W J van Blitterswijk

Lipid structural order parameters (reciprocal of fluidity) in biomembranes derived from steady-state fluorescence polarization measurements

Abstract This paper presents an interpretation of fluorescence polarization measurements in lipid membranes which are labelled with the apolar probe 1,6-diphenyl-1,3,5-hexatriene. The steady-state fluorescence anisotropy, r S , is resolved into a fast decaying or kinetic component, r f , and an infinitely slow decaying or static component, r ∞ . The latter contribution, which predominates in biological membranes, is exclusively determined by the degree of molecular packing (order) in the apolar regions of the membrane; r ∞ is proportional to the square of the lipid order parameter. An empirical relation between r S and r ∞ is presented, which is in agreement with a prediction based on a theory of rotational dynamics in liquid crystals. This relation enabled us to estimate a lipid structural order parameter directly from simple steady-state fluorescence polarization measurements in a variety of isolated biological membranes. It is shown that major factors determining the order parameter in biomembranes are the temperature, the cholesterol and sphingomyelin content and (in a few systems) the membrane intrinsic proteins.

Identification of a putative membrane receptor for the bioactive phospholipid, lysophosphatidic acid.

Lysophosphatidic acid (LPA) is a naturally occurring phospholipid with hormone‐ and growth factor‐like activities. Exogenous LPA stimulates GTP‐dependent phosphoinositide hydrolysis and inhibits adenylate cyclase in its target cells, but the site of action of LPA is unknown. We now report the identification by photoaffinity labeling of a putative LPA membrane receptor in various LPA‐responsive cell types. A 32P‐labeled LPA analogue containing a photoreactive fatty acid, [32P]diazirine‐LPA, labels a membrane protein of apparent molecular mass of 38–40 kDa in various cell types, including neuronal cells, brain homogenates, carcinoma cells, leukemic cells and normal fibroblasts. Labeling of the 38–40 kDa protein is competitively inhibited by unlabeled 1‐oleoyl‐LPA (IC50 approximately 10 nM), but not by other phospholipids. Specific labeling is not detected in rat liver membranes or in human neutrophils, which are physiologically unresponsive to LPA. Suramin, an inhibitor of both early and late events in the action of LPA, completely inhibits the binding of photoreactive LPA. We suggest that the 38–40 kDa protein represents a specific LPA cell surface receptor mediating at least part of the multiple cellular responses to LPA.

Changes in membrane lipid composition of human erythrocytes after dietary supplementation of (n − 3) polyunsaturated fatty acids. Maintenance of membrane fluidity

The effect of dietary (n-3) polyunsaturated fatty acids on erythrocyte membrane lipid composition, fluidity, and flexibility was studied in seven healthy subjects. An eight weeks daily supplementation of 3 g of the (n-3) fatty acids eicosapentaenoic and docosahexaenoic acid resulted in an increased unsaturation of erythrocyte phosphatidylcholine (PC) and phosphatidylethanolamine (PE). This change was accompanied by a slight decrease in PC and PE content (P less than 0.05) and an increase in sphingomyelin content (P less than 0.01). The erythrocyte membrane fluidity, measured with electron spin resonance of intact erythrocytes and with fluorescence polarization of erythrocyte ghosts did not change. No change was seen in the viscosity of erythrocyte suspensions of haematocrit = 0.80, measured at various shear rates. The supplementation caused a 42% decrease in plasma triacylglycerol levels. We suggest that the change in the erythrocyte membrane fatty acid composition induced by the dietary supplementation of (n-3) fatty acids might be counteracted by a change in the phospholipid class distribution, resulting in overall maintenance of membrane fluidity.

Comparative lipid analysis of purified plasma membranes and shed extracellular membrane vesicles from normal murine thymocytes and leukemic GRSL cells

The lipid fluidity in purified plasma membranes (PM) of murine leukemic GRSL cells, as measured by fluorescence polarization, is much higher than in PM of normal thymocytes. This was found to be due to relatively low contents of cholesterol and sphingomyelin and a high amount of unsaturated fatty acyl chains, especially linoleic acid, in the phospholipids. PM from GRSL cells contain markedly more phosphatidylethanolamine than those from thymocytes. For both GRSL cells and thymocytes the detailed lipid composition of isolated PM was compared with that of the corresponding shed extracellular membranes (ECM), which were isolated from the ascites fluid and from thymus cell suspensions, respectively. The somewhat decreased lipid fluidity of thymocyte ECM as compared to their PM, can be ascribed to the increased cholesterol/phospholipid molar ratio (0.88 vs. 0.74). No other major differences were found between the lipid composition of these membranes. In contrast, significant differences were found between PM and ECM from GRSL cells. In this system a much lower lipid fluidity of the shed ECM was found, due to the much increased cholesterol/phospholipid molar ratio (3.5-fold) and sphingomyelin (9-fold) content, as compared to the PM. Further, the ECM contain relatively more lysophosphatidylethanolamine and less phosphatidylcholine and -inositol. ECM contain a higher amount of polyunsaturated fatty acids, especially in the phosphatidylethanolamine and lysophosphatidylethanolamine classes. On the other hand, the fatty acids of phosphatidylcholine and lysophosphatidylcholine are more saturated than in PM. In particular, ECM of GRSL cells contain less oleic and linoleic acid residues and more arachidonic acid and 22:polyunsaturated fatty acid residues than PM. The possible relevance of these differences with respect to the mechanism of shedding of vesicles from the cell surface, is discussed.

Differences in lipid fluidity among isolated plasma membranes of normal and leukemic lymphocytes and membranes exfoliated from their cell surface

Abstract The fluorescence polarization technique with 1,6-diphenyl 1,3,5-hexatriene as a probe was used to determine the lipid microviscosity, η , of isolated plasma membranes of mouse thymus-derived ascitic leukemia (GRSL) cells and of extracellular membraneous vesicles exfoliated from these cells and occurring in the ascites fluid. For comparison, η was also determined in isolated plasma cell supernatants. For isolated plasma membranes of thymocytes and GRSL cells η values at 25° C amounted to 4.67 and 3.28 P, respectively, which were higher than the microviscosities of the corresponding intact cells, 3.24 and 1.73 P, respectively. Microviscosities inextracellular membranes of thymocytes and GRSL cells were 5.96 and 5.83 P, respectively. The fluidity difference between these membranes and plasma membranes was most pronounced for the leukemic cells and was thereby correlated with a large difference in cholesterol/phospholipid molar ratio (1.19 for extracellular membranes and 0.37 for plasma membranes). It is proposed that extracellular membraneous vesicles are shed from the surface of GRSL cells similar to the budding process of viruses, that is by selection of the most rigid parts of the host cell membrane. Liposomes of total lipid extracts of plasma membranes and extracellular membranes of both cell types exhibited about the same microviscosity as the corresponding intact membranes, indicating virtually no contribution of (glyco)-protein to the lipid fluidity as measured by the fluorescence polarization technique. For both cell types η (25° C) values of liposomes consisting of membrane phospholipids varied between 1.5 and 1.9 P, much lower than the values for total lipids, indicating a significant rigidizing effect of cholesterol in each type of membrane.

Fluorescence polarization measurements on normal and tumour cells and their corresponding plasma membranes.

Using 1,6-diphenyl-1,3,5-hexatriene as a probe, the degree of fluorescence polarization (P) at 25 degrees C of intact and disrupted cells and isolated plasma membranes were compared for a variety of systems. 1. Human erythrocytes, mouse thymocyte and leukemia cells, rat liver and hepatoma cells, and human and mouse milk fat globules displayed P values ranging from 0.300 to 0.120. 2. P values or probe labelling rates of intact and disrupted cells were similar. 3. As compared with whole or disrupted cells, the higher to much higher P values of plasma membranes isolated from the corresponding cells showed only a limited mutual variation. 4. delta P values, being the difference in P values between plasma membranes and whole cells were attributed to the extent to which endomembranes and non-membrane lipids contributed. Among these, triglycerides had the greatest relative effect. 5. Though a particular isolation procedure for plasma membranes may select for more rigid fragments, this effect is by far not sufficient to account for the observed delta P values. It is concluded that the fluorescence polarization technique with a lipophilic probe applied to whole cells represents a measure of the average fluidity of all lipids being present in a cell and thus does not exclusively monitor the cell surface membrane.

Rapid attenuation of receptor-induced diacylglycerol and phosphatidic acid by phospholipase D-mediated transphosphatidylation: formation of bisphosphatidic acid.

Generation and attenuation of lipid second messengers are key processes in cellular signalling. Receptor‐mediated increase in 1,2‐diacylglycerol (DG) levels is attenuated by DG kinase and DG lipase. We here report a novel mechanism of DG attenuation by phospholipase D (PLD), which also precludes the production of another (putative) second messenger, phosphatidic acid (PA). In the presence of an alcohol, PLD converts phosphatidylcholine (PC) into a phosphatidylalcohol (by transphosphatidylation) rather than into PA. We found in bradykinin‐stimulated human fibroblasts that PLD mediates transphosphatidylation from PC (donor) to the endogenous ‘alcohol’ DG (acceptor), yielding bis(1,2‐diacylglycero)‐3‐sn‐phosphate (bisphosphatidic acid; bisPA). This uncommon phospholipid is thus a condensation product of the phospholipase C (PLC) and PLD signalling pathways, where PLC produces DG and PLD couples this DG to a phosphatidyl moiety. Long‐term phorbol ester treatment blocks bradykinin‐induced activation of PLD and consequent bisPA formation, thereby unveiling rapid formation of DG. BisPA formation is rapid (15 s) and transient (peaks at 2–10 min) and is also induced by other stimuli capable of raising DG and activating PLD simultaneously, e.g. endothelin, lysophosphatidic acid, fetal calf serum, phorbol ester, dioctanoylglycerol or bacterial PLC. This novel metabolic route counteracts rapid accumulation of receptor‐induced DG and PA, and assigns for the first time a physiological role to the transphosphatidylation activity of PLD, that is signal attenuation.

Studies on plasma membranes: XIX. Isolation and characterization of a plasma membrane fraction from calf thymocytes

Abstract A plasma membrane fraction was isolated from calf thymocytes by a modification of the method of Wallach and Kamat (Wallach, D. F. H. and Kamat, V. B. (1966) in Methods in Enzymology) (Colowick, S. P. and Kaplan, N. O., eds), Vol. 8, pp. 164–172, Academic Press, New York). Fractions were examined electron microscopically and subjected to chemical and enzymic assays. With respect to the cell homogenate and the final microsomal fraction, respectively, the plasma membrane fraction was enriched by a factor 23 and 5.1 in cholesterol, 11 and 2.4 in phospholipid, 5.1 and 4.2 in sialic acid, 20 and 5.2 in Mg2+-ATPase (EC 3.6.1.3), and 8 and 2.6 in 5′-nucleotidase (EC 3.1.3.5). Succinate:cytochrome c oxidoreductase (EC 1.3.99.1) was lacking, and DNA was hardly if at all present in the plasma membrane fraction. The major part of the RNA found in this fraction (30 μg · mg−1 protein) was concluded to be an authentic component of the plasma membrane. The concept of membrane “markers” was briefly considered and the conclusion was reached that by current criteria and electron microscopic evidence the plasma membrane fraction obtained from calf thymocytes consisted of reasonably clean plasma membranes.

N -hexanoyl-sphingomyelin potentiates in vitro doxorubicin cytotoxicity by enhancing its cellular influx

Anticancer drugs generally have intracellular targets, implicating transport over the plasma membrane. For amphiphilic agents, such as the anthracycline doxorubicin, this occurs by passive diffusion. We investigated whether exogenous membrane-permeable lipid analogues improve this drug influx. Combinations of drugs and lipid analogues were coadministered to cultured endothelial cells and various tumour cell lines, and subsequent drug accumulation in cells was quantified. We identified N-hexanoyl-sphingomyelin (SM) as a potent enhancer of drug uptake. Low micromolar amounts of this short-chain sphingolipid, being not toxic itself, enhanced the uptake of doxorubicin up to 300% and decreased its EC50 toxicity values seven- to 14-fold. N-hexanoyl SM acts at the level of the plasma membrane, but was found not incorporated in (isolated) lipid rafts, and artificial disruption or elimination of raft constituents did not affect its drug uptake-enhancing effect. Further, any mechanistic role of the endocytic machinery, membrane leakage or ABC-transporter-mediated efflux could be excluded. Finally, a correlation was established between the degree of drug lipophilicity, as defined by partitioning in a two-phase octanol–water system, and the susceptibility of the drug towards the uptake-enhancing effect of the sphingolipid. A clear optimum was found for amphiphilic drugs, such as doxorubicin, epirubicin and topotecan, indicating that N-hexanoyl-SM might act by modulating the average degree of plasma membrane lipophilicity, in turn facilitating transbilayer drug diffusion. The concept of short-chain sphingolipids as amphiphilic drug potentiators provides novel opportunities for improving drug delivery technologies.

Diacylglycerol kinase theta is translocated and phosphoinositide 3-kinase-dependently activated by noradrenaline but not angiotensin II in intact small arteries.

Diacylglycerol (DG) kinase (DGK) phosphorylates the lipid second messenger DG to phosphatidic acid. We reported previously that noradrenaline (NA), but not angiotensin II (AII), increases membrane-associated DGK activity in rat small arteries [Ohanian and Heagerty (1994) Biochem. J. 300, 51-56]. Here, we have identified this DGK activity as DGKtheta, present in both smooth muscle and endothelial cells of these small vessels. Subcellular fractionation of artery homogenates revealed that DGKtheta was present in nuclear, plasma membrane (and/or Golgi) and cytosolic fractions. Upon NA stimulation, DGKtheta translocated towards the membrane and cytosol (155 and 153% increases relative to the control, respectively) at 30 s, followed by a return to near-basal levels at 5 min; AII was without effect. Translocation to the membrane was to both Triton-soluble and -insoluble fractions. NA, but not AII, transiently increased DGKtheta activity in immunoprecipitates (126% at 60 s). Membrane translocation and DGKtheta activation were regulated differently: NA-induced DGKtheta activation, but not translocation, was dependent on transient activation of phosphoinositide 3-kinase (PI 3-K). In addition, DGK activity co-immunoprecipitated with protein kinase B, a downstream effector of PI 3-K, and was increased greatly by NA stimulation. The rapid and agonist-specific activation of DGKtheta suggests that this pathway may have a physiological role in vascular smooth-muscle responses.