Sensitivity of leukemia cell lines to cytotoxic alkyl-lysophospholipids in relation to O-alkyl cleavage enzyme activities.

The human leukemia cell lines K562, HL60, and Raji and the mouse leukemia cell line L1210 showed a differential susceptibility to the action of the alkyl-lysophospholipid (ALP) 1-octadecyl-2-methyl-rac-glycero-3-phosphocholine (ET-18-OCH3). After 48 hours, the 50% growth-inhibition doses (ID50) of ET-18-OCH3 were found to be 0.78 microgram/ml (HL60), 1.53 microgram/ml (Raji), 4.41 micrograms/ml (K562), and 5.05 micrograms/ml (L1210), as determined by [3H]thymidine incorporation. At the same time, cell viability was determined by trypan blue exclusion and revealed median lethal doses (LD50) of 3.5 micrograms/ml (HL60), 15 micrograms/ml (Raji), 24 micrograms/ml (L1210), and 38 micrograms/ml (K562). Since O-alkyl cleavage enzyme previously was suggested as being important in the detoxification of cytotoxic ALPs, the enzyme activity was compared with the susceptibility to ET-18-OCH3 in the distinct cell lines. In comparison to an approximate sevenfold to elevenfold (ID50 and LD50, respectively) difference in the susceptibility of the above leukemia cell lines to ET-18-OCH3, no significant difference in the specific activities (0.13-0.21 nmol/min/mg) of the O-alkyl cleavage enzyme was found in the above leukemia cell lines. Therefore, the differential sensitivity of the above lines investigated cannot be explained by differences in O-alkyl cleavage enzyme activity. Experiments with radiolabeled ET-18-OCH3 in Raji cells suggest, rather, a critical role for phospholipases C and/or D in ALP metabolism.

New assay for the O-alkyl cleavage enzyme with alkyl-lysophospholipids as substrates.

The O-alkyl cleavage enzyme is important for the metabolism of cytotoxic alkyl-lysophospholipids. We have developed a simple new method for the determination of the enzyme activity which is based on the formation of water-soluble phosphate during the enzyme reaction. This is the first assay which avoids the use of radiolabeled substrates.

Inhibition of protein kinase C, (sodium plus potassium)-activated adenosine triphosphatase, and sodium pump by synthetic phospholipid analogues.

The effects and modes of action of certain antineoplastic phospholipid analogues (racemic 1-O-octadecyl-2-O-methyl glycero-3-phosphocholine, BM 41.440, JH-1, CV-3988, and HePC) on (sodium plus potassium)-activated adenosine triphosphatase (Na,K-ATPase) and sodium pump activities were investigated. Inhibition of Na,K-ATPase in purified rat brain synaptosomal membranes by these lipids, in contrast to ouabain, was subject to membrane surface dilution and unaffected by whether the reaction was started with KCl, NaCl, or ATP. Kinetic analysis indicated that the analogues, again dissimilar to ouabain, were likely to interact directly or indirectly with sodium-binding sites of Na,K-ATPase located at the intracellular surface of the plasma membrane, a conclusion also supported by studies using the inside-out vesicles of human erythrocyte membranes. The studies also showed that ouabain (but not the lipids) increased the affinity constant of Na,K-ATPase for K+, whereas the lipids (but not ouabain) increased that for Na+. The lipids also inhibited 86Rb uptake by intact human leukemia HL60 cells at potencies quite comparable to those seen for inhibition of purified protein kinase C or Na,K-ATPase. It is suggested that Na,K-ATPase (sodium pump) might represent a hitherto unrecognized site of action for the lipid analogues, and that the antineoplastic effects of the agents might be due to, in part, inhibition of both protein kinase C and Na,K-ATPase and perhaps other membrane-associated enzymes.

The influence of charge on phosphatidic acid bilayer membranes.

A complete titration of phosphatidic acid bilayer membranes was possible for the first time by the introduction of a new anaologue, 1,2-dihexadecyl-sn-glycerol-3-phosphoric acid, which has the advantage of a high chemical stability at extreme pH values. The synthesis of the phosphatidic acid is described and the phase transition behaviour in aqueous dispersions is compared with that of three ester phosphatidic acids; 1,2-dimyristoyl-sn-glycerol-3-phosphoric acid, 1,3-dimyristoylglycerol-2-phosphoric acid and 1,2-dipalmitoyl-sn-glycerol-3-phosphoric acid. The phase transition temperatures (Tt) of aqueous phosphatidic acid dispersions at different degrees of dissociation were measured using fluorescence spectroscopy and 90 degrees light scattering. The Tt values are comparable to the melting points of the solid phosphatidic acids in the fully protonated states, but large differences exist for the charged states. The Tt vs. pH diagrams of the four phosphatidic acids are quite similar and of a characteristic shape. Increasing ionisation results in a maximum value for the transition temperatures at pH 3.5 (pK1). The regions between the first and the second pK of the phosphatidic acids are characterised by only small variations in the transition temperatures (extended plateau) in spite of the large changes occurring in the surface charge of the membranes. The slope of the plateau is very shallow with increasing ionisation. A further decrease in the H+ concentration results in an abrupt change of the transition temperature. The slope of the Tt vs. pH diagram beyond pK2 becomes very steep. This is the result of reduced hydrocarbon interaction energy, which was demonstrated by differential scanning calorimetry (Blume, A. and Eibl, H., unpublished data).

The influence of charge on bilayer membranes. Calorimetric investigations of phosphatidic acid bilayers.

The pH-dependence of the phase transition of dimyristoyl phosphatidic acid and dihexadecyl phosphatidic acid has been investigated using differential scanning calorimetry. Varying the pH induces different degrees of ionization of the polar head group. The changes in transition temperature with pH as observed by calorimetry are in good agreement with those obtained by measuring the changes in light scattering, whereas the transition temperatures reported by the fluorescent probe N-phenylnaphthylamine do not always coincide with those determined from calorimetry [1]. The observed maximum of the transition temperature at pH 3.5 corresponds to a minimum in the transition enthalpy vs. pH diagram. At this pH a particular stable bilayer phase is formed. Full protonation of phosphatidic acids leads to suspensions of mycrocrystals. The transition enthalpy approaches the value of the melting enthalpy of crystalline anhydrous phosphatidic acid. The decrease in the transition enthalpy at high pH values is due to a change in the hydrocarbon chain interactions induced by the doubly charged head groups. The cooperativity of the transition varies with the degree of ionization of the head group, being lower for doubly charged phosphatidic acids.

Influence of calcium on phosphatidylethanolamine. An investigation of the structure at high pH.

The influence of calcium on the structure of 1,2-dihexadecyl-sn-glycero-3-phosphoethanolamine was investiged at pH 8 and 12 by differential scanning calorimetry and by X-ray diffraction. At pH 12, where the amino group of phosphatidylethanolamine is partly deprotonated, two separate lamellar phases are observed at 60 degrees C in the presence of CaCl2; one phase is metastable and the other is present in a crystalline structure. At high temperature (90 degrees C), the small-angle diffraction lines indicate the existence of a hexagonal phase at pH 8. At pH 12 a hexagonal phase is detected only in the presence of calcium.

A calorimetric study of the thermotropic behaviour of 1,2-dipentadecylmethylidene phospholipids.

Differential scanning calorimetry was used to study the thermotropic behaviour of 1,2-dipentadecylmethylidene phospholipids with various head groups. The structural variation in the glycerol backbone region leads to a strong restriction of conformational freedom for the first two methylene segments of the chains, so that dipentadecylmethylidene phospholipids show lower transition temperatures, lower enthalpies and lower cooperativity of the transition from the gel to the liquid crystalline phase. The extreme chemical stability of these lipids in the alkaline pH region enables investigations of phosphatidylethanolamine and phosphatidic acid dispersions at high pH values. Both phospholipids show a decrease in the transition temperature and in the transition enthalpy as they become singly and doubly charged, respectively. A complex behaviour of the transition enthalpy of doubly charged 1,2-dipentadecylmethylidene phosphatidic acid was observed when the NaCl concentration of the dispersion was increased.

The influence of phospholipid polar groups on gramicidin channels.

The influence of well-defined changes in the polar part of phospholipid molecules on the properties of black lipid membranes was studied using a series of phospholipids with identical hydrocarbon chains, but systematically changed polar groups. The hydrocarbon tails of the lipids under study were composed of 1,2-dipentadecylmethylidene glycerol. The polar parts differed in the degree of N-methylation and comprised phosphocholine, -N,N-dimethylethanolamine, -N-methylethanolamine and ethanolamine. Stable black lipid membranes could be formed with the solvents octane, decane, dodecane, tetradecane and hexadecane. The properties of gramicidin-induced single ionic channels changed systematically in membranes from the phosphatidylcholine to the phosphatidylethanolamine analogue, as indicated by an increase in the amplitude lambda of the unit conductance step and a decrease in the average channel life-time or duration tau. The series of tau-values was opposite to that expected from hydrocarbon thickness (specific capacitance). It is suggested that the surface tension gamma is a relevant parameter for the prediction of tau-values.

On the mechanism of lysophospholipase activity of secretory phospholipase A2 (EC 3.1.1.4): deacylation of monoacylphosphoglycerides by intrinsic sn-1 specificity and pH-dependent acyl migration in combination with sn-2 specificity.

We show for the first time that secreted low-molecular weight phospholipase A2 (EC 3.1.1.4) catalyzes the deacylation of monoacylphosphoglycerides directly from the sn-1 position, although at a very low rate: purified phospholipase A2 enzymes from bee venom, crotalus atrox venom, and porcine pancreas hydrolyze the sn-1 ester bond in 1-palmitoyl-2-O-methyl-sn-glycero-3-phosphorylcholine. Hydrolytic rates with the corresponding isomer, 1-O-methyl-2-palmitoyl-sn-glycero-3-phosphorylcholine, are about 3-4 orders of magnitude higher. The similarities in Ca2+ requirement and inactivation profiles suggest that deacylation, albeit with different rates, from both sn-1 and sn-2 positions is catalyzed by the same catalytic site of phospholipase A2. Furthermore, evidence is provided that phospholipase A2-catalyzed 1-acyl lysophospholipid deacylation is mediated by sn-1-directed action, but above pH 7 acyl migration with subsequent enzyme-catalyzed hydrolytic cleavage from the sn-2 position contributes to the overall deacylation of monoacylphosphoglycerides, acyl migration becoming eventually the rate-limiting factor.

Influence of pH on phosphatidic acid multilayers. A rippled structure at high pH values.

The influence of pH on the structure of 1,2-(ditetradecyl)-phosphatidic acid was investigated by differential scanning calorimetry and freeze-fracture electron microscopy. At pH 13.5--14 (2.6 M K+), where phosphatidic acid has two negative charges, calorimetric scans show a small transition (pretransition) below the main phase transition temperature. Freeze-fracture studies of the same dispersions reveal regular band patterns (so-called ripples) in the plane of the bilayers, when the lipid is quenched from below the main phase transition temperature. This rippled structure is similar to the well-known rippled structure of phosphatidylcholines.

Charge-induced pretransition in phosphatidylethanolamine multilayers. The occurrence of ripple structures.

The influence of pH and ionic strength on the phase transition behavior of 1,2-dihexadecylphosphatidylethanolamine was studied calorimetrically. In the range of ionic strength from 0.75 to 1.5 M NaCl at pH larger than 13, where the amino group of the phosphatidylethanolamine is in the deprotonated state, resulting in one negative charge per lipid molecule, the calorimetric scan shows a pretransition before the main transition. Accompanying freeze-fracture electron microscopic studies on these preparations in the temperature range between the pre- and main transitions show a regular suface, the so-called ripple structure. These are comparable with the structures seen in phosphatidylcholine-water systems at temperatures between the pre- and main transition.

Structural requirements of lysophospholipid-regulated mitochondrial Ca2+ transport.

Analogues of lysophosphatidylcholine, including PAF (platelet-activating-factor) and HePC (an experimental anticancer drug), were studied for their influence on mitochondrial Ca2+ transport and membrane potential. Lysophospholipids released Ca2+ from mitochondria and reduced the maximal Ca2+ uptake. The structure-activity relations indicate that deprotonated head groups like phosphocholines yield active compounds while partially protonated head groups like phosphoethanolamines are essentially inactive. Structural requirements for the apolar part of the molecules were acyl or alkyl chain lengths of less than 18 carbon atoms at the C1-position of the glycerol backbone and residues of small size and/or low polarity at the C2-position. Choline lysophospholipids, but not ethanolamine lysophospholipids, may therefore induce mitochondrial Ca2+ efflux and become mediators of ischaemic tissue damage where dysregulated phospholipase A2 activity and an impairment of mitochondrial function are supposed to play a crucial role.

X-ray analysis and calorimetry on phosphatidylcholine model membranes. The influence of length and position of acyl chains upon structure and phase behaviour.

The effect of variation of the acyl chain composition of phosphatidylcholines upon thermal behaviour of multilamellar liposomes was evaluated by calorimetry and X-ray studies. A total of thirteen different phosphatidylcholines were examined. They differed from each other in the length as well as in the position of the acyl chains in the glycerol backbone. The experimental results show that the hitherto accepted phase scheme for phosphatidylcholine-water systems is incomplete and has to be extended to include the behaviour of samples that have been stored for long times at low temperatures. The X-ray results show that the structure of the new low-temperature phase is not in agreement with the hexagonal packing of the acyl chains. To explain the X-ray results, a two-dimensional orthorhombic unit cell has to be assumed in order to fit all the observed reflexes in the wide-angle region.

Conformation and packing properties of membrane lipids: the crystal structure of sodium dimyristoylphosphatidylglycerol.

The conformation and molecular packing of sodium 1,2-dimyristoyl-sn-glycero-phospho-rac-glycerol (DMPG) have been determined by single crystal analysis (R = 0.098). The lipid crystallizes in the monoclinic spacegroup P2(1) with the unit cell dimensions a = 10.4, b = 8.5, c = 45.5 A and beta = 95.2 degrees. There are two independent molecules (A and B) in the asymmetric unit which with respect to configuration and conformation of their glycerol headgroup are mirror images. The molecules pack tail to tail in a bilayer structure. The phosphoglycerol headgroups have a layer-parallel orientation giving the molecules an L-shape. At the bilayer surface the (-) phosphoglycerol groups are arranged in rows which are separated by rows of (+) sodium ions. Laterally the polar groups interact by an extensive network of hydrogen, ionic and coordination bonds. The packing cross-section per molecule is 44.0 A2. The hydrocarbon chains are tilted (29 degrees) and have opposite inclination in the two bilayer halves. In the chain matrix the chain planes are arranged according to a so far unknown hybride packing mode which combines the features of T parallel and O perpendicular subcells. The two fatty acid substituted glycerol oxygens have mutually a - synclinal rather than the more common + synclinal conformation. The conformation of the diacylglycerol part of molecule A and B is distinguished by an axial displacement of the two hydrocarbon chains by four methylene units. This results in a reorientation of the glycerol back bone and a change in the conformation and stacking of the hydrocarbon chains. In molecule A the beta-chain is straight and the gamma-chain is bent while in molecule B the chain conformation is reversed.

Ca2+-induced phase separation in black lipid membranes and its effect on the transport of a hydrophobic ion.

Voltage jump-current relaxation studies have been performed with dipicrylamine-doped black membranes of binary lipid mixtures. As in the case of the carrier-mediated ion transport (Schmidt, G., Eibl, H. and Knoll, W. (1982) J. Membrane Biol. 70, 147-155) no evidence was found that the neutral lipid phosphatidylcholine (DPMPC) and the charged phosphatidic acid (DPMPA) are heterogeneously distributed in the membrane over the whole range of composition. However, besides a continuous dilution of the surface charges of DPMPA by the addition of DPMPC molecules, different structural properties of mixed membranes influence the kinetics of the dipicrylamine transport. The addition of Ca2+ to the electrolyte induces a lipid phase separation within the membrane into two fluid phases of distinctly different characteristics of the translocation of hydrophobic ions. Thus, it is possible to determine a preliminary composition phase diagram for the DPMPA/DPMPC mixtures as a function of the Ca2+ concentration.

A comparison of the headgroup conformation and dynamics in synthetic analogs of dipalmitoylphosphatidylcholine.

14N-NMR spectra and relaxation times for dipalmitoylphosphatidylcholine and three analogs were obtained in both the liquid crystal and gel phases. The analogs either changed the PO-4 to N+ (CH3)3 distance (P-N) within the headgroup by increasing the number of CH2 groups from two in the phosphocholine headgroup (PN-2) to six in the phospho-(N',N',N'-trimethyl)hexanolamine headgroup (PN-6), or replaced the ester linkages to the hydrocarbon chains with either linkages. 31P-NMR spectra were obtained for the four samples in the liquid-crystal phase. (1) The 14N- and 31P-NMR spectra and 14N relaxation times all indicate that increasing the P-N distance within the headgroup causes changes in both the average orientation of the C-N bond and its dynamics. (2) The 14N-NMR spectra provide evidence for a change in orientational order of the headgroup as a result of changing the linkage to the acyl chains. On the other hand, the relaxation time measurements indicate that the molecular motion for the headgroup is independent of the type of linkage. (3) The thermal behaviour of the four samples is clearly reflected in the 14N-NMR spectra. The second moments of the spectra show distinct changes at each of the phase transitions. (4) The 14N-NMR spectra show that the average conformation of the headgroups is not significantly altered by the main phase transition. For the PN-2 samples, T2e, the decay of the quadrupolar echo, decreases discontinuously in the P beta, phase, which is evidence for a possible exchange process between two molecular states within this phase.

Synthetic phospholipids as substrates for phospholipase C from Bacillus cereus.

The substrate requirement of phospholipids for hydrolysis with phospholipase C from Bacillus cereus was studied with synthetic lipids well-defined in structure and configuration. For optimal activity, the glycerol molecule must contain three substituents: phosphocholine in sn-3-, an ester bond in sn-2- and an ether- or ester bond in sn-1-position. The length of the ester or ether chains is of minor importance. Any deviation from these structural requirements results in a large decrease in the hydrolysis rate. These essential structural and configurational elements for optimal activity for the B. cereus enzyme are perfectly combined in the platelet activating factor, 1-O-hexadecyl-2-acetyl-sn-glycero-3- phosphocholine. This molecule is one of the best substrates for hydrolysis with the bacterial phospholipase C.

Differential scanning calorimetry of dipalmitoyl phosphatidylcholine analogues and of their interaction products with basic polypeptides.

The thermotropic behaviour of dipalmitoyl phosphatidylcholine analogues with a varying number (n) of CH2 groups between the phosphate and the quaternary ammonium has been investigated. The temperature (Tm) and the enthalpy (deltaH) of the phase transition are non-monotonous functions of the number of CH2 groups. Tm oscillates between 40 and 45 degrees C and deltaH between 7 and 13 kcal/mol for a variation of n between 2 and 11. It is concluded that the hydrocarbon chains in the head groups do not penetrate the hydrocarbon region and do not contribute directly to the melting of the acyl chains. It is suggested that their length may affect the critical balance between the attractive and the repulsive forces within the bidimensional lattice of the head groups. Copolypeptides of lysine with phenylalanine do not appreciably affect the Tm but have a pronounced effect on deltaH of the lipid phase transition, which depends strongly on the ratio of the two amino acids in the polypeptide. The effect of copolypeptide of any defined composition on deltaH is also a non-monotonous function of the number of CH2 groups in the phosphatidylcholine head group, but it does not parallel completely the oscilations in the Tm and deltaH of the pure lipids.

Phospholipid and fatty acid composition of tetrodotoxin receptor-rich membrane fragments from Electrophorus electricus.

To study the interaction of voltage-sensitive Na+-channels with membrane lipids, the phospholipid and fatty acid composition of highly purified membrane fragments from the remarkably differentiated plasma membrane of Electrophorus electricus has been analyzed. After density gradient fractionation and carrier free electrophoresis, fractions with up to 30 pmol tetrodotoxin binding/mg protein can be obtained, which may correspond to a 50% pure preparation of the extrasynaptic part of the excitable face. Phospholipid classes and cholesterol are separated by one-dimensional thin-layer chromatography in acidic and alkaline solvent systems. The following mean molar contents are found: 40% phosphatidylcholine, 23% phosphatidylserine, 30% phosphatidylethanolamine and 7% sphingomyelin. In a series of 11 animals, significant deviations from these mean values have been observed. The fatty acid composition of the phospholipids has been determined by gas chromatography. Phosphatidylcholine contains more than 50% 16:0, and about 20% unsaturated fatty acids in the C-18 group. Compared to other plasma membrane fractions, this phospholipid is the least differentiated. By contrast, phosphatidylethanolamine and phosphatidylserine show many characteristics in different membrane fractions, especially in their unsaturated components representing more than 50%. 22:6, as the major constituent in these fractions, accounts for a quarter to a third of all fatty acids in these fractions. 18:0 is the main saturated component in these two phospholipids with abundances of typically a quarter or less of all fatty acids. Knowledge of the lipid composition of these excitable membranes may help to conserve binding and structural properties when analyzing lipid-sensitive Na+-channels in vitro. It is also useful as a guideline for systematic reconstitution studies.

Effect of the structure of phospholipid on the kinetics of intravesicle scooting of phospholipase A2.

Action of pig pancreatic phospholipase A2 on vesicles of over 50 synthetic 1,2-diacylglycerol-3-phosphate derivatives and analogs is examined in the absence of any additives. In general, shorter acyl chains and small substituents on the phosphate make a better substrate, while phospholipids with large apolar substituents are not hydrolyzed. The interfacial turnover rate constant for scooting kinetics, ki, for the various phospholipids were from less than 0.1 to 1 per min. Intervesicle exchange of the bound enzyme is faster in vesicles of phospholipids with larger polar substituents, and it is promoted in the presence of anions like chloride, sulfate and thiocyanate. These factors lower the residence time of the enzyme on the bilayer and therefore effectively decrease the rate of hydrolysis. The apparent Km for the enzyme in the interface of anionic phospholipids in the presence of salts is in the 40 to 100 microM range which is 3- to 7-times larger than the dissociation constants for the bound enzyme measured by fluorescence enhancement of Trp-3. The quantum yield of the bound enzyme in vesicles of the various lipids is found to be up to 4-fold different. It is suggested that this difference is due to the E* + S to E*S equilibrium, where E*S has higher fluorescence intensity. The role of calcium in generating the enzyme binding site at the anionic interface, the role of anion anchoring site on the enzyme, and the relationship between the catalytic efficiency and the fluorescence quantum yields are discussed.