Concatenation of cyan and yellow fluorescent proteins for efficient resonance energy transfer

Highly efficient fluorescence resonance energy transfer between cyan(CFP) and yellow fluorescent proteins (YFP), the cyan- and yellow-emitting variants of the Aequorea green fluorescent protein, respectively, was achieved by tightly concatenating the two proteins. After the C-terminus of CFP and the N-terminus of YFP were truncated by 11 and 5 amino acids, respectively, the proteins were fused through a leucine-glutamate dipeptide. The resulting chimeric protein, which we called Cy11.5, exhibited a simple emission spectrum that peaked at 527 nm when the protein was excited at 436 nm. The time-resolved emission of Cy11.5 was measured using a streak camera. After excitation of Cy11.5 with a 400 nm ultrashort pulse, a fast decay of the CFP emission and a concomitant rise of the YFP emission were observed with a lifetime of 66 ps. By contrast, the emission from CFP alone showed a decay component with a lifetime of 2.9 ns. We concluded that in fully folded Cy11.5 molecules, intramolecular FRET occurred with an efficiency of 98%. Importantly, most Cy11.5 molecules were properly folded, and the protein was highly resistant to all of the tested proteases. In living cells, therefore, Cy11.5 behaved as a single fluorescent protein with a broad excitation spectrum. Moreover, Cy11.5 was used as an optical highlighter after photobleaching of YFP. When HeLa cells expressing Cy11.5 were irradiated at 514.5 nm, a 10-fold increase in the 475 nm fluorescence intensity was observed. These features make Cy11.5 useful as an optical highlighter and a new-colored fluorescent protein for multicolor imaging.     

Physical characterization of cyclosporine binding sites in lymphocytes.

The binding of cyclosporine to human peripheral blood lymphocytes (PBLs) was studied by measuring the fluorescence emission spectrum and lifetime of the fluorescent and immunosuppressive cyclosporine derivative dansyl-cyclosporine (DCs). The emission maximum and fluorescence lifetime of DCs were characterized in several solvents. The fluorescence emission maximum and lifetime of DCs increased at a high dielectric constant. The fluorescence lifetime decay curve of DCs was a monoexponential function in all solvents tested. Fluorescence micrographs of lipid vesicles and erythrocytes labeled with DCs exhibit uniform staining patterns, whereas PBLs show heterogeneous DCs labeling. DCs exhibits a relatively low emission maximum (490 nm) in erythrocyte membranes. Such an emission maximum is characteristic of a hydrophobic environment. DCs in PBLs also has a low emission maximum (484 nm). The lifetime of DCs in PBLs required two exponential terms to properly fit the lifetime decay curve and could not be attributed to light scattering. One short component (4.7 +/- 1.0 ns) and a second long component (18.5 +/- 1.0 ns) were resolved from the DCs fluorescence decay curves. Time-resolved anisotropy of DCs in PBLs revealed that the labeled drug was present in an anisotropic environment, consistent with at least some DCs being bound to a membrane. These fluorescence studies suggest that DCs interacts with multiple and/or heterogeneous sites in peripheral blood lymphocytes.     

Isolation of nuclei from epidermis cells of larvae of the blowfly Calliphora vicina R.-D

Rapid microspectrofluorometry has been used to evaluate 1-pyrene-butyric acid as an oxygen probe in single living EL2 ascites tissue culture cells. Despite instrumental conditions preventing detection of the pyrene butyric acid maxima at 380 and 400 nm, the probe having penetrated the cell can be easily identified (maximum around 440 nm in unconnected spectra) from the fluorescence emission spectrum, as compared with NAD(P)H emission in controls (maximum around 460 nm). Fluorescence changes during gradually increasing anaerobiosis under nitrogen flow, are compatible with a linear relationship between the reciprocal of the fluorescence intensity and the intracellular oxygen concentration (increase in 430, 434, 442/461 nm ratios at anaerobiosis). The cells having absorbed the probe continue to catabolize glycolytic substrate, but some inhibition is noticeable (e.g. from the amplitude of the NAD(P)H fluorescence increase spectrum due to intracellular addition of glucose-6-P). In principle rapid microspectrofluorometry allows a multiprobe (e.g. 1-pyrene-butyric acid for oxygen, vs NAD(P)H for metabolism) exploration of the living cell.     

The interaction of the anionic fluorescence probe, 1-anilinonaphthalene-8-sulfonate, with hepatocytes and hepatoma tissue culture cells

The fluorescence probe 1-anilinonaphthalene-8-sulfonate (ANS) has been used to characterize the anion transport properties of normal hepatocytes and hepatoma tissue culture cells. Incubation of hepatocytes in the presence of ANS (20 micron) resulted in a 35-fold enhancement of fluorescence and a 50 nm blue shift. The time course of this process is biphasic. A rapid initial fluorescence enhancement suggests ANS binding to the plasma membrane, and a slower component reflects the uptake of ANS into intracellular compartments. Analysis of ANS uptake showed this latter process to be saturable, with a Km of 10 micron, to be temperature dependent and to occur only in viable cells. The above observations suggest a carrier-mediated anion transport mechanism. Incubation of hepatoma tissue culture cells with ANS (20 micron) gave a fluorescence emission spectrum similar to that obtained from purified plasma membranes. The kinetics of this interaction only exhibited a rapid initial binding of ANS. The second slow component was now absent, suggesting that ANS transport by the malignant cell system was greatly reduced. Transport of ANS could, however, be stimulated in the presence of the local anesthetic tetracaine. The observed transport was now saturable, temperature dependent, and as in normal hepatocytes, required viable cells, again indicating a carrier-mediated transport system. These studies suggest a significant alteration in membrane function in hepatoma tissue culture cells resulting in a major defect in anion transport.     

Nanosecond pulse fluorometry of conformational change in phenylalanine hydroxylase associated with activation

Conformational change in rat liver phenylalanine hydroxylase associated with activation by phenylalanine or N-(1-anilinonaphth-4-yl)maleimide was investigated by measuring fluorescence spectra and fluorescence lifetimes of tryptophanyl residues as well as the probe fluorophore conjugated with SH groups of the hydroxylase. The fluorescence spectrum of tryptophan exhibited its maximum at 342 nm. It shifted by 8 nm toward longer wavelength accompanied by an increase in its intensity, by preincubation with 1 mM phenylalanine. The fluorescence intensity of tryptophan increased by 36% upon the activation. On the other hand, the binding of (6R)-L-erythro-tetrahydrobiopterin, a natural cofactor of the enzyme, induced a decrease in the fluorescence intensity by 79% without a shift of the maximum wavelength. The fluorescence lifetime of tryptophan of phenylalanine hydroxylase exhibited two components with lifetimes of 1.7 and 4.1 ns. The values of the lifetimes changed to 1.4 and 5.6 ns, respectively, upon the activation. It is considered that the change in the longer lifetime is correlated with the shift of the emission peak upon the activation. The values of both the lifetimes decreased to 0.64 and 3.6 ns upon the binding of (6R)-L-erythro-tetrahydrobiopterin, which is coincident with the decrease in the fluorescence intensity. Conjugation of N-(1-anilinonaphth-4-yl)maleimide with SH of phenylalanine hydroxylase brought about a decrease in both the fluorescence intensity and the value of the shorter lifetime of the tryptophanyl residues, while the longer lifetime remained unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies with a fluorescent vital probe for DNA in mammalian cells

Olivomycin is taken up efficiently by HeLa cells and by rat fibroblast cells at 38.5 °C, but not by BHK cells. On irradiation with light of 425 nm wavelength, the nuclei of living cells that have taken up olivomycin fluoresce. When olivomycin complexes with DNA in solution, the emission spectrum broadens and shifts, the excitation wavelength maximum shifts up 15 nm, and the fluorescence polarization increases. In HeLa and fibroblast cells, the fluorescence characteristics indicate that olivomycin is entirely complexed to DNA, and its rotational mobility indicates that it is complexed to DNA in regions where other components of the chromatin offer no steric hindrance.     

Resolution of Fluorescence Emission Spectra with Various Lifetime Components of D1/D2/Cyt b-559

PS Ⅱ reaction center D1/D2/Cyt b-559 purified from chloroplasts of spinach has four components of fluorescence decaying with lifetimes of 1.0 ns, 5.9 ns,24 ns,and 73 ns whose fractions to total fluorescence yield are 0. 05,0.34,0. 35 and 0.26 respectively. The fluorescence emission spectra of these lifetime components are closely overlapping, and only one peak is shown in steady state emission spectrum. Based on the hardware analysis of phase fluorometry,by selection of the detector phase angle,the emission from various components could be individually suppressed. If the 5.9 ns component was suppressed, the emission spectrum was red-shifted. On the contrary, the emission spectrum was blue-shifted when 73 ns component was suppressed. Based on the software analysis, the individual emission spectra were resolved with three lifetime components by measuring phase and modulation data at various wavelength. Compared with steady state spectrum,the emission maximum wavelength of 5.9 ns component was blue-shifted from 68nm to 680 nm,but those of 24 ns and 73 ns components were red-shifted to 685 nm and 683 nm respectively.     

Cycloheptaamylose-dansyl chloride complex as a fluorescent label of surface membranes in living ciliates

Labelling of surface membrane of living ciliates: Paramecium aurelia and Tetrahymena pyriformis with fluorescent compound--cycloheptaamylose-dansyl chloride complex (CDC) has been achieved. Fluorescence micrographs of the dried samples showed specific localization of CDC on the cell membrane without any intracellular penetration. On the contrary the ciliates which have been dead during labelling revealed a non-specific fluorescence of their whole bodies. Microspectrofluorimetric analysis of labelled Paramecium cells was performed with Leitz microspectrograph. Spectrum of fluorescence emission measured over the cell membrane level had maximum at 450 nm. Strikingly, the emission maximum of the cells dead at the moment of labelling was shifted 10 nm to a longer wavelength. The rate of photofading measured in this case was almost 3-fold higher than for the ciliates labelled as living ones. Fluorescence excitation spectra did not show any difference in the peak position. Thus CDC staining appears to be an useful method of supravital labelling of cell surface enabling also to distinguish--on the basis of spectral characteristics--the ciliates being alive from those dead at the moment of fluorochrome binding.     

In Situ Activity of Suspended and Immobilized Microbial Communities as Measured by Fluorescence Lifetime Imaging

In this study, the feasibility of fluorescence lifetime imaging (FLIM) for measurement of RNA:DNA ratios in microorganisms was assessed. The fluorescence lifetime of a nucleic acid-specific probe (SYTO 13) was used to directly measure the RNA:DNA ratio inside living bacterial cells. In vitro, SYTO 13 showed shorter fluorescence lifetimes in DNA solutions than in RNA solutions. Growth experiments with bacterial monocultures were performed in liquid media. The results demonstrated the suitability of SYTO 13 for measuring the growth-phase-dependent RNA:DNA ratio in Escherichia coli cells. The fluorescence lifetime of SYTO 13 reflected the known changes of the RNA:DNA ratio in microbial cells during different growth phases. As a result, the growth rate of E. coli cells strongly correlated with the fluorescence lifetime. Finally, the fluorescence lifetimes of SYTO 13 in slow- and fast-growing biofilms were compared. For this purpose, biofilms developed from activated sludge were grown as autotrophic and heterotrophic communities. The FLIM data clearly showed a longer fluorescence lifetime for the fast-growing heterotrophic biofilms and a shorter fluorescence lifetime for the slow-growing autotrophic biofilms. Furthermore, starved biofilms showed shorter lifetimes than biofilms supplied with glucose, indicating a lower RNA:DNA ratio in starved biofilms. It is suggested that FLIM in combination with SYTO 13 represents a useful tool for the in situ differentiation of active and inactive bacteria. The technique does not require radioactive chemicals and may be applied to a broad range of sample types, including suspended and immobilized microorganisms.     

Discrimination of depolarized from polarized mitochondria by confocal fluorescence resonance energy transfer

Mitochondrial depolarization promotes apoptotic and necrotic cell death and possibly other cellular events. Polarized mitochondria take up cationic tetramethylrhodamine methylester (TMRM), which is released after depolarization. Thus, TMRM does not label depolarized mitochondria. To identify both polarized and depolarized mitochondria in living cells, cultured rat hepatocytes, and sinusoidal endothelial cells were co-loaded with green-fluorescing MitoTracker Green FM (MTG) and red-fluorescing TMRM for imaging by laser scanning confocal microscopy. Like TMRM, MTG is a cationic fluorophore that accumulates electrophoretically into polarized mitochondria. Unlike TMRM, MTG binds covalently to intramitochondrial protein thiols and remains bound after depolarization. In cells labeled only with MTG, excitation with blue (488 nm) light yielded green but almost no red fluorescence. After subsequent loading with TMRM, green MTG fluorescence became quenched. Instead, blue excitation yielded red fluorescence. Mitochondrial de-energization restored green fluorescence and abolished red fluorescence. Conversely, when MTG was added to TMRM-labeled cells, red fluorescence excited by blue light was enhanced, an effect again reversed by de-energization. These observations of reversible quenching of donor fluorescence and augmentation of acceptor fluorescence signify fluorescence resonance energy transfer (FRET). In undisturbed hepatocytes, spontaneous depolarization of a subfraction of mitochondria was an ongoing phenomenon. In conclusion, confocal FRET discriminates individual depolarized mitochondria against a background of hundreds of polarized mitochondria.     

FLIM and emission spectral analysis of caspase-3 activation inside single living cell during anticancer drug-induced cell death

Two-photon excitation (TPE) fluorescence lifetime imaging microscopy (FLIM) and emission spectral imaging (ESI) are powerful tools for fluorescence resonance energy transfer (FRET) measurement. In this study, we use these two techniques to analyze caspase-3 activation inside single living cells during anticancer drug-induced human lung adenocarcinoma (ASTC-a-1) cell death. TPE-ESI of SCAT3, a caspase-3 indicator based on FRET, was performed inside single living cell stably expressing SCAT3. The TPE-ESI measurement was performed using 780 nm excitation which was considered to selectively excite the donor ECFP of SCAT3 by measuring the emission ratio of 526 to 476 nm. The emission peak at 526 nm disappeared and that of 476 nm increased after STS or bufalin treatment, but taxol treatment did not induce a significant change for the SCAT3 emission spectra, indicating that caspase-3 was activated during STS- or bufalin-induced cell apoptosis, but was not involved in taxol-induced PCD. Fluorescence lifetime of ECFP inside living cells was acquired using FLIM. The lifetime of ECFP was the same as that of the control group after taxol treatment, but increased from 1.83 ± 0.02 to 2.05 ± 0.03 and 1.90 ± 0.03 ns, respectively after STS and bufalin treatment, which agree with the results obtained using TPE-ESI. Taken together, TPE-FLIM and ESI analysis were proved to be valuable approaches for monitoring caspase-3 activation inside single living cells. W. Pan and J. Qu contributed equally to this study.     

菠萝叶片PEP羧激酶与底物结合时构象的变化

菠萝叶片PEP羧激酶与底物OAA和ATP及配基Mn~(2+)等结合时引起紫外差示吸收光谱峰位和方向上的变化。OAA与酶结合诱导产生的差示吸收光谱在268—280nm处有一个宽负峰。ATP与酶结合出现两个差示负峰(242.5和273.5nm)。双底物OAA和ATP同时与酶结合,光谱上呈现252nm和268nm两个峰。Mn~(2+)不论与ATP或与ATP+OAA一起与酶反应时,皆使原来的峰位漂移,且正负方向逆转。酶蛋白在323nm有最大的荧光发射。OAA引起荧光发射强度增大,ATP及ATP+Mn~(2+)则减弱荧光发射。Mn~(2+)与OAA及ATP的复合效应导致荧光强度进一步减弱。     

Physicochemical characterization of bovine retinal arrestin

The native conformation of bovine retinal arrestin has been characterized by a variety of spectroscopic methods. The purified protein gives rise to a near uv absorption band centered at 279 nm which results from the absorbance of its 14 tyrosine and one tryptophan residue. The extinction coefficient for this absorption band was determined to be 38.64 mM-1, cm-1 using the tyrosinate-tyrosine difference spectrum method; this extinction coefficient is ca. 17% lower than the previously reported value, and provides estimates of protein concentration which are in good agreement with estimates from the Bradford colorimetric assay. When native arrestin is purified to homogeneity, it displays a fluorescence spectrum which is dominated by tyrosine emission with no discernible contribution from tryptophan. Observation of the tyrosine-like fluorescence is dependent on the purity and structural integrity of the protein. Denaturation of arrestin by guanidine hydrochloride results in a diminution of tyrosine fluorescence and the concomitant appearance of a second fluorescence maximum at ca. 340 nm, presumably due to the single tryptophan residue. Thermal denaturation of arrestin leads to a conformation characterized by a broad fluorescence band centered at ca. 325 nm. Study of the arrestin fluorescence spectrum as a function of temperature indicates that the thermal denaturation is well modeled as a two-state transition with a transition midpoint of 60 degrees C. Temperature-dependent far uv circular dichroism studies indicate that changes in secondary structure occur coincident with the change in fluorescence. Studies of the temperature dependence of arrestin binding to light-adapted phosphorylated rhodopsin shows a strong correlation between the fluorescence spectral features of arrestin and its ability to bind rhodopsin. These data suggest that the relative intensities of tyrosine and tryptophan fluorescence are sensitive to the structural integrity of the native (i.e., rhodopsin binding) state of arrestin, and can thus serve as useful markers of conformational transitions of this protein. The lack of tryptophan fluorescence for native arrestin suggests an unusual environment for this residue. Possible mechanisms for this tryptophan fluorescence quenching are discussed.     

Synthesis and properties of a fluorescent derivative of phosphatidylcholine

1-acyl-2-(N-4-nitrobenzo-2-oxa-1,3-diazole)-aminocaproyl phosphatidyl choline, (NBD-PC) was prepared by alkylation of ?-amino caproic acid with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-C1), followed by esterification of lysophosphatidylcholine. The compound was purified by silicic acid chromatography, and exhibited a single spot on thin layer chromatography using acidic, basic and neutral solvent systems, when visualized by UV, molybdate spray, primuline, or charring. The UV-visible absorption spectrum, and the uncorrected fluorescence excitation spectrum of NBD-PC in absolute ethanol showed maxima at approximately 340 and 460 nm, while the fluorescence emission spectrum showed a single peak at 525 nm. Fluorescence intensity and emission maximum wavelength of NBD-PC are strongly dependent on solvent dielectric constant, and the relative fluorescent intensity of NBD-PC in absolute ethanol is directly proportional to its concentration from 1 ng/ml to approximately 3 μg/ml. Incorporation of NBD-PC into membranes of human lymphocytes cultures in the presence or absence of phytohemagglutinin (PHA) resulted in a marked increase in the relative fluorescent intensity of the bound fluorochrome, and a 15 nm blue shift in its emission maximum wavelength. Fluorescence titration data indicate that the unstimulated lymphocytes bound 912 pmoles NBD-PC/mg protein with an association constant of 3.45 × 10⁷ M, while the PHA stimulated cells bound 1200 pmoles NBD-PC/mg protein with an association constant of 2.82 × 10⁷ M. The temperature dependence of the fluorescent intensity of NBD-PC incorporated in control, and PHA stimulated lymphocytes showed discontinuities at 15 and 24 °C respectively. Fluorescence polarization of NBD-PC incorporated in the membranes of stimulated lymphocytes was greater than the polarization of the fluorochrome in non-stimulated cells, suggesting that the plasma membranes of PHA stimulated lymphocytes contain regions of higher microviscosity.     

Fluorescence spectra of Hoechst 33258 bound to chromatin

Fluorescence spectra of Hoechst 33258 bound to rat thymocytes were measured by flow cytometry. At low dye concentrations (less than or equal to 2 micrograms/ml) the fluorescence maximum was situated at 460 nm irrespective of solvent composition. With higher dye concentrations the fluorescence maximum was shifted upwards, the intensity decreased and the width of the fluorescence peak increased. Linear combinations of a spectrum obtained at a low dye concentration (0.5 microgram/ml, type 1 binding) and one obtained at a high dye concentration (42.4 micrograms/ml, type 2 binding) failed to reproduce spectra measured at intermediate dye concentrations (0.15 M NaCl). Hence, Hoechst 33258 forms at least three different fluorescing complexes with DNA in chromatin. The shift in the fluorescence maximum of the Hoechst 33258/chromatin complex towards higher wavelengths decreased with ionic strength. 25% ethanol in the 0.15 M NaCl staining buffer reduced the wavelength shift at high dye concentrations, indicating that the strength of type 2 binding depends on DNA conformation in addition to ionic strength. The fluorescence spectrum was independent of whether DNA in chromatin was complexed with histones or not. However, histone-depleted thymocytes fluoresced more intensely than cells in which DNA was complexed with histones, the difference being greater at low concentrations of Hoechst 33258. Hence, type 2 binding to DNA in chromatin appears to be less restricted by histones than type 1 binding.     

Cycloheptaamylose-dansyl chloride complex as a fluorescent label of surface membranes in living ciliates

Summary Labelling of surface membrane of living ciliates: Paramecium aurelia and Tetrahymena pyriformis with fluorescent compound — cycloheptaamylose-dansyl chloride complex (CDC) has been achieved. Fluorescence micrographs of the dried samples showed specific localization of CDC on the cell membrane without any intracellular penetration. On the contrary the ciliates which have been dead during labelling revealed a non-specific fluorescence of their whole bodies. Microspectrofluorimetric analysis of labelled Paramecium cells was performed with Leitz microspectrograph. Spectrum of fluorescence emission measured over the cell membrane level had maximum at 450 nm. Strikingly, the emission maximum of the cells dead at the moment of labelling was shifted 10 nm to a longer wavelength. The rate of photofading measured in this case was almost 3-fold higher than for the ciliates labelled as living ones. Fluorescence excitation spectra did not show any difference in the peak position. Thus CDC staining appears to be an useful method of supravital labelling of cell surface enabling also to distinguish — on the basis of spectral characteristics — the ciliates being alive from those dead at the moment of fluorochrome binding.     

Autofluorescence of intact Equisetum arvense L. spores during their development

The autofluorescence of horsetail Equisetum arvense spores excited with UV-light of 360-380 nm was studied by microspectrofluorimetry during their development from an individual cell to the formation of a multicellular thallus with the generative organs. The investigation involved the registration of the fluorescence spectra of individual intact developing cells and the measurement of the ratio of cell fluorescence intensities in the blue and red regions of the spectrum. Dry blue-fluorescing microspores showed the maxima at 460 and 530 nm and a small maximum at 680 nm. Thirty minutes after moistening in water, red-fluorescing cells arose among blue-fluorescing microspores, indicating the onset of development. Red fluorescence with a maximum at 680 nm enhanced as cells put off their cover, which brightly fluoresced in the blue region of the spectrum with the main maximum at 460 nm. By estimating the ratio of autofluorescence intensities in the blue region of the spectrum to red lightening of microspores at the first stages of development up to 24 h (in particular, their first division, the formation of nonfluorescencing rhizoid, etc.), nonviable (only blue-lightening) cells were distinguished from viable cells, in which red fluorescence began to prevail. After 25-40 days of development, the gametophyte fluorescing mainly at 680 nm formed male organs, antheridia, with blue-green-fluorescing spermatozoids. Then female generative organs archegonia with the egg cell appeared, which fluoresced blue, whereas the surrounding cells fluoresced red. It was supposed that the lightening in the blue and green regions of the spectrum is due to the presence of phenols, terpenoids, and azulenes, whereas the emission in the red region is associated with the presence of chlorophyll and azulenes. The observation of autofluorescence makes it possible to easily distinguish generative cells without additional staining.     

Hydrophobic interaction of isoprenic coumarin ostruthin with nonphosphorylating mitochondrial fragments

New emission maximum at 395 nm appeared in the fluorescence spectrum of ostruthin (6-geranyl-7-hydroxycoumarin) when allowed to interact with Keilin-Hartree preparation. Incubation of Keilin-Hartree preparation with umbelliferone (7-hy-droxycoumarin) did not result in any changes in its fluorescence spectrum. Different changes were observed in the fluorescence spectrum of ostruthin at incubation with bovine serum albumin, which suggest a different nature of interaction. Changes in pH or viscosity influenced the intensity, but the emission maximum of the ostruthin fluorescence spectrum was either not or very little shifted. Increase in concentration of aliphatic alcohols induced similar changes in the fluorescence spectra of both coumarins as Keilin-Hartree preparation did in the case of ostruthin. This indicated the hydrophobic nature of interaction between ostruthin and Keilin-Hartree preparation.Preincubation of Keilin-Hartree preparation with sulfhydryl reagents did not alter the fluorescence response of ostruthin. Removing lipids from Keilin-Hartree preparation resulted in a decrease in the quantum yield of ostruthin fluorescence at 395 nm and in the maximum number of binding sites. On the other hand, mild extraction of neutral lipids with pentane retained the quantum yield unaltered. At least two types of binding sites are present in Keilin-Hartree preparation from which one includes phospholipids, the other probably proteins. The maximum number of binding sites (39–50 nmoles/mg protein) corresponds to the amount of ostruthin needed for uncoupling of rat liver mitochondria.     

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.     

A reversibly photoswitchable GFP-like protein with fluorescence excitation decoupled from switching

Photoswitchable fluorescent proteins have enabled new approaches for imaging cells, but their utility has been limited either because they cannot be switched repeatedly or because the wavelengths for switching and fluorescence imaging are strictly coupled. We report a bright, monomeric, reversibly photoswitchable variant of GFP, Dreiklang, whose fluorescence excitation spectrum is decoupled from that for optical switching. Reversible on-and-off switching in living cells is accomplished at illumination wavelengths of ～365 nm and ～405 nm, respectively, whereas fluorescence is elicited at ～515 nm. Mass spectrometry and high-resolution crystallographic analysis of the same protein crystal in the photoswitched on- and off-states demonstrate that switching is based on a reversible hydration/dehydration reaction that modifies the chromophore. The switching properties of Dreiklang enable far-field fluorescence nanoscopy in living mammalian cells using both a coordinate-targeted and a stochastic single molecule switching approach.