Quantitative Multiphoton Spectral Imaging and its use for Measuring Resonance Energy Transfer

doi:10.1529/biophysj.105.061853

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Biophys. J. BioFAST: First Published July 22, 2005. doi:10.1529/biophysj.105.061853
© 2005 by the Biophysical Society.

A more recent version of this article appeared on October 1, 2005.

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SPECTROSCOPY, IMAGING, OTHER TECHNIQUES

Quantitative Multiphoton Spectral Imaging and its use for Measuring Resonance Energy Transfer

Christopher Thaler ¹, Srinagesh V Koushik ¹, Paul S Blank ² and Steven S Vogel ¹^*

¹ NIAAA/NIH
² NICHD/NIH

^* To whom correspondence should be addressed. E-mail: stevevog{at}mail.nih.gov.

Submitted on February 23, 2005
Revised on April 11, 2005
Accepted on 7 July 2005

Abstract
Protein labeling with GFP-derivatives has become an invaluabletool in cell-biology. Protein quantification, however, is difficultwhen cells express constructs with overlapping fluorescent emissions.Under these conditions, signal separation using emission filtersis inherently inefficient. Spectral imaging solves this problemby recording emission spectra directly. Unfortunately, linearunmixing, the algorithm used for quantifying individual fluorophoresfrom emission spectra fails when resonance energy transfer (RET)is present. We therefore sought to develop an unmixing algorithmthat incorporates RET. An equation for spectral emission incorporatingRET was derived and an assay based on this formalism, "spectralRET" (sRET), was developed. Standards with defined RET efficiencies,and with known Cerulean to Venus ratios were constructed andused to test sRET. We demonstrate that sRET analysis is a comprehensive,photon-efficient method for imaging RET efficiencies, and accuratelydetermines donor and acceptor concentrations in living cells.

Key Words: Cerulean, FLIM, FRET, Venus, linear-unmixing, two-photon

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