Solvent relaxation in lipid bilayers with dansyl probes

The solvent relaxation properties of the dansyl group attached to two lipids (dansylphosphatidylethanolamine and dansylphosphatidylserine), a fatty acid (dansylundecanoic acid), and two drugs (dansylbenzocaine and dansylpropranolol) were compared in a variety of different lipid systems. Several methods for characterising solvent relaxation were compared in detail for dansylpropranolol in bilayer vesicles of egg phosphatidylcholine. It was shown that the relaxation process is non-monoexponential; nevertheless, for comparative purposes, a model was adopted in which the lifetime associated with the negative exponent in a two exponential decay analysis, obtained at a particular energy on the red edge of emission, was taken as an approximation to a 'solvent relaxation' rate. A negative exponent, indicative of solvent relaxation processes, occurring in the nanosecond time-scale, was found only for dansylpropranolol, dansylPE and dansylundecanoic acid. On addition of the spin probe, 5-doxylstearate, the negative exponent was unaffected in liquid-crystalline phase lipids but was no longer found in gel-phase lipid in the case of dansylpropranolol, while for dansylPE the relaxation time was reduced. On the basis of these types of measurement it was possible to distinguish between different lipid environments using the same probe or between different dansyl environments of the different probes in the same lipid in cases where this would have been difficult or impossible solely on the basis of steady-state or fluorescence lifetime measurements.     

Photoaffinity spin-labeling of the Ca2+ ATPase in sarcoplasmic reticulum : Evidence for oligomeric structure

A spin labeled fatty acid (16-doxylstearic acid) was linked to a photochemical reacting group (azido derivative). When the molecule is introduced, at a low concentration, into rabbit sarcoplasmic reticulum membranes, the spectrum before illumination is identical to the spectrum obtained with the corresponding spin labeled fatty acid. After illumination, a large immobilized components is seen. It corresponds to about 70% of the ESR signal of the effectively bound label, at room temperature. The fraction of immobilized component varies with temperature, from 100% at 0°C to 50% at 35°C. Addition of a small amount of detergent (dodecyl octaethylene glycol monoether), under non solubilizing conditions, decreases the fraction of signal due to a strongly immobilized probe. A possible interpretation is that the immobilized signal reflects protein bound spin labels trapped in Ca²⁺ ATPase oligomers, which are partially dissociated by detergent addition or temperature increase.     

Interactions of pyrene derivatives with lipid bilayers and with (Ca2+-Mg2+)-ATPase

The intensities of fluorescence emission for pyrene and a number of its derivatives increase on binding to lipid bilayers and to the (Ca2+-Mg2+)-ATPase purified from rabbit muscle sarcoplasmic reticulum. The effect is particularly marked for the less water-soluble derivatives. Changes in intensity for monomer and excimer emission as a function of lipid concentration can be fitted to a simple model to obtain binding parameters. The number of binding sites per lipid is 0.2-0.4. For the ATPase system, at least two classes of sites are necessary to fit the data, one corresponding to the lipid component and one to sites on the ATPase. Excimer emission from the postulated sites on the ATPase is less marked than that from lipid. Pyrene-dodecanoic acid and pyreneundecyltrimethylammonium bromide, which bind to a large number of sites on the ATPase, cause marked inhibition of ATPase activity at high concentration. Pyrene and a number of water-soluble derivatives cause stimulation of the ATPase reconstituted with dimyristoleoylphosphatidylcholine and little inhibition and bind to a small number of sites on the ATPase. It is concluded that excimer emission from pyrene derivatives in systems containing proteins cannot be used to obtain reliable information about rates of diffusion in the lipid component of the membrane.     

Fluorescence and kinetic studies of the interactions of pyrethroids with the (Ca2(+) + Mg2+)-ATPase

The fluorescence quenching properties of a series of brominated and iodinated pyrethroids have been used to study the binding of pyrethroids to the (Ca2(+) + Mg2+)-ATPase purified from skeletal muscle sarcoplasmic reticulum. It is suggested that binding at the lipid/protein interface of the ATPase is weak but that binding can occur at other (non-annular sites) on the ATPase. Pyrethroids containing either a brominated fatty acyl or iodinated alcohol moiety quench the tryptophan fluorescence of the ATPase, suggesting that the pyrethroids bound to the ATPase adopt a folded conformation with both the acid and alcohol moieties in contact with hydrophobic regions of the ATPase. Whereas effects of the pyrethroids on the activity of the ATPase in bilayers of dioleoylphosphatidylcholine are small, large increases are observed in the activity of the ATPase reconstituted into bilayers of the short-chain phospholipid, dimyristoleoylphosphatidylcholine (DMPC). The rate of phosphorylation of DMPC-ATPase by ATP is slow, but is increased on addition of pyrethroid. The level of phosphorylation of the ATPase by Pi is reduced on reconstitution into bilayers of DMPC, and this is also increased by addition of pyrethroid.     

The fatty acid analogue 11-(dansylamino)undecanoic acid is a fluorescent probe for the bilirubin-binding sites of albumin and not for the high-affinity fatty acid-binding sites.

1. The fluorescent fatty acid probe 11-(dansylamino)undecanoic acid (DAUDA) binds with high affinity to bovine and human serum albumin (BSA and HSA) at three sites. 2. The Kd of the primary binding site could not be determined; however, the two secondary sites appeared to be equivalent, with an apparent Kd of 8 x 10(-7) M for both BSA and HSA. 3. The spectral characteristics of DAUDA when bound to the primary site of the two albumins were different, with HSA producing a greater fluorescence enhancement and emission maximum at a shorter wavelength (480 nm) than for BSA (495 nm). 4. Displacement studies indicated that the DAUDA-binding sites were not equivalent to the primary long-chain fatty acid-binding sites on albumin, but corresponded to the bilirubin sites. Fatty acyl-CoAs also bind to the bilirubin sites, as do medium-chain fatty acids. 5. The solubility, stability and spectral properties of DAUDA make it an excellent probe for investigating the bilirubin-binding sites of albumin, particularly HSA.     

Fitting fluorescence emission spectra of probes bound to biological membranes

We show that fluorescence emission spectra for molecules containing the dansyl fluorophor can be accurately described as skewed Gaussians, and that spectra for dansyl probes bound to biological membranes can be resolved using least-squares techniques into two components, representing probe bound to the lipid and protein sites in the membrane.     

Interactions of phenytoin with rat brain synaptosomes examined by fluorescent fatty acid probes

Phenytoin (PHT) modified the fluorescent characteristics of anthroyloxy-fatty acids in synaptosomal membranes. Association of PHT with synaptosomal membranes caused the greatest change when the fluorescent probe was located at the 6-carbon position of N-(anthroyloxy)stearic acid and was incorporated into the membranes. Phenytoin and 6-(anthroyloxy)stearic acid compete for high affinity binding regions which are probably lipid domains within the membrane. Phenytoin has a weaker association with the sites than the fluorescent fatty acids. Divalent cations, e.g. Mg²⁺ or Ca²⁺, are required to observe maximal change in polarization of fluorescence of fatty acid probes in the presence of PHT. It is proposed that the membrane lipid bilayer reorganizes to accommodate exogenous compounds, such as phenytoin or the fatty acid probe in order to permit the most efficient packing of lipids. This reorganization of the lipid bilayer may influence membrane enzyme activities and ion channels.     

Effects of lipids and long-chain alkyl derivatives on the activity of (Ca2+-Mg2+)-ATPase

The ATPase activity of the (Ca2+-Mg2+)-ATPase reconstituted into bilayers of phosphatidylcholines depends on the fatty acyl chain length of the phospholipids. It is shown that the fluorescence response to Ca2+ of the ATPase modified with fluorescein isothiocyanate is also dependent on phospholipid structure and is interpreted in terms of a change in the equilibrium between two forms of the ATPase, E1 and E2. A kinetic scheme for the ATPase is presented in which ATPase activity is markedly dependent on the rate of the transition between two phosphorylated forms of the ATPase, E1'PCa2 and E2'PCa2, and it is postulated that changing the phospholipid structure changes this rate. The rate of dephosphorylation of the ATPase and the ATP dependence of the E1'PCa2-E2'PCa2 transition are also lipid dependent. Binding of oleyl alcohol causes large, lipid-dependent changes in ATPase activity, and these are interpreted in terms of changes in the rates of these same steps. Oleylamine, which has been shown to bind more strongly at annular sites than at nonannular sites, inhibits ATPase activity irrespective of lipid structure, whereas fatty acids, which bind less strongly at annular sites, only inhibit at high concentrations. Methyl oleate, which binds more strongly at nonannular sites than at annular sites, causes marked stimulation for the ATPase reconstituted with short-chain lipids.     

Intra-albumin migration of bound fatty acid probed by spin label ESR

Conventional ESR spectra of 16-doxyl-stearic acid bound to bovine and human serum albumin were recorded at different temperatures in order to investigate the status of spin-labeled fatty acid in the interior of the protein globule. A computer spectrum simulation of measured spectra, performed by non-linear least-squares fits, clearly showed two components corresponding to strongly and weakly immobilized fatty acid molecules. The two-component model was verified on spectra measured at different pH. Thermodynamic parameters of the spin probe exchange between two spin probe states were analyzed. It was concluded that at physiological conditions, fatty acid molecules permanently migrate in the globule interior between the specific binding sites and a space among albumin domains.     

Temperature-induced transitions of function and structure in sarcoplasmic reticulum membranes

A transition in the temperature dependences of Ca²⁺ accumulation and ATPase activity occurs at 20 ° C in Sarcoplasmic reticulum membranes. The transition is characterized by an abrupt change in the activation energies for the cation transport process and the associated enzyme activities. The difference in activation energies below and above 20 °C appears to be due to changes in the entropy of activation rather than in the free energy of activation. Also, the temperature dependences of spectral parameters of lipophilic spin-labeled probes and protein-bound spin labels exhibit different behaviors on either side of this temperature. Above 20 °C the lipid matrix probed by the labels exhibits a large increase in molecular motion and a decrease in the apparent ordering of lipid alkyl chains. In addition, labels covalently bound to enzymic reactive sites indicate that the motion of protein side-chains is sensitive to this transition. The results are consistent with an order-disorder transition involving the lipid alkyl chains of the Sarcoplasmic membrane, and with a model in which molecular motion, Ca²⁺ transport and enzyme activity are limited by local viscosity of hydrophobic regions at temperatures below the transition.Another modification of the Sarcoplasmic reticulum membrane occurs between 37 and 40 °C. It appears that at this temperature the processes governing Ca²⁺ accumulation and ATPase activity are uncoupled, and Ca²⁺ accumulation is inhibited, while ATPase activity and passive Ca²⁺ efflux proceed at rapid rates. Parallel transitions of spectroscopic parameters originating from spin labels, covalently bound to the Sarcoplasmic reticulum ATPase, indicate that the uncoupling is due to a thermally-induced protein conformational change.     

Photoaffinity labelling of submitochondrial membranes with the 3-azido analogue of 9-amino-3-chloro-7-methoxyacridine

9-Amino-3-azido-7-methoxyacridine has been synthesized and shown to be a suitable photoaffinity probe for the site(s) of interaction of 9-amino-3-chloro-7-methoxyacridine with submitochondrial membranes. Both the excitation and emission spectra of the azido analogue covalently bound to membranes in the energized state display distinctive differences from the spectra of labelled, non-energized membranes (i.e., in the absence of oxidizable substrate, or its presence when uncoupler (FCCP) is also present during photolysis). Enzymatic analyses indicate that the probe interacts with the ATPase and the respiratory chain enzymes; energization appears to afford some protection against inactivation. Electrophoresis of the labelled membranes and isolation of their lipid and protein components indicate that the spectral differences are attributable to differing interactions with the lipid components of energized, relative to non-energized, membranes. Similar results have been obtained with the 3-azido analogue of quinacrine (Mueller, D.M., Hudson, R.A. and Lee, C.P. (1982) Biochemistry 21, 1445-1453), which differs significantly, however, in the extent of its interactions with the enzymes of the respiratory chain and the ATPase. These results indicate that the energy-linked fluorescence responses of 9-aminoacridines with submitochondrial membranes arise from direct interactions with membrane components and may involve redistribution of the probe molecules and/or alteration of their microenvironments upon energization.     

A fluorescent derivative of the oligomycin-sensitivity conferring protein (acrylodan-OSCP). Evidence for polarity changes in the environment of CYS118 of OSCP upon binding to mitochondrial F1

The fluorescent probe, 6-acryloyl-2-dimethylaminonaphtalene (acrylodan) was reacted with the oligomycin-sensitivity conferring protein (OSCP). Acrylodan bound covalently to the single cysteinyl residue of the protein. Acrylodan-OSCP was fully competent in conferring oligomycin sensitivity to the mitochondrial F0-F1 ATPase complex. The fluorescence emission peak of acrylodan-OSCP was blue-shifted compared to that of an acrylodan-mercaptoethanol adduct, which means that acrylodan experiences a hydrophobic environment in OSCP. Binding of acrylodan-OSCP to the isolated F1 was accompanied by a red shift of fluorescence. It was achieved in less than 1 s at 25 degrees C. The titration curve revealed one high affinity OSCP binding site per F1. Acrylodan-OSCP appears to be an interesting tool for studying the dynamics of structural changes within the mitochondrial ATPase complex.     

Fatty acids covalently bound to erythrocyte proteins undergo a differential turnover in vivo

Recently, covalently bound fatty acids have been identified on a variety of proteins. Many of these acyl proteins are physiologically important, and the lipid modification often appears to be essential for their function. In this investigation mature erythrocytes have been used to study in detail the metabolic behavior of protein-bound fatty acids. Although deficient in protein synthesis, these cells are still able to covalently attach [3H]palmitic acid to proteins located at the plasma membrane and its associated cytoskeleton. Linkage analyses demonstrated that the labeled polypeptides contained ester- or thioester-bound fatty acids. The covalent binding of fatty acid was rapidly reversible. Half-lives of the protein-bound fatty acid molecules ranged from less than 30 min to more than 3 h. The deacylation reaction was not due to a chemically labile linkage of protein and fatty acid but appeared to be physiologically induced. Differences in the fatty acid turnover rates between the acyl proteins suggested an independent regulation of their lipid turnover. A number of proteins underwent dynamic fatty acid acylation, indicating that palmitylated proteins undergoing fatty acid turnover are not a rare exception.     

Interaction with membrane lipids and heme ligand binding properties of Escherichia coli flavohemoglobin

Escherichia coli flavohemoglobin has been shown to be able to bind specifically unsaturated and/or cyclopropanated fatty acids with very high affinity. Unsaturated or cyclopropanated fatty acid binding results in a modification of the visible absorption spectrum of the ferric heme, corresponding to a transition from a pentacoordinated (typical of the ligand free protein) to a hexacoordinated, high spin, heme iron. In contrast, no detectable interaction has been observed with saturated fatty acid, saturated phospholipids, linear, cyclic, and aromatic hydrocarbons pointing out that the protein recognizes specifically double bonds in cis conformation within the hydrocarbon chain of the fatty acid molecule. Accordingly, as demonstrated in gel filtration experiments, flavohemoglobin is able to bind liposomes obtained from lipid extracts of E. coli membranes and eventually abstract phospholipids containing cis double bonds and/or cyclopropane rings along the acyl chains. The presence of a protein bound lipid strongly affects the thermodynamic and kinetic properties of imidazole binding to the ferric protein and brings about significant modifications in the reactivity of the ferrous protein with oxygen and carbon monoxide. The effect of the bound lipid has been accounted for by a reaction scheme that involves the presence of two sites for the lipid/ligand recognition, namely, the heme iron and a non-heme site located in a loop region above the heme pocket.     

Interaction of spin-labeled nicotinamide adenine dinucleotide phosphate with chicken liver fatty acid synthase

The spatial relationships between the four reduced nicotinamide adenine dinucleotide phosphate (NADPH) binding sites on chicken liver fatty acid synthase were explored with electron paramagnetic resonance (EPR) and spin-labeled analogues of NADP+. The analogues were prepared by reaction of NADP+ with 2,2,5,5-tetramethyl-1-oxy-3-pyrroline-3-carboxylic acid, with 1,1'-carbonyldiimidazole as the coupling reagent. Several esterification products were characterized, and the interaction of the N3' ester of NADP+ with the enzyme was examined in detail. Both 1H13, 14N and 2H13, 15N spin-labels were used: the EPR spectrum was simpler, and the sensitivity greater, for the latter. The spin-labeled NADP+ is a competitive inhibitor of NADPH in fatty acid synthesis, and an EPR titration of the enzyme with the modified NADP+ indicates four identical binding sites per enzyme molecule with a dissociation constant of 124 microM in 0.1 M potassium phosphate and 1 mM ethylenediaminetetraacetic acid (pH 7.0) at 25 degrees C. The EPR spectra indicate the bound spin-label is immobilized relative to the unbound probe. No evidence for electron-electron interactions between bound spin-labels was found with the native enzyme, the enzyme dissociated into monomers, or the enzyme with the enoyl reductase sites blocked by labeling the enzyme with pyridoxal 5'-phosphate. Furthermore, the EPR spectrum of bound ligand was the same in all cases. This indicates that the bound spin-labels are at least 15 A apart, that the environment of the spin-label at all sites is similar, and that the environment is not altered by major structural changes in the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Labeling of a thiol residue in sarcoplasmic reticulum ATPase by pyrene maleimide. Solvent accessibility studied by fluorescence quenching

Sarcoplasmic reticulum ATPase was specifically labeled by the fluorescent probe N-(1-pyrene)maleimide which modified 1 mol of a highly reactive thiol residue per mol of ATPase under appropriate conditions, when the probe concentration was varied in the range 0.1-1.5 microM. Addition of inorganic phosphate to the labeling medium increased both the rate of labeling and the number of modified thiol residues. Addition of ATP gave a marked kinetic protection from labeling, suggesting that the label was attached to a protein domain which is sensitive to changes at the catalytic site. Quenching of pyrene fluorescence emission of labeled ATPase by acrylamide and cesium chloride gave linear Stern-Volmer plots. The Stern-Volmer quenching constants of pyrene-ATPase fluorescence were 10 times lower than the constant obtained for acrylamide quenching of the fluorescent adduct of pyrene-maleimide-cystein used as a control, indicating that the pyrene moiety of the probe was considerably shielded from the medium solvent when covalently attached to the ATPase. The efficiency of quenching of pyrene-ATPase fluorescence increased by a significant amount upon addition of 100 microM Ca2+, when compared to the quenching in the presence of a Ca2+ chelator. It suggests that occupancy of the high affinity Ca2+ sites of the ATPase increases the accessibility of medium solvent into hydrophobic domains of the enzyme. The fluorescence lifetime of the solubilized pyrene-ATPase emission was 144-149 ns. The fluorescence polarization of pyrene-ATPase solubilized by nonionic detergent C12E8 was rho = 0.10 and it increased with an increase in the viscosity of the medium yielding a linear Perrin plot. The rotational correlation time for the soluble ATPase was 532 ns, corresponding to the overall rotation of a detergent-pyrene-ATPase particle with radius of 87A.     

S-(N-dansylaminoethyl)-6-mercaptoguanosine as a fluorescent probe for the uridine transport system in human erythrocytes.

A fluorescent derivative of 6-mercaptoguanosine, S-(N-dansylaminoethyl)-6-mercaptoguanosine, was synthesized, and found to be a strong inhibitor of the uridine transport system of erythrocyte (Ki approximately 0.3 microM). The emission spectrum of this compound has peaks at 400 and 550 nm. The emission at 550, but not that a 400 nm, in environment-sensitive. A method was devised for preparing a suspension of erythrocyte-membrane fragments with sufficiently low light scattering so that a detailed study could be made of the fluorescence of the probe when bound to membranes. Direct binding measurements showed the existence of a tight binding site, with a dissociation constant of the same order of magnitude as the inhibition constant. Binding of probe and substrate are not mutually exclusive, but the fluorescence and affinity of the bound probe are sensitive to the presence of uridine. The emission spectrum suggests that the bound probe penetrates into the bilayer region of the membrane.     

Association of the internal membrane protein with the lipid bilayer in influenza virus. A study with the fluorescent probe 12-(9-anthroyl)-stearic acid

The lipid fluorescent probe 12-(9-anthroyl)-stearic acid was introduced into the lipid bilayer of influenza virus particles. Fluorescent energy transfer was observed from the viral protein to the probe. This transfer persisted after removal of the glycoprotein spikes which cover the outside of the viral particle, demonstrating that the energy donor was an internal protein. It was concluded that the energy donor was the non-glycosylated membrane protein (M protein), the major protein component of the spikeless particle. Analysis of the emission spectrum of the spikeless particle excited at 275 nm shows that a substantial portion of the fluorescence arises from tyrosine residues, in contrast to most other proteins which contain both tryptophan and tyrosine.It is suggested that the donor residue(s) are located no more than 11 Å exterior to the bilayer surface, and that a portion of the M protein may penetrate into the bilayer.