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.     

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.     

Contribution of vesicular and micellar carriers to cholesterol transport in human bile

A nonmicellar, bile salt-independent mode of cholesterol transport in human bile involving phospholipid vesicles was recently reported by our group. In the present study, we have investigated the relative contribution of the phospholipid vesicles and mixed bile salt-phospholipid micelles to cholesterol transport in human hepatic and gallbladder biles. The vesicles (ca 800 A diameter) were demonstrated by quasi-elastic light scattering (QELS) in fresh bile and after chromatography. Gel filtration under conditions that preserved micellar integrity demonstrated that biliary cholesterol was associated with both vesicles and micelles. At low bile salt concentration, the vesicular phase was predominant and most of the cholesterol was transported by it. With increasing bile salt concentrations, a progressive solubilization of the vesicles occurred with a concomitant increase in the amount of cholesterol transported by micelles. The vesicular carrier may be of particular biological significance for cholesterol solubilization in supersaturated biles.     

Inhibition of cholesterol crystallization under bilirubin deconjugation: partial characterization of mechanisms whereby infected bile accelerates pigment stone formation

Pigment gallstones have been reported to be closely associated with biliary tract infection. We previously reported that addition of unconjugated bilirubin (UCB), which is deconjugated by beta-glucuronidase in infected bile, could enhance cholesterol crystal formation in supersaturated model bile (MB). The present study evaluated the effect of beta-glucuronidase on the processes of pigment gallstone formation and cholesterol crystallization. Supersaturated MB (taurocholate/lecithin/cholesterol at 71:18:11, a total lipid concentration of 10.0 g/dl and a cholesterol saturation index (CSI) of 2.0) and native rat bile were mixed at a ratio of 3:1. Then, mixed bile was incubated with or without beta-glucuronidase and changes of the following parameters were investigated over time: (1) the UCB/total bilirubin ratio; (2) cholesterol crystal formation; (3) the precipitate weight and the cholesterol concentration in the precipitate and supernatant; and (4) the lipid distribution of vesicles in the supernatant. Compared with beta-glucuronidase-free bile, (1) beta-glucuronidase-containing bile showed a significant increase of the UCB/total bilirubin ratio, (2) as well as a significantly longer nucleation time (96+/-17.0 vs. 114+/-20.0) and fewer cholesterol crystals. (3) The precipitate weight and the cholesterol concentration in the precipitate were significantly increased, while the cholesterol concentration in supernatant was decreased. (4) When mixed bile was incubated with beta-glucuronidase, the cholesterol concentration in the vesicles was lower than in bile without beta-glucuronidase. The precipitate weight and the cholesterol concentration in the precipitate was increased by incubation with beta-glucuronidase, while cholesterol concentration was decreased in the supernatant (especially in the vesicles). This means that bile vesicles were more stable and it was more difficult for cholesterol crystals to form. Thus, the presence of beta-glucuronidase may inhibit the formation of pure cholesterol stones even in the presence of cholesterol supersaturation.     

Fibronectin: a possible factor promoting cholesterol monohydrate crystallization in bile

To examine the hypothesis that fibronectin physiologically present in bile might be a possible nucleating factor, the concentrations of fibronectin in gallbladder bile were determined and its induced effect on nucleation time and on the form of vesicle were examined in bile-model and human gallbladder bile. The gallbladder bile samples taken from patients with cholesterol gallstone had a significantly higher concentration of fibronectin and the faster nucleation time than the control. However, no significant correlation was found between nucleation time and endogenous fibronectin concentration. The addition of 0.5, 1.2, 10 micrograms/ml of fibronectin into two kinds of bile-model significantly shortened the nucleation time in a dose-related manner. Nucleation time was significantly shortened by the addition of 1 microgram/ml exogenous fibronectin into abnormal bile while such an effect was absent in the control. The addition of fibronectin increased the size of vesicles observed by the electron microscope. The results suggest that fibronectin physiologically present in bile may be one of the possible nucleating factors.     

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.     

Effect of cholesterol nucleation-promoting activity on cholesterol solubilization in model bile

Human bile contains a factor with cholesterol nucleation-promoting activity that binds to concanavalin A-Sepharose. In this study we have investigated the effect of this activity on the dynamics of lipid solubilization in supersaturated model bile. A concanavalin A binding protein fraction of human bile was mixed with model bile and the effect on the distribution of cholesterol and phospholipid between mixed micelles and phospholipid/cholesterol vesicles was studied by means of density gradient ultracentrifugation. The nucleation-promoting activity containing fraction induced a transfer of cholesterol and phospholipid from the micellar to the vesicular phase. This led to a decrease in the density of the vesicular fraction. We have also studied the effect of promoting activity on the nucleation time of an isolated vesicle fraction. A decrease of the nucleation time of 10.7 +/- 1.3 to 2.3 +/- 0.3 days was observed. In conclusion, a concanavalin A binding protein fraction from human bile stimulated cholesterol nucleation via a double effect; it increased the amount of vesicular cholesterol and phospholipid, and it also directly induced nucleation of cholesterol from the vesicles.     

Biliary proteins: assessment of quantitative techniques and comparison in gallstone and nongallstone subjects

Although protein is the third most abundant solid in bile and is important in cholesterol crystal formation, methods for quantitating the concentration of total protein in bile have not been systematically evaluated. To establish a reliable protein assay for bile, we evaluated three protein assays (Lowry's method and the fluorescamine and Coomassie blue methods), and employed amino acid analysis as a reference technique. Large protein-to-protein variations were observed with the fluorescamine and Coomassie blue methods. Although all assays were affected by interfering substances, Lowry's method and the fluorescamine technique (after trichloroacetic acid precipitation and delipidation of bile) and the Coomassie blue method with native bile showed excellent correlations (P less than 0.0001) with those obtained by amino acid analysis. Using these reliable protein assays, we examined gallbladder bile obtained at surgery from subjects with and without gallstones. No differences in the concentrations of total biliary proteins were observed among patients with cholesterol (n = 23) or pigment (n = 7) gallstones and subjects without gallstones (n = 10). Protein values obtained by amino acid analysis also did not differ among groups. As expected, bile from patients with cholesterol gallstones was supersaturated with cholesterol while bile from nongallstone subjects and those with pigment stones was unsaturated. These results indicate that it is not possible to separate patients with and without gallstones on the basis of the total protein concentration of gallbladder bile.     

Human gallbladder mucin binds biliary lipids and promotes cholesterol crystal nucleation in model bile

The binding of phosphatidylcholine and cholesterol in model bile to human gallbladder mucin was studied by means of a rapid filtration binding assay and sucrose density gradient ultracentrifugation. Numerous low affinity binding sites for phosphatidylcholine and cholesterol were present on gallbladder mucin. Binding of phosphatidylcholine and cholesterol to mucin increased as a function of cholesterol saturation index. Proteolytic digestion of mucin disaggregated the native mucin polymer and removed hydrophobic domains on the mucin peptide core that bind l-anilino-8-naphthalenesulfonic acid. Proteolytic digestion also resulted in a 91% and 78% decrease, respectively, in the binding of phosphatidylcholine and cholesterol to mucin. The ability of trypsin-treated and native mucin to promote the nucleation of cholesterol monohydrate crystals was compared in a model bile. The incidence of cholesterol monohydrate crystal nucleation with native mucin was significantly greater at 3 days than with trypsin-treated mucin or controls (P less than 0.001). After 3, 6, and 9 days of incubation, samples containing native mucin contained significantly more crystals than controls or trypsin-digested mucin samples (P less than 0.0001 for each). These data indicate that highly purified human gallbladder mucin binds phosphatidylcholine and cholesterol in model bile. Furthermore, this study demonstrates that structural integrity of the native mucin polymer and hydrophobic domains on the peptide core are essential for the nucleation of cholesterol monohydrate crystals by mucin in model bile.     

Use of 1H-NMR to determine the distribution of lecithin between the micellar and vesicular phases in model bile

Biliary cholesterol/phospholipid vesicles play an important role in the pathogenesis of gallstone disease. A prerequisite for the study of the lipid composition and stability of these vesicles is a reliable method to quantify the amount of vesicular lipid. In the present report we show that NMR can be used to determine the distribution of biliary lecithin between the micellar and vesicular phases. The relatively large size of the vesicles leads to such a broadening of the lipid resonances that they are no longer visible in high resolution 1H-NMR spectra. Since micelles are much smaller, lipid present in the micellar phase does give rise to sharp peaks in 1H-NMR spectra. Micellar lecithin can easily be quantified in these spectra. The resonances of cholesterol are masked by the closely related bile acid that is present in a much higher concentration. By determining the difference between chemically and NMR estimated lecithin, the distribution of this phospholipid between the micellar phase and vesicular phase can be assessed. We have compared the results of NMR with gel permeation and density gradient ultracentrifugation. Using standard fractionation conditions, both gel permeation and density gradient ultracentrifugation lead to an underestimation of vesicular lecithin, the difference being minor at relatively high total lipid concentrations (10 g/dl) but large in diluted model bile. We conclude that 1H-NMR can be used to determine the distribution of lecithin in model bile.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stability of mixed micellar bile models supersaturated with cholesterol.

The maximal equilibrium solubility of cholesterol in mixtures of phosphatidylcholine (PC)1 and bile salts depends on the cholesterol/PC ratio (Rc) and on the effective ratio (Re) between nonmonomeric bile salts and the sum (CT) of PC and cholesterol concentrations (Carey and Small, 1978; Lichtenberg et al., 1984). By contrast, the concentration of bile salts required for solubilization of liposomes made of PC and cholesterol does not depend on Rc (Lichtenberg et al., 1984 and 1988). Thus, for Rc greater than 0.4, solubilization of the PC-cholesterol liposomes yields PC-cholesterol-bile salts mixed micellar systems which are supersaturated with cholesterol. In these metastable systems, the mixed micelles spontaneously undergo partial revesiculation followed by crystallization of cholesterol. The rate of the latter processes depends upon Rc, Re, and CT. For any given Rc and Re, the rate of revesiculation increases dramatically with increasing the lipid concentration CT, reflecting the involvement of many mixed micelles in the formation of each vesicle. The rate also increases, for any given CT and Re, upon increasing the cholesterol to PC ratio, Rc, probably due to the increasing degree of supersaturation. Increasing the cholate to lipid effective ratio, Re, by elevation of cholate concentration at constant Rc and CT has a complex effect on the rate of the revesiculation process. As expected, cholate concentration higher than that required for complete solubilization at equilibrium yields stable mixed micellar systems which do not undergo revesiculation, but for lower cholate concentrations decreasing the degree of supersaturation (by increasing [cholate]) results in faster revesiculation. We interpret these results in terms of the structure of the mixed micelles; micelles with two or more PC molecules per one molecule of cholesterol are relatively stable but increasing the bile salt concentration may cause dissociation of such 1:2 cholesterol:PC complexes, hence reducing the stability of the mixed micellar dispersions. The instability of PC-cholesterol-cholate mixed systems with intermediary range of cholate to lipids ratio may be significant to gallbladder stone formation as: (a) biliary bile contains PC-cholesterol vesicles which may be, at least partially, solubilized by bile salts during the process of bile concentration in the gallbladder, resulting in mixtures similar to our model systems; and (b) the bile composition of cholesterol gallstone patients is within an intermediary range of bile salts to lipids ratio.     

Effect of dietary fenugreek seeds on biliary proteins that influence nucleation of cholesterol crystals in bile

Formation of cholesterol gallstones in gallbladder is controlled by procrystallising and anticrystallising factors present in bile. Dietary fenugreek seed has been recently observed to possess anti-lithogenic potential in experimental mice. In the current animal study, we evaluated the effect of dietary fenugreek on the compositional changes in the bile, particularly its effect on glycoproteins, low-molecular-weight (LMW) and high-molecular-weight (HMW) proteins, cholesterol nucleation time and cholesterol crystal growth. Groups of Wistar rats were fed for 10 weeks with diets: (1) basal control (C), (2) C + fenugreek (12%), (3) high cholesterol diet (HCD) and (4) HCD + fenugreek (12%). Feeding of HCD containing 0.5% cholesterol for 10 weeks rendered the bile lithogenic. Incorporation of fenugreek into HCD decreased the cholesterol content (70.5%), total protein (58.3%), glycoprotein (27.5%), lipid peroxides (13.6%) and cholesterol saturation index (from 1.98 to 0.75) in bile, increased the bile flow rate (19.5%), prolonged the cholesterol nucleation time and reduced the vesicular form of cholesterol (65%), which was accompanied with an increase in smaller vesicular form (94%). There was an increase in biliary phospholipid (33%) and total bile acid (49%) contents in the HCD + fenugreek group as compared with the HCD group. Electrophoretic separation of biliary LMW proteins showed the presence of a high concentration of 28-kDa protein, which might be responsible for the prolongation of cholesterol nucleation time in the fenugreek-fed groups. These findings indicate that the beneficial anti-lithogenic effect of dietary fenugreek, which primarily is due to reduction in the cholesterol content in bile, was additionally affected through a modulation of the nucleating and anti-nucleating proteins, which, in turn, affect cholesterol crystallisation.     

Biliary micellar cholesterol nucleates via the vesicular pathway

Biliary cholesterol nucleates primarily from phospholipid vesicles. In this study, we investigated the mode of nucleation of micellar cholesterol. Ten biles (four human and six model) were examined. The vesicular and micellar fractions of each bile were separated by gel chromatography. The whole biles and their isolated carriers were incubated at 37 degrees C until nucleation time. In whole human biles, the proportion of total cholesterol in vesicles rose throughout the incubation (from zero time to nucleation time) from 15.5 +/- 8.6% to 28.0 +/- 12.5%, and in model biles from 46.8 +/- 22.4% to 75.5 +/- 8.2%. The vesicular isolated fraction remained unchanged throughout incubation. In isolated micelles devoid of vesicles at zero time, new vesicles formed during incubation, carrying increasing proportions of cholesterol. At nucleation time, these vesicles contained 11.0% of originally micellar cholesterol in human biles, and 41.2% in model biles. The new vesicles formed in whole bile and in the micellar fraction were chromatographically and chemically similar to the vesicles originally present in bile. These data suggest that micellar cholesterol nucleates via the neoformation of phospholipid vesicles, which seem to be the final common pathway for cholesterol nucleation in bile.     

Rapid isolation of vesicular and micellar carriers of biliary lipids by ultracentrifugation

A simple, rapid, and new method has been developed to isolate and to quantitate the vesicular carrier of biliary lipids by isopycnic ultracentrifugation. The method combines the use of Metrizamide, as an inert centrifugation media to change the density of bile for isopycnic separation of vesicles, and a vertical rotor, to decrease both the time of centrifugation and the pressure of the hydrostatic column in the ultracentrifuge tube. Vesicles harvested from bile-Metrizamide density gradients were identified by negative staining electron microscopy. The buoyant densitites of biliary vesicles varied between 1.010 and 1.030 g/ml. The diameter of vesicles in fractions with d less than 1.020 g/ml was 82 +/- 10 nm and in fraction with d approximately 1.030 g/ml was 57 +/- 8 nm. Gel filtration chromatography with Ultrogel AcA 34 was used to validate the quantitive isolation of vesicles by the ultracentrifugal method. In experiments with bile-Metrizamide continuous preformed density gradients, greater than 93% of vesicular cholesterol was found in fractions with d less than 1.030 g/ml after 285 min of centrifugation at 50,000 rpm in a VTi vertical rotor (Beckman Instruments, Inc.). When 16% Metrizamide was dissolved in bile and centrifuged for 120 min, greater than 96% of total vesicular cholesterol was found in the top 0.4 ml of the 5-ml centrifuge tube, as assessed by gel filtration chromatography. This fraction contained less than 8% of cholesterol carried in micelles, as assessed by gel filtration chromatography. The variation coefficient of this short ultracentrifugal method to isolate biliary vesicles was 4.6%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quantitation of phospholipid vesicles and their cholesterol content in human bile by quasi-elastic light scattering

The proportion of biliary cholesterol carried by phospholipid vesicles may be an important determinant of the lithogenicity of bile. The distribution of biliary cholesterol between vesicles and other aggregational forms is often determined by gel filtration under standard conditions. The aim of this study was to measure the proportion of biliary cholesterol in vesicles in native unprocessed bile and to compare it with values obtained by chromatography. A modified quasi-elastic light-scattering method was used to measure vesicular cholesterol in whole bile. It was suitable only for lightly pigmented biles with a relatively monodisperse population of vesicles. In ten human biles examined, the proportion of cholesterol in vesicles by gel filtration was 40 +/- 8.1% (mean +/- S.D.) by chemical measurement, and 38 +/- 7.2% by [3H]cholesterol estimation. Quasi-elastic light-scattering measurements of these biles produced vesicular cholesterol values of 36 +/- 9.4%. Chromatography may affect lipid particles in bile. Nevertheless, it provides a relatively accurate measurement of biliary cholesterol in vesicles.     

Influence of total lipid concentration, bile salt:lecithin ratio, and cholesterol content on inter-mixed micellar/vesicular (non-lecithin-associated) bile salt concentrations in model bile.

We modified classic equilibrium dialysis methodology to correct for dialysant dilution and Donnan effects, and have systematically studied how variations in total lipid concentration, bile salt (taurocholate):lecithin (egg yolk) ratio, and cholesterol content influence inter-mixed micellar/vesicular (non-lecithin-associated) concentrations (IMC) of bile salts (BS) in model bile. To simulate large volumes of dialysant, the total volume (1 ml) of model bile was exchanged nine times during dialysis. When equilibrium was reached, dialysate BS concentrations plateaued, and initial and final BS concentrations in the dialysant were identical. After corrections for Donnan effects, IMC values were appreciably lower than final dialysate BS concentrations. Quasielastic light scattering was used to validate these IMC values by demonstrating that lipid particle sizes and mean scattered light intensities did not vary when model biles were diluted with aqueous BS solutions of the appropriate IMC. Micelles and vesicles were separated from cholesterol-supersaturated model bile, utilizing high performance gel chromatography with an eluant containing the IMC. Upon rechromatography of micelles and vesicles using an identical IMC, there was no net transfer of lipid between micelles and vesicles. To simulate dilution during gel filtration, model biles were diluted with 10 mM Na cholate, the prevailing literature eluant, resulting in net transfer of lipid between micelles and vesicles, the direction of which depended upon total lipid concentration and BS/lecithin ratio. Using the present methodology, we demonstrated that inter-mixed micellar/vesicular concentrations (IMC) values increased strongly (5 to 40 mM) with increases in both bile salt (BS):lecithin ratio and total lipid concentration, whereas variations in cholesterol content had no appreciable effects. For model biles with typical physiological biliary lipid compositions, IMC values exceeded the critical micellar concentration of the pure BS, implying that in cholesterol-supersaturated biles, simple BS micelles coexist with mixed BS/lecithin/cholesterol micelles and cholesterol/lecithin vesicles. We believe that this methodology allows the systematic evaluation of IMC values, with the ultimate aim of accurately separating micellar, vesicular, and potential other cholesterol-carrying particles from native bile.     

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.     

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)     

Accurate separation of vesicles, micelles and cholesterol crystals in supersaturated model biles by ultracentrifugation, ultrafiltration and dialysis.

Gel filtration with bile salts at intermixed micellar/vesicular concentrations (IMC) in the eluant has been proposed to isolate vesicles and micelles from supersaturated model biles, but the presence of vesicular aggregates makes this method unreliable. We have now validated a new method for isolation of various phases. First, aggregated vesicles and - if present - cholesterol crystals are pelleted by short ultracentrifugation. Cholesterol contained in crystals and vesicular aggregates can be quantitated from the difference of cholesterol contents in the pellets before and after bile salt-induced solubilization of the vesicular aggregates. Micelles are then isolated by ultrafiltration of the supernatant through a highly selective 300 kDa filter and unilamellar vesicles by dialysis against buffer containing bile salts at IMC values. Lipids contained in unilamellar vesicles are also estimated by subtraction of lipid contents in filtered micelles from lipid contents in (unilamellar vesicle+micelle containing) supernatant ('subtraction method'). 'Ultrafiltration-dialysis' and 'subtraction' methods yielded identical lipid solubilization in unilamellar vesicles and identical vesicular cholesterol/phospholipid ratios. In contrast, gel filtration yielded much more lipids in micelles and less in unilamellar vesicles, with much higher vesicular cholesterol/phospholipid ratios. When vesicles obtained by dialysis were analyzed by gel filtration, vesicular cholesterol/phospholipid ratios increased strongly, despite correct IMC values for bile salts in the eluant. Subsequent extraction of column material showed significant amounts of lipids. In conclusion, gel filtration may underestimate vesicular lipids and overestimate vesicular cholesterol/phospholipid ratios, supposedly because of lipids remaining attached to the column. Combined ultracentrifugation-ultrafiltration-dialysis should be considered state-of-the-art methodology for quantification of cholesterol carriers in model biles.     

成石前后胆囊粘膜上皮多聚核蛋白体RNA含量变化—胆液糖蛋白和蛋白质增加的机制探讨

胆囊淤泥是胆囊结石的前身。测定胆囊粘膜上皮游离(FPR)和结合多聚核蛋白体(MBPR)的RNA含量及胆液粘液糖蛋白(MGP)的结果表明:胆囊淤泥患者胆囊粘膜合成和分泌MGP明显亢进,MBPR与相应GB中MGP的相关性比较提示此时尚有胆液淤积存在,且FPR的RNA含量也显著增高,提示细胞增殖加快。荧光胺法测定胆液蛋白质的含量发现,胆囊淤泥和胆固醇性结石患者胆囊液GB蛋白质含量显著高于色素性结石患者及“正常”对照,但蛋白质的GB浓度与HB浓度的比值显著低于胆固醇GB/HB比值,且GB中MGP与蛋白质含量呈显著正相关。说明蛋白质含量的增加与GB中过高的MGP阻止胆囊中蛋白质的清除过程有关。成石前GB中MGP和蛋白质含量的同时增高及其机制的确立,对认识及预防体内结石均有意义。