Oligomerization of light-harvesting I antenna peptides of Rhodospirillum rubrum.

We investigated the oligomerization of the core light-harvesting complex (LH1) of Rhodospirillum rubrum from the separated alpha beta BChl(2) subunits (B820) and the oligomerization of the B820 subunit from its monomeric peptides. The full LH1 complex was reversibly associated from B820 subunits by either varying the temperature in the range 277-300 K or by varying the detergent concentration in the buffer from 0.36 to 0.52% n-octyl-beta-D-glucopyranoside. Temperature-induced transition measurements showed hysteresis: raising the temperature induced dissociation of B873 directly into B820 subunits whereas upon recooling an intermediate spectral form was observed with an absorption maximum located around 850 nm. This intermediate form was also observed in detergent-induced transitions. It is speculated that the B850 form is a small aggregate of B820, for instance a dimer. Additionally, during a temperature-mediated transition at low detergent concentration, a set of spectral forms with maxima slightly blue-shifted from 873 nm were observed, possibly due to opened rings with one or only a few alpha beta BChl(2) units missing. The temperature-induced transition of LH1 is discussed in terms of a simple assembly model. It is concluded that a moderately cooperative assembly explains the formation of small aggregates of B820 as well as of incomplete rings. Furthermore, the B820 subunits were reversibly dissociated into the monomeric B777 form by increasing either the temperature or the detergent concentration. Estimations of the enthalpy and entropy changes for the dimeric association reaction of B777 into B820 yielded an enthalpy change of -216 kJ mol(-1) and an entropy change of -0.59 kJ mol(-1)K(-1), at a detergent concentration of 0.8% n-octyl-beta-D-glucopyranoside.

Regulation of CTP: phosphocholine cytidylyltransferase activity by the physical properties of lipid membranes: an important role for stored curvature strain energy.

CTP:Phosphocholine cytidylyltransferase (CT) catalyzes the key step in phosphatidylcholine (PC) synthesis. CT is activated by binding to certain lipid membranes. The membrane binding affinity of CT can vary from micromolar to millimolar K(d), depending on the lipid composition of the target membrane. Class II CT activators like diacylglycerols and unsaturated phosphatidylethanolamines (PE) favor inverted lipid phase formation. The mechanism(s) governing CT's association with class II lipid membranes and subsequent activation are relatively unknown. We measured CT activation by vesicles composed of PC and one of three unsaturated PEs, dioleoylglycerol (DOG), or cholesterol. For each lipid system, we estimated the stored curvature strain energy of the monolayer when confined to a relatively flat bilayer. CT binding and activation correlate very well with the curvature strain energy of several chemically distinct class II lipid systems, with the exception of those containing cholesterol, in which CT activation was less than the increase in curvature strain. CT activation by membranes containing DOG was reversed by inclusion of specific lysolipids, which reduce curvature strain energy. LysoPC, which has a larger positive curvature than lysoPE, produced greater inhibition of CT activation. Stored curvature strain energy is thus an important determinant of CT activation. Membrane interfacial polarity was investigated using a membrane-anchored fluorescent probe. Decreases in quenching of this interfacial probe by doxyl-PCs in class II membranes suggest the probe adopts a more superficial membrane location. This may reflect an increased surface hydrophobicity of class II lipid membranes, implying a role for surface dehydration in CT's interactions with membranes containing class II lipids. Cholesterol, a poor activator of CT, did not affect the positioning of the polarity-sensitive probe, suggesting that one reason for its ineffectiveness is an inability to enhance surface hydrophobicity.

Fluorescent probes used to monitor membrane interfacial polarity.

The polarity of the interface between a lipid bilayer membrane and bulk water is an important physical parameter of the membrane. It is likely that several membrane-dependent biological functions are modulated by this property. However, interfacial polarity can be difficult to define because of an imprecise knowledge of the molecular nature of the interface. Nevertheless, attempts have been made to measure this quantity with the use of fluorescent probes which are sensitive to the solvent polarity. Often, however, other factors, such as the rate of solvent relaxation must be known in order to interpret the fluorescent properties in terms of the dielectric constant. In addition, the spatial orientation and location of the fluorophore are often not known precisely. Nevertheless, there have been successful efforts to gain a more accurate knowledge of this aspect of membrane physical properties and its relationship to biological phenomena is discussed.

14-3-3 proteins double the number of outward-rectifying K+ channels available for activation in tomato cells

Outward-rectifying K+ channels are modulated in response to environmental stimuli by a range of intracellular factors, such as cytoplasmic Ca2+, pH, kinases and phosphatases. Here we report that voltage-dependent outward-rectifying K+ channels in tomato cells are also targets for modulation by 14-3-3 proteins. In whole-cell patch-clamp experiments, recombinant 14-3-3 protein (tomato isoform TFT7) was introduced into tomato cell protoplasts via the patch pipette. As a result the steady-state outward K+ current increased twofold and this increase was not dependent upon the presence of cytoplasmic ATP. A phosphorylated peptide that contained a phosphorylated 14-3-3 target-binding motif (RSTS*TP), derived from nitrate reductase, blocked the effect of 14-3-3, thus showing the specific nature of 14-3-3 action. Kinetic parameters of the conductance, like (de)activation kinetics, voltage dependence of gating and activation potential, were not significantly different between control and 14-3-3 infused cells. Analysis of single-channel activity and whole-cell noise indicated that the single-channel conductance was not affected by 14-3-3 infusion. We conclude that 14-3-3 proteins recruit 'sleepy' channels into a voltage-activatable state. The molecular mechanism underlying the 1 : 1 ratio of constitutively active and 14-3-3 recruited channels is discussed in the light of known functions of 14-3-3 dimers.

Interfacial membrane properties modulate protein kinase C activation: role of the position of acyl chain unsaturation.

We studied the effects of the addition of a series of 1, 2-dioctadecenoyl-sn-glycerol-3-phosphoethanolamines to vesicles composed of 1-palmitoyl-2-oleoylphosphatidylserine and 1-palmitoyl-2-oleoylphosphatidylcholine on the activity and membrane binding of protein kinase C (PKC). The three phosphatidylethanolamines (PEs) were dipetroselinoyl-PE, dioleoyl-PE, and divaccenoyl-PE, which have double bonds in positions 6, 9, and 11, respectively. These lipids represent a group of structurally homologous compounds whose physical properties have been compared. We also used a fluorescent probe, 4-[(n-dodecylthio)methyl]-7-(N, N-dimethylamino)coumarin to measure the relative interfacial polarities of LUVs containing each of the three PEs. We find dipetroselinoyl-PE allows the least access of the fluorescent probe to the membrane. This is also the lipid that shows the lowest activation of PKC. The activity of PKC was found to correlate best with the interfacial properties of the three PEs rather than with the curvature energy of the membrane. The results show the sensitivity of the activity of PKC to small changes in lipid structure.

The ATP synthase gamma subunit provides the primary site of activation of the chloroplast enzyme: experiments with a chloroplast-like Synechocystis 6803 mutant.

The activation characteristics of the F1Fo-ATP synthase (where F1 and Fo are the hydrophilic and membrane-bound parts respectively of the enzyme) from Synechocystis 6803 wild-type and a Synechocystis 6803 mutant with a chloroplast-like insertion in the gamma subunit have been studied. Activation of the ATP synthase in wild-type and mutant membrane vesicles was performed by acid-base transition-induced generation of a proton motive force (Delta mu H+). Since the mutant containing the regulatory segment of the chloroplast gamma subunit showed thiol-modulation (typical of the chloroplast enzyme), this segment is indeed involved in the regulation of enzyme activation. It is shown that the ATP synthase from Synechocystis 6803 wild type corresponds functionally to the reduced form of the chloroplast ATP synthase, in view of the low Delta mu H+ required for activation of the enzyme and the high stability of the active state. Both the cyanobacterial wild-type and mutant ATP synthases can be activated by methanol, which apparently does not require the presence of the gamma subunit regulatory segment.

Fluorescent probes of membrane surface properties.

We have studied the properties of two new fluorescent probes, 7-dimethylaminocoumarin derivatives, 4-[N, N-dimethyl-N-(n-tetradecyl)ammoniummethyl]-7-(N,N-dimethylamino)co umarin chloride (TAMAC) and 4-(n-dodecylthiomethyl)-7-(N,N-dimethylamino)coumarin (DTMAC) in model membrane systems. Both probes are sensitive to solvent polarity. The TAMAC probe has a quaternary ammonium function to position it at a fixed location with respect to the membrane interface. In membranes of dipalmitoleoylphosphatidylethanolamine (DiPoPE), both probes detect marked increases in surface hydrophobicity as the bilayer to hexagonal phase transition temperature is approached. This does not occur when the probes are embedded in dipalmitoleoylphosphatidylcholine (DiPoPC) in which case the fluorescence emission is found to be largely independent of temperature. A nitroxide quencher covalently linked to the 5 position of the sn-2 acyl chain of phosphatidylcholine quenches the fluorescence of DTMAC in DiPoPC more than in DiPoPE, indicating the deeper insertion of this probe in DiPoPC. As the temperature is increased the DTMAC fluorophore moves even further out of the membrane. These findings indicate that DTMAC, which does not contain a group to fix its location along the bilayer normal, adjusts its position to small changes in environment polarity, so as to maintain an environment of a fixed dielectric constant. However, with greater changes in membrane interfacial polarity the environment of the probe will be altered. Thus, in addition to the sensitivity of these probes to solvent polarity, the ability of a fixed nitroxide to quench DTMAC becomes another parameter with which to characterize membrane properties with these probes.

Monovalent cations differentially affect membrane surface properties and membrane curvature, as revealed by fluorescent probes and dynamic light scattering.

The effects of monovalent cations on the interfacial electrostatic potential (psi d), hydrodynamic shear boundary distance (ds), and membrane curvature were studied in large unilamellar phospholipid and galacto/sulfolipid liposomes containing different fractions of negatively charged lipids. The differential effects of alkali metal ions on psi d could be accurately determined at physiological surface charge densities with a surface-anchored fluorescent probe. Li+ and Na+ more effectively decrease psi d and exhibit higher association constants (Kas) than K+ and Cs+. These two groups of cations display qualitatively different perturbations of the interfacial structure. Combining Kas values with the electrokinetic (zeta) potentials yielded the respective ds values. At low ionic strength ds more substantially increases with Li+ or Na+ than with K+ or Cs+. Increasing surface charge density causes increased membrane curvature in the presence of K+ or Cs+, but this is largely prevented by Li+ or Na+. Membrane binding of the amphiphilic cation acridine orange decreases surface charge and membrane curvature more extensively than H3O+, Li+, and Na+. The differential interface-perturbing behavior of monovalent cations is discussed with regard to their different hydration tendencies that will modulate the extent and stability of the hydrogen-bond network along the charged membrane surface.

Annexin V perturbs or stabilises phospholipid membranes in a calcium-dependent manner.

The potency of annexin V to transport Ca2+ ions across phospholipid membranes was investigated, using large unilamellar phospholipid vesicles loaded with the Ca2+ indicator fura-2. It was demonstrated that annexin V leaves the vesicle membranes intact when added in the presence of 1 mM Ca2+. However, if the vesicles were first incubated with annexin V in the absence of Ca2+, subsequent addition of Ca2+ produced a fluorescence signal due to binding of Ca2+ to fura-2. Centrifugation of the vesicle suspension immediately thereafter showed that this signal originated from the supernatant and not from the sedimented vesicles. Our results show that annexin V causes loss of vesicle integrity in the absence of Ca2+, and leakage of trapped fura-2, rather than inward Ca2+ transport. Bovine serum albumin or Ca2+ concentrations higher than 2.5 mM also caused such fura-2 leakage. Apparently, calcium-dependent binding of annexin V to the membrane prevents aspecific membrane damage caused by this protein.

The effect of sulfite on the ATP hydrolysis and synthesis activity of membrane-bound H(+)-ATP synthase from various species.

The action of sulfite on ATP hydrolysis and synthesis activities is investigated in membrane vesicles prepared from the cyanobacterium Synechococcus 6716, chromatophores from the photosynthetic purple bacterium Rhodospirillum rubrum, membrane vesicles from the related non-photosynthetic bacterium Paracoccus denitrificans, and bovine heart submitochondrial particles. Without any further pretreatment ATP hydrolysis is stimulated by sulfite in all four membrane preparations. Typically ATP synthesis in the cyanobacterial membrane vesicles is inhibited by sulfite, whereas ATP synthesis in chromatophores and the submitochondrial particles is not. These differences in sensitivity of ATP synthesis to sulfite, however, correspond well with the distribution of (photosynthetic) sulfur oxidizing pathways in the remaining three organisms/organelles compared in this study.

Modulation of the proton-translocation stoichiometry of H(+)-ATP synthases in two phototrophic prokaryotes by external pH.

The stoichiometry between proton translocation and ATP synthesis/hydrolysis was studied in two different photosynthetic prokaryotes, the thermophilic cyanobacterium Synechococcus 6716 and the purple bacterium Rhodospirillum rubrum. The H+/ATP ratio was determined by acid-base transitions as a function of the external pH. The H+/ATP ratio of the Synechococcus 6716 ATP synthase was found to increase with increasing pH. In contrast, in R. rubrum this ratio decreased with increasing pH. These results were qualitatively supported by experiments using the fluorescence probe 9-aminoacridine. The degree of coupling between the H+ flux and the ATP synthesis/hydrolysis reaction is apparently modulated by the conditions under which the proton pump has to work. Such modulation of the H+/ATP ratio may be of physiological significance for an organism, for example when ATP synthesis is necessary at low proton-electrochemical potential difference (delta mu H+ levels). The different pH dependencies of the H+/ATP ratios in these organisms are considered in relation to the differences in the charged amino acids that are present in the F0 subunits a and c.

Probing biomembrane interfacial potential and pH profiles with a new type of float-like fluorophores positioned at varying distance from the membrane surface.

Fluorophores of a new type were synthesized to probe the electrostatic potential or pH profiles in the external interface of biomembranes. The probes consist of the pH-sensitive fluorophore 7-hydroxycoumarin, coupled to a tetradecyl (myristyl) tail by a spacer group of varying length. A positively charged group is included between the tetradecyl and spacer groups to encourage a float-like alignment in the membrane head-group region. Three probes of this type were compared with 4-heptadecyl-7-hydroxycoumarin the fluorophore of which is embedded in the lipid head-group domain. Thus, a ruler-type positioning of the fluorophores was obtained at about 0.2, 0.6, 1.0, and 1.3 nm from the surface. The membrane-bound probes were tested in well-defined liposomes prepared by extrusion with different surface charge densities and size. The predicted positioning of the float-like probes is supported by their binding behavior in liposomes and by steady-state and nanosecond time-resolved fluorescence anisotropy, as well as by their accessibility to different quenchers. The interfacial electrostatic potential (psi d) and pH (pHd) values were derived from the observed apparent pKa shifts of the probes. The obtained psi d and pHd profiles as function of the surface potential (psi 0) and distance from the membrane surface are in good harmony with predictions from nonlinear Gouy-Chapman theory. The electrokinetic potentials (zeta) of the liposome series, measured by Doppler-electrophoretic frequency shift of laser light scattering, are in good proportion to the probe data. When bound to yeast cells, these probes monitor interfacial changes in parallel with glucose-induced medium acidification.(ABSTRACT TRUNCATED AT 250 WORDS)

On the activation mechanism of the H(+)-ATP synthase and unusual thermodynamic properties in the alkalophilic cyanobacterium Spirulina platensis.

The activation requirements and thermodynamic characteristics of ATP synthase from the alkalophilic cyanobacterium Spirulina platensis were studied in coupled membrane vesicles. Activation by methanol increased the Vmax, while the Km for MgATP was unaffected (0.7 mM). We propose that in Sp. platensis, as in chloroplasts, the activating effect of methanol is based on perturbation of the gamma-epsilon subunit interaction. Light-driven ATP synthesis by membrane vesicles of Sp. platensis was stimulated by dithiothreitol. The characteristics of the activation of the ATP synthase by the proton electrochemical potential difference (delta mu H+) were analyzed on the basis of the uncoupled rates of ATP hydrolysis as a function of a previously applied proton gradient. Two values of delta mu H+, at which 50% of the enzyme is active, were found; 13-14 kJ.mol-1 for untreated membrane vesicles, and 4-8 kJ.mol-1 for light-treated and dithiothreitol-treated membrane vesicles. These values are lower than the corresponding values for the oxidized and reduced forms, respectively, of the chloroplast enzyme. Although no bulk proton gradient could be observed, membrane vesicles of Sp. platensis were able to maintain an equilibrium phosphate potential (delta Gp) of 40-43.5 kJ.mol-1, comparable to values found for Synechococcus 6716 and Anabaena 7120 membrane vesicles. Acid/base-transition experiments showed that the thermodynamic threshold, delta mu H+, for ATP synthesis, catalyzed by light-treated and dithiothreitol-treated Spirulina membrane vesicles, was less than 5 kJ.mol-1. The activation characteristics and the low thermodynamic threshold allow ATP synthesis to occur at low delta mu H+ values. The findings are discussed, both with respect to differences and similarities with the enzymes from chloroplasts and other cyanobacteria, and with respect to the alkalophilic properties of Sp. platensis.

Cellular daunomycin fluorescence in multidrug resistant 2780AD cells and its relation to cellular drug localisation.

Multidrug resistant (MDR) 2780AD human ovarian carcinoma cells were loaded with the fluorescent anticancer agent daunomycin (DN). Fluorescence anisotropy was lower than for corresponding A2780 wild-type cells, indicating that DN was less rigidly bound than in the wild-type cells. Average fluorescence quenching of DN was lower for 2780AD cells. Data were fitted into a model with a highly quenched fraction (fraction A), corresponding to DN intercalated in DNA, and an unquenched fraction (fraction B). The ratio A/B was one order of magnitude lower for the MDR cells than for the wild-type cells. Two other MDR cell lines were investigated and low A/B ratios were found in both cases. Thus, evidence has been provided that in MDR cells the DNA-bound fraction is relatively low and that more free DN is present, for example in acidic vesicles.

The use of carotenoids and oxonol VI as probes for membrane potential in proteoliposomes.

Carotenoids present in lipids extracted from the cyanobacterium Synechococcus 6716 indicate trans-membrane potential in proteoliposomes reconstituted from these lipids and the ATPase complex isolated from the same organism. A carotenoid absorbance band shift to a longer wavelength is obtained with valinomycin-induced potassium ion diffusion potentials, irrespective of the polarity of the potassium gradient. In contrast to this, the (externally added) probe oxonol VI only shows an absorbance band shift when the external potassium ion concentration is higher than the internal one. In liposomes without ATPase complex, no carotenoid absorbance band shifts were observed.

Studies on 9-amino-6-chloro-2-methoxy acridine fluorescence quenching and enhancement in relation to energy transduction in spheroplasts and intact cells of the cyanobacterium Plectonema boryanum.

The fluorescent probe 9-amino-6-chloro-2-methoxy acridine was used to study the energy transduction in the thylakoid and cell membranes of the cyanobacterium Plectonema boryanum. Apart from light-driven electron transfer, the dark endogenous respiration also leads to energization resulting in an ACMA fluorescence response, that is sensitive to the electron flow inhibitor 2, 5-dibromo-3-methyl-6-isopropyl-p-benzoquinone, to the energy transfer inhibitors dicyclohexylcarbodiimide and venturicidine and to the uncoupler 5-chloro-3-t-butyl-2'-chloro-4'-nitrosalicylanilide.In spheroplasts, in which the cell membranes have lost their capacity to maintain a proton gradient, the respiration-and light-induced ACMA fluorescence changes (quenching) are similar to those in chloroplasts. In intact cells a combination of reversible quenching and enhancement of ACMA fluorescence was found. This dualistic behaviour is supposedly caused by an opposite orientation of the thylakoid and cell membranes. ACMA quenching at the level of the thylakoids was obtained either by respiratory or photosynthetic electron transfer and gave similar responses to those obtained in the spheroplasts. The slower ACMA fluorescence enhancement, only observed in cells with intact cell membranes, also evoked by both respiration and light-induced energization is sensitive to the compounds mentioned above and in addition to KCN.Our results support the view [8] that dark oxidation of substrates by O2 proceeds via the thylakoid membrane and terminates at a CN(-) sensitive oxidase located in the cell membrane which requires the involvement of a mobile cytoplasmic redox mediator.

Proton movements and electric potential generation in reconstituted ATPase proteoliposomes from the thermophilic cyanobacterium Synechococcus 6716.

ATP hydrolysis-induced proton translocation and electric potential generation have been studied in ATPase proteoliposomes by means of various optical probes. The proteoliposomes consisted of reconstituted ATPase complex and native lipid mixture isolated from the thermophilic cyanobacterium Synechococcus 6716 [Van Walraven et al. (1983) Eur. J. Biochem. 137, 101-106]. The native cartenoids and added oxonol VI served as probes for the electric membrane potential generated by the net charge separation (negative outside, positive inside). Their responses, with similar half-times as 9-tetradecylamino-6-chloro-2-methoxyacridine, are sensitive to valinomycin and stimulated by nigericin, as expected. The proton concentrations of extraliposomal and intraliposomal aqueous spaces were monitored by neutral red and cresol red; for internal measurements these pH indicators were trapped inside the vesicles during detergent dialysis. Internal acidification and external alkalinization induced by ATP hydrolysis are inhibited by nigericin and enhanced by valinomycin; at the commonly used higher valinomycin concentrations the neutral red response becomes transient, while the much slower cresol red response is diminished right from its onset. At smaller preset pH gradients both ATP hydrolysis activity and neutral red response are diminished. At increasing MgCl2 concentrations the neutral red responses are slowed down and the cresol red responses are slightly enhanced; this is observed for both internal and external dye responses. Neutral red permeation through the membrane is insignificant under our experimental conditions but is enhanced at temperatures below the lipid-phase transition. In the case of externally added neutral red the non-permeant buffer Hepes is only effective at high MgCl2 concentration, whereas some external cresol red response is visible only at high MgCl2 concentration in the presence of Hepes. The kinetics of the pH indicator and electric potential probe responses clearly distinguish fast interfacial and intra-membrane proton displacements from slow bulk proton equilibration. The data are summarized in a model that supports the importance of localized proton displacements for the primary energy-transducing events.

Lipid specificity for the reconstitution of well-coupled ATPase proteoliposomes and a new method for lipid isolation from photosynthetic membranes.

The lipid specificity for the enzymatic and proton-translocating functions of a reconstituted thermophilic ATPase complex has been investigated. The proteoliposomes were prepared from the ATPase complex of the thermophilic cyanobacterium Synechococcus 6716 and various lipids and lipid mixtures extracted from this organism and from a related mesophilic strain. Some commercial lipids were used as well. An improved method of lipid extraction from chlorophyll-containing membranes is presented. This method is based on acetone extraction and additional chlorophyll separation and results in higher yields, less chlorophyll contamination and a simpler procedure than the conventional methods based on chloroform/methanol extraction. The lipids of Synechococcus 6716 thus extracted were fractionated by thin-layer chromatography. The fatty acyl chain composition of the separated lipids was analyzed by gas chromatography. The coupling quality of the reconstituted ATPase proteoliposomes made of different lipids was tested by a membrane-bound fluorescent probe and uncoupler stimulation of ATP hydrolysis. None of the separated lipids alone was able to produce a well-coupled system. The best results were obtained with the native lipid mixture. The minimum requirement was the combination of a typical bilayer-forming lipid and the non-bilayer (hexagonal II structure)-forming monogalactosyldiacylglycerol. Lipids from the mesophilic Synechococcus 6301 and commercial lipids (also mesophilic) produced poorly coupled vesicles but significant improvement was obtained when thermophilic monogalactosyldiacylglycerol was included. Both the reconstituted and solubilized ATPase complex have a sharp temperature optimum at 50 degrees C. The effect of reconstitution and measurement temperatures on the yield of well-coupled vesicles from different lipid sources was also studied.