Photoaffinity labeling of the tetrodotoxin binding component ofElectrophorus electricus electroplax

Radioactive azide derivatives of tetrodotoxin (TTX) were synthesized using 2-nitro-4-azidephenyl-[3H]beta alanine for the purpose of photolabeling of the Na channel. Three azide derivatives, N1, N2 and N3, were separated by ion exchange chromatography on Bio-Rex 70 resin and reversed phase high performance liquid chromatography. N3 was more stable and obtained at a higher yield than the other two derivatives. Bioactivity of N3 was one-twentieth of that of TTX. N3 showed reversible binding to membranes of Electrophorus electricus electroplax in the dark with Kd = 30 nM and B max = 5.2 pmol/mg protein. By photoirradiation, irreversible binding of N3 to the membranes was observed. A N3 binding component was solubilized by lubrol PX and partially purified from the electroplax membranes by Sephadex G25 and Sepharose 6B column chromatography. The component, purified 500 fold from the starting membranes, showed molecular weight of 10,000.     

Modification of lipid phase behavior with membrane-bound cryoprotectants

Several derivatives of cholesterol containing oxyethylene headgroups with and without a terminal galactose have been synthesized in order to examine the effects of immobilizing a cryoprotectant at a membrane surface. In this work, we have studied the ability of the triethoxycholesterol (TEC) and triethoxycholesterol galactose (TEC-Gal) derivatives to modulate the phase behavior of phosphatidylcholine and phosphatidylethanolamine membranes. Methods of fluorescence polarization, 31P-NMR and freeze-fracture electron microscopy were employed to monitor these changes in lipid phase behavior. Fluorescence polarization data demonstrated the ability of the derivatives to fluidize gel state and rigidify liquid-crystalline state phosphatidylcholines in a manner similar to that observed for cholesterol. Unlike cholesterol, however, the Tm of dipalmitoylphosphatidylcholine (DPPC) was reduced in a concentration-dependent manner with each of the derivatives. Freeze-fracture electron microscopy and 31P-NMR of DOPE dispersions indicate an increase in the lamellar to hexagonal phase-transition temperature on the order of 10-20 C degrees above room temperature for mixtures with 20 mol% of the derivatives. These results are discussed in terms of the properties exhibited by compounds such as carbohydrates, which are known to serve as cryoprotectants for synthetic and biological membranes.     

Lipid bilayer position and orientation of novel carprofens,modulators of γ-secretase in Alzheimer's disease

γ-Secretase is an integral membrane protein complex and is involved in the cleavage of the amyloid precursor protein APP to produce amyloid-β peptides. Amyloid-β peptides are considered causative agents for Alzheimer's disease and drugs targeted at γ-secretase are investigated as therapeutic treatments. We synthesized new carprofen derivatives, which showed γ-secretase modulating activity and determined their precise position, orientation, and dynamics in lipid membranes by combining neutron diffraction, solid-state NMR spectroscopy, and molecular dynamics simulations. Our data indicate that the carprofen derivatives are inserted into the membrane interface, where the exact position and orientation depends on the lipid phase. This knowledge will help to understand the docking of carprofen derivatives to γ-secretase and in the design of new potent drugs. The approach presented here promises to serve as a general guideline how drug/target interactions in membranes can be analyzed in a comprehensive manner.     

Oxygen gradients in mitochondria examined with delayed luminescence from excited-state triplet probes

Phosphorescent probes are described that are quenchable by dioxygen and that partition into membranes. These probes are derivatives of porphyrin, in which the central metal, either zinc or palladium, induces intersystem crossing to enhance the triplet yield. The location of the probe in a suspension of membranes depends upon the charge distribution of side groups on the porphyrins. Probes that partition into the membrane are sensitive to phase transitions in lecithin artificial membranes. In the mitochondria these membrane probes are within transfer distance from tryptophans in membrane proteins. Although absolute concentrations of oxygen in membranes cannot be determined by this method, by comparing the oxygen dependence of a probe in the aqueous phase with that in the membrane phase under actively respiring and inhibited conditions, it is possible to examine the extent of O2 depletion at the mitochondrial surface. We show that at oxygen tensions of 0.2 microM and higher these gradients are insignificant at usual oxygen consumption rates of mitochondria.     

Polyene--sterol interaction and selective toxicity

From permeability experiments carried out with series of amphotericin B derivatives in both biological and model membranes, it was concluded that derivatives, whose carboxyl group at the C18 position is blocked by substitution, are much more efficient at inducing permeability in ergosterol-containing than in cholesterol-containing membranes, whereas derivatives whose carboxyl group is free and ionizable are equally efficient in both membranes types. Binding measurements on erythrocyte membranes showed that all amphotericin B derivatives simply partition between membrane lipids and aqueous medium, according to their lipid solubility. There is no relationship between binding and efficiency in inducing permeability. Permeability studies carried out on lipidic vesicles containing various sterols showed that: 1) derivatives having their carboxyl free induced permeability of the 'channel' type, regardless of the sterol present, and no detectable permeability in sterol-free membranes; 2) derivatives whose carboxyl group is blocked induce channels only in membranes containing ergosterol or sterols having an alkyl side chain identical to that of ergosterol. In the presence of other sterols or in sterol-free membranes, their ionophoric activity is poor and always of the 'mobile-carrier' type. A model of polyene-sterol interaction is proposed, accounting for the data obtained with both biological and model membranes.     

Phase separation is induced by phenothiazine derivatives in phospholipid/sphingomyelin/cholesterol mixtures containing low levels of cholesterol and sphingomyelin

Lipid rafts are membrane structures enriched in cholesterol, sphingomyelin and glycolipids. In majority raft-mimicking model systems high contents of cholesterol and sphingomyelin (approximately 30 mol%) are used. Existence of raft-like structures was, however, reported also in model and natural membranes containing low levels of cholesterol and sphingomyelin. In the present work differential scanning calorimetry and fluorescence spectroscopy with the use of Laurdan probe was employed to demonstrate the existence of phase separation in model systems containing DPPC with addition of 5 mol% or 10 mol% of both cholesterol and sphingomyelin. Additionally, the influence of three phenothiazine derivatives on phase separation in mixed DPPC/cholesterol/sphingomyelin bilayers was investigated. Chlorpromazine, thioridazine and trifluoperazine were able to induce phase separation in DPPC and DPPC/cholesterol/sphingomyelin bilayers in temperatures below lipid main phase transition. However, only trifluoperazine induced phase separation in temperatures close to or above main phase transition. Trifluoperazine also induced phase separation in bilayers composed of egg yolk PC or DOPC mixed with cholesterol and sphingomyelin. We concluded that presence of lipid domains can be observed in model membranes containing low levels of cholesterol and sphingomyelin. Among three phenothiazine derivatives studied, only trifluoperazine was able to induce a permanent phase separation in phosphatidylcholine/cholesterol/sphingomyelin systems.     

Effect of ring-substituted oxysterols on the phase behavior of dipalmitoylphosphatidylcholine membranes

Oxysterols are oxygenated derivatives of cholesterol that form a class of potent regulatory molecules with diverse biological activity. Given the implications of oxysterols in several physiological/pathophysiological pathways of human diseases, it is important to identify how their presence affects the biophysical properties of cell membranes. In this article we first describe the structure, formation, and biological functions of oxysterols, and previous work on the effect of these molecules on the structure and phase behavior of lipid membranes. We then present results of our X-ray diffraction experiments on aligned multilayers of dipalmitoylphosphatidylcholine (DPPC) membranes containing ring-substituted oxysterols. The effect of these molecules on the phase behavior of DPPC membranes is found to be very similar to that of cholesterol. All the oxysterols studied induce a modulated phase in DPPC membranes, similar to that reported in DPPC–cholesterol membranes. However, some differences are observed in the ability of these molecules to suppress the main transition of the lipid and to induce chain ordering, which might be related to differences in their orientation in the bilayer.     

Microsequence analysis of electroblotted proteins. II. Comparison of sequence performance on different types of PVDF membranes.

The influence of different types of polyvinylidene difluoride (PVDF) membranes on gas phase sequence performance has been evaluated. These PVDF membranes have been classified as either high retention (Trans-Blot and ProBlott) or low retention membranes (Immobilon-P) based on their ability to bind proteins during electroblotting from gels. Initial yields, repetitive yields, and extraction efficiency of the anilinothiazolinone amino acid derivatives have been compared for several standard proteins that have been either electroblotted or loaded onto PVDF membranes by direct adsorption. These results show that the major differences in initial sequence yields between membranes arise from differences in the amount of protein actually transferred to the membrane rather than sequencer-related factors. In contrast to several previous observations from other laboratories, more tightly bound proteins do not sequence with lower initial yields and initial yields are not affected by the ratio of surface area to protein. The stronger binding on high retention PVDF membranes does not adversely affect recoveries of difficult to extract, or very hydrophobic, amino acid derivatives. Several amino acids, especially tryptophan, are actually recovered in dramatically higher yield on high retention membranes compared with either Immobilon or glass filters. At the same time, the protein and peptide binding properties of high retention membranes will frequently improve the repetitive yield by minimizing sample extraction during the sequencer cycle. Stronger protein binding together with improved electroblotting yields offer substantially improved sequence performance when high retention PVDF membranes are used.     

A spin label study of E. coli membrane vesicles

The phase transition in E. coli membrane vesicles has been investigated by the spin labeling technique. N-oxyl-4′,4′-dimethyloxazolidine derivatives of stearic acid were incorporated into the vesicles. The results suggest that there are two phase transitions in these bacterial membrane vesicles (one at ≈20°C and the other at ≈30°C). These two phase transitions may be related to some of the functional properties of the membranes.     

Synthesis and pharmacological properties of TOAC-labeled angiotensin and bradykinin analogs

Angiotensin II (AngII) and bradykinin (BK) derivatives containing the TOAC (2,2,6,6-tetramethylpiperidine-N-oxyl-4-amino-4-carboxylic acid) spin label were synthesized by solid phase methodology. Ammonium hydroxide (pH 10, 50 degrees C, l h) was the best means for reverting nitroxide protonation occurring during peptide cleavage. EPR spectra yielded rotational correlation times for internally labeled analogs that were nearly twice as large as those of N-terminally labeled analogs. Except for TOAC(1)-AngII and TOAC(0)-BK, which showed high intrinsic activities, other derivatives were inactive in smooth muscle preparations. These active paramagnetic analogs may be useful for conformational studies in solution and in the presence of model and biological membranes.     

Preparation and evaluation of polyvinyl alcohol-co-oleylvinyl ether derivatives as tumor-specific cytotoxic systems

A series of poly(vinyl alcohol) amphiphilic derivatives have been prepared to obtain polymeric aggregates in aqueous phase holding thermodynamic instability. The aim was to evaluate their ability to interact with tumor cells eliciting selective cytotoxicity. The poly(vinyl alcohol) derivatives were prepared by partial substitution of poly(vinyl alcohol) (MW 10 kDa) with both oleyl chains and poly(ethylene glycol) monoethyl ethers (PEGMEE) of different molecular weights. The substitution degree was 1.5% for the oleyl chains and 1% for the PEGMEE chains (moles of substituent per 100 mol of hydroxyvinyl monomer). The polyvinyl derivatives obtained easily dissolved in water. Dynamic and static light scattering measurements on the polymer aqueous solutions indicated the formation of polymeric aggregates characterized by low polydispersity (0.232-0.299) and mean size (218-382 nm) in the range suitable for intravenous administration. Moreover, they were characterized by different packing densities and thermodynamic instabilities driving the polymers to interact with hydrophobic membranes. Among the analyzed polymers, the poly(vinyl alcohol)-co-oleylvinyl ether substituted with triethylene glycol monoethyl ether (P10(4)) provided in solution the highest affinity for hydrophobic membranes. P10(4), moreover, was the most cytotoxic toward the tumor cell lines analyzed (neuroblastoma: SH-SY5Y, IMR-32, HTLA-230. melanoma: MZ2-MEL, RPMI7932.), while it did not appreciably alter the viability of the normal resting lymphocytes. The peculiar behavior of the P10(4) aggregates has been correlated to their high thermodynamic instability in solution due to the high packing density that triggers the polymeric aggregates to interact with hydrophobic membranes such as the tumor cell membranes, thus eliciting cytotoxicity.     

The influence of dolichol, dolichol esters, and dolichyl phosphate on phospholipid polymorphism and fluidity in model membranes

The effect of dolichols, polyprenols, dolichol esterified with fatty acids, and dolichyl phosphate on the structure and fluidity of model membranes was studied using 31P NMR, small-angle x-ray scattering, differential scanning calorimetry, and freeze-fracture electron microscopy. These studies suggest that dolichol and dolichol derivatives destabilize unsaturated phosphatidylethanolamine containing bilayer structures and promote hexagonal II phase formation; high concentrations of dolichol induce lipid structures characterized by "isotropic" 31P NMR and particulate fracture faces; dolichol, contrary to cholesterol, has no effect on the thermotropic behavior of membranes consisting of phosphatidylcholine, while dolichyl-P incorporation abolishes the transition from the gel to liquid crystalline phase in 1,2-dimyristoyl-sn-glycero-3-phosphocholine; both dolichol and dolichyl-P increase the fatty acid fluidity in phosphatidylethanolamine mixtures; the effect of dolichol on bilayer structure and fluidity is more pronounced with increasing number of isoprene residues; dolichol esters are only soluble to a limited extent in the bilayer and segregates into domains at low concentrations; the results are consistent with a localization of dolichyl-P in which the phosphate group is oriented to the water interphase. The induction of hexagonal II phase by dolichyl-P may elicit the transmembrane movement of glycosylated lipid intermediate.     

Role of membrane charge and semiquinone structure on naphthosemiquinone derivatives and 1,4-benzosemiquinone disproportionation and membrane-buffer distribution coefficients.

Semiquinone membrane/buffer partition coefficients have been determined for 1,2-naphthosemiquinone (ONQ.-), 1,4-naphthosemiquinone (NQ.-) and two of its hydroxylated derivatives, 5,8-dihydroxy-1,4-naphthosemiquinone (NZQ.-) and 5-hydroxy-1,4-naphthosemiquinone (JQ.-) as a function of membrane charge in multilamellar vesicles of phosphatidylcholine (PC) and equimolar mixtures of this lipid and phosphatidic acid (PC:PA) and cetyltrimethylammonium bromide (PC:CTAB) at physiological pH with the exception of values corresponding to PC:PA mixtures which were obtained at pH 9. These coefficients follow the order PC:PA < PC < PC:CTAB in agreement with the negative charge of the semiquinones. The disproportionation equilibria of the naphthosemiquinone derivatives are shifted to the semiquinone in the presence of neutral and positive membranes, being more pronounced in the latter. However, very low partition coefficients as well as small shifts in the semiquinone disproportionation equilibrium were observed for ONQ.- as compared to the other semiquinones. No partition of 1,4-benzosemiquinone (BQ.-) into the lipid phase was detected for either charged or neutral lipid membranes. The presence of lipid membranes decreases the BQ.- equilibrium concentration in the presence of all the types of membranes considered here.     

Alterations in membrane surfaces induced by attachment of carbohydrates

We have examined the behavior of the dry phospholipid dipalmitoylphosphatidylcholine (DPPC) in the presence of several carbohydrate derivatives. These carbohydrate derivatives possess a hydrophobic portion which is incorporated directly into the DPPC membrane and a hydrophilic portion which places the carbohydrate structure at the membrane interface with the surrounding matrix. In the presence of these derivatives, the physical properties of the membrane are altered. These alterations are evident in changes observed in the phosphate and carbonyl vibrational modes of the phospholipid portion of the membrane. In addition, the phase transition behavior of the lipid is significantly altered as evidenced by a reduction in the gel to liquid-crystalline phase transition temperature. These results are consistent with those previously reported for free carbohydrates interacting with membranes in which a water replacement hypothesis has been used to explain the behavior. The attachment of carbohydrates to the membrane enhances these effects by localizing the agent responsible for these alterations at the membrane interface.     

Characterization of Imido [8-3H] Guanosine 5′-Triphosphate Binding Sites to Rat Brain Membranes

Besides their well-defined intracellular roles in transmembrane signals transduction, guanine derivatives play important roles by acting from the outside of neural cell membranes. These roles are mediated by two different pool sites in cell membranes: G proteins, which bind to specific (GDP and GTP) intracellular guanine derivatives, and sites that bind to extracellular guanine derivatives. In this study we investigated some methodological characteristics of both guanine derivatives binding sites (intracellular and extracellular) in rat brain neural membranes. By investigating the binding of a poorly hydrolyzed GTP analogue and the adenylate cyclase activity in neural membranes, we observed some distinctiveness of guanine derivatives binding sites: stability to washing procedures (extracellular) and modulation of adenylate cyclase activity (intracellular). These results allow dealing with each site separately, which could be useful for discriminating the roles of extracellular and intracellular guanine derivatives in the central nervous system.     

Interactions of two O-phosphorylresveratrol derivatives with model membranes

The hydrosoluble resveratrol derivative 3-O-phosphorylresveratrol was shown to be more cytotoxic against DU 145 prostate cancer cells than its analog 4'-O-phosphorylresveratrol. In an attempt to unveil the molecular determinants that lye at the root of their different biological effects, here we investigate the interactions of the two resveratrol derivatives with DMPC model membranes by using DSC, membrane permeation/poration assays and molecular dynamics. The results show that the 3-O-derivative interacts with DMPC membranes and diffuses across them. The 4'-O-derivative lies preferentially onto the surface of membrane. The MD simulations provide a molecular interpretation of the experiments and highlight that, in order to maximize the apolar interactions, the 3-O-derivative is embedded in the lipid hydrophobic region. This topographical position of the 3-O resveratrol analog perturbs the liquid-crystalline order of the lipid bilayer promoting membrane curvature and partial lipid loss from the vesicle. This finding reconciles with the lowering of the enthalpy of the lipid phase transition and the ability of the molecule to diffuse across membranes. The present data contribute to explain the different biological activity of the two molecules and evidence that membrane permeability is a key requirement for effective design of resveratrol derivatives to be used for therapeutic purposes.     

The aggregation state of spin-labeled melittin in solution and bound to phospholipid membranes: evidence that membrane-bound melittin is monomeric

Spin-labeled derivatives of the bee venom protein, melittin, were obtained by reacting on the average one of the four amino groups of the protein with succinimidyl-2,2,5,5-tetramethyl-3-pyrroline-1-oxyl-3-carboxylate. All 16 statistically possible reaction products with 0, 1, 2, 3 or 4 spin labels per protein were then separated in a single pass with reversed phase high performance liquid chromatography. With the help of trypsin digestion and diode array detection it was possible to assign the primary structure of all 16 eluting fractions. All fractions with only one spin label per protein were purified for electron paramagnetic resonance measurements. The labeling sites cover different regions of the protein: one is at the N-terminus, one at lysine-7, and two are near the C-terminus at lysine-21 and lysine-23, respectively. This set of specifically labeled melittins was used to study the structure and dynamics of melittin in aqueous solutions and when bound to neutral or negatively charged membranes. In aqueous solution a reduction in rotational correlation time and appearance of spin-spin interaction was observed during salt-induced transition from a random coil monomer to a mostly alpha-helical tetramer. Membrane binding to phospholipid bilayers in low or high ionic strength was reflected only in a further decrease in mobility. The absence of any spin interaction in the membrane-bound state suggests that melittin is monomeric under these conditions. All derivatives were able to detect these structural changes, but melittin labeled at the N-terminal amino group was especially valuable. Because of postulated intramolecular hydrogen bonding, this label reflects directly the motion of the entire protein or tetramer. Broadening experiments with chromium oxalate show that all labeled sites are at least partially exposed to the aqueous phase when melittin is bound to membranes. This suggests that an alpha-helical melittin monomer binds to membranes with its axis parallel to the membrane surface.     

Preparation and characterization of two LysB29 specifically labelled fluorescent derivatives of human insulin.

The preparation and characterization of two novel LysB29 selectively labelled fluorescent derivatives of human insulin are described. Two probes were chosen: 4-chloro-7-nitrobenz-2-oxa-1,3-diazole (NBD) and 7-methoxycoumarin-4-acetic acid (MCA), which have a relatively small, compact structure and are able to react with amino groups to form highly fluorescent derivatives. The combination of solid phase peptide synthesis and enzymatic semisynthesis was chosen for preparation of these fluorescent derivatives. Using two different protocols of solid-phase peptide synthesis, two fluorescent octapeptides were prepared corresponding to the position B23-B30 of human insulin, each with a different fluorescent label, NBD or MCA, on the epsilon-amino group of lysine. Then, the fluorescent octapeptides were coupled to desoctapeptide-(B23-B30)-insulin by a trypsin catalysed reaction. The receptor binding affinities of two novel fluorescent derivatives of human insulin with NBD and MCA (HI-NBD and HI-MCA) were determined on rat adipose tissue plasma membranes. Both fluorescent insulins, HI-NBD and HI-MCA, had only slightly reduced binding affinity and will be used for studying the interaction of insulin with its receptor.     

The role of the carboxyl and amino groups of polyene macrolides in their interactions with sterols and their selective toxicity. A P-NMR study

The permeability induced by amphotericin B and vacidin A derivatives in large unilamellar lipidic vesicles containing various sterols has been studied using the proton-cation exchange method and ³¹P-NMR spectroscopy. Derivatives which have a free ionizable carboxyl group induce biphasic ‘all or none’ permeability typical of channel-forming ionophores, whatever the sterol present. In sterol-free membranes, they have no significant activity. Derivatives which lack a free ionizable carboxyl group exhibit this channel-like mode of action only in membranes containing ergosterol or sterols with an alkyl side like that of ergosterol. In membranes containing cholesterol or sterol whose side-chain is alike, a slow and progressive permeability is observed at high concentrations. This activity is observed in sterol-free membranes as well. Derivatives containing sugars with substituted amino groups always have lower ionophoric activity than those which are unsubstituted. The greatest decrease in activity was observed for N-acetyl derivatives. Substitution of the amino groups has no effect on the mode of action. A model of interaction of polyenes with sterols is presented accounting for the data obtained on vesicles and the observed selective toxicity of polyene derivatives in biological membranes.