Green fluorescent protein variants as ratiometric dual emission pH sensors. 2. Excited-state dynamics

In the preceding paper [Hanson, G. T., McAnaney, T. B., Park, E. S., Rendell, M. E. P., Yarbrough, D. K., Chu, S., Xi, L., Boxer, S. G., Montrose, M. H., and Remington, S. J. (2002) Biochemistry 41, 15477-15488], novel mutants of the green fluorescent protein (GFP) that exhibit dual steady-state emission properties were characterized structurally and discussed as potential intracellular pH probes. In this work, the excited-state dynamics of one of these new dual emission GFP variants, deGFP4 (C48S/S65T/H148C/T203C), is studied by ultrafast fluorescence upconversion spectroscopy. Following excitation of the high-energy absorption band centered at 398 nm and assigned to the neutral form of the chromophore, time-resolved emission was monitored from the excited state of both the neutral and intermediate anionic chromophores at both high and low pH and upon deuteration of exchangeable protons. The time-resolved emission dynamics and isotope effect appear to be very different from those of wild-type GFP [Chattoraj, M., King, B. A., Bublitz, G. U., and Boxer, S. G. (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 8362-8367]; however, due to overlapping emission bands, the apparent difference can be analyzed quantitatively within the same framework used to describe GFP excited-state dynamics. The results indicate that the pH-sensitive steady-state emission characteristics of deGFP4 are a result of a pH-dependent modulation of the rate of excited-state proton transfer. At high pH, a rapid interconversion from the excited state of the higher energy neutral chromophore to the lower energy intermediate anionic chromophore is achieved by proton transfer. At low pH, excited-state proton transfer is slowed to the point where it is no longer rate limiting.     

Green fluorescent protein variants as ratiometric dual emission pH sensors. 1. Structural characterization and preliminary application

Novel dual emission, pH-sensitive variants of the green fluorescent protein (GFP) have been constructed and are suitable for ratiometric emission measurements in vivo. This new class of GFPs, termed deGPFs, results from substitution of wild-type residue 65 with threonine and residues 148 and/or 203 with cysteine. deGFPs display pK(a) values ranging from 6.8 to 8.0 and emission that switches from a green form (lambda(max) approximately 515 nm) to a blue form (lambda(max) approximately 460 nm) with acidifying pH. In this report we analyze in most detail the deGFP1 variant (S65T/H148G/T203C, pK(a) approximately 8.0) and the deGFP4 variant (S65T/C48S/H148C/T203C, pK(a) approximately 7.3). In the following paper [McAnaney, T. B., Park, E. S., Hanson, G. T., Remington, S. J., and Boxer, S. G. (2002) Biochemistry 41, 15489-15494], data obtained by ultrafast fluorescence upconversion spectroscopy can be described by a kinetic model that includes an excited-state proton-transfer pathway at high pH but not at low pH. Crystal structure analyses of deGFP1 at high-pH and low-pH conformations were performed to elucidate the basis for the dual emission characteristics. At low pH the structure does not contain a hydrogen bond network that would support rapid transfer of a proton from the excited state of the neutral chromophore to a suitable acceptor; hence blue emission is observed. At high pH, backbone rearrangements induced by changes in the associated hydrogen bond network permit excited-state proton transfer from the excited state of the neutral chromophore to the bulk solvent via Ser147 and bound water molecules, resulting in green emission from the anionic chromophore. Comparative analysis suggests that the basis for dual emission is elimination of the wild-type proton-transfer network by the S65T substitution, a general reduction in hydrogen-bonding opportunities, and a concomitant increase in the hydrophobic nature of the chromophore environment resulting from the cysteine substitutions. We evaluated the suitability of the deGFP4 variant for intracellular pH measurements in mammalian cells by transient expression in PS120 fibroblasts. The responses of deGFP4 and a commercially available pH-sensitive dye, SNARF-1, to changes in pH were compared in the same cells. Results show that the dynamic range of the emission ratio change is comparable between the two pH sensors over the range examined. Two-photon excitation was found to elicit a better deGFP4 fluorescent signal above cellular autofluorescence when compared to conventional confocal microscopy. Given their favorable optical characteristics, suitable pK(a)'s for the physiological pH range, and suitability for ratiometric measurements, dual emission GFPs should make excellent probes for studying pH in vivo.     

Ultrafast excited-state dynamics in the green fluorescent protein variant S65T/H148D. 1. Mutagenesis and structural studies

Wild type green fluorescent protein (wt-GFP) and the variant S65T/H148D each exhibit two absorption bands, A and B, which are associated with the protonated and deprotonated chromophores, respectively. Excitation of either band leads to green emission. In wt-GFP, excitation of band A ( approximately 395 nm) leads to green emission with a rise time of 10-15 ps, due to excited-state proton transfer (ESPT) from the chromophore hydroxyl group to an acceptor. This process produces an anionic excited-state intermediate I* that subsequently emits a green photon. In the variant S65T/H148D, the A band absorbance maximum is red-shifted to approximately 415 nm, and as detailed in the accompanying papers, when the A band is excited, green fluorescence appears with a rise time shorter than the instrument time resolution ( approximately 170 fs). On the basis of the steady-state spectroscopy and high-resolution crystal structures of several variants described herein, it is proposed that in S65T/H148D, the red shift of absorption band A and the ultrafast appearance of green fluorescence upon excitation of band A are due to a very short (相似文献   

An alternative excited-state proton transfer pathway in green fluorescent protein variant S205V

Wild-type green fluorescent protein (wt-GFP) has a prominent absorbance band centered at approximately 395 nm, attributed to the neutral chromophore form. The green emission arising upon excitation of this band results from excited-state proton transfer (ESPT) from the chromophore hydroxyl, through a hydrogen-bond network proposed to consist of a water molecule and Ser205, to Glu222. Although evidence for Glu222 as a terminal proton acceptor has already been obtained, no evidence for the participation of Ser205 in the proton transfer process exists. To examine the role of Ser205 in the proton transfer, we mutated Ser205 to valine. However, the derived GFP variant S205V, upon excitation at 400 nm, still produces green fluorescence. Time-resolved emission spectroscopy suggests that ESPT contributes to the green fluorescence, and that the proton transfer takes place approximately 30 times more slowly than in wt-GFP. The crystal structure of S205V reveals rearrangement of Glu222 and Thr203, forming a new hydrogen-bonding network. We propose this network to be an alternative ESPT pathway with distinctive features that explain the significantly slowed rate of proton transfer. In support of this proposal, the double mutant S205V/T203V is shown to be a novel blue fluorescent protein containing a tyrosine-based chromophore, yet is incapable of ESPT. The results have implications for the detailed mechanism of ESPT and the photocycle of wt-GFP, in particular for the structures of spectroscopically identified intermediates in the cycle.     

Ultrafast excited-state dynamics in the green fluorescent protein variant S65T/H148D. 3. Short- and long-time dynamics of the excited-state proton transfer

Steady-state emission, femtosecond pump-probe spectroscopy, and time-correlated single-photon counting (TCSPC) measurements were used to study the photophysics and the excited-state proton transfer (ESPT) reactions in the green fluorescent protein (GFP) variant S65T/H148D at three pH values: 6.0, 7.9, and 9.5. Selective mutation of GFP caused a dramatic change in the steady-state and excited-state behavior as compared to the wild-type GFP (wt-GFP) studied earlier. An excitation wavelength dependence of the quantum yield of the strong emission band at 510 nm (I* band) indicates the competition between adiabatic and non-adiabatic excited-state proton-transfer reactions. Pump-probe measurements show that the signal buildup probed at 510 nm is biphasic, where 0.8 of the signal amplitude is ultrashort, <150 fs, and 0.2 of the signal decreases with a approximately 10 ps time constant. This effect is a summary result of adiabatic ESPT to the carboxylate group of Asp148 and nonradiative processes. When compared with the luminescence of wt-GFP, the steady-state intensity at 450 nm is lower by a factor of about 10. This very weak emission at 450 nm has a nonexponential decay. It is relatively pH insensitive and, at about 25 ps, is almost twice as long as in wt-GFP. The former exhibits a surprisingly small kinetic deuterium isotope effect (KDIE), compared with the KDIE of about 5 for wt-GFP. Such weak proton dependence may indicate that this emission comes from the species not directly involved in the ESPT. In contrast, pH and H/D isotope dependence of the intense nonexponential luminescence decay of the S65T/H148D deprotonated form measured at 510 nm may result from an isomerization-induced deactivation that is accompanied by the proton recombination quenching. The data are complementary to the femtosecond time-resolved emission data obtained by ultrafast fluorescence up-conversion spectroscopy, found in the preceding paper (Shi et al.). The spectroscopic results are discussed on the basis of the detailed X-ray structure of the mutant published in the preceding paper (Shu et al.).     

Anomalous negative fluorescence anisotropy in yellow fluorescent protein (YFP 10C): quantitative analysis of FRET in YFP dimers

Yellow fluorescent protein (YFP) is widely used as a genetically encoded fluorescent marker in biology. In the course of a comprehensive study of this protein, we observed an unusual, negative fluorescence anisotropy at pH 6.0 (McAnaney, T. B., Zeng, W., Doe, C. F. E., Bhanji, N., Wakelin, S., Pearson, D. S., Abbyad, P., Shi, X., Boxer, S. G., and Bagshaw, C. R. (2005) Biochemistry 44, 5510-5524). Here we report that the fluorescence anisotropy of YFP 10C depends on protein concentration in the low micromolar range that was not expected. We propose that the negative anisotropy is a result of unidirectional F?rster resonance energy transfer (FRET) in a dimer of YFP, with the donor chromophore in the neutral form and the acceptor chromophore in the anionic form. This unusual mechanism is supported by studies of a monomeric YFP (A206K YFP) and transient-absorption spectroscopy of YFP 10C. A detailed analysis of the chromophore transition dipole moment direction is presented. The anisotropy and rate constant of this energy transfer are consistent with values produced by an analysis of the dimer structure observed in crystals.     

Investigating mitochondrial redox potential with redox-sensitive green fluorescent protein indicators

Current methods for determining ambient redox potential in cells are labor-intensive and generally require destruction of tissue. This precludes single cell or real time studies of changes in redox poise that result from metabolic processes or environmental influences. By substitution of surface-exposed residues on the Aequorea victoria green fluorescent protein (GFP) with cysteines in appropriate positions to form disulfide bonds, reduction-oxidation-sensitive GFPs (roGFPs) have been created. roGFPs have two fluorescence excitation maxima at about 400 and 490 nm and display rapid and reversible ratiometric changes in fluorescence in response to changes in ambient redox potential in vitro and in vivo. Crystal structure analyses of reduced and oxidized crystals of roGFP2 at 2.0- and 1.9-A resolution, respectively, reveal in the oxidized state a highly strained disulfide and localized main chain structural changes that presumably account for the state-dependent spectral changes. roGFP1 has been targeted to the mitochondria in HeLa cells. Fluorometric measurements on these cells using a fluorescence microscope or in cell suspension using a fluorometer reveal that the roGFP1 probe is in dynamic equilibrium with the mitochondrial redox status and responds to membrane-permeable reductants and oxidants. The roGFP1 probe reports that the matrix space in HeLa cell mitochondria is highly reducing, with a midpoint potential near -360 mV (assuming mitochondrial pH approximately 8.0 at 37 degrees C). In other work (C. T. Dooley, T. M. Dore, G. Hanson, W. C. Jackson, S. J. Remington, and R. Y. Tsien, submitted for publication), it is shown that the cytosol of HeLa cells is also unusually reducing but somewhat less so than the mitochondrial matrix.     

Analysis of DsRed Mutants. Space around the fluorophore accelerates fluorescence development.

Earlier mutagenesis of the red fluorescent protein drFP583, also called DsRed, resulted in a mutant named Fluorescent Timer (Terskikh, A., Fradkov, A., Ermakova, G., Zaraisky, A., Tan, P., Kajava, A. V., Zhao, X., Lukyanov, S., Matz, M., Kim, S., Weissman, I., and Siebert, P. (2000) Science 290, 1585--1588). Further mutagenesis generated variants with novel and improved fluorescent properties. The mutant called AG4 exhibits only green fluorescence. The mutant, called E5up (V105A), shows complete fluorophore maturation, eventually eliminating residual green fluorescence present in DsRed. Finally, the mutant, called E57 (V105A, I161T, S197A), matures faster than DsRed as demonstrated in vitro with purified protein and in vivo with recombinant protein expressed in Escherichia coli and Xenopus leavis. Comparative analysis of the mutants in the context of the crystal structure of DsRed suggests that mutants with free space around the fluorophore mature faster and more completely.     

Noninvasive Measurement of Bacterial Intracellular pH on a Single-Cell Level with Green Fluorescent Protein and Fluorescence Ratio Imaging Microscopy

We show that a pH-sensitive derivative of the green fluorescent protein, designated ratiometric GFP, can be used to measure intracellular pH (pH_i) in both gram-positive and gram-negative bacterial cells. In cells expressing ratiometric GFP, the excitation ratio (fluorescence intensity at 410 and 430 nm) is correlated to the pH_i, allowing fast and noninvasive determination of pH_i that is ideally suited for direct analysis of individual bacterial cells present in complex environments.     

Binding of quercetin with human serum albumin: a critical spectroscopic study

Flavonols are plant pigments that are ubiquitous in nature. Quercetin (3,3',4',5,7-pentahydroxyflavone) and other related plant flavonols have come into recent prominence because of their usefulness as anticancer, antitumor, anti-AIDS, and other important therapeutic activities of significant potency and low systemic toxicity. Quercetin is intrinsically weakly fluorescent in aqueous solution, showing an emission maximum at approximately 538 nm. Upon binding to human serum albumin (HSA), quercetin undergoes dramatic enhancement in its fluorescence emission intensity, along with the appearance of dual emission behavior, consisting of normal and excited-state proton transfer (ESPT) fluorescence. In addition, the occurrence of a third emitting species has been noted for the first time. This is attributed to a electronic ground-state complex formed in the protein environment. High values of the fluorescence anisotropy (r) are obtained in the presence of HSA for the ESPT tautomer (r = 0.18), as well as the complex species (r = 0.37) of quercetin, indicating that the precursor ground-state molecules for both these emitting species of quercetin molecules are located in the motionally constrained sites of HSA. The steady-state emission data suggest that quercetin binds to two distinct sites in HSA from which the emissions from the normal tautomer and complex species take place. The preliminary results of studies on emission decay kinetics are also reported herein. Studies by far-UV circular dichroism spectroscopy reveal that binding of quercetin induces no significant perturbation in the secondary structure of HSA.     

Structural and spectral response of green fluorescent protein variants to changes in pH

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria has become a useful tool in molecular and cell biology. Recently, it has been found that the fluorescence spectra of most mutants of GFP respond rapidly and reversibly to pH variations, making them useful as probes of intracellular pH. To explore the structural basis for the titration behavior of the popular GFP S65T variant, we determined high-resolution crystal structures at pH 8.0 and 4.6. The structures revealed changes in the hydrogen bond pattern with the chromophore, suggesting that the pH sensitivity derives from protonation of the chromophore phenolate. Mutations were designed in yellow fluorescent protein (S65G/V68L/S72A/T203Y) to change the solvent accessibility (H148G) and to modify polar groups (H148Q, E222Q) near the chromophore. pH titrations of these variants indicate that the chromophore pKa can be modulated over a broad range from 6 to 8, allowing for pH determination from pH 5 to pH 9. Finally, mutagenesis was used to raise the pKa from 6.0 (S65T) to 7.8 (S65T/H148D). Unlike other variants, S65T/H148D exhibits two pH-dependent excitation peaks for green fluorescence with a clean isosbestic point. This raises the interesting possibility of using fluorescence at this isosbestic point as an internal reference. Practical real time in vivo applications in cell and developmental biology are proposed.     

Ultrafast excited-state dynamics in the green fluorescent protein variant S65T/H148D. 2. Unusual photophysical properties

In the preceding accompanying paper [Shu, X., et al. (2007) Biochemistry 46, 12005-12013], the 1.5 A resolution crystal structure of green fluorescent protein (GFP) variant S65T/H148D is presented, and the possible consequences of an unusual short hydrogen bond (相似文献   

Green fluorescent protein as a noninvasive intracellular pH indicator.

It was found that the absorbance and fluorescence of green fluorescent protein (GFP) mutants are strongly pH dependent in aqueous solutions and intracellular compartments in living cells. pH titrations of purified recombinant GFP mutants indicated >10-fold reversible changes in absorbance and fluorescence with pKa values of 6.0 (GFP-F64L/S65T), 5.9 (S65T), 6.1 (Y66H), and 4.8 (T203I) with apparent Hill coefficients of 0.7 for Y66H and approximately 1 for the other proteins. For GFP-S65T in aqueous solution in the pH range 5-8, the fluorescence spectral shape, lifetime (2.8 ns), and circular dichroic spectra were pH independent, and fluorescence responded reversibly to a pH change in <1 ms. At lower pH, the fluorescence response was slowed and not completely reversed. These findings suggest that GFP pH sensitivity involves simple protonation events at a pH of >5, but both protonation and conformational changes at lower pH. To evaluate GFP as an intracellular pH indicator, CHO and LLC-PK1 cells were transfected with cDNAs that targeted GFP-F64L/S65T to cytoplasm, mitochondria, Golgi, and endoplasmic reticulum. Calibration procedures were developed to determine the pH dependence of intracellular GFP fluorescence utilizing ionophore combinations (nigericin and CCCP) or digitonin. The pH sensitivity of GFP-F64L/S65T in cytoplasm and organelles was similar to that of purified GFP-F64L/S65T in saline. NH4Cl pulse experiments indicated that intracellular GFP fluorescence responds very rapidly to a pH change. Applications of intracellular GFP were demonstrated, including cytoplasmic and organellar pH measurement, pH regulation, and response of mitochondrial pH to protonophores. The results establish the application of GFP as a targetable, noninvasive indicator of intracellular pH.     

Catalytic strategy of citrate synthase: effects of amino acid changes in the acetyl-CoA binding site on transition-state analog inhibitor complexes.

Acetyl-CoA enol has been proposed as an intermediate in the citrate synthase (CS) reaction with Asp375 acting as a base, removing a proton from the methyl carbon of acetyl-CoA, and His274 acting as an acid, donating a proton to the carbonyl [Karpusas, M., Branchaud, B., & Remington, S.J. (1990) Biochemistry 29, 2213]. CS-oxaloacetate (OAA) complexes with the transition-state analog inhibitor, carboxymethyl-CoA (CMCoA), mimic those with acetyl-CoA enol. Asp375 and His274 interact intimately with the carboxyl of the bound inhibitor. While enzymes in which these residues have been changed to other amino acids have very low catalytic activity, we find that they retain their ability to form complexes with substrates and the transition-state analog inhibitor. In comparison with the value of the chemical shift of the protonated CMCoA carboxyl in acidic aqueous solutions or its value in the wild-type ternary complex, the values in the Asp375 mutants are unusually low. Model studies suggest that these low values result from complete absence of one hydrogen bond partner for the Gly mutant and distortions in the active site hydrogen bond systems for the Glu mutant. The high affinity of Asp375Gly-OAA for CMCoA suggests that the unfavorable proton uptake required to stabilize the CMCoA-OAA ternary complex of the wild-type enzyme [Kurz, L.C., Shah, S., Crane, B.R., Donald, L.J., Duckworth, H.W., & Drysdale, G.R. (1992) Biochemistry (preceding paper in this issue)] is not required by this mutant; the needed proton is most likely provided by His274. This supports the proposed role of His274 as a general acid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Noninvasive measurement of bacterial intracellular pH on a single-cell level with green fluorescent protein and fluorescence ratio imaging microscopy

We show that a pH-sensitive derivative of the green fluorescent protein, designated ratiometric GFP, can be used to measure intracellular pH (pHi) in both gram-positive and gram-negative bacterial cells. In cells expressing ratiometric GFP, the excitation ratio (fluorescence intensity at 410 and 430 nm) is correlated to the pHi, allowing fast and noninvasive determination of pHi that is ideally suited for direct analysis of individual bacterial cells present in complex environments.     

Fluorescent derivatives of the GFP chromophore give a new insight into the GFP fluorescence process

The photophysical properties of synthetic compounds derived from the imidazolidinone chromophore of the green fluorescent protein were determined. Various electron-withdrawing or electron-donating substituents were introduced to mimic the effect of the chromophore surroundings in the protein. The absorption and emission spectra as well as the fluorescence quantum yields in dioxane and glycerol were shown to be highly dependent on the electronic properties of the substituents. We propose a kinetic scheme that takes into account the temperature-dependent twisting of the excited molecule. If the activation energy is low, the molecule most often undergoes an excited-state intramolecular twisting that leads it to the ground state through an avoided crossing between the S(1) and S(0) energy surfaces. For a high activation energy, the torsional motion within the compounds is limited and the ground-state recovery will occur preferentially by fluorescence emission. The excellent correlation between the fluorescence quantum yields and the calculated activation energies to torsion points to the above-mentioned avoided crossing as the main nonradiative deactivation channel in these compounds. Finally, our results are discussed with regard to the chromophore in green fluorescent protein and some of its mutants.     

Molecular basis for pH sensitivity and proton transfer in green fluorescent protein: protonation and conformational substates from electrostatic calculations.

We performed a theoretical study to elucidate the coupling between protonation states and orientation of protein dipoles and buried water molecules in green fluorescent protein, a versatile biosensor for protein targeting. It is shown that the ionization equilibria of the wild-type green fluorescent protein-fluorophore and the internal proton-binding site E222 are mutually interdependent. Two acid-base transitions of the fluorophore occur in the presence of neutral (physiologic pH) and ionized (pH > 12) E222, respectively. In the pH-range from approximately 8 to approximately 11 ionized and neutral sites are present in constant ratio, linked by internal proton transfer. The results indicate that modulation of the internal proton sharing by structural fluctuations or chemical variations of aligning residues T203 and S65 cause drastic changes of the neutral/anionic ratio-despite similar physiologic fluorophore pK(a) s. Moreover, we find that dipolar heterogeneities in the internal hydrogen-bond network lead to distributed driving forces for excited-state proton transfer. A molecular model for the unrelaxed surrounding after deprotonation is discussed in relation to pathways providing fast ground-state recovery or slow stabilization of the anion. The calculated total free energy for excited-state deprotonation ( approximately 19 k(B)T) and ground-state reprotonation ( approximately 2 k(B)T) is in accordance with absorption and emission data (相似文献   

Ratiometric measurement of intracellular pH in cultured human keratinocytes using carboxy-SNARF-1 and flow cytometry

In this study we describe a method to measure intracellular pH in cultured human keratinocytes using flow cytometry. Keratinocytes pose a technical problem because the population is heterogeneous with respect to size and metabolic activity (nonspecific esterase activity), resulting in variability in dye uptake. In order to compensate for this, dyes were selected that change colour with pH. The ratio of fluorescence intensities at two wavelengths was recorded and used as a measure of intracellular pH by reference to the pH in the presence of the proton ionophore nigericin. However, methods published till now do not routinely combine the ratiometric technique and excitation with an argon ion laser set at 488 nm. Therefore we have tested the recently developed pH-sensitive dye carboxyseminaphthorhodafluor-1 (SNARF-1) as a possible candidate for flow cytometric pH measurements and compared it with 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein (BCECF) and 2,3-dicyanohydroquinone (DCH) with respect to emission spectra, resolution, range, and stability of cellular fluorescence. SNARF-1 had a practical and stable excitation wavelength of 488 nm rather than UV, it offered the possibility of ratiometric measurements on the basis of a real emission shift, and had superior resolution for the pH range 7-8. With SNARF-1 we found that keratinocytes cultured under low serum conditions (0.2%) contain a higher proportion of cells with relatively low intracellular pH compared to high serum cultures (6%). Furthermore, pH changes were followed by changes in relative DNA content. These findings suggest that intracellular pH can be an early functional proliferation marker for human keratinocytes.     

The relationship between thermal stability and pH optimum studied with wild-type and mutant Trichoderma reesei cellobiohydrolase Cel7A.

The major cellulase secreted by the filamentous fungus Trichoderma reesei is cellobiohydrolase Cel7A. Its three-dimensional structure has been solved and various mutant enzymes produced. In order to study the potential use of T. reesei Cel7A in the alkaline pH range, the thermal stability of Cel7A was studied as a function of pH with the wild-type and two mutant enzymes using different spectroscopic methods. Tryptophan fluorescence and CD measurements of the wild-type enzyme show an optimal thermostability between pH 3.5-5.6 (Tm, 62 +/- 2 degrees C), at which the highest enzymatic activity is also observed, and a gradual decrease in the stability at more alkaline pH values. A soluble substrate, cellotetraose, was shown to stabilize the protein fold both at optimal and alkaline pH. In addition, unfolding of the Cel7A enzyme and the release of the substrate seem to coincide at both acidic and alkaline pH, demonstrated by a change in the fluorescence emission maximum. CD measurements were used to show that the five point mutations (E223S/A224H/L225V/T226A/D262G) that together result in a more alkaline pH optimum [Becker, D., Braet, C., Brumer, H., III, Claeyssens, M., Divne, C., Fagerstr?m, R.B., Harris, M., Jones, T.A., Kleywegt, G.J., Koivula, A., et al. (2001) Biochem. J.356, 19-30], destabilize the protein fold both at acidic and alkaline pH when compared with the wild-type enzyme. In addition, an interesting time-dependent fluorescence change, which was not observed by CD, was detected for the pH mutant. Our data show that in order to engineer more alkaline pH cellulases, a combination of mutations should be found, which both shift the pH optimum and at the same time improve the thermal stability at alkaline pH range.     

Dual‐color‐emitting green fluorescent protein from the sea cactus Cavernularia obesa and its use as a pH indicator for fluorescence microscopy

We isolated and characterized a green fluorescent protein (GFP) from the sea cactus Cavernularia obesa. This GFP exists as a dimer and has absorption maxima at 388 and 498 nm. Excitation at 388 nm leads to blue fluorescence (456 nm maximum) at pH 5 and below, and green fluorescence (507 nm maximum) at pH 7 and above, and the GFP is remarkably stable at pH 4. Excitation at 498 nm leads to green fluorescence (507 nm maximum) from pH 5 to pH 9. We introduced five amino acid substitutions so that this GFP formed monomers rather than dimers and then used this monomeric form to visualize intracellular pH change during the phagocytosis of living cells by use of fluorescence microscopy. The intracellular pH change is visualized by use of a simple long‐pass emission filter with single‐wavelength excitation, which is technically easier to use than dual‐emission fluorescent proteins that require dual‐wavelength excitation. Copyright © 2013 John Wiley & Sons, Ltd.