Abstract
Ratiometric measurements with FRET-based biosensors in living cells using a single fluorescence excitation wavelength are often affected by a significant ion sensitivity and the aggregation behavior of the FRET pair. This is an important problem for quantitative approaches. Here we report on the influence of physiological ion concentration changes on quantitative ratiometric measurements by comparing different FRET pairs for a cAMP-detecting biosensor. We exchanged the enhanced CFP/enhanced YFP FRET pair of an established Epac1-based biosensor by the fluorophores mCerulean/mCitrine. In the case of enhanced CFP/enhanced YFP, we showed that changes in proton, and (to a lesser extent) chloride ion concentrations result in incorrect ratiometric FRET signals, which may exceed the dynamic range of the biosensor. Calcium ions have no direct, but an indirect pH-driven effect by mobilizing protons. These ion dependences were greatly eliminated when mCerulean/mCitrine fluorophores were used. For such advanced FRET pairs the biosensor is less sensitive to changes in ion concentration and allows consistent cAMP concentration measurements under different physiological conditions, as occur in metabolically active cells. In addition, we verified that the described FRET pair exchange increased the dynamic range of the FRET efficiency response. The time window for stable experimental conditions was also prolonged by a faster biosensor expression rate in transfected cells and a greatly reduced tendency to aggregate, which reduces cytotoxicity. These properties were verified in functional tests in single cells co-expressing the biosensor and the 5-HT(1A) receptor.
Highlights
For such biosensors with fixed donor-acceptor stoichiometry, common ratiometric fluorescence measurements can be performed to identify changes in FRET
In the case of enhanced CFP/enhanced YFP, we showed that changes in proton, and chloride ion concentrations result in incorrect ratiometric FRET signals, which may exceed the dynamic range of the biosensor
Photon counts for the donor and acceptor component of CEPAC* reached similar values in contrast to EPAC*, which is beneficial for the signal/noise ratio of the ratiometric FRET analysis
Summary
Plasmids encoding mCerulean and mCitrine were obtained from Addgene, and their coding sequences were amplified by PCR, introducing recombinant recognition sites for restriction enzymes using the primers mCerulean-NotI-for (5Ј-GCGGCCGC aat ggt gag caa ggg cga gga g-3Ј), mCerulean-EcoRV-rev (5Ј-GATATC gag atc tga gtc cgg act tgt aca gct cgt cca tgc c-3Ј), mCitrine-NheI-for (5Ј-GCTAGC gag ctc atg gtg agc aag ggc gag gag-3Ј), and mCitrine-EcoRI-rev (5Ј-GAATTC ctt gta cag ctc gtc cat gcc-3Ј). MCerulean and mCitrine were isolated from the vectors with the restriction enzyme pairs NotI/EcoRV and NheI/EcoRI (New England Biolabs) and cloned into corresponding sites in the vector pcDNA3.1-CFP-Epac(␦DEP-CD)–YFP [7] (encoding the protein denoted EPAC*) to replace previous fluorophores. The cloning provided the vector pcDNA3.1-mCeruleanEpac(␦DEP-CD)–mCitrine (encoding the protein denoted CEPAC*). Neuroblastoma cells (N1E-115) were transfected with cDNA encoding for (a) enhanced cyan fluorescence protein (pECFPN1, Clontech), (b) enhanced yellow fluorescence protein (pEYFP-N1, Clontech), (c) mCerulean, (d) mCitrine, (e) pcDNA3.1/CAT (Invitrogen), (f) EPAC*, (g) CEPAC*, or (h) a co-transfection of 5-HT1AR (HA-tagged 5-HT1A-receptor cloned into the pcDNA3.1 plasmid [23]) together with CEPAC* and EPAC*, respectively
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