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Quantitative Multiphoton Spectral Imaging and Its Use for Measuring Resonance Energy Transfer

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

^* National Institute of Alcohol Abuse and Alcoholism, and National Institute of Child Health and Human Development, National Institutes of Health, Bethesda, Maryland 20892

Correspondence: Address reprint requests to Steven S. Vogel, E-mail: stevevog{at}mail.nih.gov.

Protein labeling with green fluorescent protein derivatives has become an invaluable tool in cell biology. Protein quantification, however, is difficult when cells express constructs with overlapping fluorescent emissions. Under these conditions, signal separation using emission filters is inherently inefficient. Spectral imaging solves this problem by recording emission spectra directly. Unfortunately, linear unmixing, the algorithm used for quantifying individual fluorophores from emission spectra, fails when resonance energy transfer (RET) is present. We therefore sought to develop an unmixing algorithm that incorporates RET. An equation for spectral emission incorporating RET was derived and an assay based on this formalism, spectral RET (sRET), was developed. Standards with defined RET efficiencies and with known Cerulean/Venus ratios were constructed and used to test sRET. We demonstrate that sRET analysis is a comprehensive, photon-efficient method for imaging RET efficiencies and accurately determines donor and acceptor concentrations in living cells.

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