Until recently, genes coding for homologues of the autofluorescent protein GFP had only been identified in marine organisms from the phyla Cnidaria and Arthropoda. New fluorescent-protein genes have now been found in the phylum Chordata, coding for particularly bright oligomeric fluorescent proteins such as the tetrameric yellow fluorescent protein lanYFP from Branchiostoma lanceolatum. A successful monomerization attempt led to the development of the bright yellow-green fluorescent protein mNeonGreen. The structures of lanYFP and mNeonGreen have been determined and compared in order to rationalize the directed evolution process leading from a bright, tetrameric to a still bright, monomeric fluorescent protein. An unusual discolouration of crystals of mNeonGreen was observed after X-ray data collection, which was investigated using a combination of X-ray crystallography and UV-visible absorption and Raman spectroscopies, revealing the effects of specific radiation damage in the chromophore cavity. It is shown that X-rays rapidly lead to the protonation of the phenolate O atom of the chromophore and to the loss of its planarity at the methylene bridge.
We have studied the fluorescence decays of the purified enhanced cyan fluorescent protein (ECFP, with chromophore sequence Thr-Trp-Gly) and of its variant carrying the single H148D mutation characteristic of the brighter form Cerulean. Both proteins exhibit highly complex fluorescence decays showing strong temperature and pH dependences. At neutral pH, the H148D mutation leads (i) to a general increase in all fluorescence lifetimes and (ii) to the disappearance of a subpopulation, estimated to be more than 25% of the total ECFP molecules, characterized by a quenched and red-shifted fluorescence. The fluorescence lifetime distributions of ECFP and its H148D mutant remain otherwise very similar, indicating a high degree of structural and dynamic similarity of the two proteins in their major form. From thermodynamic analysis, we conclude that the multiexponential decay of ECFP cannot be simply ascribed, as is generally admitted, to the slow conformational exchange characterized by NMR and X-ray crystallographic studies [Seifert, M. H., et al. (2002) J. Am. Chem. Soc. 124, 7932-7942; Bae, J. H., et al. (2003) J. Mol. Biol. 328, 1071-1081]. Parallel measurements in living cells show that these fluorescence properties in neutral solution are very similar to those of cytosolic ECFP.
Cyan fluorescent proteins (CFPs) are widely used as FRET donors in genetically encoded biosensors for live cell imaging. Recently, cyan variants with greatly improved fluorescence quantum yields have been developed by large scale random mutagenesis. We show that the introduction of only two mutations, T65S and H148G, is able to confer equivalent performances on the popular form ECFP, leading to Aquamarine (QY = 0.89, τ(f) = 4.12 ns). Besides an impressive pH stability (pK(1/2) = 3.3), Aquamarine shows a very low general sensitivity to its environment, and undetectable photoswitching reactions. Aquamarine gives efficient and bright expression in different mammalian cell systems, with a long and single exponential intracellular fluorescence lifetime mostly insensitive to the fusion or the subcellular location of the protein. Aquamarine was also able to advantageously replace the CFP donor in the FRET biosensor AKAR for ratiometric measurements of protein kinase A activity. The performances of Aquamarine show that only two rounds of straightforward single point mutagenesis can be a quick and efficient way to optimize the donor properties in FRET-based biosensors.
It is generally acknowledged that the popular cyan and yellow fluorescent proteins carried by genetically encoded reporters suffer from strong pH sensitivities close to the physiological pH range. We studied the consequences of these pH responses on the intracellular signals of model Förster resonant energy transfer (FRET) tandems and FRET-based reporters of cAMP-dependent protein kinase activity (AKAR) expressed in the cytosol of living BHK cells, while changing the intracellular pH by means of the nigericin ionophore. Although the simultaneous pH sensitivities of the donor and the acceptor may mask each other in some cases, the magnitude of the perturbations can be very significant, as compared to the functional response of the AKAR biosensor. Replacing the CFP donor by the spectrally identical, but pH-insensitive Aquamarine variant (pK1/2 = 3.3) drastically modifies the biosensor pH response and gives access to the acid transition of the yellow acceptor. We developed a simple model of pH-dependent FRET and used it to describe the expected pH-induced changes in fluorescence lifetime and ratiometric signals. This model qualitatively accounts for most of the observations, but reveals a complex behavior of the cytosolic AKAR biosensor at acid pHs, associated to additional FRET contributions. This study underlines the major and complex impact of pH changes on the signal of FRET reporters in the living cell.
RÉSUMÉ L’étude de l’acceptabilité renvoie à de nombreux modèles (Modèle d’acceptation des technologies : Davis, Bagozzi, & Warshaw, 1989 ; P3, Pouvoir, performance, perception : Dillon & Morris, 1999 ; ou encore Unified Theory of Acceptance and Use of Technology : Venkatesh, Morris, Davis, & Davis, 2003) pour prédire le comportement de l’utilisateur. Dans ces modèles le poids des variables sociales pour prédire l’intention d’usage ou le comportement de l’utilisateur est variable (de .02 à .51). Cet article a pour objectif d’analyser les déterminants de cette variabilité en convoquant deux dimensions permettant de mieux cerner l’intervention des variables sociales : la prise en compte des normes descriptives et injonctives (Cialdini, Reno, & Kallgren, 1990) d’une part et d’autre part la pesanteur sociale du comportement réalisé par l’utilisateur alors qu’il recourt à la technologie qu’on lui présente.
The tendency of GFP-like fluorescent proteins to dimerize in vitro is a permanent concern as it may lead to artifacts in FRET imaging applications. However, we have found recently that CFP and YFP (the couple of GFP variants mostly used in FRET studies) show no trace of association in the cytosol of living cells up to millimolar concentrations. In this study, we investigated the oligomerization properties of purified CFP, by fluorescence anisotropy and sedimentation velocity. Surprisingly, we found that CFP has a much weaker homoaffinity than other fluorescent proteins (K(d) ≥ 3 × 10(-3) M), and that this is due to the constitutive N146I mutation, originally introduced into CFP to improve its brightness.
pH is an important parameter that affects many functions of live cells, from protein structure or function to several crucial steps of their metabolism. Genetically encoded pH sensors based on pH-sensitive fluorescent proteins have been developed and used to monitor the pH of intracellular compartments. The quantitative analysis of pH variations can be performed either by ratiometric or fluorescence lifetime detection. However, most available genetically encoded pH sensors are based on green and yellow fluorescent proteins and are not compatible with multicolor approaches. Taking advantage of the strong pH sensitivity of enhanced cyan fluorescent protein (ECFP), we demonstrate here its suitability as a sensitive pH sensor using fluorescence lifetime imaging. The intracellular ECFP lifetime undergoes large changes (32 %) in the pH 5 to pH 7 range, which allows accurate pH measurements to better than 0.2 pH units. By fusion of ECFP with the granular chromogranin A, we successfully measured the pH in secretory granules of PC12 cells, and we performed a kinetic analysis of intragranular pH variations in living cells exposed to ammonium chloride.
Cyan fluorescent proteins (CFP) derived from Aequorea victoria GFP, carrying a tryptophan-based chromophore, are widely used as FRET donors in live cell fluorescence imaging experiments. Recently, several CFP variants with near-ultimate photophysical performances were obtained through a mix of site-directed and large scale random mutagenesis. To understand the structural bases of these improvements, we have studied more specifically the consequences of the single-site T65S mutation. We find that all CFP variants carrying the T65S mutation not only display an increased fluorescence quantum yield and a simpler fluorescence emission decay, but also show an improved pH stability and strongly reduced reversible photoswitching reactions. Most prominently, the Cerulean-T65S variant reaches performances nearly equivalent to those of mTurquoise, with QY = 0.84, an almost pure single exponential fluorescence decay and an outstanding stability in the acid pH range (pK1/2 = 3.6). From the detailed examination of crystallographic structures of different CFPs and GFPs, we conclude that these improvements stem from a shift in the thermodynamic balance between two well defined configurations of the residue 65 hydroxyl. These two configurations differ in their relative stabilization of a rigid chromophore, as well as in relaying the effects of Glu222 protonation at acid pHs. Our results suggest a simple method to greatly improve numerous FRET reporters used in cell imaging, and bring novel insights into the general structure-photophysics relationships of fluorescent proteins.
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