Differential effects of cholesterol and desmosterol on the ligand binding function of the hippocampal serotonin1A receptor: Implications in desmosterolosis

Cholesterol is a unique molecule in terms of high level of in-built stringency, fine tuned by natural evolution for its ability to optimize physical properties of higher eukaryotic cell membranes in relation to biological functions. We previously demonstrated the requirement of membrane cholesterol in maintaining the ligand binding activity of the hippocampal serotonin_1A receptor. In order to test the molecular stringency of the requirement of cholesterol, we depleted cholesterol from native hippocampal membranes followed by replenishment with desmosterol. Desmosterol is an immediate biosynthetic precursor of cholesterol in the Bloch pathway differing only in a double bond at the 24th position in the alkyl side chain. Our results show that replenishment with desmosterol does not restore ligand binding activity of the serotonin_1A receptor although replenishment with cholesterol led to significant recovery of ligand binding. This is in spite of similar membrane organization (order) in these membranes, as monitored by fluorescence anisotropy measurements. The requirement for restoration of ligand binding activity therefore appears to be more stringent than the requirement for the recovery of overall membrane order. These novel results have potential implications in understanding the interaction of membrane lipids with this important neuronal receptor in diseases such as desmosterolosis.     

Molecular dynamics simulation of the structure of dimyristoylphosphatidylcholine bilayers with cholesterol, ergosterol, and lanosterol

Five molecular dynamics computer simulations were performed on different phospholipid:sterol membrane systems in order to study the influence of sterol structure on membrane properties. Three of these simulated bilayer systems were composed of a 1:8 sterol:phospholipid ratio, each of which employed one of the sterol molecules: cholesterol, ergosterol, and lanosterol. The two other simulations were of a bilayer with a 1:1 sterol:phospholipid ratio. These simulations employed cholesterol and lanosterol, respectively, as their sterol components. The observed differences in simulations with cholesterol and lanosterol may have their implication on the form of the phospholipid/sterol phase diagram.     

Effects of a supernatant protein activator on microsomal squalene-2,3-oxide-lanosterol cyclase.

A soluble protein termed "supernatant protein factor" (SPF) that stimulates microsomal squalene epoxidase has been isolated in this laboratory (Ferguson, J.B., and Bloch, K. (1977) J. Biol. Chem. 252, 5381-5385). We now show that the purified protein also stimulates microsomal squalene-2,3-oxide leads to lanosterol cyclase but has no effect on the subsequent conversion of lanosterol to cholesterol. Phospholipid, specifically phosphatidylglycerol or phosphatidylethanolamine, is required for maximal stimulation of the cyclase by purified SPF. The response of microsomal squalene epoxide-lanosterol cyclase to SPF was abolished by pretreatment of the membranes with phospholipase A2 or by low concentrations of deoxycholate, indicating that an intact membrane system is required. Digestion of intact microsomes with trypsin had no effect on the SPF-stimulated cyclase activity. However, in the presence of 0.4% deoxycholate, trypsin completely inhibited microsomal squalene epoxide-lanosterol cyclase. We conclude that the cyclase is located on the luminal side of the microsomal membrane. SPF also significantly enhances the formation of lanosterol from squalene-2,3-oxide already bound to microsomes. This finding is constant with the proposal that SPF influences intramembrane events.     

Cholesterol-induced effects on the viscoelasticity of monoglyceride bilayers.

Changes in the viscoelastic properties of glycerol monooleate bilayers resulting from the incorporation of cholesterol into the membranes have been measured. The interface tension increases with the cholesterol concentration, reaching saturation for a 4.2:1 mole ratio of cholesterol:lipid in the film-forming solution. Incorporation of cholesterol in the membrane causes the appearance of a large intrinsic viscosity; this also increases with the sterol content of the membrane. Molecular models of lipid-sterol interactions and packing are considered to explain both the observed changes in membrane properties and similarities with comparable lipid systems.     

Speculations on the evolution of sterol structure and function.

The essential oxygen requirement for sterol biosynthesis dates this molecule as a relative latecomer in cellular evolution. Structural details of the cholesterol molecule and related sterols can be rationalized in terms of optimal hydrophobic interactions between the planar sterol ring system and phospholipid acyl chains in the membrane bilayer. The prediction that the cholesterol precursor lanosterol (4,4',14 trimethyl cholastadienol) is incompetent for membrane function is verified by in vivo experiments with eucaryotic sterol auxotrophs and microviscosity measurements of sterol-containing artificial membranes. For procaryotic cells the sterol specificity is very much broader. Methylococcus capsulatus produces 4,4-dimethyl- and 4-monomethyl sterols, but not sterols of the cholesterol type. Similarly lanosterol and its partially demethylated derivatives satisfy the sterol requirement of Mycoplasma capricolum. A more primitive but unspecified role of cyclized squalene derivatives is therefore postulated for procaryotic membranes. The finding that cholesterylmethyl ether satisfies the sterol requirement of certain microbial systems is at variance with current views on the role played by the sterol hydroxyl group in membrane organization and function.     

Cholesterol-rich intracellular membranes: a precursor to the plasma membrane

The disposition of newly synthesized sterols in cultured human fibroblasts has been examined in this study. We began by demonstrating that cholesterol mass and exogenously added [3H]cholesterol both are markers for the plasma membrane, perhaps better than 5'-nucleotidase. Cells were incubated with radioactive acetate to label their endogenous sterols biosynthetically, treated with cholesterol oxidase to convert plasma membrane cholesterol to cholestenone, and then homogenized and spun to equilibrium on sucrose gradients. The density gradient profiles of the various organelles were monitored using these markers: plasma membrane, radioactive cholestenone; smooth endoplasmic reticulum, 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase); and Golgi apparatus, galactosyltransferase. The buoyant density profiles of radioactive intracellular cholesterol and lanosterol both had a peak at 1.12 g/cm3, similar to 5'-nucleotidase and galactosyltransferase but not to HMG-CoA reductase. This result suggests that cholesterol biosynthesis is not taken to completion in the endoplasmic reticulum. Digitonin treatment shifted the profiles of both plasma membrane and intracellular cholesterol to higher densities. Pretreatment of intact cells with cholesterol oxidase abolished the digitonin shift of plasma membranes but not the intracellular cholesterol, indicating that these two membrane pools are not entirely physically associated. Because intracellular cholesterol was shifted more than any of the organelle markers, it must reside in a separate membrane. Since digitonin selectively shifts the density of membranes rich in cholesterol, we infer that newly synthesized cholesterol accumulates in such membranes prior to its delivery to the plasma membrane. Taken together, these results suggest that cholesterol may be concentrated for delivery to the plasma membrane by being synthesized from a sterol precursor such as lanosterol in a discrete but undefined intracellular membrane.     

Universal behavior of membranes with sterols

Lanosterol is the biosynthetic precursor of cholesterol and ergosterol, sterols that predominate in the membranes of mammals and lower eukaryotes, respectively. These three sterols are structurally quite similar, yet their relative effects on membranes have been shown to differ. Here we study the effects of cholesterol, lanosterol, and ergosterol on 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine lipid bilayers at room temperature. Micropipette aspiration is used to determine membrane material properties (area compressibility modulus), and information about lipid chain order (first moments) is obtained from deuterium nuclear magnetic resonance. We compare these results, along with data for membrane-bending rigidity, to explore the relationship between membrane hydrophobic thickness and elastic properties. Together, such diverse approaches demonstrate that membrane properties are affected to different degrees by these structurally distinct sterols, yet nonetheless exhibit universal behavior.     

Cholesterol is not synthesized in membranes bearing 3-hydroxy-3-methylglutaryl coenzyme A reductase

We have shown previously that newly synthesized lanosterol and cholesterol in homogenates of cultured human fibroblasts do not have the same equilibrium buoyant density as the 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase) in the smooth endoplasmic reticulum (SER) (Lange, Y., and Steck, T. L. (1985) J. Biol. Chem. 260, 15592-15597). This finding suggested two alternative and novel hypotheses: (a) that lanosterol and cholesterol might be transported rapidly from the SER to other internal membranes or (b) that synthesis of the sterols is not associated with the SER, or at least not with that portion of this organelle bearing HMG-CoA reductase. We therefore compared the subcellular distribution of HMG-CoA reductase with that of enzymes which convert lanosterol to cholesterol. The two activities studied were the consumption of exogenous [3H]lanosterol and the conversion of exogenous radiolanosterol to radiocholesterol. Differential centrifugation, rate zonal centrifugation, and equilibrium sucrose gradient centrifugation of rat liver homogenates all showed that these enzyme activities did not comigrate with HMG-CoA reductase. The subcellular distribution of newly synthesized sterols also was examined in cultured human fibroblasts. Cells were incubated with radioactive acetate to label endogenous sterols biosynthetically, homogenized, and spun to equilibrium on sucrose gradients. The buoyant density profiles of radioactive cholesterol and lanosterol both had a peak at 1.12 g/cm3. Digitonin treatment shifted both sterols to higher densities, strong evidence that they resided in cholesterol-rich membranes. Pretreatment of intact cells with cholesterol oxidase, which selectively oxidizes plasma membrane cholesterol, abolished the digitonin shift of lanosterol but not of intracellular cholesterol. These findings provide support for the hypothesis that newly synthesized cholesterol and lanosterol are not in the same membrane.     

Desmosterol may replace cholesterol in lipid membranes

Recently, knockout mice entirely lacking cholesterol have been described as showing only a mild phenotype. For these animals, synthesis of cholesterol was interrupted at the level of its immediate precursor, desmosterol. Since cholesterol is a major and essential constituent of mammalian cellular membranes, we asked whether cholesterol with its specific impact on membrane properties might be replaced by desmosterol. By employing various approaches of NMR, fluorescence, and EPR spectroscopy, we found that the properties of phospholipid membranes like lipid packing in the presence of cholesterol or desmosterol are very similar. However, for lanosterol, a more distant precursor of cholesterol synthesis, we found significant differences in comparison with cholesterol and desmosterol. Our results show that, from the point of view of membrane biophysics, cholesterol and desmosterol behave identically and, therefore, replacement of cholesterol by desmosterol may not impact organism homeostasis.     

Topographic heterogeneity in cholesterol biosynthesis

We have examined the membrane topography of cholesterol biosynthesis in cultured human fibroblasts. We fed the cells with radioacetate and then interrupted the biosynthetic pathway so as to trap labeled intermediates in their subcellular locations. We analyzed homogenates of human fibroblasts labeled biosynthetically from radioacetate by centrifugation to equilibrium on sucrose gradients. The following two methods were used to interrupt cholesterol biosynthesis: incubation at 10 degrees C and treatment with 4,4,10 beta-trimethyl-trans-decal-3 beta-ol, a specific inhibitor of oxidosqualene cyclase. Incubation at 10 degrees C caused the accumulation of radiolanosterol at the expense of cholesterol. The lanosterol appeared predominantly at an unusually buoyant density (20% (w/w) sucrose; d = 1.08 g/cm3) as well as at the density normally labeled at 37 degrees C (30% sucrose; d = 1.13 g/cm3). 4,4,10 beta-Trimethyl-trans-decal-3 beta-ol treatment caused the accumulation of labeled squalene and squalene 2,3-oxide. Reversal of the block permitted the label to progress rapidly as a wave into lanosterol and ultimately into cholesterol. The profiles of the three precursors did not coincide, suggesting that they were mostly in different membranes. Squalene was uniquely confined to a density of 1.18 g/cm3 (40% sucrose) while squalene 2,3-oxide appeared in peaks of density 1.08 g/cm3 and 1.13 g/cm3 (20% and 30% sucrose). Lanosterol was in a peak of density 1.13 g/cm3. Pulse-chase experiments showed that lanosterol synthesized in the membranes at 20% sucrose moved rapidly to the membranes at 30% sucrose where it was converted to cholesterol. The density gradient profiles of the following organelle markers also were monitored: plasma membrane, cholesterol mass; Golgi apparatus, galactosyltransferase; endoplasmic reticulum, RNA, 3-hydroxy-3-methylglutaryl-coenzyme A reductase and cytochrome c reductase; peroxisomes, catalase. None of these markers appeared at the buoyant density of 1.08 g/cm3. We conclude that 1) cholesterol biosynthesis may be topographically heterogeneous and 2) newly synthesized squalene 2,3-oxide resides in a buoyant membrane fraction distinct from markers for the major organelles.     

Effects of Natural and Enantiomeric Cholesterol on the Thermotropic Phase Behavior and Structure of Egg Sphingomyelin Bilayer Membranes

Phospholipids, sphingolipids, and sterols are the major lipid components of the plasma membranes of eukaryotic cells. Because these three lipid classes occur naturally as enantiomerically pure compounds, enantiospecific lipid-lipid and lipid-sterol interactions could in principle occur in the lipid bilayers of eukaryotic plasma membranes. Although previous biophysical studies of phospholipid and phospholipid-sterol model membrane systems have consistently failed to observe such enantiomerically selective interactions, a recent monolayer study of the interactions of natural and enantiomeric cholesterol with egg sphingomyelin has apparently revealed the existence of enantiospecific sterol-sphingolipid interactions. To determine whether enantiospecific sterol-sphingolipid interactions also occur in more biologically relevant lipid-bilayer systems, differential scanning calorimetric, x-ray diffraction, and neutral buoyant-density measurements were utilized to study the effects of natural and enantiomeric cholesterol on the thermotropic phase behavior and structure of egg sphingomyelin bilayers. The calorimetry experiments show that the natural and enantiomeric cholesterol have essentially identical effects on the temperature, enthalpy, and cooperativity of the gel/liquid-crystalline phase transition of egg sphingomyelin bilayers within the limits of experimental error. As well, the x-ray diffraction and neutral buoyancy experiments indicate that bilayers formed from mixtures of natural or enantiomeric cholesterol and egg sphingomyelin have, within experimental uncertainty, the same structure and mass density. We thus conclude that significant enantioselective cholesterol-sphingolipid interactions do not occur in this lipid-bilayer model membrane system.     

Significance of sterol structural specificity. Desmosterol cannot replace cholesterol in lipid rafts

Desmosterol is an immediate precursor of cholesterol in the Bloch pathway of sterol synthesis and an abundant membrane lipid in specific cell types. The significance of the difference between the two sterols, an additional double bond at position C24 in the tail of desmosterol, is not known. Here, we provide evidence that the biophysical and functional characteristics of the two sterols differ and that this is because the double bond at C24 significantly weakens the sterol ordering potential. In model membranes, desmosterol was significantly weaker than cholesterol in promoting the formation or stability of ordered domains, and in mammalian cell membranes, desmosterol associated less avidly than cholesterol with detergent-resistant membranes. Atomic scale molecular dynamics simulations showed that the double bond gives rise to additional stress in the tail, creating a rigid structure between C24 and C27 and favoring tilting of desmosterol distinct from cholesterol. Functional effects of desmosterol in cell membranes were assessed upon acutely exchanging approximately 70% of cholesterol to desmosterol. This led to impaired raft-dependent signaling via the insulin receptor, whereas non-raft-dependent protein secretion was not affected. We suggest that the choice of cholesterol synthesis route may provide a physiological mechanism to modulate raft-dependent functions in cells.     

Cholesterol precursors stabilize ordinary and ceramide-rich ordered lipid domains (lipid rafts) to different degrees. Implications for the Bloch hypothesis and sterol biosynthesis disorders

Genetic disorders of cholesterol biosynthesis result in accumulation of cholesterol precursors and cause severe disease. We examined whether cholesterol precursors alter the stability and properties of ordered lipid domains (rafts). Tempo quenching of a raft-binding fluorophore was used to measure raft stability in vesicles containing sterol, dioleoylphosphatidylcholine, and one of the following ordered domain-forming lipids/lipid mixtures: dipalmitoylphosphatidylcholine (DPPC), sphingomyelin (SM), a SM/cerebroside mixture or a SM/ceramide (cer) mixture. Relative to cholesterol, early cholesterol precursors containing an 8-9 double bond (lanosterol, dihydrolanosterol, zymosterol, and zymostenol) only weakly stabilized raft formation by SM or DPPC. Desmosterol, a late precursor containing the same 5-6 double bond as cholesterol, but with an additional 24-25 double bond, also stabilized domain formation weakly. In contrast, two late precursors containing 7-8 double bonds (lathosterol and 7-dehydrocholesterol) were better raft stabilizers than cholesterol. For vesicles containing SM/cerebroside and SM/cer mixtures the effect of precursor upon raft stability was small, although the relative effects of different precursors were the same. Using both detergent resistance and a novel assay involving fluorescence quenching induced by certain sterols we found cholesterol precursors were displaced from cer-rich rafts, and could displace cer from rafts. Precursor displacement by cer was inversely correlated to precursor raft-stabilizing abilities, whereas precursor displacement of cer was greatest for the most highly raft-stabilizing precursors. These observations support the hypothesis that sterols and cer compete for raft-association (Megha, and London, E. (2004) J. Biol. Chem. 279, 9997-10004). The results of this study have important implications for how precursors might alter raft structure and function in cells, and for the Bloch hypothesis, which postulates that sterol properties are gradually optimized for function along the biosynthetic pathway.     

Comparative calorimetric and spectroscopic studies of the effects of lanosterol and cholesterol on the thermotropic phase behavior and organization of dipalmitoylphosphatidylcholine bilayer membranes

We carried out comparative DSC and Fourier transform infrared spectroscopic studies of the effects of cholesterol and lanosterol on the thermotropic phase behavior and organization of DPPC bilayers. Lanosterol is the biosynthetic precursor of cholesterol and differs in having three rather than two axial methyl groups projecting from the β-face of the planar steroid ring system and one axial methyl group projecting from the α-face, whereas cholesterol has none. Our DSC studies indicate that the incorporation of lanosterol is more effective than cholesterol is in reducing the enthalpy of the pretransition. Lanosterol is also initially more effective than cholesterol in reducing the enthalpies of both the sharp and broad components of the main phase transition. However, at sterol concentrations of 50 mol %, lanosterol does not abolish the cooperative hydrocarbon chain-melting phase transition as does cholesterol. Moreover, at higher lanosterol concentrations (~30–50 mol %), both sharp and broad low-temperature endotherms appear in the DSC heating scans, suggestive of the formation of lanosterol crystallites, and of the lateral phase separation of lanosterol-enriched phospholipid domains, respectively, at low temperatures, whereas such behavior is not observed with cholesterol at comparable concentrations. Our Fourier transform infrared spectroscopic studies demonstrate that lanosterol incorporation produces a less tightly packed bilayer than does cholesterol, which is characterized by increased hydration in the glycerol backbone region of the DPPC bilayer. These and other results indicate that lanosterol is less miscible in DPPC bilayers than is cholesterol, but perturbs their organization to a greater extent, probably due primarily to the rougher faces and larger cross-sectional area of the lanosterol molecule and perhaps secondarily to its decreased ability to form hydrogen bonds with adjacent DPPC molecules. Nevertheless, lanosterol does appear to produce a lamellar liquid-ordered phase in DPPC bilayers, although this phase is not as tightly packed as comparable cholesterol/DPPC mixtures.     

Diffusion of cholesterol and its precursors in lipid membranes studied by 1H pulsed field gradient magic angle spinning NMR

Cholesterol content is critical for membrane functional properties. We studied the influence of cholesterol and its precursors desmosterol and lanosterol on lateral diffusion of phospholipids and sterols by1H pulsed field gradients (PFG) magic angle spinning (MAS) NMR spectroscopy. The high resolution of resonances afforded by MAS NMR permitted simultaneous diffusion measurements on 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and sterols. The cholesterol diffusion mirrored the DPPC behavior, but rates were slightly higher at all cholesterol concentrations. DPPC and cholesterol diffusion rates decreased and became cholesterol concentration dependent with the onset of liquid-ordered phase formation. The activation energies of diffusion in the coexistence region of liquid-ordered/liquid-disordered phases are higher by about a factor of 2 compared to pure DPPC and to the pure liquid-ordered state formed at higher cholesterol concentrations. We assume that the higher activation energies are a reflection of lipid diffusion across domain boundaries. In lanosterol- and desmosterol-containing membranes, the DPPC and sterol diffusion coefficients are somewhat higher. Whereas the desmosterol rates are only slightly higher than those of DPPC, the lanosterol diffusion rates significantly exceed DPPC rates, indicating a weaker interaction between DPPC and lanosterol.     

Sterol structure determines miscibility versus melting transitions in lipid vesicles

Lipid bilayer membranes composed of DOPC, DPPC, and a series of sterols demix into coexisting liquid phases below a miscibility transition temperature. We use fluorescence microscopy to directly observe phase transitions in vesicles of 1:1:1 DOPC/DPPC/sterol within giant unilamellar vesicles. We show that vesicles containing the "promoter" sterols cholesterol, ergosterol, 25-hydroxycholesterol, epicholesterol, or dihydrocholesterol demix into coexisting liquid phases as temperature is lowered through the miscibility transition. In contrast, vesicles containing the "inhibitor" sterols androstenolone, coprostanol, cholestenone, or cholestane form coexisting gel (solid) and liquid phases. Vesicles containing lanosterol, a sterol found in the cholesterol and ergosterol synthesis pathways, do not exhibit coexisting phases over a wide range of temperatures and compositions. Although more detailed phase diagrams and precise distinctions between gel and liquid phases are required to fully define the phase behavior of these sterols in vesicles, we find that our classifications of promoter and inhibitor sterols are consistent with previous designations based on fluorescence quenching and detergent resistance. We find no trend in the liquid-liquid or gel-liquid transition temperatures of membranes with promoter or inhibitor sterols and measure the surface fraction of coexisting phases. We find that the vesicle phase behavior is related to the structure of the sterols. Promoter sterols have flat, fused rings, a hydroxyl headgroup, an alkyl tail, and a small molecular area, which are all attributes of "membrane active" sterols.     

Effect of 26-oxygenosterols from Ganoderma lucidum and their activity as cholesterol synthesis inhibitors

Ganoderma lucidum is a medicinal fungus belonging to the Polyporaceae family which has long been known in Japan as Reishi and has been used extensively in traditional Chinese medicine. We report the isolation and identification of the 26-oxygenosterols ganoderol A, ganoderol B, ganoderal A, and ganoderic acid Y and their biological effects on cholesterol synthesis in a human hepatic cell line in vitro. We also investigated the site of inhibition in the cholesterol synthesis pathway. We found that these oxygenated sterols from G. lucidum inhibited cholesterol biosynthesis via conversion of acetate or mevalonate as a precursor of cholesterol. By incorporation of 24,25-dihydro-[24,25-3H2]lanosterol and [3-3H]lathosterol in the presence of ganoderol A, we determined that the point of inhibition of cholesterol synthesis is between lanosterol and lathosterol. These results demonstrate that the lanosterol 14alpha-demethylase, which converts 24,25-dihydrolanosterol to cholesterol, can be inhibited by the 26-oxygenosterols from G. lucidum. These 26-oxygenosterols could lead to novel therapeutic agents that lower blood cholesterol.     

Probing the dynamics of intact cells and nuclear envelope precursor membrane vesicles by deuterium solid state NMR spectroscopy

Membrane dynamics is an essential part of many cellular mechanisms such as intracellular trafficking, membrane fusion/fission and mitotic organelle reconstitution. The dynamics of membranes is dependent primarily on their phospholipid and cholesterol composition and how these molecules are ordered in relation to one another. To determine the physical status of membranes in whole cells or purified membranes of subcellular compartments we have developed a novel application exploiting solid-state (2)H-NMR spectroscopy. We utilise this method to probe the dynamics of intact sperm and nuclear envelope precursor membranes. We show, using mass spectrometry, that either multilamellar or small unilamellar vesicles of deuterium-labelled palmitoyl-oleoylphosphatidylcholine can be used to probe the dynamics of sperm cells or nuclear envelope precursor membrane vesicles, respectively. Using (2)H-NMR we determine the order parameters of sperm cells and nuclear envelope precursor membrane vesicles. We demonstrate that whole sperm membranes are more dynamic than nuclear envelope precursor membranes due to the higher cholesterol levels of the latter. Our new application can be exploited as a generic method for monitoring membrane dynamics in whole cells, various subcellular membrane compartments and membrane domains in subcellular compartments.     

Vesicle fluctuation analysis of the effects of sterols on membrane bending rigidity

Sterols are regulators of both biological function and structure. The role of cholesterol in promoting the structural and mechanical stability of membranes is widely recognized. Knowledge of how the related sterols, lanosterol and ergosterol, affect membrane mechanical properties is sparse. This paper presents a comprehensive comparison of the effects of cholesterol, lanosterol, and ergosterol upon the bending elastic properties of 1-palmitoyl-2-oleoyl- sn-glycero-3-phosphocholine giant unilamellar vesicles. Measurements are made using vesicle fluctuation analysis, a nonintrusive technique that we have recently improved for determining membrane bending rigidity. Giving a detailed account of the vesicle fluctuation analysis technique, we describe how the gravitational stabilization of the vesicles enhances image contrast, vesicle yield, and the quality of data. Implications of gravity on vesicle behaviour are also discussed. These recent modifications render vesicle fluctuation analysis an efficient and accurate method for determining how cholesterol, lanosterol, and ergosterol increase membrane bending rigidity.