Spectrally-resolved response properties of the three most advanced FRET based fluorescent protein voltage probes

Hiroki Mutoh; Amelie Perron; Dimitar Dimitrov; Yuka Iwamoto; Walther Akemann; Dmitriy M. Chudakov; Thomas Knöpfel

doi:10.1371/journal.pone.0004555

Spectrally-resolved response properties of the three most advanced FRET based fluorescent protein voltage probes

Hiroki Mutoh^*, Amelie Perron, Dimitar Dimitrov, Yuka Iwamoto, Walther Akemann, Dmitriy M. Chudakov, Thomas Knöpfel

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Journal article › peer-review

68 Citations (Scopus)

Abstract

Genetically-encoded optical probes for membrane potential hold the promise of monitoring electrical signaling of electrically active cells such as specific neuronal populations in intact brain tissue. The most advanced class of these probes was generated by molecular fusion of the voltage sensing domain (VSD) of Ci-VSP with a fluorescent protein (FP) pair. We quantitatively compared the three most advanced versions of these probes (two previously reported and one new variant), each involving a spectrally distinct tandem of FPs. Despite these different FP tandems and dissimilarities within the amino acid sequence linking the VSD to the FPs, the amplitude and kinetics of voltage dependent fluorescence changes were surprisingly similar. However, each of these fluorescent probes has specific merits when considering different potential applications.

Original language	English
Article number	e4555
Number of pages	5
Journal	PLoS ONE
Volume	4
Issue number	2
DOIs	https://doi.org/10.1371/journal.pone.0004555
Publication status	Published - 23 Feb 2009

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AU - Mutoh, Hiroki

AU - Perron, Amelie

AU - Dimitrov, Dimitar

AU - Iwamoto, Yuka

AU - Akemann, Walther

AU - Chudakov, Dmitriy M.

AU - Knöpfel, Thomas

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N2 - Genetically-encoded optical probes for membrane potential hold the promise of monitoring electrical signaling of electrically active cells such as specific neuronal populations in intact brain tissue. The most advanced class of these probes was generated by molecular fusion of the voltage sensing domain (VSD) of Ci-VSP with a fluorescent protein (FP) pair. We quantitatively compared the three most advanced versions of these probes (two previously reported and one new variant), each involving a spectrally distinct tandem of FPs. Despite these different FP tandems and dissimilarities within the amino acid sequence linking the VSD to the FPs, the amplitude and kinetics of voltage dependent fluorescence changes were surprisingly similar. However, each of these fluorescent probes has specific merits when considering different potential applications.

AB - Genetically-encoded optical probes for membrane potential hold the promise of monitoring electrical signaling of electrically active cells such as specific neuronal populations in intact brain tissue. The most advanced class of these probes was generated by molecular fusion of the voltage sensing domain (VSD) of Ci-VSP with a fluorescent protein (FP) pair. We quantitatively compared the three most advanced versions of these probes (two previously reported and one new variant), each involving a spectrally distinct tandem of FPs. Despite these different FP tandems and dissimilarities within the amino acid sequence linking the VSD to the FPs, the amplitude and kinetics of voltage dependent fluorescence changes were surprisingly similar. However, each of these fluorescent probes has specific merits when considering different potential applications.

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Spectrally-resolved response properties of the three most advanced FRET based fluorescent protein voltage probes

Abstract

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