Spontaneous transfer of gangliotetraosylceramide between phospholipid vesicles

The transfer kinetics of the neutral glycosphingolipid gangliotetraosylceramide (asialo-GM1) were investigated by monitoring tritiated asialo-GM1 movement from donor to acceptor vesicles. Two different methods were employed to separate donor and acceptor vesicles at desired time intervals. In one method, a negative charge was imparted to dipalmitoylphosphatidylcholine donor vesicles by including 10 mol% dipalmitoylphosphatidic acid. Donors were separated from neutral dipalmitoylphosphatidylcholine acceptor vesicles by ion-exchange chromatography. In the other method, small, unilamellar donor vesicles (20-nm diameter) and large, unilamellar acceptor vesicles (70-nm diameter) were coincubated at 45 degrees C and then separated at desired time intervals by molecular sieve chromatography. The majority of asialo-GM1 transfer to acceptor vesicles occurred as a slow first-order process with a half-time of about 24 days assuming that the relative concentration of asialo-GM1 in the phospholipid matrix was identical in each half of the donor bilayer and that no glycolipid flip-flop occurred. Asialo-GM1 net transfer was calculated relative to that of [14C]cholesteryl oleate, which served as a nontransferable marker in the donor vesicles. A nearly identical transfer half-time was obtained when the phospholipid matrix was changed from dipalmitoylphosphatidylcholine to palmitoyloleoylphosphatidylcholine. Varying the acceptor vesicle concentration did not significantly alter the asialo-GM1 transfer half-time. This result is consistent with a transfer mechanism involving diffusion of glycolipid through the aqueous phase rather than movement of glycolipid following formation of collisional complexes between donor and acceptor vesicles. When viewed within the context of other recent studies involving neutral glycosphingolipids, these findings provide additional evidence for the existence of microscopic, glycosphingolipid-enriched domains within the phospholipid bilayer.     

Effects of apolipoproteins on the kinetics of cholesterol exchange

The effects of apolipoproteins on the kinetics of cholesterol exchange have been investigated by monitoring the transfer of [14C]cholesterol from donor phospholipid/cholesterol complexes containing human apolipoproteins A, B, or C. Negatively charged discoidal and vesicular particles containing purified apolipoproteins complexed with lipid (75 mol % egg PC, 15 mol % dicetyl phosphate, and 10 mol % cholesterol) and a trace of [14C]cholesterol were incubated with a 10-fold excess of neural, acceptor, small unilamellar vesicles (SUV; 90 mol % egg PC and 10 mol % cholesterol). The donor and acceptor particles were separated by chromatography on DEAE-Sepharose, and the rate of movement of labeled cholesterol was analyzed as a first-order exchange process. The kinetics of exchange of cholesterol from both vesicular and discoidal complexes that contain apoproteins are consistent with an aqueous diffusion mechanism, as has been established previously for PC/cholesterol SUV. The addition of 2-3 molecules of apo A-I to a donor SUV does not significantly alter the half-time (t1/2), which is 80 +/- 9 min at 37 degrees C. However, addition of 5-12 apo A-I molecules progressively decreases t1/2 from 65 +/- 2 to 45 +/- 4 min. This enhancement in the rate of desorption of cholesterol molecules is presumed to arise from the creation of packing defects at boundaries around the apoprotein molecules, which are intercalated among the phospholipid and cholesterol molecules in the surface of the donor SUV.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transbilayer movement of cholesterol in the human erythrocyte membrane

The rate of transbilayer movement of cholesterol was measured in intact human erythrocytes. Suspended erythrocytes were incubated briefly with [3H]cholesterol in ethanol at 4 degrees C, or with liposomes containing [3H]cholesterol over 6 hr at 4 degrees C to incorporate the tracer into the outer leaflet of erythrocyte plasma membranes. The erythrocytes were then incubated at 37 degrees C to allow diffusion of cholesterol across the membrane bilayer. Cells were treated briefly with cholesterol oxidase to convert a portion of the outer leaflet cholesterol to cholestenone, and the specific radioactivity of cholestenone was determined over the time of tracer equilibration. The decrease in specific radioactivity of cholestenone reflected transbilayer movement of [3H]cholesterol. The transbilayer movement of cholesterol had a mean half-time of 50 min at 37 degrees C in cells labeled with [3H]cholesterol in ethanol, and 130 min at 37 degrees C in cells labeled with [3H]cholesterol exchanged from liposomes. The cells were shown, by the absence of hemolysis, to remain intact throughout the assay. The presence of 1 mM Mg2+ in the assay buffer was essential to prevent hemolysis of cells treated with cholesterol oxidase perturbed the cells, resulting in an accelerated rate of apparent transbilayer movement. Our data are also consistent with an asymmetric distribution of cholesterol in erythrocyte membranes, with the majority of cholesterol in the inner leaflet.     

Spontaneous cholesterol movement between lipid vesicles and monkey small intestinal brush border membrane

[14C]Cholesterol movement between egg phosphatidylcholine-cholesterol lipid vesicles and vesicles prepared from monkey small intestinal brush border membrane (BBMV) was studied in physiological buffer at 37 degrees C. The rate of cholesterol transfer from sonicated unilamellar vesicles (ULV) to BBMV follows apparently first-order kinetics. Intermembrane cholesterol movement was strikingly similar in both the directions. However, from BBMV to ULV, the transfer rate was three times faster than that of ULV to brush border membrane (BBM). Similarity in the rate constant was observed when cholesterol transfer was studied using either large multilamellar lipid vesicles or ULV as the donor and BBMV as the acceptor membrane. Rate constant was also the same when the acceptor membrane used was either intact BBMV or ULV prepared from BBM lipids. The rate of transfer of label was not affected even when the acceptor vesicle concentration was increased over fivefold, indicating the first-order nature of the reaction. Transfer of cholesterol from ULV to BBMV was accelerated by the presence of acetone, dimethyl sulfoxide (DMSO), deoxycholate, and papain. Partially purified nonspecific lipid-exchange protein increased the rate of cholesterol transfer by about threefold. Reduction in BBM cholesterol and phospholipid content was noted by DMSO, acetone, and deoxycholate, while papain caused a small depletion of membrane protein. Cholesterol transfer is temperature dependent with an activation energy of 31 kJ X mol-1, which is almost identical in the presence or absence of nonspecific lipid-exchange protein. The molecular mechanism of intermembrane cholesterol movement is discussed in view of the kinetic data obtained.     

Cholesterol distribution and movement in the Mycoplasma gallisepticum cell membrane.

The time course and extent of transfer of [14C]-cholesterol from resting Mycoplasma gallisepticum cells or membrane preparations to high-density lipoproteins were studied. More than 90% of the total cholesterol in isolated, unsealed membrane preparations was exchanged in a single kinetic process. In intact cells, however, cholesterol exists in two different environments. Cholesterol in one environment, representing approximately 50% of the total unesterified cholesterol, is readily exchanged with the cholesterol of high-density lipoproteins, with a half-time of about 4 h at 37 degrees C. The rate of exchange of [14C]cholesterol from the other environment was exceedingly slow, with a half-time of about 18 days. The fraction of the total cholesterol in the readily exchangeable cholesterol pool in intact cells increased somewhat upon aging of the culture. Electron spin resonance spectra of nitroxide-labeled stearic acids incorporated into membranes of M. gallisepticum cells indicated increased rigidity at the late exponential phase of growth. These results suggest that cholesterol is present in approximately equal concentrations on both surfaces of the M. gallisepticum membrane and that in resting cells the rate of movement of cholesterol molecules from the inner to outer halves of the lipid bilayer is exceedingly slow or nonexistent.     

An activation-collision mechanism for cholesterol transfer between membranes

We report the results of experiments which show that cholesterol transfer between membranes cannot proceed by aqueous diffusion, as widely held, but must involve a more complex mechanism. (a) The rate of transfer of [3H]cholesterol from red blood cells was found to vary inversely with the size of the acceptor particle (ghosts, vesicles of ghosts, liposomes, and plasma lipoproteins). (b) The transfer of [3H]cholesterol from red blood cells to ghosts was accelerated by the presence of plasma, even though the plasma competed with the ghosts as an acceptor. (c) The rate of transfer of [3H]cholesterol from red blood cells to ghosts decreased to zero with increasing dilution but was not simply second-order. (d) The cholesterol in retinal rod disc membranes is not at equilibrium with plasma lipoproteins in that disc cholesterol increased when the homogenates were incubated in vitro with plasma. (e) The kinetics of cholesterol transfer cannot be limited by unstirred layer effects since the transfer of lysolecithin in the same system was faster than that of cholesterol by 3 orders of magnitude. The simplest model compatible with all the data suggests a two-step pathway involving a first-order followed by a second-order process. The first step could be a unimolecular activation event, perhaps the movement of the sterol in the donor particle to a more exposed (hydrated) position. In the second step, the activated sterol would be transferred during transient collisions between donor and acceptor particles. When collision is not rate-limiting, the overall process would appear to be simply first-order, hence kinetically indistinguishable from the aqueous diffusion mechanism. The activation-collision model thus not only rationalizes our data but is also consistent with the simpler kinetics previously reported for the transfer of both membrane phospholipids and sterols.     

Symmetrical distribution and rapid transbilayer movement of cholesterol in Mycoplasma gallisepticum membranes

The exchange of cholesterol between [¹⁴C]cholesterol-labeled Mycoplasma gallisepticum cells and an excess of sonicated egg phosphatidylcholine/cholesterol vesicles (molar ratio of 0.9) was measured. More than 90% of the radioactive cholesterol underwent transfer from intact cells to the vesicles. The kinetics of the transfer was biphasic. About 50% of the radioactive cholesterol was exchanged with a half-time of about 4 h. The residual was exchanged at a slower rate with a half-time of about 9 h at 37°C. Bovine serum albumin had a pronounced effect in enhancing both the fast and slow rates of cholesterol exchange, but did not affect the pool sizes significantly. The half-time for equilibration of the two pools in the presence of 2% albumin, calculated using a reversible two-pool method of analysis, was 6.2 h. The effect of albumin was also obtained with isolated membrane preparations and with cells treated with growth inhibitors, suggesting that this effect is independent of albumin preservation of cell viability. The rate enhancement of albumin was concentration dependent with maximal effects observed with 2%, where the rates of exchange of both the rapidly and slowly exchanging pools were twice as fast. The mechanism by which albumin may affect the exchange rates is discussed.     

Spontaneous activation of the first component of human complement (C1) by an intramolecular autocatalytic mechanism

For biochemical characterization, the first component of human complement (C1) was reconstituted from physiologic concentrations of purified C1q, 125I C1r, and 131I C1s. Upon incubation at 37 degrees C, C1 spontaneously activated, as evidenced by the characteristic proteolysis of the C1r and C1s polypeptide chains as detected by SDS-PAGE analysis. This spontaneous C1 activation followed first-order kinetics (t 1/2 = 4 min and k = 0.173 min-1) with an activation energy of 19.1 kcal/mol. Spontaneous C1 activation was unaffected by the general protease inhibitor phenylmethylsulfonylfluoride (PMSF) but reversibly blocked by a known inhibitor of C1 activation, nitrophenylguanidinobenzoate (NPGB). Spontaneous C1 activation was measured at C1 concentrations ranging from 9 to 160 nM (i.e., 0.05 to 1.0 times physiologic concentrations). The data indicate that C1 spontaneously activates by an intramolecular autocatalytic mechanism, for first-order kinetics were observed over the entire concentration range with t 1/2 = 4 min at each concentration. However, the percentage of activable C1 decreased with dilution due to C1 dissociation (i.e., C1qr2s2 leads to C1q + C1r2s2). The observed concentration of C1 that spontaneously activated at each dilution equalled the concentration of C1 present as macromolecular C1. When reconstituted C1 was mixed with normal human serum (NHS) and then incubated at 37 degrees C, spontaneous C1 activation was completely inhibited. Pretreating NHS at 56 degrees C for 30 min destroyed its inhibitory activity. In conclusion, C1 spontaneously autoactivates at 37 degrees C by an intramolecular mechanism. This activation is suppressed in NHS.     

Anisotropic motion of cholesterol in oriented DPPC bilayers studied by quasielastic neutron scattering: the liquid-ordered phase.

Quasielastic neutron scattering (QENS) at two energy resolutions (1 and 14 microeV) was employed to study high-frequency cholesterol motion in the liquid ordered phase (lo-phase) of oriented multilayers of dipalmitoylphosphatidylcholine at three temperatures: T = 20 degrees C, T = 36 degrees C, and T = 50 degrees C. We studied two orientations of the bilayer stack with respect to the incident neutron beam. This and the two energy resolutions for each orientation allowed us to determine the cholesterol dynamics parallel to the normal of the membrane stack and in the plane of the membrane separately at two different time scales in the GHz range. We find a surprisingly high, model-independent motional anisotropy of cholesterol within the bilayer. The data analysis using explicit models of molecular motion suggests a superposition of two motions of cholesterol: an out-of-plane diffusion of the molecule parallel to the bilayer normal combined with a locally confined motion within the bilayer plane. The rather high amplitude of the out-of-plane diffusion observed at higher temperatures (T >/= 36 degrees C) strongly suggests that cholesterol can move between the opposite leaflets of the bilayer while it remains predominantly confined within its host monolayer at lower temperatures (T = 20 degrees C). The locally confined in-plane cholesterol motion is dominated by discrete, large-angle rotational jumps of the steroid body rather than a quasicontinous rotational diffusion by small angle jumps. We observe a significant increase of the rotational jump rate between T = 20 degrees C and T = 36 degrees C, whereas a further temperature increase to T = 50 degrees C leaves this rate essentially unchanged.     

Kinetics of cholesterol and phospholipid exchange between Mycoplasma gallisepticum cells and lipid vesicles. Alterations in membrane cholesterol and protein content

The kinetics of exchange of radiolabeled cholesterol and phospholipids between intact Mycoplasma gallisepticum cells and unilamellar lipid vesicles were investigated over a wide range of cholesterol/phospholipid molar ratio. The change in cholesterol/phospholipid molar ratio was achieved by adapting the sterol-requiring M. gallisepticum to grow in cholesterol-poor media, providing cells with decreased unesterified cholesterol content. At least 90% of the cholesterol molecules in unsealed M. gallisepticum membranes underwent exchange at 37 degrees C as a single kinetic pool in the presence of albumin (2%, w/v). However, we observed biphasic exchange kinetics with intact cells, indicating that cholesterol translocation from the inner to outer monolayers was rate-limiting in the exchange process. Approximately 50% of the cholesterol molecules were localized in each kinetic pool, independent of the cholesterol/phospholipid molar ratio in the cells and vesicles. A striking change in the kinetic parameters for cholesterol exchange occurred between 20 and 26 mol % cholesterol; for example, when the cholesterol/phospholipid molar ratio was decreased from 0.36 to 0.25, the half-time for equilibration of the two cholesterol pools at 37 degrees C decreased from 4.6 +/- 0.5 to 2.5 +/- 0.1 h. Phospholipid exchange rates were also enhanced on decreasing the membrane cholesterol content. The ability of cholesterol to modulate its own exchange rate, as well as that of phospholipids, is suggested to arise from the sterol's ability to regulate membrane lipid order. Extensive chemical modification of the membrane surface by cross-linking of some of the protein constituents with 1,4-phenylenedimaleimide decreased the cholesterol exchange rate. Depletion of membrane proteins by treatment of growing cultures with chloramphenicol increased the cholesterol exchange rate, possibly because of removal of some of the protein mass that may impede lipid translocation. The observations that phospholipid exchange was one order of magnitude slower than cholesterol exchange and that dimethyl sulfoxide, potassium thiocyanate, and potassium salicylate enhanced the cholesterol exchange rate are consistent with a mechanism involving lipid exchange by diffusion through the aqueous phase.     

Charge transfer across a single lipid-water interface causes ion pumping across the bilayer.

The photoformation of magnesium-porphyrin cations (P+) at a single lipid bilayer-water interface can pump lipophilic borate anions completely across the lipid bilayer and causes an actual reversal of the photovoltage. The system consists of a lipid bilayer containing magnesium octaethylporphyrin, an aqueous or interfacial electron acceptor on one side, and chloro- or fluoro-substituted tetraphenylborate in both aqueous electrolyte solutions. With 1-micros pulsed illumination, an immediate positive photovoltage is observed, which decreases on the microsecond and millisecond time scales. On the time scale of seconds, as the P+ cation concentration decays in reverse electron transfer, the voltage swings negative to a value almost equal to its initial value and finally decays with a half-time (approximately 20 s) longer than the time constant of the system (approximately 5 s). Thus, an ion gradient across the membrane is formed, trapped by the nonlinear relation between ion mobility and ion concentration. Continuous light illumination confirms that negative charge moves in the direction opposite that of the initial photoinduced electron transfer. Steady-state measurements indicate an ion pumping efficiency of approximately 30%. This simple mechanism may be a progenitor of photobiological ion pumps.     

Cholesterol transfer from small and large unilamellar vesicles

The rates of transfer of [14C]cholesterol from small and large unilamellar cholesterol/egg yolk phosphatidylcholine vesicles to a common vesicle acceptor were compared at 37 degrees C. The rate of exchange of cholesterol between vesicles of identical cholesterol concentrations (20 mol%) did not differ from the rate of transfer from donor vesicles containing 20 mol% cholesterol to egg yolk PC vesicles. Further, the rate of transfer of [14C]cholesterol from vesicles containing 15 mol% dicetyl phosphate (to confer a negative charge) was not different from the rate of transfer from neutral vesicles. However, the half-time for transfer of [14C]cholesterol from large unilamellar donor vesicles was about 5-times greater (10.2 h, 80 nm diameter) than from small unilamellar vesicles (2.3 h, 23 nm diameter). These data suggest that increased curvature in small unilamellar vesicles reduces cholesterol-nearest neighbor interactions to allow a more rapid transfer of cholesterol into the aqueous phase.     

Effects of apolipoprotein structure on the kinetics of apolipoprotein transfer between phospholipid vesicles

The kinetics and mechanism of transfer of 14C-labeled human apolipoproteins A-I, A-II and C-III1 between small unilamellar vesicles (SUV) have been investigated. Ion exchange chromatography was used for rapid separation of negatively charged egg phosphatidylcholine (PC)/dicetyl phosphate donor SUV containing bound 14C-labeled apoprotein from neutral egg PC acceptor SUV present in 10-fold molar excess. The transfer kinetics of these apolipoproteins at 37 degrees C are consistent with the existence of fast, slow and apparently 'nontransferrable' pools of SUV-associated lipoprotein: the transfers from these pools occur on timescales of seconds (or less), minutes/hours and days/weeks, respectively. For donor SUV containing about 15 apoprotein molecules per vesicle and at a donor SUV concentration of 0.15 mg phospholipid/ml incubation mixture, the sizes of the fast kinetic pools for apolipoproteins A-I, A-II and C-III1 associated with donor SUV are 2, 10 and 11%, respectively. The sizes of the slow kinetic pools for these apolipoproteins are 16, 71 and 50%, respectively. The transfer of the various apolipoproteins from the slow kinetic pool follows first order kinetics and the half-time (t1/2) values are in the order: apo C-III1 less than apo A-I. Increasing the number of apoprotein molecules per donor SUV enlarges the size of the fast pool and increases the t1/2 of slow transfer. The differences in the kinetics of apolipoprotein transfer between SUV are consequences of the variations in the primary and secondary structures of the apolipoprotein molecules. The slow transfer of apoprotein molecules is mediated by collisions between donor and acceptor SUV; the rate is dependent on the apoprotein molecular weight with larger molecules transferring more slowly from donor SUV containing the same lipid/protein molar ratio. The hydrophobicity of the apoprotein molecule is also significant with less hydrophobic molecules transferring more rapidly. Further understanding of the differences in the kinetics of transfer of these apolipoproteins will require more knowledge of their secondary and tertiary structures.     

Monitoring the permeability profile of lipid membranes with spin probes

The rate of reaction of the ascorbate ion with the nitroxide group of spin probes intercalated in lipid bilayers has been studied to examine the mechanism of transport of solutes across membranes. The loss of electron spin resonance (ESR) signal follows first-order kinetics. For a given bilayer system, the half-time of the process increases with the distance of the reacting group from the aqueous interface, according to an approximately linear permeation profile. The dependence on phospholipid headgroup is that which would be predicted from the net charge; addition of negatively charged headgroups increases the half-time of reaction, and positively charged headgroups decrease it, compared with bilayers having no net charge. Addition of cholesterol, which is known to decrease the fluidity of the hydrocarbon core of the bilayer, is found to increase the half-time of reaction. The results have been analyzed in terms of a partition-diffusion mechanism. It is suggested that the rate-limiting step for partitioning the solute into the bilayer might be removal of water of hydration. Cholesterol increases the activation energy, most probably by increasing the height of the barriers to diffusion. Quantitation of the changes in reaction rates gives an estimate of the change in bilayer surface potential on changing the headgroup composition. Examination of the permeation profile supports a diffusive mechanism, from which it can be estimated that the diffusion coefficient is approximately halved on adding 35 mol% cholesterol to egg lecithin bilayers.     

Calcium modulates the lipid dynamics of rat hepatocyte plasma membranes by direct and indirect mechanisms

Calcium ion decreases the motional freedom of lipid molecules in isolated rat hepatocyte plasma membranes and in sonicated dispersions (liposomes) of the membrane lipid. The decrease in lipid fluidity was monitored by estimation of the fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene. At least two processes are involved in the mode of action of the cation. The first is direct, i.e., observed on addition of calcium to the liposomes, relatively rapid, with a half-time of 10-15 at 37 degrees C, proportional to the calcium concentration in the range 0-4 mM, and readily reversed on addition of excess EDTA. The second mechanism is indirected and requires the presence of the membrane proteins. It occurs relatively slowly, with a half-time of 75 min at 37 degrees C, tends to plateau with a calcium half-saturation concentration of approximately 1 mM, is of greater magnitude than the direct effect, and cannot be reversed on chelation of calcium by EDTA. Moreover, the indirect effect is specific for Ca2+ as compared to other divalent cations and it results in changes in the lipid composition. Stimulation of phospholipase A activity is likely but does not account for the change in fluidity. The direct action of calcium is ascribed to binding to the lipid bilayer, whereas the indirect action probably results from modulation of membrane-bound enzymes which can alter the lipid composition. The effects of calcium on the membrane lipid fluidity may underly certain of its regulatory actions on membrane functions.     

Effect of fatty acyl chain length of phosphatidylcholine on their transfer from liposomes to erythrocytes and transverse diffusion in the membranes inferred by TEMPO-phosphatidylcholine spin probes

TEMPO-phosphatidylcholine (PC) spin probes which have homologous saturated acyl chains of 10, 12, 14 and 16 carbon atoms, were synthesized as analogues of PC. Transfer of TEMPO-PCs from liposomal membrane to the ghost membrane of human erythrocyte and transverse diffusion of TEMPO-PCs within the membrane of intact erythrocytes were determined by measurement of spontaneous increase and decrease in signal amplitude of an anisotropic triplet spectrum, due to dilution of the label by natural phospholipid of the membrane and reduction of the label by the cytoplasmic content of the erythrocyte, respectively. TEMPO-PC molecules in TEMPO-PC liposomes, except dipalmitoyl TEMPO-PC, were rapidly incorporated into the ghost membrane by incubation at 37 degrees C; the PC having shorter acyl chains was transferred faster. The cytoplasmic content of the erythrocyte rapidly reduced the nitroxide radical of the spin probe. The central peak height of ESR signal was once increased by incorporation of TEMPO-PC into the erythrocyte membrane and then was spontaneously decreased during further incubation at 37 degrees C. This decrease indicates that PC molecules traverse from the outer to the inner layer of the membrane lipid bilayer. The decrease of signal amplitude was faster with PC of shorter acyl chain. These findings suggest that both transfer between membranes and transverse diffusion in the membrane may be favored to the PC species with shorter acyl chains.     

Spontaneous phosphatidylcholine transfer by collision between vesicles at high lipid concentration

The transfer kinetics of [3H]-1-palmitoyl-2-oleoylphosphatidylcholine ([3H]POPC) and 1-palmitoyl-2-(pyrenyldecanoyl)phosphatidylcholine (PyrPC) from POPC small unilamellar vesicles were examined at 37 degrees C with lipid concentrations ranging from 0.1 to 40 mM. The rate of [3H]POPC transfer was determined by analyzing the movement of this lipid from charged donor to neutral acceptor vesicles. The rate of decay of the ratio of the intensity of pyrene excimer fluorescence to that from the pyrene monomer (E/M) upon addition of an unlabeled vesicle population to a population containing PyrPC was used to evaluate PyrPC transfer. For both lipids, the kinetic data are best described by a model which assumes that transfer occurs by vesicle collisions as well as by desorption from the bilayer. For [3H]POPC, the off-rate constant is 0.014 h-1 while the collisional rate constant is 0.0016 mM-1 h-1. PyrPC has an off-rate constant of 0.023 h-1 and a collisional constant of 0.0015 mM-1 h-1. These numbers were calculated by assuming the rate of interbilayer transfer to be negligible relative to that of intervesicular transfer. The large transfer fluxes in the high vesicle concentration range where the collisional process dominates suggest that spontaneous transfer may be of importance in membrane biogenesis.     

Lipid recycling between the plasma membrane and intracellular compartments: transport and metabolism of fluorescent sphingomyelin analogues in cultured fibroblasts

We examined the metabolism and intracellular transport of the D-erythro and L-threo stereoisomers of a fluorescent analogue of sphingomyelin, N-(N-[6-[(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino] caproyl])-sphingosylphosphorylcholine (C6-NBD-SM), in Chinese hamster ovary (CHO-K1) fibroblast monolayers. C6-NBD-SM was integrated into the plasma membrane bilayer by transfer of C6-NBD-SM monomers from liposomes to cells at 7 degrees C. The cells were washed, and within 10-15 min of being warmed to 37 degrees C, C6-NBD-SM was internalized from the plasma membrane to a perinuclear location that colocalized with the centriole and was distinct from the lysosomes and the Golgi apparatus. This perinuclear region was also labeled by internalized rhodamine-conjugated transferrin. C6-NBD-SM endocytosis was not inhibited when the microtubules were disrupted with nocodazole; rather, the fluorescent lipid was distributed in vesicles throughout the cell periphery instead of being internalized to the perinuclear region of the cell. The metabolism of C6-NBD-SM to other fluorescent sphingolipids at 37 degrees C and its effect on C6-NBD-SM transport was also examined. To study plasma membrane lipid recycling, C6-NBD-SM was first inserted into the plasma membrane of CHO-K1 cells and then allowed to be internalized by the cells at 37 degrees C. Any C6-NBD-SM remaining at the plasma membrane was then removed by incubation with nonfluorescent liposomes at 7 degrees C, leaving cells containing only internalized fluorescent lipid. The return of C6-NBD-SM to the plasma membrane from intracellular compartments upon further 37 degrees C incubation was then observed. The half-time for a complete round C6-NBD-SM recycling between the plasma membrane and intracellular compartments was approximately 40 min. Pretreatment of cells with either monensin or nocodazole did not inhibit C6-NBD-SM recycling.     

Effect of lipid physical state on the rate of peroxidation of liposomes.

The effect of cholesterol on the rate of peroxidation of arachidonic acid and 1-palmitoyl-2-arachidonoyl phosphatidylcholine (PAPC) in dimyristoylphosphatidylcholine (DMPC) liposomes was examined above and below the phase transition temperature (Tm) of the lipid. The rate of peroxidation of arachidonic acid was more rapid below the phase transition temperature of the host lipid. At a temperature below the Tm (4 degrees C), increasing concentrations of cholesterol reduced the rate of peroxidation of arachidonic acid as judged by the production of thiobarbituric acid reactive substances. Above Tm (37 degrees C), cholesterol increased the rate of peroxidation of the fatty acid. Similarly, PAPC was peroxidized more rapidly at 4 degrees C than at 37 degrees C. However, cholesterol had little effect on the rate of peroxidation of PAPC at 4 degrees C. The rate of peroxidation of arachidonic acid was related to the lipid bilayer fluidity as judged by fluorescence anisotropy measurements of diphenylhexatriene. The rate of peroxidation increased slowly with increasing rigidity of the probe environment when the bilayer was relatively fluid and more rapidly as the environment became more rigid. The increase in the rate of peroxidation of arachidonic acid in the less fluid host lipid was unrelated to differences in iron binding or to transfer of arachidonic acid to the aqueous phase. Decreasing the concentration of arachidonic acid in DMPC to less than 2 mol% dramatically decreased the rate of peroxidation at 4 degrees C, suggesting that formation of clusters of fatty acids at 4 degrees C is required for rapid peroxidation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transfer of cholesterol from its site of synthesis to the plasma membrane

We have followed the transfer of newly synthesized cholesterol to the plasma membrane in cultured fibroblasts using cholesterol oxidase as a probe. Since the enzyme has access only to the plasma membrane in intact cells, it permits the discrimination of cell surface and endogenous cholesterol. Cholesterol synthesized from radiolabeled acetate was transferred to the plasma membrane in a strictly first order fashion with a half-time of 1-2 h at 37 degrees C. The rate of transfer was similar in rapidly growing and confluent cells and was not affected by preincubating the cells in lipoprotein-deficient serum which greatly stimulated cholesterol synthesis. We used equilibrium density gradient centrifugation of homogenates from cholesterol oxidase-treated cells to examine further the distribution of newly synthesized cholesterol between cellular pools. We identified membrane fractions enriched in newly synthesized cholesterol yet inaccessible to cholesterol oxidase. The cholesterol in these membranes eventually moved to the plasma membrane. The movement of exogenous radiocholesterol from the plasma membrane to the cell interior also was examined by this method. No detectable transfer was observed over several hours, during which time endogenous cholesterol moved to the plasma membrane. We conclude that the transfer of newly synthesized cholesterol to the plasma membrane is a vectorial process and is not mediated by a simple diffusional equilibrium.