaging of redox signaling circumvents many of the technical limitations currently encountered in the study of complex redox-based phenomena and promises to contribute substantially to this expanding area of signal transduction.
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