Abstract
Many genetically encoded biosensors use Förster resonance energy transfer (FRET) to dynamically report biomolecular activities. While pairs of cyan and yellow fluorescent proteins (FPs) are most commonly used as FRET partner fluorophores, respectively, green and red FPs offer distinct advantages for FRET, such as greater spectral separation, less phototoxicity, and lower autofluorescence. We previously developed the green-red FRET pair Clover and mRuby2, which improves responsiveness in intramolecular FRET reporters with different designs. Here we report the engineering of brighter and more photostable variants, mClover3 and mRuby3. mClover3 improves photostability by 60% and mRuby3 by 200% over the previous generation of fluorophores. Notably, mRuby3 is also 35% brighter than mRuby2, making it both the brightest and most photostable monomeric red FP yet characterized. Furthermore, we developed a standardized methodology for assessing FP performance in mammalian cells as stand-alone markers and as FRET partners. We found that mClover3 or mRuby3 expression in mammalian cells provides the highest fluorescence signals of all jellyfish GFP or coral RFP derivatives, respectively. Finally, using mClover3 and mRuby3, we engineered an improved version of the CaMKIIα reporter Camuiα with a larger response amplitude.
Highlights
We developed a GFP-RFP pair, Clover and mRuby[2], which offers FRET imaging with decreased phototoxicity and improved sensor responses over cyan fluorescent proteins (CFP)-yellow fluorescent proteins (YFP) pairs, and improved spectral properties over existing www.nature.com/scientificreports/
Clover and mRuby[2] remains the GFP-RFP pair with the highest FRET efficiency, FRET radius, and dynamic range in reporters[1,18]; this pair may be improved by increasing the photostability of Clover and the brightness of mRuby[2]
We show that mRuby[3] is the brightest and most photostable monomeric RFP to date, and offers high FRET efficiency in GFP-RFP fusions
Summary
We developed a GFP-RFP pair, Clover and mRuby[2], which offers FRET imaging with decreased phototoxicity and improved sensor responses over CFP-YFP pairs, and improved spectral properties over existing www.nature.com/scientificreports/. Clover and mRuby[2] remains the GFP-RFP pair with the highest FRET efficiency, FRET radius, and dynamic range in reporters[1,18]; this pair may be improved by increasing the photostability of Clover and the brightness of mRuby[2]. Starting with Clover and mRuby[2], we engineered new proteins mClover[3] and mRuby[3], which feature improved properties for FRET imaging. We find that mClover[3] is a brighter and more photostable variant of Clover that compares favorably with other bright monomeric GFPs. Together, the mClover3-mRuby[3] GFP-RFP pair improves FRET efficiency and improves dynamic responses in the calcium/calmodulin-dependent kinase II alpha (CaMKIIα ) reporter, Camuiα 4,20
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