Merocyanine 540, a fluorescent probe sensitive to lipid packing

Binding of the lipophilic probe merocyanine 540 to artificial bilayers was assessed by measuring the enhancement of fluorescence which results when dye enters the hydrophobic environment of the membrane. Titration of a constant amount of dye with increasing amounts of vesicles revealed that much more dye binds to multilamellar and 1000-Å, unilamellar vesicles which are in the fluid-phase state than to comparable vesicles which are in the gel-phase state. Incorporation of cholesterol into fluid-phase vesicles at levels of greater than 20 mol% reduced dye binding, whereas cholesterol had no effect at any concentration when incorporated into gel-phase vesicles. Sonicated 200–300-Å unilamellar gel-phase vesicles, which because of their reduced radius of curvature resemble fluid-phase bilayers in their more widely spaced exterior leaflet lipids, bound more dye than 1000-Å unilameilar gel-phase vesicles constructed from the same lipid. These results suggest that merocyanine 540 is able to sense the degree of lipid packing of bilayers and inserts preferentially into bilayers whose lipids are more widely spaced.     

Merocyanine 540 as a fluorescent probe of membranes: staining of electrically excitable cells.

With the exception of certain blood cells considered in the accompanying paper (Valinsky, Easton and Reich, 1978), merocyanine 540 (MC 540), a fluorescent membrane probe, selectively strains the membranes of a wide variety of electrically excitable cells, but not those of nonexcitable cells. This reaction is Ca2+-dependent when staining is performed in buffered iso-osmotic sucrose, Ca2+-independent when staining proceeds at high ionic strength, inhibited by La3+ and sodium Suramin, enhanced by controlled, low level photosensitization of cell-associated dye and essentially irreversible. These characteristics of the staining reaction depend upon the maintenance of both cell viability and a normal unperturbed membrane structure. Although the mechanisms involved in the staining specificity remain unknown, observation of MC 540 partitioning between benzene and water in model reactions indicates that dye transport into hydrophobic solvents is accompanied by the formation of stoichiometric complexes with cations and phospholipids. These results may suggest the existence of specific, possibly phospholipid-rich membrane domains that mediate complex formation with MC 540 in excitable cells; comparable domains either would not exist, or would be inaccessible at the external surfaces of nonexcitable cells.     

Merocyanine 540 as a fluorescent probe of membranes: selective staining of leukemic and immature hemopoietic cells.

We have reported (Easton, Valinsky and Reich, 1978) that merocyanine 540 (MC 540) specifically stains a variety of living excitable cells, but not nonexcitable cells. This paper describes the exceptional permeability to MC 540 of leukemic leukocytes and immature hemopoietic precursor cells. We have used fluorescence microscopy and uptake of radioactive dye to study MC 540 staining of peripheral blood leukocytes from 80 leukemic and 34 normal individuals; leukemic leukocytes stain, whereas normal leukcytes do not. The leukocyte staining reaction differs from that previously described for excitable cells since it is independent of the ionic composition of the staining medium, kinetically complex, enhanced by light, enhanced by oxygen and essentially irreversible. Virtually all circulating nucleated cells from leukemic individuals are stained to approximately the same extent, and there is no qualitative or quantitative distinction between the various forms of leukemia. We have also found that MC 540 interacts with granulopoietic colony-forming cells (CFU-C) and with spleen colony-forming cells derived from mouse bone marrow (CFU-S). We cannot as yet identify a specific property of leukocyte plasma membranes that determines MC 540 permeability; since changes in MC 540 uptake appear to be correlated with cellular maturation during normal hemopoiesis, the retention of staining by leukemic cells, some of which appear morphologically normal, may indicate of failure in membrane maturation during leukemic blood cell development.     

Merocyanine 540 as a fluorescent probe of altered membrane phospholipid asymmetry in activated whole blood platelets

BACKGROUND: Platelet activation leads to the loss of a natural asymmetry of membrane phospholipids (PL) and the subsequent exposure of negatively charged PL in platelets with procoagulant activity that can be monitored routinely with annexin V (AN-V). METHODS: Flow cytometric analysis of merocyanine 540 (MC540) binding may be the alternate choice for the monitoring of platelet procoagulant activity. Due to the increased partition of negatively charged phosphatidylserine (PS) in the membrane outer leaflet of activated platelets, the interaction with MC540 is reduced. RESULTS: Collagen, which facilitated platelet PL bilayer symmetrization, vastly reduced MC540 fluorescence and augmented AN-V binding to platelets. Such a collagen-induced symmetrization was further augmented in the presence of thrombin receptor-activating peptide (TRAP, SFLLRNPNDKYEPF). In the presence of VO(4) ((-3)) (the inhibitor of aminophospholipid translocase), the rebuilt of membrane asymmetry was attenuated, which resulted in further reduced MC540 fluorescence and enhanced AN-V binding in activated cells. In platelets incubated with thapsigargin, the inhibitor of platelet tubular system Ca(2+) ATP-ase, which elevates intraplatelet Ca(2+) concentration, TRAP increased AN-V and reduced MC540 binding. The chelating of Ca(2+) with EGTA outside of activated platelets reduced AN-V binding, but did not affect MC540-positive platelets. The fluctuations in reduced staining with MC540 paralleled enhanced AN-V binding (r = -0.481, P < 0.01), especially for strong "procoagulant" activating agents. CONCLUSIONS: (1) MC540 may be used in whole blood flow cytometry for the monitoring of platelet membrane symmetrization as an alternate or compounding method to AN-V. (2) Platelet staining with MC540 is sensitive to the fluctuations in the intraplatelet [Ca(2+)] during platelet activation. (3) Use of MC540 is characterized by improved diagnostic precision and reliability compared with AN-V.     

Temperature dependence of the lipid packing in thylakoid membranes studied by time- and spectrally resolved fluorescence of Merocyanine 540

The lipid packing of thylakoid membranes is an important factor for photosynthetic performance. However, surprisingly little is known about it and it is generally accepted that the bulk thylakoid lipids adopt the liquid-crystalline phase above -30 degrees C and that a phase transition occurs only above 45 degrees C. In order to obtain information on the nature of the lipid microenvironment and its temperature dependence, steady-state and time-resolved fluorescence measurements were performed on the fluorescence probe Merocyanine 540 (MC540) incorporated in isolated spinach thylakoids and in model lipid systems (dipalmitoyl phosphatidylcholine and dioleoyl phosphatidylethanolamine) adopting different phases. It is demonstrated that the degree and way of incorporation differs for most lipid phases--upon selective excitation at 570 nm, the amplitude of the fluorescence component that corresponds to membrane-incorporated MC540 is about 20% in gel-, 60% in rippled gel-, and 90% in liquid-crystalline and inverted hexagonal phase, respectively. For thylakoids, the data reveal hindered incorporation of MC540 (amplitude about 30% at 7 degrees C) and marked spectral heterogeneity at all temperatures. The incorporation of MC540 in thylakoids strongly depends on temperature. Remarkably, above 25 degrees C MC540 becomes almost completely extruded from the lipid environment, indicating major rearrangements in the membrane.     

Molecular packing of a crystalline ether-linked phosphatidylcholine: an electron diffraction study

Electron diffraction data from solution- and epitaxially-crystallized samples of 1,2-dihexadecyl-sn-glycerophosphocholine are used in an analysis of its molecular packing in the minimally hydrated crystal form. The molecular chain axes are found to be perpendicular to the bilayer plane and the chains pack in the hexagonal methylene subcell. Translational search of a model based on a known diacyl phosphatidylcholine crystal structure indicates that a crystallographic residual minimum corresponds to a headgroup packing distance similar to values found for the dipalmitoyl analog at low relative humidity. The bilayer packing for the ether-linked phosphatidylcholine is therefore similar to the one reported for a sphingomyelin.     

Amphotericin B-sterol complex formation and competition with egg phosphatidylcholine: a monolayer study

The conditions of formation of amphotericin B-cholesterol or -ergosterol complexes in monolayers are investigated by the penetration into a monolayer of egg phosphatidylcholine/sterol of 14C-labelled N-fructosyl-amphotericin B dissolved in the aqueous subphase. An increase of both surface pressure and radioactivity as a function of concentration are observed simultaneously while a 'saturation' effect occurs only for the surface pressure. The experiments are not accurate enough to make conclusions about the number of actually penetrated amphotericin B molecules. Therefore, the existence of an amphotericin B-sterol complex was evidenced from a study of surface pressure area per molecule isotherm. The results indicate that a complex with a 2:1 stoichiometry is formed and that the amphotericin B-ergosterol interaction is larger than the amphotericin B-cholesterol interaction. The complex is dissociated by addition of egg phosphatidylcholine due to a competition between egg phosphatidylcholine and amphotericin B for sterol.     

Microcrystals of the annexin, p68: paracrystal to crystal transition and molecular packing as determined by electron microscopy and image reconstruction.

The calcium-sensitive, membrane-binding annexin, p68, has been crystallized from solutions of polyethylene glycol and ammonium sulfate. Our electron microscopy and X-ray diffraction data indicate that p68 crystals are tetragonal, in space group P4(1), and have unit cell dimensions of a = b = 68.4 A and c = 209.6 A. The mechanism of crystallization from polyethylene glycol involves a transition from a paracrystalline form to ordered crystals by lateral reordering of chains of molecules extended along the c axis. These chains are directional and might reflect a mechanism whereby the two different ends of (chains of) the p68 molecules interact with different membranes.     

Physical and photophysical characterization of a BODIPY phosphatidylcholine as a membrane probe

Lipids containing the dimethyl BODIPY fluorophore are used in cell biology because their fluorescence properties change with fluorophore concentration (C.-S. Chen, O. C. Martin, and R. E. Pagano. 1997. Biophys J. 72:37-50). The miscibility and steady-state fluorescence behavior of one such lipid, 1-palmitoyl-2-(4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-pentanoyl)-sn-glycero-3-phosphocholine (PBPC), have been characterized in mixtures with 1-stearoyl-2-oleoyl-sn-glycero-3-phosphocholine (SOPC). PBPC packs similarly to phosphatidylcholines having a cis-unsaturated acyl chain and mixes nearly ideally with SOPC, apparently without fluorophore-fluorophore aggregation. Increasing PBPC mole fraction from 0.0 to 1.0 in SOPC membranes changes the emission characteristics of the probe in a continuous manner. Analysis of these changes shows that emission from the excited dimethyl BODIPY monomer self quenches with a critical radius of 25.9 A. Fluorophores sufficiently close (< or =13.7 A) at the time of excitation can form an excited dimer, emission from which depends strongly on total lipid packing density. Overall, the data show that PBPC is a reasonable physical substitute for other phosphatidylcholines in fluid membranes. Knowledge of PBPC fluorescence in lipid monolayers has been exploited to determine the two-dimensional concentration of SOPC in unilamellar, bilayer membranes.     

Effects of epicholesterol on the phosphatidylcholine bilayer: a molecular simulation study

Epicholesterol (Echol) is an epimeric form of cholesterol (Chol). A molecular dynamics simulation of the fully hydrated dimyristoylphosphatidylcholine-Echol (DMPC-Echol) bilayer membrane containing approximately 22 mol % of Echol was carried out for 5 ns. A 3-ns trajectory generated between 2 and 5 ns of molecular dynamics simulation was used for analyses to determine the effects of Echol on the membrane properties. As reference systems, pure DMPC and mixed DMPC-Chol bilayers were used. The study shows that Echol, like Chol, changes the organization of the bilayer/water interface and increases membrane order and condensation, but to a lesser degree. Effects of both sterols are based on the same atomic level mechanisms; their different strength arises from different vertical localizations of Echol and Chol hydroxyl groups in the membrane/water interface.     

A surface film study of the lateral packing of phosphatidylcholine and cholesterol

The interaction between phosphatidylcholine (PC) and cholesterol (CHL) has been studied with equilibrium spreading pressure, and surface balance measurements. The results from the studies of mixed films composed of egg phosphatidylcholine (EPC), dipalmitoylphosphatidylcholine (DPPC) and CHL strongly indicate that all three components are miscible in the films and that CHL interacts randomly with the PCs. Starting from a hexagonal chain packing where two PC fatty acid chains are replaced by one CHL critical proportions arise at CHL mole fractions of 0.20, 0.33, 0.50 and 1.00     

Use of surface enhanced infrared absorption spectroscopy (SEIRA) to probe the functionality of a protein monolayer

We present a novel infrared method to investigate the functionality of a protein monolayer tethered to a metal substrate. The approach employs Surface Enhanced Infrared Absorption Spectroscopy (SEIRAS), which renders high surface sensitivity by enhancing the signal of the adsorbed protein by up to approximately 2 orders of magnitude. We demonstrate that the electrochemically induced absorption changes of a cytochrome c monolayer can be observed with excellent signal-to-noise ratio when the protein is adhered to a modified gold surface. To probe membrane proteins, a concept is introduced for the oriented incorporation into solid supported lipid bilayers. Recombinant cytochrome c oxidase solubilized in detergent is immobilized on a chemically modified gold surface via the affinity of its histidine (His)-tag to a nickel-chelating nitro-triacetic acid (NTA) surface. The protein monolayer is reconstituted into the lipid environment by detergent removal. Changing the orientation of the protein with respect to the metal surface is achieved by inserting the His-tag on either side of the membrane protein surface. Orientational control is mandatory for experiments in which electrons are injected from the electrode into the protein. The presented methodology opens new avenues to study the mechanism of the biomedically relevant class of electron and voltage-gated proteins on the atomic level.     

The behaviour of beta-carotene in the phosphatidylcholine bilayer as revealed by a molecular simulation study

A molecular dynamics (MD) simulation of the fully hydrated bilayer made of 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) and containing beta-carotene (beta-Car) molecules was carried out as a complementary approach to experimental techniques to investigate the orientation of beta-Car in the lipid membrane as well as its influence on the bilayer properties. The bilayer reached thermal equilibrium after 1200 ps of MD simulation and the productive run was carried out for 2800 ps. The results indicate that the carotene rings are located in the region occupied by the carbonyl groups of the POPC gamma-chain with no trace of penetration towards the centre of the bilayer. Carotene exhibits an ordering effect on both the beta- and the gamma-chain. While the fully saturated gamma-chain is affected evenly along, the order of the mono-unsaturated beta-chain is modified mainly below the double bond. In general, a high value of the order parameter and the chain tilt in the range from 11.4 degrees to 26.7 degrees were observed for the beta-Car molecules. However, for chain segment adjacent to methyl groups the value of the order parameter is low and the tilt angle is close to 75 degrees . Moreover, the probability of trans conformation being generally close to 1.0 along the beta-Car chain is reduced for these segments. Our MD simulation study suggests two pools of the preferential orientation of beta-Car: a slightly bent structure corresponding to a small chain tilt angle and a rather stretched structure that corresponds to a higher chain tilt. The results are discussed in the light of experimental findings.     

A comparison of the packing behavior of egg phosphatidylcholine with cholesterol and biogenically related sterols in Langmuir monolayer films

Cholesterol and selected derivatives were studied as mixed Langmuir monolayers with egg phosphatidylcholine (PC). As an extension of our earlier work, which employed binary sterol/PC mixtures, here we examined ternary mixed monolayers containing cholesterol along with an alternate sterol and PC in different molar ratios, using pressure-area isotherms. The ternary systems behaved similarly to the binary sterol/PC systems reported previously, with similar condensation noted for the sterol/PC films. To better understand how variations in sterol structure affect sterol packing in such membrane monolayers, binary mixtures containing cholestenone, cholestanol, and lanosterol with PC were also studied. Cholestanol behaved similarly to cholesterol when incorporated with PC, while cholestenone and lanosterol did not cause as much film condensation. The observed differences in molecular packing, and attributed sterol structural differences, are considered within the context of sterol/phospholipid mixtures in biological membranes.     

Fluorescence recovery spectroscopy as a probe of slow rotational motions.

Pump-and-probe techniques can be used to follow the slow rotational motions of fluorescent labels bound to macromolecules in solution. A strong pulse of polarized light initially anisotropically depletes the ground-state population. A continuous low-intensity beam of variable polarization then probes the anisotropic ground-state distribution. Using an additional emission polarizer, the generated fluorescence can be recorded as it rises towards its prepump value. A general theory of fluorescence recovery spectroscopy (FRS) is presented that allows for irreversible depletion processes like photobleaching as well as slowly reversible processes like triplet formation. In either case, rotational motions modulate recovery through cosine-squared laws for dipolar absorption and emission processes. Certain pump, probe, and emission polarization directions eliminate the directional dependence of either dipole and simplify the resulting expressions. Two anisotropy functions can then be constructed to independently monitor the rotations of either dipole. These functions are identical in form to the anisotropy used in fluorescence depolarization measurements and all rotational models developed there apply here with minor modifications. Several setups are discussed that achieve the necessary polarization alignments. These include right-angle detection equipment that is commonly available in laboratories using fluorescence methods.     

Variable-angle epifluorescence microscopy: a new way to look at protein dynamics in the plant cell cortex

Live-cell microscopy imaging of fluorescent-tagged fusion proteins is an essential tool for cell biologists. Total internal reflection fluorescence microscopy (TIRFM) has joined confocal microscopy as a complementary system for the imaging of cell surface protein dynamics in mammalian and yeast systems because of its high temporal and spatial resolution. Here we present an alternative to TIRFM, termed variable-angle epifluorescence microscopy (VAEM), for the visualization of protein dynamics at or near the plasma membrane of plant epidermal cells and root hairs in whole, intact seedlings that provides high-signal, low-background and near real-time imaging. VAEM uses highly oblique subcritical incident angles to decrease background fluorophore excitation. We discuss the utilities and advantages of VAEM for imaging of fluorescent fusion-tagged marker proteins in studying cortical cytoskeletal and membrane proteins. We believe that the application of VAEM will be an invaluable imaging tool for plant cell biologists.     

Evaluation of uranyl photocleavage as a probe to monitor ion binding and flexibility in RNAs

In order to evaluate uranyl photocleavage as a tool to identify and characterize structural and dynamic properties in RNA, we compared uranyl cleavage sites in five RNA molecules with known X-ray structures, namely the hammerhead and hepatitis delta virus ribozymes, the P4-P6 domain of the Tetrahymena group I intron, as well as tRNA(Phe) and tRNA(Asp) from yeast. Uranyl photocleavage was observed at specific positions in all molecules investigated. In order to characterize the sites, photocleavage was performed in the absence and in increasing amounts of MgCl(2). Uranyl photocleavage correlates well with sites of low calculated accessibility, suggesting that uranyl ions bind in tight RNA pockets formed by close approach of phosphate groups. RNA foldings require ion binding, usually magnesium ions. Thus, upon the adoption of the native structure, uranyl ions can no longer bind well except in flexible and open to the solvent regions that can undergo induced-fit without disrupting the native fold. Uranyl photocleavage was compared to N-ethyl-N-nitrosourea and lead-induced cleavages in the context of the three-dimensional X-ray structures. Overall, the regions protected from ENU attack are sites of uranyl cleavage, indicating sites of low accessibility which can form ion binding sites. On the contrary, lead cleavages occur at flexible and accessible sites and correlate with the unspecific cleavages prevalent in dynamic and open regions. Applied in a magnesium-dependent manner, and only in combination with other backbone probing agents such as N-ethyl-N-nitrosourea, lead and Fenton cleavage, uranyl probing has the potential to reveal high-affinity metal ion environments, as well as regions involved in conformational transitions.     

Cholesterol effects on the phosphatidylcholine bilayer nonpolar region: a molecular simulation study

A 15-ns molecular dynamics (MD) simulation of the fully hydrated dimyristoylphosphatidylcholine-cholesterol (DMPC-Chol) bilayer in the liquid-crystalline state was carried out to investigate the effect of Chol on the hydrocarbon chain region of the bilayer. The last 8-ns fragment of the generated trajectory was used for analyses. As a reference system, a pure DMPC bilayer (M. Pasenkiewicz-Gierula, Y. Takaoka, H. Miyagawa, K. Kitamura, and A. Kusumi, 1999, Biophys. J. 76:1228-1240) simulated for 14 ns was used. The study shows that a Chol-induced increase of the bulk molecular order parameter along both beta- and gamma-chain is mainly caused by a decrease of the average tilt of the chains, because the bulk average number of gauche rotamers/myristoyl chain is not significantly changed by Chol. Nevertheless, for DMPCs located near Chol molecules both the number of gauche rotamers/chain and the chain tilt are decreased. The magnitude of the Chol effect on the PC alkyl chains depends, in addition to the PC-Chol distance, on the side of the Chol molecule (alpha- or beta-face) that the chains are in contact with. This study provides some new insight into the properties of the coexistence region of the partial phase diagram for DMPC-Chol bilayers.