Spectrophotometric measurements of transmembrane potential and pH gradients in chromaffin granules

The electrical potential (delta psi) and proton gradient (alpha pH) across the membranes of isolated bovine chromaffin granules and ghosts were simultaneously and quantitatively measured by using the membrane- permeable dyes 3,3'dipropyl-2,2'thiadicarbocyanine (diS-C3-(5)) to measure delta psi and 9-aminoacridine or atebrin to measure delta pH. Increases or decreases in the delta psi across the granular membrane could be monitored by fluorescence or transmittance changes of diS-C3- (5). Calibration of the delta psi was achieved by utilization of the endogenous K+ and H+ gradients, and valinomycin or carbonyl cyanide-p- trifluoromethoxyphenylhydrazone (FCCP), respectively, with the optical response of diS-C3-(5) varying linearly with the Nernst potential for H+ and K+ over the range -60 to +90 mV. The addition of chromaffin granules to a medium including 9-aminoacridine or atebrin resulted in a rapid quenching of the dye fluorescence, which could be reversed by agents known to cause collapse of pH gradients. From the magnitude of the quenching and the intragranular water space, it was possible to calculate the magnitude of the alpha pH across the chromaffin granule membrane. The time-course of the potential-dependent transmittance response of diS-C3-(5) and the delta pH-dependent fluorescence of the acridine dyes were studied simultaneously and quantitatively by using intact and ghost granules under a wide variety of experimental conditions. These results suggest that membrane-permeable dyes provide an accurate method for the kinetic measurement of delta pH and delta psi in an amine containing subcellular organelle.     

The lysosomal proton pump is electrogenic

Lysosomes were purified approximately 40-fold from rat kidney cortex by differential and Percoll density gradient centrifugation. In a sucrose medium, the lysosomes quenched the fluorescence of the potential sensitive dye diS-C3-(5) (3,3'-dipropylthiocarbo-cyanine iodide) in a time-dependent manner, indicating that the dye accumulates within the lysosomal interior. After treatment of the lysosomes with valinomycin, the dye fluorescence displayed a logarithmic dependence upon the external K+ concentration; thus, the fluorescence signal provides a semiquantitative measure of the lysosomal membrane potential (delta psi). In the absence of valinomycin, lysosomal quenching of diS-C3-(5) fluorescence was partially reversed by agents which collapse the lysosomal pH gradient (ammonium sulfate, chloroquine, and K nigericin), suggesting that the proton gradient across the lysosomal membrane contributes to delta psi. A rapid increase in diS-C3-(5) fluorescence, indicative of an increase in delta psi, was observed upon the addition of Mg-ATP to the lysosomes. The ATP-dependent fluorescence change was inhibited by protonophores, K valinomycin, permeable anions, and N-ethylmaleimide, but was unaffected by ammonium sulfate, K nigericin, or sodium vanadate. Oligomycin had no effect at concentrations below 2 micrograms/ml; at higher concentrations, oligomycin partially inhibited the fluorescence response to Mg-ATP, but it also inhibited the fluorescence response to K valinomycin, suggesting that it had modified the permeability of the lysosomal membrane. Dicylohexylcarbodiimide behaved similarly to oligomycin. Mg-ATP also altered the lysosomal distribution of 86Rb+ (in the presence of valinomycin) and S[14C]CN-, consistent with an increase in the potential of the lysosomal interior of 40-50 mV. The results demonstrate that the lysosomal proton pump is electrogenic.     

Cyanine and safranine dyes as membrane potential probes in cytochrome c oxidase reconstituted proteoliposomes

Safranine and the cyanine dye, 3',3'-dipropylthiadicarbocyanine (diSC3-5), were examined as membrane potential probes in cytochrome c oxidase vesicles. The spectra of the vesicle-associated dyes resemble those of the same dyes in organic solvents, indicating that safranine and diSC3-5 probably dissolve in a hydrophobic region of the proteoliposomal membrane. This binding of safranine to proteoliposomes occurs with a dye-membrane dissociation constant in the micromolar range. The binding of safranine and of diSC3-5 to liposomes or proteoliposomes is accompanied by fluorescence enhancement. This enhanced fluorescence is quenched by respiration or by the establishment of a K+ diffusion potential by valinomycin (negative interior). An optimal dye/lipid ratio was required to secure maximum fluorescence quenching of the dyes, whether that quenching was active or passive. Calibrations of both the safranine and the diSC3-5 responses with K+ diffusion potentials were also affected by the dye/lipid ratio. At lower dye/lipid ratios, the calibration curve was linear at higher potentials but deviated from linearity at lower potentials. The converse was true at higher dye/lipid ratios. The non-linearity of the calibration curve at higher potential was attributed to a 'saturation' effect; it may also involve increased permeability of proteoliposomal membrane to protons. Destacking of dye at the lower dye/lipid ratio was probably responsible for the non-linearity of the calibration curves at lower potentials. When all these effects are taken into account, the steady-state value of delta psi generated during maximal proteoliposomal respiration was calculated to be between 140 and 160 mV (interior negative) when measured with either safranine or diSC3-5. We conclude that quantitative estimates of delta psi values can be made using these probes in cytochrome c oxidase reconstituted proteoliposomes provided that appropriate precautions are taken.     

Oxonol-v as a probe of chromaffin granule membrane potentials

The dye, oxonol-V (bis(3-phenyl-5-oxoisoxazol-4-yl)pentamethine oxonol), can be used to estimate the transmembrane potential of chromaffin granules. The potentials result either from a resting-state Donnan equilibrium (inside negative at pH 6.6) or from an ATP-driven proton pump. The fluorescence and absorption changes generated by ATP addition depended on the pH of the medium and the dye-to-vesicle ratio. Energization resulted in an increase in the number of oxonol-V binding sites, the new binding sites having the same dissociation constant. The rate of dye association was higher with resting than with energized chromaffin granules. The absorption change was associated with a red shift whereas the fluorescence change involved a quenching due to the increase in dye concentration on the membrane. The absorption and fluorescence changes varied linearly with the transmembrane potential difference when the interior potential was positive relative to the medium.     

Mitochondrial membrane potential in lymphocytes as monitored by fluorescent cation diS-C3-(5)

A lipophilic fluorescent cation diS-C3-(5) and rotenone suppress the oxygen consumption rate of thymocytes in similar concentrations. Seventy percent inhibition corresponds to an inhibitor:cytochrome a molar ratio of about 1:1. Addition of uncouplers decreases the inhibition of respiration by diS-C3-(5) (but not rotenone). FCCP in similar concentrations increases O2 consumption in the absence of diS-C3-(5) and the diS-C3-(5) fluorescence intensity in the presence of TMPD in thymocyte suspensions. In most thymocyte preparations, oligomycin (0.05-0.1 microgram/mL) increases the fluorescence of diS-C3-(5) and further addition of TMPD (50-100 microM) decreases the fluorescence. Addition of NaCN (400 microM) after oligomycin leads to a fluorescence increase that is hardly affected by subsequent addition of 0.2 microM FCCP. Nigericin (10-50 nM) decreases the diS-C3-(5) fluorescence. The data indicate that the diS-C3-(5) fluorescence associated with mitochondrial transmembrane potential (delta psi m) may be an essential part of the diS-C3-(5) fluorescence in lymphocyte suspensions. The changes of the diS-C3-(5) fluorescence intensity in the presence of TMPD after FCCP addition reflect delta psi m.     

Measurement of transmembrane potentials in Rhodospirillum rubrum chromatophores with an oxacarbocyanine dye

The fluorescent dye 3,3-dipentyloxacarbocyanine (OCC) can be used as a fluorescence probe to measure transmembrane potentials across Rhodospirillum ruburm chromatophore membranes. A reversible fluorescence increase is observed in the light which is sensitive to inhibitors, permeable ions and uncouplers.Partial interchangeability between the electrical potential and the proton concentration gradient has been demonstrated by measurement of the fluorescence increase with OCC and the fluorescence quenching with 9-aminoacridine.OCC fluorescence changes can be induced also in the dark by injection of permeable salts and by rapid pH changes presumably indicating diffusion potentials. Using salt-induced diffusion potentials for calibrating the light signals and with several assumptions, the light-induced potentials were estimated as 170 mV for the maximal signal and 90–110 mV at the steady state.OCC has been shown to apparently increase the electrical conductivity of the chromatophore membrane, a fact which may be relevant to the mechanism of action of this probe.A red shift in the OCC absorption spectrum occurs when mixed with chromatophores, with a difference spectrum maximum at 495 nm. The absorption changes at 495 nm taking place in the light are similar in kinetics to the fluorescence changes. The absorbance spectrum of OCC in organic solvents is red shifted and the extent of the shift depends on the hydrophobicity of the medium. The difference spectrum compared to water in sec-butyl $\text{acetate}\text{n-}\text{hexane}$ (3 : 1, v/v) with a dipole moment of 5 was nearly identical to that of chromatophore-associated dye.The uncoupling properties of OCC at high concentrations and some difficulties in calibration limit the usefulness of this probe for quantitative measurements of transmembrane potentials.     

Monitoring of real changes of plasma membrane potential by diS-C3(3) fluorescence in yeast cell suspensions

The fluorescent dye 3,3'-dipropylthiadicarbocyanine, diS-C(3)(3), is a suitable probe to monitor real changes of plasma membrane potential in yeast cells which are too small for direct membrane potential measurements with microelectrodes. A method presented in this paper makes it possible to convert changes of equilibrium diS-C(3)(3) fluorescence spectra, measured in yeast cell suspensions under certain defined conditions, into underlying membrane potential differences, scaled in the units of millivolts. Spectral analysis of synchronously scanned diS-C(3)(3) fluorescence allows to assess the amount of dye accumulated in cells without otherwise necessary sample taking and following separation of cells from the medium. Moreover, membrane potential changes can be quantified without demanding calibration protocols. The applicability of this approach was demonstrated on the depolarization of Rhodotorula glutinis yeast cells upon acidification of cell suspensions and/or by increasing extracellular K(+) concentration.     

Calibration of the calcium dissociation constant of Rhod(2)in the perfused mouse heart using manganese quenching

Both theoretical and experimental results are presented for in vivo calibration of the dissociation constant K(Ca)(d)of the calcium-sensitive fluorescent dye Rhod(2)in the perfused mouse heart, using manganese quenching of fluorescence transients. An analytical model is derived, based on the biochemical equilibrium of manganese competition with calcium for Rhod(2)binding. Expressing the differential of the changes between systole and diastole in fluorescence transient (delta Delta F(sys-dia)). delta DeltaF(sys-dia)in a beating heart as a function of the perfusate manganese concentration [Mn(2+)](p)allows correlation of the measured differential transient changes delta Delta F(sys-dia)with the calcium dissociation constant K(Ca)(d)of Rhod(2)and the calcium concentration in the heart. Numerical modeling indicates that the K(Ca)(d)predominantly affects the asymptotic slope of the delta Delta F(sys-dia)versus [Mn(2+)](p)curve at certain manganese concentrations, which suggests that the K(Ca)(d)can be inversely calculated by partially fitting the delta Delta F(sys-dia)distribution as a function of the perfusate manganese concentration. The feasibility of this approach is confirmed by quenching of calcium transients by manganese infusion into isolated perfused beating mouse hearts. The resulting calculated dissociation constant K(Ca)(d)of Rhod(2)is 720nM. Using the same approach, we are able to also estimate intracellular calcium concentrations of 700nM at peak systole and 300nM in diastole. This is in good agreement with values obtained by calibration of fluorescence values with a calcium saturation tetanization procedure in the same perfused mouse heart model.     

Effect of the Ca ionophore A-23187 on the plasmatic and mitochondrial potentials of the brain synaptosomes in rats: fluorescence measurements

The applicability of the potential-sensitive dye diS-C3-(5) for the study of A23187 + Ca2+ induced plasma membrane hyperpolarization was tested in rat brain synaptosomes. An appropriate dye synaptosome ratio was chosen for the fluorescence titration dye in Ca-free Krebs-Ringer solution. The fluorescence intensity of the probe was increased upon the addition of Ca2+ (1 microM) to the synaptosomes in the presence of A23187 (1 microM). The effect of Ca2+ + A23187 persisted in a Na+-free medium or when Na+ channels were inhibited by tetrodotoxin as well as in high K+-depolarized synaptosomes (75 microM KCl). In the presence of oligomycin or a protonophore (1 microM) the effect of Ca2+ + A23187 was suppressed. This suggests that the A23187-induced fluorescence increase is due to a depolarization of intrasynaptosomal mitochondria. Therefore, the use of the dye diS-C3-(5) for the study of Ca-induced hyperpolarization does not seem to be feasible unless a quantitative model of changes in fluorescence related to the plasma and mitochondrial membrane potentials is elaborated.     

Use of oxonol V as a probe of membrane potential in proteoliposomes containing cytochrome oxidase in the submitochondrial orientation

Absorbance changes in the anionic dye bis[3-phenyl-5-oxoisoxazol-4-yl]pentamethineoxonol (oxonol V) can be used to monitor the membrane potential of liposomes and cytochrome c containing cytochrome oxidase proteoliposomes (c-loaded COV). Diffusion potentials (positive inside the vesicles) cause an increase in the dye extinction, with a maximum at 640 nm. A similar increase is seen upon energization of internally facing cytochrome oxidase molecules in c-loaded COV. Both "passive" and "active" responses are only seen when the dye is fully bound to the vesicle membrane. Calibration curves using potassium or n-butyltriphenylphosphonium ion (BTPP+) diffusion potentials are linear up to 100 mV and pass through the origin. Diffusion potentials (positive inside) also cause an increase and red shift in the oxonol V fluorescence emission spectrum. However, potentials of the same sign induced by cytochrome oxidase turnover induce a large fluorescence quenching in c-loaded COV. A similar anomaly has been observed with submitochondrial particles [Smith, J. C., Russ, P., Cooperman, B. S., & Chance, B. (1976) Biochemistry 15, 5094-5105]. A model is proposed consistent with these responses. It is suggested that the dye molecules move further into the membrane phase upon energization, causing the absorbance increase. In the presence of active enzyme, anionic dye molecules are attracted to a positive dipole on each enzyme molecule, causing self-quenching of the fluorescence.     

Factors and processes involved in membrane potential build-up in yeast: diS-C3(3) assay.

No methods are currently available for fully reliable monitoring of membrane potential changes in suspensions of walled cells such as yeast. Our method using the Nernstian cyanine probe diS-C3(3) monitors even relatively fast changes in membrane potential delta psi by recording the shifts of probe fluorescence maximum lambda max consequent on delta psi-dependent probe uptake into, or exit from, the cells. Both increased [K+]out and decreased pHout, but not external NaCl or choline chloride depolarise the membrane. The major ion species contributing to the diS-C3(3)-reported membrane potential in S. cerevisiae are thus K+ and H+, whereas Na+ and Cl- do not perceptibly contribute to measured delta psi. The strongly pHout-dependent depolarisation caused by the protonophores CCCP and FCCP, lack of effect of the respiratory chain inhibitors rotenone and HQNO on the delta psi, as well as results obtained with a respiration-deficient rho- mutant show that the major component of the diS-C3(3)-reported membrane potential is the delta psi formed on the plasma membrane while mitochondrial potential forms a minor part of the delta psi. Its role may be reflected in the slight depolarisation caused by the F1F0-ATPase inhibitor azide in both rho- mutant and wildtype cells. Blocking the plasma membrane H(+)-ATPase with the DMM-11 inhibitor showed that the enzyme participates in delta psi build-up both in the absence and in the presence of added glucose. Pore-forming agents such as nystatin cause a fast probe entry into the cells signifying membrane damage and extensive binding of the probe to cell constituents reflecting obviously disruption of ionic balance in permeabilised cells. In damaged cells the probe therefore no longer reports on membrane potential but on loss of membrane integrity. The delta psi-independent probe entry signalling membrane damage can be distinguished from the potential-dependent diS-C3(3) uptake into intact cells by being insensitive to the depolarising action of CCCP.     

Lymphocyte membrane potential assessed with fluorescent probes

The membrane potential of mouse spleen lymphocytes has been assessed with two fluorescent probes. 3,3'-Dipropylthiadicarbocyanine (diS-C3-(5)) was used for most of the experiments. Solutions with high K+ concentrations depolarised the cells. Valinomycin, an inophore which adds a highly K+-selective permeability membranes, slightly hyperpolarised cells in standard (6 mM K+) solution, and in 145 mM K+ solution produced a slight additional depolarisation. These findings indicate a membrane whose permeability is relatively selective for K+. Very small changes in potential were seen when choline replaced Na+, or gluconate replaced Cl-, supporting the idea of K+ selectivity. The resting potential could be estimated from the K+ concentration gradient at which valinomycin did not change the potential-the "valinomycin null point" - and under the conditions used the resting potential was approx.-60 mV. B cell-enriched suspensions were prepared either from the spleens of nu/nu mice or by selective destruction of T cells in mixed cell populations. The membrane potential of these cells was similar to that estimated for the mixed cells. In solution with no added K+, diS-C3-(5) itself appeared to depolarise the lymphocytes, in a concentration dependent manner. With the 100 nM dye normally used, the membrane potential in K+-free solution was around -45 mV, and 500 nM dye almost completely depolarised the cells. In standard solution quinine depolarised the cells. Valinomycin could still depolarise these cells indicating that depolarisation had not been due to dissipation of the K+ gradient. Since in K+-free solution diS-C3-(5) blocks the Ca2+-activated K+ channels in human red blood cell ghosts and quinine also blocks this K+ channel it is suggested that the resting lymphocyte membrane may have a similar Ca2+-activated K+ permeability channel. Because of the above mentioned effect of diS-C3-(5) and other biological side effects, such as inhibition of B cell capping, a chemically distinct fluorescent probe of membrane potential, bis(1,3-diethylthiobarbiturate)-trimethineoxonol was used to support the diS-C3-(5) data. This new probe proved satisfactory except that it formed complexes with valinomycin, ruling out the use of this ionophore. Results with the oxonol on both mixed lymphocytes and B cell-enriched suspensions gave confirmation of the conclusions from diS-C3-(5) experiments and indicated that despite its biological side effects, diS-C3-(5) could still give valid assessment of membrane potential.     

Light-induced proton permeability changes in retinal rod photoreceptor disk membranes.

We have used the membrane-permeant charged fluorescent dye, 3,3'-dipropylthiadicarbocyanine iodide (diS-C3[5]), to monitor electrical potentials across the membranes of isolated bovine disks. Calibration curves obtained from experiments where a potential was created across the disk membrane by a potassium concentration gradient and valinomycin showed an approximately linear relation between dye fluorescence and calculated membrane potential from 0 to -120 mV. Light exposure in the presence of the permeant buffer, imidazole, caused a rapid decay of the membrane potential to a new stable level. Addition of CCCP, a proton ionophore, in the dark produced the same effect as illumination. When the permeant buffer, imidazole, was replaced by the impermeant buffer, Hepes, neither light nor CCCP discharged the gradient. We interpret the changes in membrane potential measured upon illumination to be the result of a light-induced increase in the permeability of the disk membrane to protons. A permeant buffer is required to prevent the build-up of a pH gradient which would inhibit the sustained proton flow needed for an observable change in membrane potential.     

Localization of cyanine dye binding to brush-border membranes by quenching of n-(9-anthroyloxy) fatty acid probes

The location and orientation of 3,3'-dipropylthiodicarbocyanine (diS-C3-(5)) binding sites in renal brush-border membrane vesicles was examined from the quenching of n-(9-anthroyloxy) fatty acid (n-AS) fluorescence. Based on previous kinetic studies (Cabrini, G. and Verkman, A.S. (1986) J. Membrane Biol. 90, 163-175) monomeric aqueous diS-C3-(5) binds to brush-border membrane vesicles (BBMV) by an initial 6 ms association to form bound monomer, a 30-40 ms equilibrium between bound monomer (M) and bound dimer (D), and a 1-1.3 s translocation of D from the outer to inner membrane leaflet. Based on Stern-Volmer and lifetime analyses, M and D quench the fluorescence of the n-AS probes by a collisional mechanism. At low [diS-C3-(5)]/[BBMV] (R), where M predominates, the n-AS quenching efficiencies (Q) are similar (n = 2-16); at high R, where D predominates, Q increases with n (16 greater than 12 much much greater than 6 greater than 2), suggesting that M is oriented parallel, and D perpendicular, to the phospholipid chains deep within the membrane. Mixture of diS-C3-(5) with brush-border membrane vesicles containing n-AS in a stopped-flow apparatus gave a biexponential fluorescence decrease (excitation 390 nm, emission above 450 nm) with time constants 30-40 ms and 1-1.5 s; there was no 6 ms quenching process. These findings are incorporated into a model in which diS-C3-(5) adheres loosely to the outer membrane surface in 6 ms, binds parallel to the membrane phospholipid in 30-40 ms, dimerizes and rotates by 90 degrees in much less than 30 ms, and translocates to the opposite half of the bilayer in 1-15 s.     

Ca2+-activated K+ conductance of human red cell membranes exhibits two different types of voltage dependence

The voltage dependence for outward-going current of the Ca-activated K+ conductance (gK(Ca] of the human red cell membrane has been examined over a wide range of membrane potentials (Vm at constant values of [K+]ex, [K+]c and pHc, the intact cells being preloaded to different concentrations of ionized calcium. Outward-current conductances were calculated from initial net effluxes of K+ and the corresponding (Vm - EK) values. The basic conductance, defined as the outward-current conductance at (Vm - EK) greater than or equal to 20 mV and [K+]ex greater than or equal to 3 mM (B. Vestergaard-Bogind, P. Stampe and P. Christophersen, J. Membrane Biol. 95:121-130, 1987) was found to be a function of cellular ionized Ca. At all degrees of Ca activation gK(Ca) was an apparently linear function of voltage (Vm range -40 to +70 mV), the absolute level as well as the slope decreasing with decreasing activation. In a simple two-state model the constant voltage dependence can, at the different degrees of Ca activation, be accounted for by a Boltzmann-type equilibrium function with an equivalent valence of approximately 0.4, assuming chemical equilibrium at Vm = 0 mV. Alternatively, the phenomenon might be explained by a voltage-dependent block of the outward current by an intracellular ion. Superimposed upon the basic conductance is the apparently independent inward-rectifying steep voltage function with an equivalent valence of approximately 5 and chemical equilibrium at the given EK value.     

Rhodamine 123 as a probe of transmembrane potential in isolated rat-liver mitochondria: spectral and metabolic properties

The spectral and metabolic properties of Rhodamine 123, a fluorescent cationic dye used to label mitochondria in living cells, were investigated in suspensions of isolated rat-liver mitochondria. A red shift of Rhodamine 123 absorbance and fluorescence occurred following mitochondrial energization. Fluorescence quenching of as much as 75% also occurred. The red shift and quenching varied linearly with the potassium diffusion potential, but did not respond to delta pH. These energy-linked changes were accompanied by dye uptake into the matrix space. Concentration ratios, in-to-out, approached 4000:1. A large fraction of internalized dye was bound. At concentrations higher than those needed to record these spectral changes, Rhodamine 123 inhibited ADP-stimulated (State 3) respiration of mitochondria (Ki = 12 microM) and ATPase activity of inverted inner membrane vesicles (Ki = 126 microM) and partially purified F1-ATPase (Ki = 177 microM). The smaller Ki for coupled mitochondria was accounted for by energy-dependent Rhodamine 123 uptake into the matrix. Above about 20 nmol/mg protein (10 microM), Rhodamine 123 caused rapid swelling of energized mitochondria. Effects on electron-transfer reactions and coupling were small or negligible even at the highest Rhodamine 123 concentrations employed. delta psi-dependent Rhodamine 123 uptake together with Rhodamine 123 binding account for the intense fluorescent staining of mitochondria in living cells. Inhibition of mitochondria ATPase likely accounts for the cytotoxicity of Rhodamine 123. At concentrations which do not inhibit mitochondrial function, Rhodamine 123 is a sensitive and specific probe of delta psi in isolated mitochondria.     

Comparative measurements of membrane potentials with microelectrodes and voltage-sensitive dyes

The usefulness of a new voltage-sensitive fluorescent dye, the membrane permeant negatively charged oxonol dye diBA-C4-(3)-, was evaluated by measuring the membrane potentials of BICR/M1R-k and L cells with glass microelectrodes and simultaneously recording the fluorescence of the stained cells. The membrane potential of BICR/M1R-k cells was varied between -25 mV and -90 mV by changing the bicarbonate concentration in the medium or by voltage clamping. To avoid any interference by the inserted electrodes with the fluorescence measurement of the cytoplasm, the cells were fused by polyethyleneglycol to form giant cells (homokaryons). These homokaryons also allowed penetration by two glass microelectrodes without causing a serious leakage of the plasma membrane. The slow responding dye diBA-C4-(3)- had a fluorescence response of about 1% per mV. Mathematical analysis of the fluorescence changes after voltage clamping revealed a first-order reaction with a rate constant between 0.1 min-1 and 0.8 min-1, depending on the cell size which was determined by the number of nuclei per homokaryon. A model for the mechanism of the fluorescence changes is proposed.     

Characterization of two quenchers of chlorophyll fluorescence with different midpoint oxidation-reduction potentials in chloroplasts.

The properties of two redox quenchers of chlorophyll fluorescence in chloroplasts at room temperature have been investigated. (1) Redox titration of the fluorescence yield reveals two n = 1 components with Em7.8 at--45 and --247 mV, accounting for approx. 70 and 30% of the total yield, respectively. (2) Neutral red, a redox mediator often used at redox potentials below --300 mV, preferentially quenches the fluorescence controlled by the --247 mV component. Titrations using neutral red artifactually create an n = 2 quenching component with Em7.8 = --375 mV. (3) Analysis of fluorescence induction curves recorded at different redox potentials indicates that both the --45 and --247 mV components can be photochemically reduced. The reduction of the --247 mV component corresponds to a fast phase of the induction curve whilst the slower reduction of the 45 mV component accounts for the tail phase. (4) The excitation spectra for the fluorescence controlled by the two quenchers show small differences in the ratio of chlorophyll a and b. (5) Whereas the --247 mV component readily shows a 60 mV per pH unit dependency on solution pH, the ability of the --45 mV component to respond to pH change is restricted. (6) Triton Photosystem II particles contain both quenchers but the --247 mV component accounts for approx. 70% of the fluorescence and the high component has an Em7.8 of +48 mV. The relative merits of sequential and parallel models in explaining the presence of the two quenchers are considered.     

Dual-wavelength ratiometric fluorescence measurement of the membrane dipole potential.

The electrostatic potentials associated with cell membranes include the transmembrane potential (delta psi), the surface potential (psi s), and the dipole potential (psi D). psi D, which originates from oriented dipoles at the surface of the membrane, rises steeply just within the membrane to approximately 300 mV. Here we show that the potential-sensitive fluorescent dye 1-(3-sulfonatopropyl)-4-[beta[2-(di-n-octylamino)-6- naphthyl]vinyl]pyridinium betaine (di-8-ANEPPS) can be used to measure changes in the intramembrane dipole potential. Increasing the content of cholesterol and 6-ketocholestanol (KC), which are known to increase psi D in the bilayer, results in an increase in the ratio, R, of the dye fluorescence excited at 440 nm to that excited at 530 nm in a lipid vesicle suspension; increasing the content of phloretin, which lowers psi D, decreases R. Control experiments show that the ratio is insensitive to changes in the membrane's microviscosity. The lack of an isosbestic point in the fluorescence excitation and emission spectra of the dye at various concentrations of KC and phloretin argues against 1:1 chemical complexation between the dye and KC or phloretin. The macromolecular nonionic surfactant Pluronic F127 catalyzes the insertion of KC and phloretin into lipid vesicle and cell membranes, permitting convenient and controlled modulation of dipole potential. The sensitivity of R to psi D is 10-fold larger than to delta psi, whereas it is insensitive to changes in psi S. This can be understood in terms of the location of the dye chromophore with respect to the electric field profile associated with each of these potentials.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cyanine dye as monitor of membrane potentials in Escherichia coli cells and membrane vesicles.

The fluorescence response of a positively charged cyanine dye: 3,3'-dimethylindodicarbocyanine iodide can be specifically related to the generation in Escherichia coli cells and E. coli membrane vesicles of an electrical membrane potential induced either by substrate oxidation or by an artificially imposed potassium diffusion gradient. The energy-dependent quenching of the dye fluorescence correlates well with the known effect on delta phi of: oxidation of various energy sources, external pH and solute accumulation. Thus, in the vesicles, the fluorescence quenching of the dye increases from succinate to D-lactate, to ascorbate/phenazine methosulfate and parallels the increasing ability of these electron donors to generate a delta phi. In the vesicles, delta phi is only weakly dependent on external pH, whereas in the cells, delta phi increases with increasing external pH. Lactose accumulation in the vesicles results in the partial utilization of delta phi. A calibration of the dye fluorescence in terms of delta phi has been determined using valinomycin-induced potassium diffusion potential.