Hélène Pasquier

The single T65S mutation generates brighter cyan fluorescent proteins with increased photostability and pH insensitivity.

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.

Newly engineered cyan fluorescent proteins with enhanced performances for live cell FRET imaging

Cyan fluorescent proteins (CFPs) derived from Aequorea victoria green fluorescent protein are the most widely used Förster resonant energy transfer (FRET) donors in genetically encoded biosensors for live‐cell imaging and bioassays. However, the weak and complex fluorescence emission of cyan variants, such as enhanced cyan fluorescent protein (ECFP) or Cerulean, has long remained a major bottleneck in these FRET techniques. Recently, several CFPs with greatly improved performances, including mTurquoise, mTurquoise2, mCerulean3, and Aquamarine, have been engineered through a mixture of site‐directed and large‐scale random mutagenesis. This review summarizes the engineering and relative merits of these new cyan donors, which can readily replace popular CFPs in FRET imaging protocols, while reaching fluorescence quantum yields close to 90%, and unprecedented long, near‐single fluorescence lifetimes of about 4 ns. These variants display an increased general photostability and much reduced environmental sensitivity, notably towards acid pH. These new, bright, and robust CFPs now open up exciting outlooks for fluorescence lifetime imaging microscopy and advanced quantitative FRET analyses in living cells. In addition, the stepwise engineering of Aquamarine shows that only two critical mutations in ECFP, and one in Cerulean, are required to achieve these performances, which brings new insights into the structural bases of their photophysical properties.

pH sensitivity of FRET reporters based on cyan and yellow fluorescent proteins

AbstractIt 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. Graphical AbstractThe complex behaviour of a cytosolic FRET construct carrying cyan and yellow fluorescent proteins in conditions of varying pH is well described by a simple analytical model. Changing the ECFP donor for an Aquamarine unveils the strong pH sensitivity of the yellow acceptor

Photophysics and Spectroscopy of Fluorophores in the Green Fluorescent Protein Family

Proteins homologous to the green fluorescent protein (GFPs) form a large family of unconventional, genetically encoded fluorophores with widely diverse colors and applications, which have profoundly renewed the fields of biological imaging and drug screening. Their detailed spectroscopy stems from a complex interplay between the electronic properties of a relatively simple, yet flexible and multiprotonable chromophore formed after specific biosynthesis, and the spatial and dynamic organizationof its protein carrier. Early experimental and theoretical studies of GFP from the Aequorea victoria jellyfish and of model synthetic compounds have revealed that chromophore twisting, cis-trans isomerization, proton transfer, and electron transfer are major excited state reactions that determine its photophysics and photochemistry. It has been found later that quite similar mechanisms are at work in several distant members of the GFP family, suggesting a unified picture that may guide the future development of new GFP-based biosensors.

Relation between pH, structure, and absorption spectrum of Cerulean: A study by molecular dynamics and TD DFT calculations

Molecular dynamics (MD) and quantum mechanical calculations of the Cerulean green fluorescent protein (a variant of enhanced cyan fluorescent protein ECFP) at pH 5.0 and 8.0 are presented, addressing two questions arising from experimental results (Malo et al., Biochemistry 2007;46:9865–9873): the origin of the blue shift of absorption spectrum when the pH is decreased from 8.0 to 5.0, and the lateral chain orientation of the key residue Asp148. We demonstrate that the blue shift is reproduced assuming that a rotation around the single bond of the exocyclic ring of the chromophore takes place when the pH changes from 5.0 to 8.0. We find that Asp148 is protonated and inside the barrel at pH 5.0 in agreement with crystallographic data. However, the hydrogen bond pattern of Asp148 is different in simulations of the solvated protein and in the crystal structure. This difference is explained by a partial closing of the cleft between strands 6 and 7 in MD simulations. This study provides also a structure at pH 8.0: the Asp148 carboxylate group is exposed to the solvent and the chromophore is stabilized in the trans conformation by a tighter hydrogen bond network. This work gives some insight into the relationship between the pH and the chromophore conformation and suggests an interpretation of the very similar fluorescent properties of ECFP and ECFP/H148D. Proteins 2010.

Interferences of Silica Nanoparticles in Green Fluorescent Protein Folding Processes

We investigated the relationship between unfolded proteins, silica nanoparticles and chaperonin to determine whether unfolded proteins could stick to silica surfaces and how this process could impair heat shock protein activity. The HSP60 catalyzed green fluorescent protein (GFP) folding was used as a model system. The adsorption isotherms and adsorption kinetics of denatured GFP were measured, showing that denaturation increases GFP affinity for silica surfaces. This affinity is maintained even if the surfaces are covered by a protein corona and allows silica NPs to interfere directly with GFP folding by trapping it in its unstructured state. We determined also the adsorption isotherms of HSP60 and its chaperonin activity once adsorbed, showing that SiO2 NP can interfere also indirectly with protein folding through chaperonin trapping and inhibition. This inhibition is specifically efficient when NPs are covered first with a layer of unfolded proteins. These results highlight for the first time the antichaperonin activity of silica NPs and ask new questions about the toxicity of such misfolded proteins/nanoparticles assembly toward cells.

Structural analysis of the bright monomeric yellow-green fluorescent protein mNeonGreen obtained by directed evolution.

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.

Engineering fluorescent proteins towards ultimate performances: lessons from the newly developed cyan variants

New fluorescent proteins (FPs) are constantly discovered from natural sources, and submitted to intensive engineering based on random mutagenesis and directed evolution. However, most of these newly developed FPs fail to achieve all the performances required for their bioimaging applications. The design of highly optimised FP-based reporters, simultaneously displaying appropriate colour, multimeric state, chromophore maturation, brightness, photostability and environmental sensitivity will require a better understanding of the structural and dynamic determinants of FP photophysics. The recent development of cyan fluorescent proteins (CFPs) like mCerulean3, mTurquoise2 and Aquamarine brings a different view on these questions, as in this particular case, a step by step evaluation of critical mutations has been performed within a family of spectrally identical and evolutionary close variants. These efforts have led to CFPs with quantum yields close to unity, near single exponential emission decays, high photostability and complete insensitivity to pH, making them ideal choices as energy transfer donors in FRET and FLIM imaging applications. During this process, it was found that a proper amino-acid choice at only two positions (148 and 65) is sufficient to transform the performances of CFPs: with the help of structural and theoretical investigations, we rationalise here how these two positions critically control the CFP photophysics, in the context of FPs derived from the Aequorea victoria species. Today, these results provide a useful toolbox for upgrading the different CFP donors carried by FRET biosensors. They also trace the route towards the de novo design of FP-based optogenetic devices that will be perfectly tailored to dedicated imaging and sensing applications.