Bovine gallbladder mucin promotes cholesterol crystal nucleation from cholesterol-transporting vesicles in supersaturated model bile

This study examined the ability of purified gallbladder mucin to accelerate the nucleation of cholesterol monohydrate crystals from the cholesterol-transporting particles in supersaturated model bile. Mixed lipid micelles and cholesterol-phosphatidylcholine vesicles in supersaturated model bile were separated by Sephadex G-200 column chromatography. Mixed lipid micelles prepared by column chromatography had a low cholesterol-phosphatidylcholine ratio (0.30) and did not spontaneously nucleate cholesterol monohydrate crystals. In contrast, vesicles prepared by column chromatography had a cholesterol-phosphatidylcholine ratio of 1.00 and nucleated cholesterol crystals rapidly (P less than 0.001). Nucleation of cholesterol crystals was significantly accelerated in a concentration- and time-dependent manner by purified bovine gallbladder mucin in cholesterol containing vesicles, but not in mixed lipid micelles (P less than 0.001). A rapid filtration binding assay demonstrated significant binding of cholesterol and phosphatidylcholine in vesicles to gallbladder mucin but only minimal binding of cholesterol and phosphatidylcholine in mixed micelles. These data indicate that gallbladder mucin binds cholesterol and phosphatidylcholine in vesicles and accelerates the nucleation of cholesterol monohydrate crystals from these cholesterol-transporting particles in supersaturated model bile.     

Biliary cholesterol crystallization characterized by single-crystal cryogenic electron diffraction

Cholesterol crystals are the building blocks of cholesterol gallstones. The exact structure of early-forming crystals is still controversial. We combined cryogenic-temperature transmission electron microscopy with cryogenic-temperature electron diffraction to sequentially study crystal development and structure in nucleating model and native gallbladder biles. The growth and long-term stability of classic cholesterol monohydrate (ChM) crystals in native and model biles was determined. In solutions of model bile with low phospholipid-to-cholesterol ratio, electron diffraction provided direct proof of a novel transient polymorph that had an elongated habit and unit cell parameters differing from those of classic triclinic ChM. This crystal is exactly the monoclinic ChM phase described by Solomonov and coworkers (Biophysical J., In press) in cholesterol monolayers compressed on the air-water interface. We observed no evidence of anhydrous cholesterol crystallization in any of the biles studied. In conclusion, classic ChM is the predominant and stable form in native and model biles. However, under certain (low phospholipid) conditions, transient intermediate polymorphs may form. These findings, documenting single-crystal analysis in bulk solution, provide an experimental approach to investigating factors influencing biliary cholesterol crystal nucleation and growth as well as other processes of nucleation and crystallization in liquid systems.     

Nucleation of cholesterol crystals from native bile and the effect of protein hydrolysis

Nucleation time represents the terminal step in in vitro studies examining bile lithogenicity. Because of the concern that residual microcrystals, left after ultracentrifugation, may be responsible for the rapid nucleation time of gallbladder bile from patients with cholesterol gallstones, we have included a final filtration step. However, we found this procedure to considerably lengthen the nucleation time of abnormal biles. In view of the central importance of the nucleation assay we compared the effect of three commonly used gallbladder bile pre-treatment regimes (designed to remove endogenous crystals) on nucleation time. They were: a) immediate filtration of bile (0.22 micron filter); b) ultracentrifugation; and c) ultracentrifugation followed by filtration. The respective nucleation times were: a) 9.3 +/- 3.7 days, n = 6; b) 2.9 +/- 0.4 days, n = 10; c) 12.8 +/- 2.3 days, n = 11. To determine whether the dramatic change in nucleation time was due to the removal of components other than seed crystals, we examined the mucus content, the total lipid composition of bile, and that of its cholesterol transport components following the different pre-treatments. No significant difference in total lipid, percentage cholesterol carried by the transport components, or their cholesterol/phospholipid ratio were found. Ultracentrifugation alone was sufficient to removal all detectable large molecular weight mucus glycoprotein. Although nucleation time of the abnormal gallbladder samples was extended in the ultracentrifuged/filtered biles, it was still significantly different (P less than 0.01) from that of normal gallbladder biles, confirming an intrinsic difference between abnormal and normal biles, in cholesterol metastability. We also examined the effect of protein digestion on the nucleation time of native biles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vesicular cholesterol in bile. Relationship to protein concentration and nucleation time

A study was done to determine whether the nucleation time was related to the amount of cholesterol carried in vesicles. Bile was obtained from cholesterol gallstone patients and controls. Gel-exclusion chromatography was used to separate vesicles and micelles in the native bile using an eluting buffer containing 10 mM sodium cholate. The percent of total cholesterol carried in vesicles in gallbladder bile of stone patients was significantly greater than that in control patients. Total cholesterol concentration in gallbladder bile of stone patients was significantly greater than in controls. This difference was due to the fact that vesicular cholesterol concentration was significantly greater in the gallbladder bile of stone patients compared to controls. Micellar cholesterol concentrations were similar in the two groups. Nucleation time was related significantly to vesicular cholesterol concentration in correlation analysis and, as previously shown, so was total protein concentration. This study supports the importance of vesicular cholesterol in solid crystal formation and demonstrates for the first time that the rate of cholesterol monohydrate crystal formation is directly related to the amount of cholesterol transported in vesicles.     

Effect of gallbladder hypomotility on cholesterol crystallization and growth in CCK-deficient mice

We investigated the effect of gallbladder hypomotility on cholesterol crystallization and growth during the early stage of gallstone formation in CCK knockout mice. Contrary to wild-type mice, fasting gallbladder volumes were enlarged and the response of gallbladder emptying to a high-fat meal was impaired in knockout mice on chow or the lithogenic diet. In the lithogenic state, large amounts of mucin gel and liquid crystals as well as arc-like and tubular crystals formed first, followed by rapid formation of classic parallelogram-shaped cholesterol monohydrate crystals in knockout mice. Furthermore, three patterns of crystal growth habits were observed: proportional enlargement, spiral dislocation growth, and twin crystal growth, all enlarging solid cholesterol crystals. At day 15 on the lithogenic diet, 75% of knockout mice formed gallstones. However, wild-type mice formed very little mucin gel, liquid, and solid crystals, and gallstones were not observed. We conclude that lack of CCK induces gallbladder hypomotility that prolongs the residence time of excess cholesterol in the gallbladder, leading to rapid crystallization and precipitation of solid cholesterol crystals. Moreover, during the early stage of gallstone formation, there are two pathways of liquid and polymorph anhydrous crystals evolving to monohydrate crystals and three modes for cholesterol crystal growth.     

Factors affecting cholesterol monohydrate crystal nucleation time in model systems of supersaturated bile

We explored the influence of several compositional factors considered capable of influencing the nucleation time of model biles supersaturated in cholesterol. In addition to the classical techniques, e.g., electron microscopy and quasielastic light scattering, employed for size measurement and structural assessment, we employed a novel technique, i.e., video-enhanced microscopy, for particle evaluation in these polydisperse systems which often may simultaneously contain isolated small vesicles, their complex aggregates, and small cholesterol monohydrate crystals. The factors we studied included dilution, degree of cholesterol supersaturation, bile salt/lecithin molar ratio, and Ca2+ concentration. Dilution markedly raised the degree of cholesterol saturation, prolonged nucleation time for cholesterol monohydrate crystals, and favored formation of metastable small unilamellar vesicles. Increasing the degree of cholesterol supersaturation as an independent variable in more concentrated systems both shortened the nucleation time and favored spontaneous formation of a relatively small number of isolated vesicles. A decrease in bile salt/lecithin molar ratio within the physiologically relevant range was accompanied by a prolonged nucleation time and favored spontaneous vesicle formation. Large numbers of small unilamellar vesicles were observed even in concentrated model bile solutions (total lipids: 20 g/dl) when the bile salt/lecithin molar ratio was 1.9 or less. At physiological concentrations, Ca2+ promoted nucleation of cholesterol monohydrate crystals only in vesicle-containing solutions. Taken together, the following conclusions can be drawn. First, spontaneous vesicle formation in dilute systems prolongs solid cholesterol crystal nucleation. It can thus provide a supplementary non-micellar mode of cholesterol transport in micellar systems of supersaturated human bile. Second, dilution, degree of cholesterol supersaturation, and a decrease in bile salt/lecithin ratio prolong cholesterol crystal nucleation time and favor spontaneous vesicle formation. With increasing calcium concentrations, opposite effects are observed. Third, the presence of vesicles may help to account for the frequently observed and otherwise unexplained remarkable degree of metastable supersaturation and prolonged metastability (delayed nucleation time) for cholesterol in human bile.     

Targeted disruption of the murine mucin gene 1 decreases susceptibility to cholesterol gallstone formation

Gallbladder mucins play a critical role in the pathogenesis of cholesterol gallstones because of their ability to bind biliary lipids and accelerate cholesterol crystallization. Mucin secretion and accumulation in the gallbladder is determined by multiple mucin genes. To study whether mucin gene 1 (Muc1) influences susceptibility to cholesterol cholelithiasis, we investigated male Muc1-deficient (Muc1(-/-)) and wild-type mice fed a lithogenic diet containing 1% cholesterol and 0.5% cholic acid for 56 days. Gene expression of the gallbladder Muc1 and Muc5ac was significantly reduced in Muc1(-/-) mice in response to the lithogenic diet. Muc3 and Muc4 levels were upregulated and were similar between Muc1(-/-) and wild-type mice. Little or no Muc2 and Muc5b mRNAs were detected. Muc1(-/-) mice displayed significant decreases in total mucin secretion and accumulation in the gallbladder as well as retardation of crystallization, growth, and agglomeration of cholesterol monohydrate crystals. At 56 days of feeding, gallstone prevalence was decreased by 40% in Muc1(-/-) mice. However, cholesterol saturation indices of gallbladder bile, hepatic secretion of biliary lipids, and gallbladder size were comparable in Muc1(-/-) and wild-type mice. We conclude that decreased gallstone formation in mice with disrupted Muc1 gene results from reduced mucin secretion and accumulation in the gallbladder.     

Microstructural analysis of bile: relevance to cholesterol gallstone pathogenesis

The study of physical-chemical factors and pathways leading to cholesterol crystallization in bile has important clinical relevance. The major processes in cholesterol gallstone formation can be subdivided into nucleation, formation and precipitation of solid crystals (crystallization), crystal growth, crystal agglomeration and stone growth. A clear understanding of the microstructural events occurring during the earliest stages of these processes in bile is crucial for the identification of factors possibly delaying or preventing precipitation of cholesterol crystals and, therefore, gallstone formation in bile. Detection and characterization of microstructures in native and model biles can be achieved by both direct and indirect techniques. Direct imaging techniques provide more readily interpretable information, but sample preparation problems, particularly for electron microscopy, are a source of artifacts. Moreover, microscopic techniques provide only qualitative data without the possibility to quantitate or to analyse the composition of microstructures. Several indirect techniques have been used to obtain additional microstructural information about nucleating bile. These techniques have the disadvantage of often being model dependent in addition to constraints specific for each method. The systematic, judicious use of a combination of complementary direct and indirect techniques have led to a comprehensive understanding of the various microstructural processes and interactions occurring during bile secretion, flow in the biliary tract and storage in the gallbladder. This forms the basis for our current understanding of cholesterol nucleation, crystallization and gallstone formation.     

Gastric mucin hydrophobicity: effects of associated and covalently bound lipids, proteolysis, and reduction

The hydrophobic properties of gastric mucus glycoprotein were investigated using the fluorescent probe, bis(8-anilino-1-naphthalenesulfonate). The glycoprotein was subjected to removal of associated and covalently bound lipids, peptic degradation, and disulfide bridge reduction. Fluorescence titration data revealed the presence of 55 hydrophobic binding sites in the intact mucin molecule, 71 binding sites in the glycoprotein devoid of associated lipids, and 53 binding sites in the glycoprotein devoid of associated lipids and covalently bound fatty acids. Proteolytic digestion of the glycoprotein with pepsin essentially abolished the probe binding, while reduction of disulfide bridges resulted in glycoprotein subunits whose combined number of binding sites was about 3 times greater than that of the mucin polymer. The binding of the probe to mucus glycoprotein varied with the pH of the medium, being highest at pH 2.0 and lowest at pH 9.0. The results indicate that lipids contribute to the hydrophobic character of gastric mucin and that hydrophobic binding sites reside on the nonglycosylated regions of the glycoprotein polymer buried within its core.     

Interaction of mucin with cholesterol enriched vesicles: role of mucin structural domains

We utilized fluorescence recovery after photobleaching (FRAP) and fluorescence correlation spectroscopy (FCS) to examine the role of gallbladder mucin (GBM) in promoting the aggregation and/or fusion of cholesterol enriched vesicles. By fluorescent labeling either the vesicle or the mucin, we could examine the change in vesicle size as well as changes in mucin's diffusion constant. Both FRAP and FCS show that GBM has a profound effect in inducing vesicles to aggregate/fuse, particularly after overnight incubation. GBM mucin domains (either protease digested or reduced GBM) are not as effective as native GBM. Intact GBM alone was able to shorten crystal appearance time and increase the number of crystals nucleated by polarized optical microscopy. In summary, our findings would suggest that both glycosylated and nonglycosylated domains of GBM are involved in early aggregation of cholesterol enriched vesicles but that this effect is reversible in the absence of nonglycosylated domains.     

Identification of a phosphatidylcholine active phospholipase C in human gallbladder bile

This study describes the identification of a phospholipase C activity against phosphatidylcholine in delipidated human gallbladder bile. All biles were obtained from cholesterol gallstone patients and were negative on bacterial culture. The biliary enzyme was inhibited by EDTA and had a pH optimum of between 7-8. All of the 15 gallbladders examined contained significant phospholipase C activity (32.85 +/- 8.37 nmol/h/mg delipidated protein). The finding of a phospholipase C in gallbladder bile of patients with cholesterol gallstones may be one of the factors responsible for or related to the rapid in vitro nucleation seen in these biles.     

Comparative analysis of cholesterol transport in bile from patients with and without cholesterol gallstones

Aggregation of cholesterol-phospholipid vesicles in supersaturated biles precedes cholesterol crystal formation. In this study we examined the relationship between the percentage of cholesterol carried by vesicles and/or their composition and the propensity to form cholesterol crystals (nucleation time). Bile (common bile duct, gallbladder and T-tube) was obtained from patients with and without gallstones. Gel filtration chromatography resolved three peaks, a void volume vesicle, a smaller vesicle (identified by electron microscopy and of distinct composition compared to the larger void volume vesicle), and the mixed micelle. The void volume vesicle was present in 11 of 28 abnormal gallbladder biles, but in none of the 10 normal gallbladder biles. Despite this difference, no correlation between the nucleation time of whole bile with either the percentage of cholesterol carried by or cholesterol/phospholipid ratio of the void volume vesicle was found. Nucleation time was, however, found to correlate with the composition of the small-vesicular transport form. No significant difference in the composition or percentage of the small-vesicular form or the combined vesicular forms was found between normal and abnormal gallbladder biles, although the latter nucleated significantly more rapidly. Our results confirm the importance of vesicles in the nucleation process but suggest that other factors, not yet identified, appear to be responsible for the more rapid nucleation seen in abnormal gallbladder biles.     

Gender Differences in Cholesterol Nucleation in Native Bile: Estrogen Is a Potential Contributory Factor

The incidence of gallstone disease is two to three times higher in women than in men, and female sex hormones, particularly estrogens, have been implicated as contributory factors. Cholesterol nucleation is the initial step in gallstone pathogenesis and proceeds from cholesterol-rich phospholipid vesicles. The aim of this study was to investigate if there is a difference in cholesterol nucleation rates in male and female bile and whether estrogen influences nucleation rates by interacting with cholesterol-rich regions known as “lipid rafts” that exist within the cholesterol-phospholipid vesicles of the bile. Cholesterol nucleation from native prairie dog bile and the interaction of estrogens with lipid rafts in model bile solutions were investigated using Förster resonance energy transfer (FRET). Female native bile samples showed a greater reduction in energy transfer than did male native bile, indicating that cholesterol nucleation occurred more readily in female bile than in male bile. Model bile experiments demonstrated that the addition of estrogen has a significant effect, either cholesterol nucleation or raft disruption, but only in samples containing cholesterol-rich rafts. These results suggest that estrogen interacts with cholesterol-rich rafts in vesicles within bile to promote cholesterol nucleation and predispose females to gallstone formation.     

No pathophysiologic relationship of soluble biliary proteins to cholesterol crystallization in human bile

This study explores the pathophysiologic effects of soluble biliary glycoproteins in comparison to mucin gel and cholesterol content on microscopic crystal and liquid crystal detection times as well as crystallization sequences in lithogenic human biles incubated at 37 degrees C. Gallbladder biles from 13 cholesterol gallstone patients were ultracentrifuged and microfiltered (samples I). Total biliary lipids were extracted from portions of samples I, and reconstituted with 0.15 m NaCl (pH 7.0) (samples II). Portions of samples II were supplemented with purified concanavalin A-binding biliary glycoproteins (final concentration = 1 mg/mL) (samples III), or mucin gel (samples IV), respectively, isolated from the same cholesterol gallstone biles. Samples V consisted of extracted biliary lipids from uncentrifuged and unfiltered bile samples reconstituted with 0.15 m NaCl (pH 7.0). Analytic lipid compositions of samples I through IV were identical for individual biles but, as anticipated, samples V displayed significantly higher cholesterol saturation indexes. Detection times of cholesterol crystals and liquid crystals were accelerated in the rank order of samples: IV > V > I = II = III, indicating that total soluble biliary glycoproteins in pathophysiologic concentration had no appreciable effect. Crystallization sequences (D. Q-H. Wang and M. C. Carey. J. Lipid Res. 1996. 37: 606-630; and 2539-2549) were similar among samples I through V. Crystal detection times and numbers of solid cholesterol crystals were accelerated in proportion to added mucin gel and the cholesterol saturation of bile only.For pathophysiologically relevant conditions, our results clarify that mucin gel and cholesterol content, but not soluble biliary glycoproteins, promote cholesterol crystallization in human gallbladder bile.     

Phospholipid peroxidation as a factor in gallstone pathogenesis

Phospholipid peroxidation markedly reduces the stability of mixed micellar systems composed of cholate, phosphatidylcholine and supersaturating levels of cholesterol. This suggests that lipid peroxidation is likely to play a significant role in the precipitation of cholesterol from gallbladder bile, thus in the pathogenesis of cholesterol gallstones. This conclusion is supported by studies of the nucleation time of cholesterol in gallbladder biles, which was significantly reduced by exposure to a stream of oxygen. This effect of phospholipid peroxidation on cholesterol solubility may occur in other biological fluids as well. In view of the increased lipid peroxidation in the elderly, it may explain the effect of age on the frequency of various diseases related to cholesterol precipitation.     

Cholesterol crystal formation and growth in model bile solutions

Cholesterol monohydrate crystal formation was studied in supersaturated model bile solutions, containing unlabeled cholesterol, sodium cholate and soybean phosphatidylcholine, and tracer amounts of [3H]cholesterol. Solutions were either seeded with cholesterol crystals to initiate growth, or not seeded to allow self-nucleation and subsequent crystal growth to occur. Crystal growth at 37 degrees C was measured by two methods. First, radioactive cholesterol crystals were isolated by filtration, and the mass of cholesterol that had precipitated was calculated. In unseeded solutions, there was a long lag period before crystal growth was detected. This lag time was decreased by increases in the cholesterol concentration, temperature, and lipid concentration. In seeded solutions, crystal growth also was dependent on the cholesterol concentration, temperature, and lipid concentration. The second method used to measure crystal growth involved the Coulter Counter. At 37 degrees C, reproducible results were not obtained using unseeded solutions due to blocking of the counter aperture with large crystals. In seeded solutions, crystal growth could be measured as an increase in total particle volume. However, comparison of growth rate estimates from the Coulter Counter with those obtained radiochemically revealed poor agreement between the two methods. It is probable that the Coulter Counter is inaccurate in measuring the volume of cholesterol monohydrate crystals due to their anisometric shape.     

The induction of lamellar stacking by cholesterol in lecithin-bile salt model systems and human bile studied by synchrotron X-radiation

Small angle X-ray scattering (SAXS) with synchroton radiation was used to investigate interactions among lipid particles in lecithin-bile salt model systems and in native gallbladder biles. In model systems in the absence of cholesterol, isotropic, continuous spectra were found, indicating the absence of periodic structures. In the presence of excess cholesterol, interaction in the form of lamellar stacking was detected by the appearance of discrete diffraction peaks. In the supersaturated cholesterol region of the commonly accepted phase diagram [1], where cholesterol crystals were expected, we found lamellar stacking. The high proportion of cholesterol to bile salts seems to be the common denominator of these models. The lamellar stacking was also found in native unprocessed bile. This effect of cholesterol on lipid structure has not been previously described. Lamellar stacking may contribute to cholesterol solubilization. Its influence on the kinetics of cholesterol crystallization is presently unknown.     

Estrogen induces two distinct cholesterol crystallization pathways by activating ERα and GPR30 in female mice

To distinguish the lithogenic effect of the classical estrogen receptor α (ERα) from that of the G protein-coupled receptor 30 (GPR30), a new estrogen receptor, on estrogen-induced gallstones, we investigated the entire spectrum of cholesterol crystallization pathways and sequences during the early stage of gallstone formation in gallbladder bile of ovariectomized female wild-type, GPR30(^−/−), ERα(^−/−), and GPR30(^−/−)/ERα(^−/−) mice treated with 17β-estradiol (E₂) at 6 µg/day and fed a lithogenic diet for 12 days. E₂ disrupted biliary cholesterol and bile salt metabolism through ERα and GPR30, leading to supersaturated bile and predisposing to the precipitation of cholesterol monohydrate crystals. In GPR30(^−/−) mice, arc-like and tubular crystals formed first, followed by classical parallelogram-shaped cholesterol monohydrate crystals. In ERα(^−/−) mice, precipitation of lamellar liquid crystals, typified by birefringent multilamellar vesicles, appeared earlier than cholesterol monohydrate crystals. Both crystallization pathways were accelerated in wild-type mice with the activation of GPR30 and ERα by E₂. However, cholesterol crystallization was drastically retarded in GPR30(^−/−)/ERα(^−/−) mice. We concluded that E₂ activates GPR30 and ERα to produce liquid crystalline versus anhydrous crystalline metastable intermediates evolving to cholesterol monohydrate crystals from supersaturated bile. GPR30 produces a synergistic lithogenic action with ERα to enhance E₂-induced gallstone formation.     

Vesicle aggregation in model systems of supersaturated bile: relation to crystal nucleation and lipid composition of the vesicular phase

The presence of small vesicles composed of phospholipid and cholesterol has recently been demonstrated in super-saturated model and in dilute native human biles by several groups using differing methods. Among compositional factors shown to favor spontaneous vesicle formation and prolong the cholesterol monohydrate nucleation time in model bile systems are dilution, a raised cholesterol saturation index (CSI), and a low bile salt/phospholipid ratio. Time-lapse video-enhanced microscopy of a series of model bile systems representing systematically designed variations in the above factors revealed strong evidence for an essential linkage between antecedent vesicle aggregation and subsequent crystal nucleation. Stability of vesicles was inversely related to their degree of cholesterol saturation, i.e., the greater the degree of vesicular cholesterol saturation, the less their stability (metastability). Instability of vesicles was reflected by their early aggregation followed by rapid cholesterol crystal nucleation. The lowest degree of vesicular cholesterol saturation was found in dilute systems which also exhibited the greatest metastability despite a high degree of cholesterol solubility (raised CSI). Conversely, the more concentrated and least metastable systems exhibited both rapid vesicle aggregation and rapid onset of crystal nucleation. These systems, while influenced by the other compositional factors, were found to have a high degree of vesicular cholesterol saturation, i.e., cholesterol/phospholipid molar ratio = 2.0. An additional finding was the extreme variability in the proportionate distribution of total solution cholesterol distributed to the vesicular phase, i.e., from zero to as high as 37%. Higher solute concentration, raised bile salt/lecithin ratio, and raised CSI were interactive and almost equally capable of increasing the proportionate amount of cholesterol in the vesicular phase. In conclusion, lipid compositional differences in model bile systems drastically affect the cholesterol saturation of spontaneously formed phospholipid-cholesterol vesicles. This effect, in turn, exerts a potent influence upon the metastability of vesicles, subsequently affecting the cholesterol crystal nucleation time.     

Non-raft forming sphingomyelin-cholesterol mixtures

Sphingomyelin from biological membranes forms segregated domains with cholesterol in fluid bilayers. However, a synthetic form of sphingomyelin with an oleoyl chain linked to sphingosine is not incorporated into cholesterol-rich domains. We have studied the properties of mixtures of oleoyl-sphingomyelin and cholesterol as well as mixtures of oleoyl-sphingomyelin with 1-stearoyl-2-oleoyl-phosphatidylcholine by DSC and NMR. Cholesterol has a high miscibility with oleoyl-sphingomyelin and it does not separate in crystalline form until the mol fraction of cholesterol reaches a value above 0.6. A large fraction of the cholesterol crystals that are formed are in the monohydrate form. Furthermore, these crystals rehydrate relatively rapidly compared with pure cholesterol crystals in the absence of phospholipid. The environment of the carbonyl group of the phospholipid indicates that it is similar to other forms of sphingomyelin with saturated acyl chains. Also similar to other forms of sphingomyelin, the quaternary ammonium group of oleoyl-sphingomyelin is more rigid than that of phosphatidylcholines, as indicated by the strong resonance observed with cross-polarization/magic angle spinning. Additionally, oleoyl-sphingomyelin produces a larger alteration than egg sphingomyelin of the phase transition of 1-stearoyl-2-oleoyl-phosphatidylcholine. These studies indicate that oleoyl-sphingomyelin, unlike saturated forms of sphingomyelin, does not form segregated domains with cholesterol because of its greater miscibility with phosphatidylcholine.