Effects on the hepatocyte [Ca2+]i oscillator of inhibition of the plasma membrane Ca2+ pump by carboxyeosin or glucagon-(19-29)

Single rat hepatocytes, microinjected with the Ca(2+)-sensitive photoprotein aequorin, respond to agonists acting through the phosphoinositide signalling pathway by the generation of oscillations in cytosolic free Ca2+ concentration ([Ca2+]i). The duration of [Ca2+]i transients generated is characteristic of the receptor species activated; the variability results in differences in the rate of fall of [Ca2+]i from its peak. It is conceivable that the plasma membrane Ca(2+)-ATPase (PM Ca2+ pump) may have an important role in the mechanism underlying agonist specificity. It has recently been shown that an esterified form of carboxyeosin, an inhibitor of the red cell PM Ca2+ pump, is suitable for use in whole cell studies. Glucagon-(19-29) (mini-glucagon) inhibits the Ca2+ pump in liver plasma membranes, mediated by Gs. We show here that carboxyeosin and mini-glucagon inhibit Ca2+ efflux from populations of intact rat hepatocytes. We show that carboxyeosin and mini-glucagon enhance the frequency of oscillations induced by Ca(2+)-mobilizing agonists in single hepatocytes, but do not affect the duration of individual transients. Furthermore, we demonstrate that inhibition of the hepatocyte PM Ca2+ pump enables the continued generation of [Ca2+]i oscillations for a prolonged period following the removal of extracellular Ca2+.

Flow cytometric analysis of band 3 protein of human erythrocytes

Flow cytometry was used to quantify the transmembrane anion exchanger (band 3 protein) of human erythrocytes by covalently bound eosin-5-maleimide. In vitro and in vivo vesiculated red blood cells were investigated. The fluorescence and light scatter signals of cells after heat induced vesiculation, in vivo ageing, and in patients with hereditary spherocytosis were decreased. These results reflect a deficiency of band 3 protein which is presumably caused by membrane surface area loss. It was possible to distinguish control erythrocytes, erythrocytes from patients with hereditary spherocytosis, and from other forms of haemolytic anaemias on the basis of their light scatter and fluorescence signals characteristics.

Source of transport site asymmetry in the band 3 anion exchange protein determined by NMR measurements of external Cl- affinity

Flux measurements indicate that a far greater number of unloaded band 3 anion transport sites face the cytoplasm than face the external medium, but the reason for this striking asymmetry has remained obscure. To resolve this question, we have measured the apparent Cl- affinity of the transport site of human red blood cell band 3 protein under various conditions by analyzing the 35Cl NMR free induction decay (FID). The [Cl-] that half-saturates the transport sites with [Cli] = [Clo] (K1/2) in RBC membranes (ghosts) is 46 +/- 5 mM at 0 degree C, while the Ko1/2 (for half-saturation with [Clo] at constant [Cli]) of intact cells is 3.2 +/- 2.1 mM. When cells were pretreated with EM, an inhibitor of band 3 anion exchange that does not prevent Cl- binding to the external transport site, K1/2 and Ko1/2 are 41 +/- 14 and 46 +/- 12 mM, respectively. The EM-induced increase in Ko1/2 with little change in K1/2 can be most simply interpreted as meaning that EM abolishes the effects of the translocation rate constants on Ko1/2 so that Ko1/2 and K1/2 of EM-treated cells now both reflect the true dissociation constant for binding of Cl- to the external transport site, Ko. The fact that Ko for a slowly transported anion, iodide, is nearly the same in EM-treated as in control cells indicates that EM does not significantly affect Ko for chloride. Our results indicate that the true dissociation constants for Cl- at the inside and outside are very similar but that the rate constant for inward translocation is much larger than that for outward translocation. For this reason, both unloaded and Cl-loaded transport sites are asymmetrically oriented toward the inside, and Ko1/2 (in untreated cells) is much lower than Ko.

Chemical labelling of arginyl-residues involved in anion transport mediated by human band 3 protein and some aspects of its location in the peptide chain

The anion exchange system of human red blood cells can be completely inhibited by a large number of arginine-specific reagents. Kinetic studies have shown that these reagents act on the substrate binding site. Complete inhibition of the transport system with 14C phenylglyoxal is accompanied by modification of 2 to 3 arginine residues on the transmembrane segment of band 3. The inhibition and the binding of 14C phenylglyoxal to band 3 is reduced significantly in presence of chloride ions. The interactions between the reversible competitive inhibitor, 4-hydroxy-3-nitrophenylglyoxal (HNPG) and other irreversible anion transport inhibitors with well localized binding sites have been studied. A positive cooperativity between HNPG binding and the inhibition caused by eosin-5-maleimide (EMA), has been measured. Nearly no interactions have been found between HNPG binding site and the histidine residue(s) which react with diethylpyrocarbonate (DEPC). Sulphate self-exchange is irreversibly inhibited by two carboxyl-group reagents, 1-ethyl-3-(3-dimethyl-aminopropyl)carbodiimde (EDC) and N'-(3-dimethylaminopropyl)-N-ethylcarbodiimid methoiodide (EAC), studies on their interaction with the HNPG binding site gave results showing that the reaction site(s) of these reagents do not overlap and are not adjacent to the essential arginine(s). A model concerning such interactions is discussed.

The orientation of eosin-5-maleimide on human erythrocyte band 3 measured by fluorescence polarization microscopy

The dominant motional mode for membrane proteins is uniaxial rotational diffusion about the membrane normal axis, and investigations of their rotational dynamics can yield insight into both the oligomeric state of the protein and its interactions with other proteins such as the cytoskeleton. However, results from the spectroscopic methods used to study these dynamics are dependent on the orientation of the probe relative to the axis of motion. We have employed polarized fluorescence confocal microscopy to measure the orientation of eosin-5-maleimide covalently reacted with Lys-430 of human erythrocyte band 3. Steady-state polarized fluorescence images showed distinct intensity patterns, which were fit to an orientation distribution of the eosin absorption and emission dipoles relative to the membrane normal axis. This orientation was found to be unchanged by trypsin treatment, which cleaves band 3 between the integral membrane domain and the cytoskeleton-attached domain. this result suggests that phosphorescence anisotropy changes observed after trypsin treatment are due to a rotational constraint change rather than a reorientation of eosin. By coupling time-resolved prompt fluorescence anisotropy with confocal microscopy, we calculated the expected amplitudes of the e-Dt and e-4Dt terms from the uniaxial rotational diffusion model and found that the e-4Dt term should dominate the anisotropy decay. Delayed fluorescence and phosphorescence anisotropy decays of control and trypsin-treated band 3 in ghosts, analyzed as multiple uniaxially rotating populations using the amplitudes predicted by confocal microscopy, were consistent with three motional species with uniaxial correlation times ranging from 7 microseconds to 1.4 ms.

Detection of Cl- binding to band 3 by double-quantum-filtered 35Cl nuclear magnetic resonance

We have applied double-quantum-filtered (DQF) NMR of 35Cl to study binding of Cl- to external sites on intact red blood cells, including the outward-facing anion transport sites of band 3, an integral membrane protein. A DQF 35Cl NMR signal was observed in cell suspensions containing 150 mM KCl, but the DQF signal can be totally eliminated by adding 500 microM 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS), an inhibitor that interferes with Cl- binding to the band 3 transport site. Therefore, it seems that only the binding of Cl- to transport sites of band 3 can give rise to a 35Cl DQF signal from red blood cell suspensions. In accordance with this concept, analysis of the single quantum free induction decay (FID) revealed that signals from buffer and DNDS-treated cells were fitted with a single exponential function, whereas the FID signals of untreated control cells were biexponential. The DQF signal remained after the cells were treated with eosin-5-maleimide (EM), a noncompetitive inhibitor of chloride exchange. This result supports previous reports that EM does not block the external chloride binding site. The band 3-dependent DQF signal is shown to be caused at least in part by nonisotropic motions of Cl- in the transport site, resulting in incompletely averaged quadrupolar couplings.

Anisotropy decay measurement of segmental dynamics of the anion binding domain in erythrocyte band 3

Time-resolved anisotropy was utilized to detect nanosecond segmental motions of the band 3 intramembrane domain. Band 3 at lysine 430 was fluorescently labeled in ghost membranes by fluorescein or eosin maleimide treatment of intact human erythrocytes followed by hypotonic lysis. Single lifetimes for fluorescein (3.8-4.1 ns) and eosin (3.2-3.4 ns) were observed. Phase-modulation measurement of anisotropy decay indicated a segmental motion model, r(t) = exp(-t/tau 1c)[r infinity + (ro-r infinity) exp(-t/tau 2c)], defined by rotational correlation times corresponding to band 3 segmental motion (tau 1c, 30-70 ns) and rapid fluorescein motion in its binding pocket (tau 2c, 200-400 ps), and a residual anisotropy (r infinity, 0.23-0.28) describing hindered fluorescein motion. In PBS at pH 7.4, tau 1c, tau 2c, and r infinity were 44 ns, 307 ps, and 0.24, respectively, predicting a steady-state anisotropy of 0.24, in agreement with the measured value of 0.23. Factors that might influence band 3 structure/dynamics were examined. Whereas pH (range 5-10) had little effect on r(t), [NaCl] addition (0-150 mM) remarkably decreased tau 1c from 68 to 44 ns. The decrease in tau 1c correlated with solution ionic strength, and did not depend on osmolality (studied by mannitol addition), or specific anion interactions (comparing Cl, Br, F, SO4, citrate). The ionic strength effect was not observed in fluorescein-labeled carbonic anhydrase and trypsin-cleaved band 3, suggesting a specific effect on intact band 3. Anisotropy decay was relatively insensitive to external lectin or internal 2,3-DPG binding, but was sensitive to temperature, membrane fluidity, urea denaturation, fluid-phase viscosity, and aldehyde fixation.(ABSTRACT TRUNCATED AT 250 WORDS)

NADP-malic enzyme from maize leaves: a fluorescence study

NADP-malic enzyme from maize leaves is covalently labeled with a fluorescent-SH reactive probe eosin-5-maleimide (EMA), which reacts with groups that are totally protected by NADP against inactivation. The comparison of the emission fluorescence spectra of the native and the modified enzyme suggests the proximity of the fluorescent groups of the native enzyme (probably tryptophanyl groups) and the EMA modified residues. Intrinsic fluorescence quenching studies shows that NADP is the only substrate capable to interact with the fluorescent excited groups of the enzyme, while Mg2+ is able to increase this interaction. Quenching studies of EMA-bound fluorescence shows that the NADP-binding site was modified and thus uncapable of further interaction with the nucleotide. When the results of protection studies are combined with those of extrinsic quenching experiments, we must conclude that EMA reacts with sulfhydryl groups that are involved in the NADP-binding site of the enzyme.

35Cl nuclear magnetic resonance line broadening shows that eosin-5-maleimide does not block the external anion access channel of band 3

It has been suggested that Lys-430 of band 3, with which eosin-5-maleimide (EM) reacts, is located in the external channel through which anions gain access to the external transport site, and that EM inhibits anion exchange by blocking this channel. To test this, we have used 35Cl nuclear magnetic resonance (NMR) to measure Cl- binding to the external transport site in control and EM-treated human red blood cells. Intact cells were used rather than ghosts, because in this case all line broadening (LB) results from binding to external sites. In an NMR spectrometer with a 9.4-T magnetic field, red blood cells at 50% concentration (v/v) in 150 mM Cl- medium at 3 degrees C caused 19.0 +/- 1.2 Hz LB. Of this, 7.9 +/- 0.7 Hz was due to Cl- binding to the high affinity band 3 transport sites, because it was prevented by an apparently competitive inhibitor of anion exchange, 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS). The LB was not due to hemoglobin released from the cells, as little LB remained in the supernatant after cells were removed by centrifugation. Saturable Cl- binding remained in EM-treated cells, although the binding was no longer DNDS-sensitive, because EM prevents binding of DNDS. The lower limit for the rate at which Cl- goes from the binding site to the external medium is 2.15 x 10(5) s-1 for control cells and 1.10 x 10(5) s-1 for EM-treated cells, far higher than the Cl- translocation rate at 3 degrees C (about 400 s-1). Thus, EM does not inhibit Cl- exchange by blocking the external access channel. EM may therefore be useful for fixing band 3 in one conformation for studies of Cl- binding to the external transport site.

Use of resonance energy transfer to determine the proximity of the guanine nucleotide binding site of transducin relative to a conformationally-sensitive site on the gamma subunit of the cyclic GMP phosphodiesterase

In this work, we have used resonance energy transfer to determine the relative positions of a reactive cysteine residue on the gamma subunit of the retinal cyclic GMP phosphodiesterase (gamma PDE) and a reactive lysine residue on the alpha subunit of transducin (alpha T). The single cysteine residue on gamma PDE (residue 68) is located at a site that is sensitive to the binding of both the inactive and active forms of alpha T. This is demonstrated by the finding that the addition of an alpha T-GDP complex to a gamma PDE subunit labeled with the environmentally-sensitive probe 2-(4-maleimidoanilino)naphthalene-6-sulfonate (MIANS) results in an enhancement in the MIANS fluorescence. The alpha TGDP-induced fluorescence enhancement is dose-dependent and yields an apparent Kd value of approximately 3 microM. Activation of alpha TGDP by aluminum fluoride, when bound to the MIANS-labeled gamma PDE (M-gamma PDE), then results in a quenching of the MIANS fluorescence. The aluminum fluoride-induced change in M-gamma PDE fluorescence occurs on a time scale identical to that observed for changes in the intrinsic alpha T fluorescence that correspond to activating conformational changes in the alpha T "switch II" region. These results suggest that the induction of the activated state of the alpha T subunit results in a change in conformation close to cysteine 68 in gamma PDE.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthesis and interaction of fluorescent thapsigargin derivatives with the sarcoplasmic reticulum ATPase membrane-bound region

Fluorescent derivatives of thapsigargin (TG) were synthesized by replacing the C8-butanoyl chain with a dansyl (DTG) or eosin (ETG) moiety. DTG and ETG retain the inhibitory effect of TG on the sarcoplasmic reticulum (SR) ATPase, displaying a 2 and 10 microM Ki, respectively. Steady state and lifetime fluorescence measurements are consistent with energy transfer between tryptophanyl residues assigned to the ATPase membrane-bound region and DTG. This phenomenon exhibits saturation behavior, occurs in the presence of DTG concentrations producing ATPase inhibition, and is partially prevented by inhibitory concentrations of TG. Although long range conformational effects of TG binding affect the fluorescence properties of endogenous tryptophans as well as of a fluorescein 5'-isothiocyanate (FITC) label of the ATPase extramembranous region, no significant energy transfer was detected between DTG and the FITC label. It is concluded that the inhibitors partition within the membrane and the binding domain resides within or near the membrane-bound region of the ATPase.

Stabilities of the fluorescent SH-reagent eosin-5-maleimide and its adducts with sulfhydryl compounds

The stabilities of the SH-reagent eosin-5-maleimide (EMA) and its adducts with the SH-compounds L-cysteine, N-acetyl-L-cysteine and glutathione (reduced form) were studied under various conditions in comparison with those of the adducts of N-ethylmaleimide (NEM). Studies by reversed-phase high performance liquid chromatography and mass spectrometry showed that EMA was less stable than NEM at neutral and moderately alkaline pH values. EMA formed a succinimide-type adduct with SH-compounds, and then underwent further modification by nucleophilic attack of OH- or an amino group. The succinimide-type adducts with acetylcysteine and glutathione were converted to open-type adducts, in which the succinimide ring was cleaved, whereas the adduct with cysteine was modified to a thiazine-type adduct. Kinetic analyses showed that these open-type and thiazine-type adducts were readily formed and were stable at moderately alkaline pH values such as pH 8.0 or 9.0.

Evidence that eosin-5-maleimide binds close to the anion transport site of human erythrocyte band 3: a fluorescence quenching study

The interaction between eosin-5-maleimide (EMA), an inhibitor of the anion transport protein, band 3, and I-, a transportable substrate, was investigated by fluorescence quenching. The Stern-Volmer plot for the quenching reaction between EMA-labeled band 3 and I- exhibits downward curvature both in human erythrocyte ghosts and in purified band 3. The quenching reaction is insensitive to the viscosity of the bulk phase. The shape of the Stern-Volmer plot becomes more linear with increasing temperature. Following the approach of Blatt et al. [(1986) Biophys. J. 50, 349-356], we have developed a binding-diffusion model which is in good agreement with the quenching data. The model supposes that EMA is located in a compartment or "pocket" in band 3 which is separate from the bulk phase and contains a binding site or sites for the quencher. Quenching of band 3-bound EMA fluorescence by I- is inhibited by DIDS and by the transportable anions Cl-, HCO3-, and Br-. Analysis of these experiments yields dissociation constants for the anions which are in reasonable agreement with those determined from transport kinetics and by NMR. We thus deduce that the quencher binding site is the anion binding/transport site on band 3. We propose that EMA is located in the wall of the anion access channel such that it does not inhibit anion binding. The methods described in this report should facilitate detailed studies of anion binding to the transport site on band 3 under a variety of experimental conditions.

Aluminum fluoride activation of bovine transducin induces two distinct conformational changes in the alpha subunit

We have used resonance energy transfer to read out the interactions of the alpha subunit of transducin (alpha T) with the transducin beta gamma subunit complex (beta gamma T) and to compare the rate of aluminum fluoride-induced alpha T activation, as reflected by the enhancement of the alpha T tryptophan fluorescence, with the rate for the dissociation of holotransducin into its component subunits. Specifically, a beta gamma T complex that was labeled with 5-(iodoacetamido)fluorescein (IAF-beta gamma T) served as a donor for resonance energy transfer and an alpha T-GDP species labeled with eosin 5-isothiocyanate (EITC-alpha TGDP) served as the acceptor. The quenching of IAF-beta gamma T fluorescence emission by the addition of the EITC-alpha TGDP species, due to resonance energy transfer between the IAF and EITC moieities, ranged from 10% to 15%. The association of the transducin subunits was rapid (i.e., within the time period of mixing) and dose-dependent, yielding an apparent Kd of approximately 150 nM for the alpha TGDP/beta gamma T interaction. Unexpectedly, we find that the dissociation of IAF-beta gamma T from an aluminum fluoride-activated alpha TGDP/IAF-beta gamma T complex occurs prior to the onset of the intrinsic fluorescence changes in alpha T that accompany activation of this subunit. Thus, there are at least two structural changes in alpha T that result from the occupation of the gamma-phosphate position in the nucleotide binding cleft of alpha T by aluminum fluoride.(ABSTRACT TRUNCATED AT 250 WORDS)

Importance of loops of mitochondrial ADP/ATP carrier for its transport activity deduced from reactivities of its cysteine residues with the sulfhydryl reagent eosin-5-maleimide

The effects of various compounds such as the transport substrate ADP and the transport inhibitors carboxyatractyloside (CATR) and bongkrekic acid (BKA) on the labeling of cysteine residues in the ADP/ATP carrier of bovine heart submitochondrial particles by the SH reagent eosin-5-maleimide (EMA) were studied. Of the four cysteine residues in the carrier, the labeling of Cys159 by EMA progressed predominantly and rapidly, and those of Cys56 and Cys256 moderately, but Cys128 was not labeled, as we reported previously [Majima, E., et al. (1993) J. Biol. Chem. 268, 22181-22187]. ADP inhibited the labelings of Cys56, Cys159, and Cys256 by EMA. BKA markedly inhibited the labeling of Cys159 by EMA, and also the labeling of Cys256, but did not affect the labeling of Cys56, suggesting that it binds from the matrix side to a region close to Cys159 in the second loop facing the matrix space. CATR completely inhibited the labeling by EMA when added on the cytosolic side, but had no effect when added on the matrix side. From these results, the conformational changes of the carrier induced by CATR, BKA, and ADP are discussed. Furthermore, a mechanism of adenine nucleotide transport through the ADP/ATP carrier in association with change in its conformation is proposed.

Fluorescence photooxidation with eosin: a method for high resolution immunolocalization and in situ hybridization detection for light and electron microscopy

A simple method is described for high-resolution light and electron microscopic immunolocalization of proteins in cells and tissues by immunofluorescence and subsequent photooxidation of diaminobenzidine tetrahydrochloride into an insoluble osmiophilic polymer. By using eosin as the fluorescent marker, a substantial improvement in sensitivity is achieved in the photooxidation process over other conventional fluorescent compounds. The technique allows for precise correlative immunolocalization studies on the same sample using fluorescence, transmitted light and electron microscopy. Furthermore, because eosin is smaller in size than other conventional markers, this method results in improved penetration of labeling reagents compared to gold or enzyme based procedures. The improved penetration allows for three-dimensional immunolocalization using high voltage electron microscopy. Fluorescence photooxidation can also be used for high resolution light and electron microscopic localization of specific nucleic acid sequences by in situ hybridization utilizing biotinylated probes followed by an eosin-streptavidin conjugate.

Interaction of eosin-5-maleimide with band 3 of human erythrocytes

The interaction between EMI (eosin-5-maleimide) and band 3 of human erythrocytes was studied under various conditions. It was found that the effects of the ionic strength on the EMI-band 3 interaction strongly depended on pH. At pH 6.0, the ionic strength had remarkable effects on the EMI-bound band 3, whereas at pH 7.4, the EMI-band 3 interaction was independent of ionic strength. From the change in the circular dichroism spectra of the EMI-bound band 3, it was revealed that the conformation or the structure of the EMI-binding sites in the cytoplasmic domain of band 3 was strongly dependent on ionic strength. The thermodynamic parameters for the covalent-binding between EMI and band 3 were calculated on the basis of the difference spectra of the EMI and ghost system. The values of activation energy and activation entropy change at pH 6.0 were extraordinarily small compared with those values at pH 7.4. These findings represent the characteristics of the EMI-binding sites in the cytoplasmic domain of band 3. The interaction of EMI with an isolated fragment of the cytoplasmic domain, 43k fragment, was also examined. The circular dichroism spectra of the EMI-bound 43k fragments was significantly different from those of the EMI-bound band 3. This may indicate that the quaternary structure of the EMI-binding site in the cytoplasmic domain of band 3 is altered by an allosteric connection with the membrane-spanning domain of band 3. Further, from the pH titration of the 43k fragment, it was suggested that lysine residues are responsible for the ionic interaction between EMI and the 43k fragment.

Characterization of cysteine residues of mitochondrial ADP/ATP carrier with the SH-reagents eosin 5-maleimide and N-ethylmaleimide

The effects of the membrane-impermeable fluorescent sulfhydryl reagent eosin 5-maleimide (EMA) and the membrane-permeable sulfhydryl reagent N-ethylmaleimide (NEM) on ADP transport via the ADP/ATP carrier and their labeling sites in the carrier were studied in bovine heart submitochondrial particles. Of the 4 cysteine residues in the carrier, EMA labeled Cys159 very rapidly, Cys56 slowly, and Cys256 very slowly and did not label Cys128. Its labeling of Cys159 was associated with inhibition of the ADP transport, suggesting that the peptide segment containing Cys159 is involved in the transport of adenine nucleotides. In contrast to the very rapid binding of EMA to Cys159, NEM bound to Cys56 more slowly and labeled Cys159 and Cys256 much more slowly. Like EMA, it did not react with Cys128. The labeling of Cys56 with NEM also inhibited ADP transport. From these results, the locations of these cysteine residues in the ADP/ATP carrier are discussed in relation to the transport of adenine nucleotides mediated by the ADP/ATP carrier.

Avidin-EITC: an alternative to avidin-FITC in confocal scanning laser microscopy

Detection of fluorescein-5-isothiocyanate (FITC)-labeled conjugates is suboptimal in two-color confocal scanning laser microscopy (CLSM). This limits the detection of small, dimly fluorescent targets. We explored the possible advantages of applying eosin-5-isothiocyanate (EITC) conjugated to avidin (Av-EITC) as an alternative for Av-FITC in CSLM. Despite the lower quantum efficiency of EITC, we found that the measured Av-EITC and Av-FITC emission intensities were similar as a result of the standard filter combinations used for simultaneous two-color detection in the Bio-Rad MRC 600 CSLM. The advantage of Av-EITC was that its fading characteristics compared very favorably to those of Av-FITC. An excitation intensity-dependent increase in Av-EITC fluorescence was observed, followed by an exponential decrease. This increase in fluorescence allows longer observation times, averaging of several scans without loss of brightness, and thus detection of dimly fluorescent targets by CSLM.

Inhibition of the red blood cell calcium pump by eosin and other fluorescein analogues

This paper addresses the mechanism of inhibition of the plasma membrane Ca pump by fluorescein analogues and their isothiocyanate derivatives. Eosin (i.e., tetrabromofluorescein) was found to be one of the most potent reversible inhibitors of the erythrocyte Ca pump [half-maximal inhibitory concentration (IC50) < 0.2 microM]; fluorescein itself was about four orders of magnitude less potent (IC50 approximately 1,000 microM). Eosin decreased the maximum influx and thus did not compete with ATP for the Ca pump. Irreversible inhibition produced by the isothiocyanate analogues of eosin and fluorescein [eosin 5-isothiocyanate (EITC) and fluorescein 5-isothiocyanate (FITC), respectively] was also studied. While EITC bound reversibly at the eosin site, two results suggest that EITC does not react covalently at this site: 1) eosin did not alter the time course of the EITC irreversible reaction, and 2) the concentration dependence for reversible EITC inhibition was different from the concentration dependence for irreversible EITC inhibition. ATP did slow the rate of inactivation of both EITC and FITC consistent with the idea that EITC and FITC bind to the ATP site. Our results are consistent with eosin and ATP binding to separate sites and EITC reacting covalently at the ATP site, but not the eosin site.

Eosin-5-maleimide inhibits red cell Cl- exchange at a noncompetitive site that senses band 3 conformation

Eosin-5-maleimide (EM) has been used as a fluorescent probe for the external-facing transport site of the human erythrocyte band 3 protein. Changes in chloride concentration at both sides of the membrane have no significant effect on the inhibitory potency of EM as a reversible inhibitor of Cl- exchange at 0 degrees C, however, demonstrating that it is not a competitive inhibitor. The affinity of EM for the form of band 3 with the transport site facing outward is approximately five times greater than for the form with the transport site facing the cytoplasm; binding of iodide to the external transport site causes no statistically significant decrease in affinity for EM. Eosin, without the maleimide moiety, is a slightly more potent inhibitor than is EM. Erythrosin, an analogue with four iodide atoms replacing the four bromide atoms in eosin, is a much more potent inhibitor, with a half-inhibitory concentration of only 3.1 microM, > 30 times lower than that of EM. Neither eosin nor erythrosin inhibition is affected by changes in chloride concentration as would be expected for a competitive inhibitor. Thus EM and the other eosin derivatives bind to a site separate from the external transport site, but one that is affected by the changes of transport site conformation from the inward-facing to the outward-facing state.

Lys-430, site of irreversible inhibition of band 3 Cl- flux by eosin-5-maleimide, is not at the transport site

Although eosin-5-maleimide (EM) covalently labels band 3 and has been thought to react at the external-facing anion transport site, EM reversibly inhibits Cl- exchange at 0 degrees C in a noncompetitive fashion, indicating that under these conditions it does not bind to the transport site [Knauf, P.A., N.M. Strong, J. Penikas, R.B. Wheeler, Jr., and S.J. Liu. Am. J. Physiol. 264 (Cell Physiol. 33): C1144-C1154 1993]. To see whether or not the covalent labeling by EM takes place at the same noncompetitive site as the reversible binding, we examined the dependence of reaction rate on EM concentration. The reaction rate saturates with increasing EM concentration, indicating that reversible binding precedes covalent reaction and that EM therefore acts as an affinity label. A more complex model in which reversible binding prevents a bimolecular reaction at a different site cannot, however, be ruled out. Cl- gradients across the membrane affect EM reversible binding in a manner suggesting that EM binds preferentially to the Eo form of band 3, with the transport site unloaded and facing outward. Thus EM binds to and probably reacts covalently with a site that is different from the transport site, but whose conformation is affected by the orientation of the transport site. Lysine-430, the amino acid residue which is covalently labeled by EM (4), may be near the transport site but does not seem to be directly involved in the binding of transported substrates such as chloride. EM binding to one band 3 monomer decreases the reactivity of the adjacent monomer but does not decrease the affinity constant of the reversible binding step that precedes covalent reaction. Although a small fraction (approximately 1%) of band 3 monomers fail to react with EM, EM nearly completely inhibits transport in those monomers with which it reacts.

Mechanism of hypotonic hemolysis of human erythrocytes

A mechanism of hemolytic hole formation during rapid hemolysis in a hypotonic medium has been investigated using eosin-5-maleimide (EMI) as a probe. The EMI-labeled erythrocytes revealed a distinct cluster and/or ring of intense fluorescence staining in a hypotonic 5 mM Hepes buffer (pH 7.4), but not in an isotonic buffer containing 150 mM KCl. This EMI cluster indicates an association of band 3 proteins, which correspond to a hemolytic hole. The hole was confirmed by an atomic force microscopy image. The erythrocytes showed a single large hole in the membrane. By the use of EMI-labeled ghosts, it was observed that the lateral clustering of band 3 was accompanied by a biphasic change of fluorescence intensity of EMI. This biphasic change is interpreted as the hemolytic hole formation by band 3, followed by a disappearance of the hole accompanied by band 3 diffusion or distribution within membrane. The latter event corresponds to a spontaneous membrane seal. When a cytoplasmic domain of band 3 was digested with trypsin, or when SH groups in the cytoplasm-facing components of the membrane were also labeled by EMI, no fluorescence change was observed. These results suggest that the association and/or dissociation of band 3 proteins in a hypotonic medium are strongly influenced by cytoplasmic domains. The apparent biphasic change of the fluorescence intensity in the hypotonic medium was well explained by assuming three events: swelling, clustering of band 3, and sealing accompanied by band 3 redistribution.

Time-resolved studies of singlet-oxygen emission from L1210 leukemia cells labeled with 5-(N-hexadecanoyl)amino eosin. A comparison with a one-dimensional model of singlet-oxygen diffusion and quenching

Time-resolved measurements were made of near-infrared emission from 5-(N-hexadecanoyl)amino-eosin-labeled L1210 leukemia cells following pulsed-laser excitation. The cells were suspended in phosphate-buffered saline made with deuterium oxide solvent. A significant fraction of the emission occurring 10-80 microseconds after the laser pulse was due to singlet oxygen. This singlet-oxygen emission is believed to result from singlet oxygen generated near the cell-membrane surface, where 5-(N-hexadecanoyl)amino eosin is known to concentrate, and then diffusing out into the buffer. The intensity and the kinetics of the experimentally observed singlet-oxygen emission were in excellent agreement with the predictions of a theoretical one-dimensional model of singlet-oxygen diffusion and quenching. During the 10-80 microseconds time period studied, most of the singlet oxygen was located in the buffer. Thus, the use of water-soluble singlet-oxygen quenchers, such as histidine, provide one means of separating the singlet-oxygen emission from other sources of light during this time interval.

Resonance energy transfer between guanine nucleotide binding protein subunits and membrane lipids

Resonance energy transfer was used to estimate the distances of closest approach between fluorescent labels on G protein subunits (alpha, beta, and gamma) and the phospholipid bilayer surface. Fluorescein-labeled alpha, beta, and gamma subunits were the energy transfer donors and hexadecylaminoeosin (HAE) in phospholipid vesicles was the acceptor. Bovine brain G protein (alpha o, beta, and gamma subunits) were individually labeled with fluorescein as described in the accompanying paper [Kwon et al. (1993) Biochemistry (preceding paper in this issue)]. Fluorescein-labeled subunits were combined with the appropriate unlabeled G protein subunits and reconstituted into phospholipid vesicles. HAE quenched the fluorescein emission in a concentration-dependent manner which was dependent upon the G protein subunit labeled (gamma = beta > alpha o). From steady-state quenching data with hexadecylaminofluorescein (HAF) as a standard to determine the density of HAE in the phospholipid bilayer, the calculated distances between fluorescein-alpha o, -beta, and -gamma and HAE are 46 +/- 2, 38 +/- 3, and 37 +/- 2 A, respectively. Energy transfer was identified as the means of fluorescence quenching by two methods: (1) addition of 0.1% Lubrol reversed the quenching of fluorescein-labeled G protein subunits by HAE and (2) sensitized HAE emission was observed in the presence of fluorescein-labeled G protein subunits. These results are the first physical measurements of the distances between sites on G protein subunits and the lipid bilayer. These data demonstrate that the label in the beta and gamma subunits is closer to the lipid bilayer than that in the alpha subunit.

Protein rotational dynamics investigated with a dual EPR/optical molecular probe. Spin-labeled eosin

An acyl spin-label derivative of 5-aminoeosin (5-SLE) was chemically synthesized and employed in studies of rotational dynamics of the free probe and of the probe when bound noncovalently to bovine serum albumin using the spectroscopic techniques of fluorescence anisotropy decay and electron paramagnetic resonance (EPR) and their long-lifetime counterparts phosphorescence anisotropy decay and saturation transfer EPR. Previous work (Beth, A. H., Cobb, C. E., and J. M. Beechem, 1992. Synthesis and characterization of a combined fluorescence, phosphorescence, and electron paramagnetic resonance probe. Society of Photo-Optical Instrumentation Engineers. Time-Resolved Laser Spectroscopy III. 504-512) has shown that the spin-label moiety only slightly altered the fluorescence and phosphorescence lifetimes and quantum yields of 5-SLE when compared with 5-SLE whose nitroxide had been reduced with ascorbate and with the diamagnetic homolog 5-acetyleosin. In the present work, we have utilized time-resolved fluorescence anisotropy decay and linear EPR spectroscopies to observe and quantitate the psec motions of 5-SLE in solution and the nsec motions of the 5-SLE-bovine serum albumin complex. Time-resolved phosphorescence anisotropy decay and saturation transfer EPR studies have been carried out to observe and quantitate the microseconds motions of the 5-SLE-albumin complex in glycerol/buffer solutions of varying viscosity. These latter studies have enabled a rigorous comparison of rotational correlation times obtained from these complementary techniques to be made with a single probe. The studies described demonstrate that it is possible to employ a single molecular probe to carry out the full range of fluorescence, phosphorescence, EPR, and saturation transfer EPR studies. It is anticipated that "dual" molecular probes of this general type will significantly enhance capabilities for extracting dynamics and structural information from macromolecules and their functional assemblies.

Measurement of rotational dynamics by the simultaneous nonlinear analysis of optical and EPR data

In the preceding companion article in this issue, an optical dye and a nitroxide radical were combined in a new dual function probe, 5-SLE. In this report, it is demonstrated that time-resolved optical anisotropy and electron paramagnetic resonance (EPR) data can be combined in a single analysis to measure rotational dynamics. Rigid-limit and rotational diffusion models for simulating nitroxide EPR data have been incorporated into a general non-linear least-squares procedure based on the Marquardt-Levenberg algorithm. Simultaneous fits to simulated time-resolved fluorescence anisotropy and linear EPR data, together with simultaneous fits to experimental time-resolved phosphorescence anisotropy decays and saturation transfer EPR (ST-EPR) spectra of 5-SLE noncovalently bound to bovine serum albumin (BSA) have been performed. These results demonstrate that data from optical and EPR experiments can be combined and globally fit to a single dynamic model.

The orientation of transition moments of dye molecules used in fluorescence studies of muscle systems

Fluorescence and phosphorescence depolarization techniques can provide information on orientational order and rotational motion of crossbridges in muscle fibres. However the depolarization experiment monitors the orientation and motion of the crossbridges indirectly. The changes in depolarization arise from a change in the orientation of the transition dipoles of the dye attached to the crossbridge. In order to extract the physiologically relevant orientations from the data it is therefore necessary to characterize the orientation of the dye molecule relative to the crossbridge and the orientation of the transition moments in the frame of the dyes. The dyes 1,5-I-AEDANS and eosin-5-maleimide are commonly used for labelling the crossbridge in muscle fibres. The orientations of the absorption and fluorescence emission dipoles of these two dyes in the molecular frame were determined. Angle resolved fluorescence depolarization experiments on the dyes, macroscopically aligned in a stretched polymer matrix of poly vinyl alcohol, were carried out. The data were analyzed in terms of an orientational distribution of the dye molecules in the film and the orientations of the absorption and emission dipoles in the frame of the dye molecule. Experimental data, obtained from a given sample at different excitation wavelengths, were analyzed simultaneously in a global target approach. This leads to a reduction in the number of independent parameters optimized by the non-linear least squares procedure.

Effect of membrane potential on band 3 conformation in the human erythrocyte membrane detected by triplet state quenching experiments

The triplet lifetime and absorption anisotropy decay of eosin-labeled band 3 was measured in resealed erythrocyte ghosts. Membrane potentials were generated by the addition of valinomycin in the presence of a K+ gradient. Neither negative nor positive membrane potentials had any detectable effect on the rotational diffusion of band 3 nor on the eosin triplet lifetime. The membrane potential did, however, affect quenching of the eosin triplet state by I- and TEMPO (2,2,6,6-tetramethylpiperidine-N-oxyl). Quenching was enhanced by a negative membrane potential (negative inside) and reduced by a positive membrane potential. In addition, it was found that a negative membrane potential enhanced the efficiency of eosin labeling of band 3 in intact erythrocytes. A positive membrane potential had the opposite effect. These results indicate that the eosin binding site on band 3 becomes more accessible to the extracellular aqueous phase in the presence of a negative membrane potential and less accessible in the presence of a positive membrane potential. Quenching by I- and TEMPO of the triplet state of eosin-labeled band 3 was further investigated as a function of pH. Quenching by TEMPO and its dependence on membrane potential were relatively insensitive to pH. In contrast, the rate of quenching by I- showed a marked decrease over the range pH 5.5-9.5. Moreover, the effect of a negative membrane potential on I- quenching also varied with pH. These results are discussed on the supposition that the eosin probe is located in the anion access channel of band 3.(ABSTRACT TRUNCATED AT 250 WORDS)

Rotational diffusion of the erythrocyte integral membrane protein band 3: effect of hemichrome binding

Human erythrocyte band 3 was covalently labeled within the integral membrane domain by incubating intact erythrocytes with the phosphorescent probe eosinyl-5-maleimide. The rotational diffusion of band 3 in membranes prepared from these labeled cells was measured using the technique of time-resolved phosphorescence anisotropy. Three rotational correlation times ranging from 16 to 3800 microseconds were observed, suggesting that band 3 exists in different aggregate states within the plane of the membrane. The oxidizing agent phenylhydrazine was used to induce hemichrome formation within intact erythrocytes. The immobilization of band 3 in membranes prepared from these erythrocytes suggests that the binding of hemichromes induces clustering of band 3. The addition of purified hemichromes to erythrocyte ghosts leads to a similar effect. We have also examined the mobility of the cytoplasmic domain of band 3. This region was labeled indirectly using a phosphorescently labeled antibody which binds to an epitope within the cytoplasmic domain. We observed very rapid motion of the cytoplasmic region of band 3, which was only partially restricted upon hemichrome binding. This suggests that the integral and cytoplasmic domains of band 3 may be independently mobile.

Two-dimensional diffusion of F1F0-ATP synthase and ADP/ATP translocator. Testing a hypothesis for ATP synthesis in the mitochondrial inner membrane

We report here the first experimentally determined lateral diffusion coefficients of the F1F0-ATP synthase and the ADP/ATP translocator in isolated inner membranes of rat liver mitochondria. Rabbit IgG developed against the F1F0-ATP synthase isolated from rat liver mitochondria was determined to be immunospecific for the synthase subunits, notably the alpha-beta doublet, gamma and delta subunits of F1 and subunits two, three and four of F0. This IgG, conjugated with lissamine-rhodamine, was used as a fluorescent probe to monitor the diffusion of the synthase in the membrane. IgG to cytochrome bc1 complex, prepared and labeled similarly, was used as a fluorescent probe for diffusion of this redox component. Eosin maleimide was determined to specifically label the ADP/ATP translocator in the isolated inner membrane and was used as a specific probe for the diffusion of the translocator. Using fluorescence recovery after photobleaching, the experimental average lateral diffusion coefficient of the F1F0-ATP synthase was determined to be 8.4 x 10(-10) cm2/s or twice that of cytochrome bc1 complex while the diffusion coefficient of the ADP/ATP translocator was 1.7 x 10(-9) cm2/s or four times that of cytochrome bc1 complex suggesting that all three components are independent two-dimensional diffusants. Using these diffusion coefficients and applying a number of basic assumptions, we calculated the theoretical two-dimensional diffusion-controlled collision frequencies and derived collision efficiencies (protons transferred per collision) between each of the three proton-transferring redox complexes and both the F1F0-ATP synthase and ADP/ATP translocator by treating the redox components as proton donors and the synthase and translocator as proton acceptors. These collision efficiencies support the physical possibility of a diffusion-based, random collision process of proton transfer and ATP synthesis in the mitochondrial inner membrane.

Determining the extent of labeling for tetramethylrhodamine protein conjugates

A new, relatively simple, spectrophotometric technique has been developed which is useful for accurately determining the extent of chromophore labeling of proteins. Often the absorbance spectra and extinction coefficients of dye/protein conjugates are strongly affected by changes in the chromophore microenvironment that may occur at high dye/protein ratios. In the method being presented, the microenvironment effects have been significantly reduced by denaturing the dye/protein complex in 6 M guanidine hydrochloride prior to making the necessary spectrophotometric measurements. With this approach, extinction coefficients were obtained under native and denatured conditions for tetramethylrhodamine isothiocyanate (TRITC) when bound to a model protein receptor, the sugar binding protein concanavalin A (ConA). The extinction coefficients used for TRITC/ConA conjugates under native and denaturing conditions were 6.52 x 10(4) M-1 cm-1 and 6.96 x 10(4) M-1 cm-1, respectively. These values were obtained from a model dye complex formed between TRITC and epsilon-amino-n-caproic acid which closely resembles the sidechain of lysine residues. Additional dye/ConA conjugates were prepared with tetramethylrhodamine succinimidyl ester (RHS) and eosin isothiocyanate (EITC), and the effects of microenvironment changes on these conjugates were examined. Extinction coefficients for these dyes in native and denaturing conditions, as a function of the degree of labeling, were not appreciably different indicating that changes in the microenvironment did not have a significant affect on the spectral properties of these two dyes. In summary, with this new approach it is quite easy to accurately determine the dye/protein ratio for TRITC conjugates. Also, it is expected that RHS would be a better dye than TRITC for protein conjugation because more accurate values for dye/protein ratios can be obtained under native conditions.

The rotational diffusion of chloroplast phosphate translocator and of lipid molecules in bilayer membranes

The rotational mobility of the phosphate translocator from the chloroplast envelope and of lipid molecules in the membrane of unilamellar azolectin liposomes has been investigated. The rotational dynamics of the liposome membrane were investigated by measuring the rotational diffusion of eosin-5-isothiocyanate(EITC)-labeled L-alpha-dipalmitoylglycerophosphoethanolamine (Pam2 GroPEtn) in the lipid phase of the vesicles, either in the presence or absence of the reconstituted phosphate translocator. The temperature dependence of the anisotropy decay showed that above 25 degrees C the main contribution to the anisotropy decay was caused by uniaxial anisotropic rotation of the labelled lipid molecules around the axis normal to the membrane plane. The rate of rotation of the labelled lipid molecules was strongly dependent on the viscosity of the medium (eta 1). Extrapolation to eta 1 = 0 Pa.s yielded a correlation time of phi = 20 +/- 5 ns, t = 30 degrees C, for lipid rotation with respect to the membrane normal. The rotational diffusion coefficient of the lipid molecules was calculated to be Dr = 2.0 x 10(9) rad2.s-1 and the apparent microviscosity in the vesicle membrane, as derived from the rotational correlation time, was eta 2 approximately 12 mPa.s. The rotational correlation time of the phosphate translocator in the membrane was only slightly dependent on the viscosity of the medium. The temperature dependence of the protein rotation also indicated that the rotation of the protein in the membrane was largely restricted and occurred mainly about the axis normal to the membrane plane. Measurements at a medium viscosity of eta 1 = 1 mPa.s yielded a value of phi r approximately 450 ns corresponding to Dr = 8.8 x 10(7) rad2.s-1 for protein rotation with respect to the membrane normal. From this value and the data of the lipid rotation, the cross-sectional area of the protein part embedded in the membrane was calculated to be approximately 9 nm2. This cross-sectional area is large enough to include at most 14 membrane-spanning helices. Our results also indicated that at lipid/protein molar ratios greater than or equal to 1.5 x 10(4): 1 aggregation occurred in the model membranes below 30 degrees C. However, above 30 degrees C and at a high dilution of the protein in the membrane it appeared that the membrane viscosity monitored by lipid and protein rotational diffusion were identical.

Xanthene-dye-labelled phosphatidylethanolamines as probes of interfacial pH. Studies in phospholipid vesicles

We have been developing the use of plasma-membrane-bound fluorescent probes to measure the pH values at the surfaces of living chondrocytes. For this purpose, three lipophilic pH indicators were made by covalently binding the xanthene dyes fluorescein, eosin or dichlorofluorescein to the amino group of phosphatidylethanolamine. The probes were incorporated into phospholipid vesicles and the effect of pH on the fluorescence was characterized. Fluorescence was measured at a single emission wavelength during excitation at two wavelengths, and the ratio of the intensities was calculated. The experimentally observed pKobs. values were determined by fitting the fluorescence ratios to the Henderson-Hasselbalch equation. All three probes acted as pH indicators, and the eosinyl-, dichlorofluoresceinyl- and fluoresceinylphosphatidylethanolamines had pKobs. values of 3.5, 6.3 and 7.5 respectively. At physiological salt concentrations, changes in the composition of the vesicle membrane had little effect on these values. We concluded that these probes were promising candidates for the measurement of pH values at cell surfaces.

Regulation of band 3 mobilities in erythrocyte ghost membranes by protein association and cytoskeletal meshwork

Rotational diffusion of erythrocyte anion channel protein band 3 was measured in ghost membranes by observing time-resolved phosphorescence anisotropy decays of eosinyl-5-maleimide covalently attached to the protein. Experiments were carried out under conditions similar to those employed by Tsuji and Ohnishi (1986) for translational diffusion measurement of band 3 [(1986) Biochemistry 25, 6133-6139] to allow direct comparison of rotational and translational diffusion of band 3. Detailed analysis of diffusive properties of band 3 in ghost membranes was made on the basis of these rotational and translational diffusion data. Rotational diffusion measurements indicated that there are at least three populations of band 3 molecules with high, low, and no rotational mobilities in the time scale of 10(-4)-10(-2) s. These populations are in equilibrium, and the fractional ratios are strongly temperature dependent. At 26 degrees C, 44% of band 3 molecules are mobile (16% have an average rotational correlation time of 0.19 ms, and 28% have an average correlation time of 2.4 ms), and 56% are immobile. These results correlate well with translational diffusion data which indicated 40% mobile and 60% immobile fractions of band 3. The rotational diffusion data together with the translational diffusion data by Tsuji and Ohnishi (1986) and Golan and Veatch [(1980) Proc. Natl. Acad. Sci. U.S.A. 77, 2537-2541] suggest that immobilization of band 3 is largely caused by binding of band 3 oligomers to ankyrin, which abolishes both rotational and translational diffusion of band 3.(ABSTRACT TRUNCATED AT 250 WORDS)

Preparation of a one-subunit cytochrome oxidase from Paracoccus denitrificans: spectral analysis and enzymatic activity

Cytochrome c oxidase was isolated from Paracoccus denitrificans as a two-subunit enzyme. Chymotrypsin-catalyzed proteolysis reduced the molecular weight of each subunit by about 8000. The spectral properties of this preparation, as well as its Km for cytochrome c(1.7 muM), remained unchanged with respect to the native enzyme. Vmax was reduced by about 55% when assayed in Triton X-100 or in Triton X-100 supplemented with asolectin. Following further proteolysis by Staphylococcus aureus V8 protease, subunit I remained unchanged as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, whereas subunit II was split into small peptides. These were removed by ion-exchange high-performance liquid chromatography. The one-subunit enzyme had an apparent molecular weight of 43,000. The reduction of molecular weight was also confirmed by the diminution of the ultraviolet/Soret absorption ratio. This value was 1.8-2.1 for the native enzyme and 1.3-1.5 for the one-subunit enzyme. The spectral properties (including the spectrum CO reduced minus reduced) were not modified by the proteolytic treatment, indicating that cytochromes a and a3 were present in equal amounts. The lack of spectral alteration and the known close association of the copper B atom with cytochrome a3 suggest that copper B is also contained within the one-subunit enzyme. The Km of the one-subunit oxidase was similar to that of the two-subunit enzyme; Vmax was decreased by about 50%. The activity of the one-subunit oxidase had a salt-dependent maximum at 30 mM KCl, almost identical with that of the undigested enzyme, and was inhibited by micromolar concentrations of KCN.

Inhibition of deoxyribonuclease I activity by actin covalently cross-linked to chick brain actin depolymerizing factor through exposed sulfhydryls

All but one of the six free sulfhydryl groups of chick brain actin depolymerizing factor (ADF) are protected from modification when ADF forms a 1:1 complex with actin. This exposed sulfhydryl can be cross-linked to cys 374 of actin with N,N'-phenylenedimaleimide. The cross-linked complex inhibits the hydrolytic activity of pancreatic deoxyribonuclease (DNase I) to an identical extent as both the untreated complex and an equivalent amount of free actin. These data indicate that ADF binds to actin at a site which does not overlap with the DNase I binding site.

Inhibition and labelling of the mitochondrial 2-oxoglutarate carrier by eosin-5-maleimide

Unlike hydrophobic maleimides, eosin-5-maleimide and to a lesser extent other relatively polar maleimides inhibit the 2-oxoglutarate carrier of bovine heart mitochondria. The impermeable eosin-5-maleimide labels the 2-oxoglutarate carrier in intact mitochondria but not in submitochondrial particles. 2-Oxoglutarate protects the carrier against inactivation by eosin-5-maleimide and decreases the fluorescence associated with the purified protein. Other anions which are not substrates of the carrier have no protective effect. It is concluded that sulfhydryl groups essential for the activity of the 2-oxoglutarate carrier are located at the cytosolic face of the inner mitochondrial membrane. They appear to be present at the substrate-binding site and located in a hydrophilic environment.

Diffusion properties of clathrin on the surface of isolated mouse liver nuclei by the fluorescence recovery after photobleaching technique

Clathrin labeled with eosin maleimide showed physicochemical properties similar to the native clathrin. The diffusion coefficients of clathrin protomers and cages measured at 20 degrees C by the fluorescence recovery after photobleaching technique (FRAP) were found equal to (9 +/- 1).10(-8) cm2.s-1 and (3 +/- 0.4.10(-8) cm2.s-1, respectively. After incubation with isolated mouse liver nuclei suspended in an aqueous buffer, FRAP measurements showed that 78% of clathrin was immobilized on the nuclear surface. This immobile fraction might correspond to aggregates of molecules resembling coated pits. The mobile fraction had a diffusion coefficient of 2.5.10(-9) cm2.s-1 which was reduced seven times when the suspension medium of the nuclei contained 50% sucrose, showing that the aqueous phase exerted an important drag on the clathrin molecules motion diffusing on the nuclear surface.

Microsecond rotational dynamics of phosphorescent-labeled muscle cross-bridges

We have measured the microsecond rotational motions of myosin heads in muscle cross-bridges under physiological ionic conditions at 4 degrees C, by detecting the time-resolved phosphorescence of eosin-maleimide covalently attached to heads in skeletal muscle myofibrils. The anisotropy decay of heads in rigor (no ATP) is constant over the time range from 0.5 to 200 microsecond, indicating that they do not undergo rotational motion in this time range. In the presence of 5 mM MgATP, however, heads undergo complex rotational motion with correlation times of about 5 and 40 microsecond. The motion of heads in relaxed myofibrils is restricted out to 1 ms, as indicated by a nonzero value of the residual anisotropy. The anisotropy decay of eosin-labeled myosin, extracted from labeled myofibrils, also exhibits complex decay on the 200-microsecond time scale when assembled into synthetic thick filaments. The correlation times and amplitudes of heads in filaments (under the same ionic conditions as the myofibril experiments) are unaffected by MgATP and very similar to the values for heads in relaxed myofibrils. The larger residual anisotropy and longer correlation times seen in myofibrils are consistent with a restriction of rotational motion in the confines of the myofibril protein lattice. These are the first time-resolved measurements under physiological conditions of the rotational motions of cross-bridges in the microsecond time range.

Proximity between fluorescent probes attached to four essential lysyl residues in phosphoenolpyruvate carboxylase. A resonance energy transfer study

Phosphoenolpyruvate carboxylase, purified from maize leaves, is rapidly inactivated by the fluorescence probe dansyl chloride. The loss of activity can be ascribed to the covalent modification of an R-NH2 group, presumably the epsilon-NH2 group of lysine. Analysis of the data by the statistical method of Tsou [Sci. Sin. 11, 1535-1558 (1962)] provides clear evidence that a pH 8 eight R-NH2 groups can be modified in the tetrameric form of the enzyme, four of which are essential for catalytic activity. Essential groups are modified about five times more rapidly than the non-essential ones. The enzyme was completely protected against inactivation by Mg2+ plus phosphoenolpyruvate and consequently binding of the modifier to the essential groups is completely abolished. Hence the four essential groups seemed to be located at or near the active site(s). One of the four essential groups was modified with dansyl chloride and the other three progressively with eosin isothiocyanate. In the doubly labeled protein non-radiative single-singlet energy transfer between dansyl chloride (donor) and eosin isothiocyanate (acceptor) was observed. The low variance (+/- 5%) in the efficiency of energy transfer obtained at a particular acceptor stoichiometry (0.8-1.1, 1.9-2.1, 2.9-3.1) in triplicate samples provided confidence that the measured transfer efficiency may be interpreted as transfer between specific sites. The distances calculated from the efficiency of resonance energy transfer revealed two acceptor sites, equally separated, 4.8-5.1 nm from the donor site and third site being 6.4 nm apart from the donor. Under conditions where the tetrameric enzyme dissociates into the monomers, no transfer of resonance energy between the protein-bound dansyl chloride and eosin isothiocyanate was observed. Most likely the four essential lysyl residues in the tetrameric enzyme are located in different subunits of the enzyme, hence each of the subunits would contain a substrate-binding site with one lysyl residue crucial for activity.

Ionic effects on the rotational dynamics of cross-bridges in myosin filaments, measured by triplet absorption anisotropy

We have measured the rotational motion of myosin heads in synthetic thick filaments at 4 degrees C in the time range from 10(-7) to 10(-4) seconds, by measuring transient absorption anisotropy of an eosin probe attached to a reactive sulfhydryl on the myosin head. Under conditions that result in monomeric myosin (500 mM ionic strength), the anisotropy decay is independent of pH in the range from 7.0 to 8.2 and [Mg2+] in the range from 0.1 to 10 mM; the anisotropy decays bi-exponentially with correlation times of 0.4 and 2 microseconds to a constant value of 0.016. Under more physiological conditions (115 mM ionic strength), resulting in filament formation, the anisotropy decay is sensitive to both pH and [Mg2+]. The anisotropy at pH 8.2 and 0.1 mM-Mg2+ decays with correlation times of 0.5 and 3.8 microseconds to a constant limiting anisotropy of 0.038. When the [Mg2+] is increased to 10 mM, the correlation times are 0.6 and 5.7 microseconds and the limiting anisotropy value is 0.055. Identical changes in the anisotropy decay are caused by an increase in [H+] to pH 7.0, in the presence of 0.1 mM-Mg2+. Increasing the total ionic strength to 187 mM decreases the amplitude of the cation effects. These results provide direct evidence that the rotational dynamics of myosin heads in thick filaments are influenced by physiological concentrations of cations. The results are qualitatively consistent with the proposal that these and other ionic conditions regulate transitions between "spread" and "compact" cross-bridge conformations, but the quantitative results indicate that cross-bridges undergo large-amplitude microsecond rotations even under conditions where the compact state should predominate.

Domain structural flexibility in rhodanese examined by quenching of a phosphorescent probe

Rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) is an enzyme composed of two domains with the catalytic site located in the bottom of the crevice formed by the two domains. In this work, rhodanese was labeled at its catalytic site with the phosphorescence probe eosin isothiocyanide. The accessibility of molecules to the probe was determined by phosphorescence lifetime-quenching studies. The phosphorescent probe was much more accessible to small molecules (I- and thiosulfate, radius about 3-5 A) than to a larger molecule (spin-label probe TEMPO, radius about 8-10 A). It was observed that a temperature-induced change in the rate of quenching occurred at around 28 degrees C. The results are interpreted in terms of structural fluctuations and displacement in the domains.

Rotational motions of myosin heads in myofibril studied by phosphorescence anisotropy decay measurements

We studied the rotational Brownian motions of myosin heads, of which the sulfhydryl group was selectively labeled with the triplet probe 5-eosinylmaleimide, in myofibril by using flash-induced phosphorescence anisotropy decay measurements. The anisotropy decay curve under relaxing conditions consisted of a fast (submicrosecond) and a slow (a few microseconds) component and a small constant part as in the synthetic myosin filaments in solution. The decay curves could be analyzed by assuming that a head part, i.e. subfragment 1 (S1), wobbles in the first cone and a part connecting S1 and the tail of a myosin molecule of which the length is shorter than subfragment 2 (S2) wobbles in the second cone (a double-cone model); the semiangles of the former and the latter cones were about 30 degrees and 50 degrees, respectively. The rotational freedom of myosin heads was only slightly restricted by the limited space of the filament lattice in myofibrils. Under rigor conditions, no motion of myosin heads was observed in the 10-microseconds time scale.

Characterization of eosin 5-isothiocyanate binding site in band 3 protein of the human erythrocyte

The characteristics of the anion transport system in human erythrocyte, which can be modified by eosin 5-isothiocyanate (EITC), were studied using the pH titration method and by measuring the sulfate efflux. Based on the pH dependence of EITC binding to the erythrocyte ghosts, it was found that the reaction rate was maximal at about pH 6.4, and that the pH profile of EITC binding was similar to that of divalent anion transport. The interaction between EITC and ghosts was interpreted by a two-step reaction, a fast ionic-binding reaction and a slow covalent-binding reaction. The induced CD spectrum of the EITC-ghost system was also dependent on pH. The intensity of the CD band at 530 nm was decreased in acidic pH region, and the inflection point was observed at about pH 6.3, indicating a participation of the histidine residue in the interaction of EITC with band 3. In order to characterize the EITC-binding site, the kinetics of sulfate efflux in intact and EITC-modified cells were examined at various pH values. The inhibitory effect of EITC was dependent on pH. From the experimental results, the followings are suggested. The rate of ionic interaction in the early stage is much slower than that in a general ionic reaction. A conformational change may participate in the reaction. The conformation of the EITC-binding site depends on pH, relating to the dissociation of the histidine residues. The EITC molecules act also as a competitive inhibitor to the sulfate efflux after binding covalently to band 3 protein.

Adenine nucleotide and phosphate transport systems of mitochondria. Relative location of sulfhydryl groups based on the use of the novel fluorescent probe eosin-5-maleimide

Eosin-5-maleimide is impermeable to the inner mitochondrial membrane, exhibiting essentially no reactivity with matrix glutathione or with beta-hydroxybutyrate dehydrogenase located on the matrix surface of the inner membrane. In intact mitochondria, eosin-5-maleimide is unreactive with the ADP/ATP antiporter even under conditions which promote maximal labeling by N-[3H]ethylmaleimide (i.e., ADP present). However, eosin-5-maleimide readily labels the ADP/ATP antiporter in "inverted" inner membrane vesicles even in the presence of N-ethylmaleimide. Labeling is prevented if the vesicles are prepared from mitochondria pretreated with carboxyatractyloside. In contrast to the ADP/ATP antiporter, essential sulfhydryl groups of the Pi/H+ symporter are accessible to eosin-5-maleimide in intact mitochondria with optimal inhibition of phosphate transport being observed at 25 degrees C. Eosin-5-maleimide also prevents labeling of the Pi/H+ symporter by N-[3H]ethylmaleimide. These results show that essential sulfhydryl groups of the ADP/ATP antiporter and the Pi/H+ symporter have differing reactivities and locations in functionally intact mitochondria. With respect to eosin-5-maleimide, sulfhydryl groups of the ADP/ATP carrier occur in two distinct classes, both of which are inaccessible in intact mitochondria. Only one class, depending on conditions, can be exposed in submitochondrial particles. In contrast, sulfhydryl group(s) of the Pi/H+ symporter behave as a single reactive class which is readily accessible in mitochondria at 25 degrees C.

Selective labeling of beef heart cytochrome oxidase subunit III with eosin-5-maleimide

Cytochrome c oxidase has been isolated from beef heart mitochondria and labeled with the fluorochrome eosin-5-maleimide (EMA) after pretreatment with mersalyl. On SDS-polyacrylamide gels, EMA fluorescence and absorption occurred at a single band corresponding to subunit III. Since only Cys 115 of the two cysteinyl residues of subunit III had been shown to be reactive towards water-soluble SH-reagents, it was concluded that this residue was the one labeled by EMA. The EMA/enzyme ratio was about 1. Gel filtration experiments have shown that upon treatment with dicyclohexylcarbodiimide, subunit III was loosened from the complex; this result suggests that the inhibitory effect of dicyclohexylcarbodiimide on the H+-translocation activity may be related to such a phenomenon.

Quantitation of protein 3 content of circulating erythrocytes at the single-cell level

The density and size of human erythrocytes has been roughly correlated with cell age, with the denser and smaller cells being older. Observations of this type have led to a hypothesis that the membranes of circulating erythrocytes are dynamic with respect to composition and that material is lost from the membrane during cell maturation and circulation. In this study, flow cytofluorimetry was used to investigate the distribution of the human erythrocyte anion transport protein (protein 3) in heterogeneous samples of circulating red cells. We verified that protein 3 can be specifically and quantitatively labeled in intact human erythrocytes with eosin-5-maleimide, a luminescent probe. Individual cells were accordingly analyzed for size by forward light scattering and for protein 3 content by quantitation of eosin fluorescence. Initial results indicated that the smallest erythrocytes had a protein 3 content equal to that of the largest circulating erythrocytes. This result was independently verified by light scatter-activated cell sorting; direct measurement of cell diameters by microscopy verified that the cell sizes of erythrocytes showing the 10% greatest and 10% smallest light-scattering signal were indeed distinct. Independent analysis of the size-sorted erythrocytes for protein 3 content was accomplished by gel electrophoresis of stroma from 150,000 large and small erythrocytes. Quantitative scanning densitometry of silver-stained gels of prepared stroma showed that protein 3 content of each set of fractionated cells was equal and did not vary as a function of cell size. Taken in combination with the reported correlation between increasing red blood cell age and decreasing cell size, these results indicate that any loss of membranous material during the cell aging process is not random.