Differential effects of cholesterol and its immediate biosynthetic precursors on membrane organization

Cholesterol is the most representative sterol present in vertebrate membranes and is the end product of the long and multistep sterol biosynthetic pathway. 7-Dehydrocholesterol (7-DHC) and desmosterol are the immediate biosynthetic precursors of cholesterol in the Kandutsch-Russell and Bloch pathway. In this article, we have monitored the effect of cholesterol and its two immediate biosynthetic precursors on biophysical and dynamic properties of fluid and gel phase membranes. Toward this goal, we have used fluorescent membrane probes, DPH and TMA-DPH, and the hydrophobic probe, pyrene. Our results using these probes show that although both 7-DHC and desmosterol differ with cholesterol in one double bond, they exhibit differential effects on membrane organization and dynamics. Importantly, we show that the effect of cholesterol and desmosterol on membrane organization and dynamics is similar in most cases, while 7-DHC has a considerably different effect. This demonstrates that the position of the double bond in sterols is an important determinant in maintaining membrane order and dynamics. These results assume relevance since the accumulation of cholesterol precursors have been reported to result in severe pathological conditions.     

Cholesterol substitution increases the structural heterogeneity of caveolae

Caveolin-1 binds cholesterol and caveola formation involves caveolin-1 oligomerization and cholesterol association. The role of cholesterol in caveolae has so far been addressed by methods that compromise membrane integrity and abolish caveolar invaginations. To study the importance of sterol specificity for the structure and function of caveolae, we replaced cholesterol in mammalian cells with its immediate precursor desmosterol by inhibiting 24-dehydrocholesterol reductase. Desmosterol could substitute for cholesterol in maintaining cell growth, membrane integrity, and preserving caveolar invaginations. However, in desmosterol cells the affinity of caveolin-1 for sterol and the stability of caveolin oligomers were decreased. Moreover, caveolar invaginations became more heterogeneous in dimensions and in the number of caveolin-1 molecules per caveola. Despite the altered caveolar structure, caveolar ligand uptake was only moderately inhibited. We found that in desmosterol cells, Src kinase phosphorylated Cav1 at Tyr(14) more avidly than in cholesterol cells. Taken the role of Cav1 Tyr(14) phosphorylation in caveolar endocytosis, this may help to preserve caveolar uptake in desmosterol cells. We conclude that a sterol C24 double bond interferes with caveolin-sterol interaction and perturbs caveolar morphology but facilitates Cav1 Src phosphorylation and allows caveolar endocytosis. More generally, substitution of cholesterol by a structurally closely related sterol provides a method to selectively modify membrane protein-sterol affinity, structure and function of cholesterol-dependent domains without compromising membrane integrity.     

Secretion of sterols and the NPC2 protein from primary astrocytes

Astrocytes secrete cholesterol in lipoprotein particles. Here we show that primary murine embryonic astrocytes secrete endogenously synthesized cholesterol but also the cholesterol precursors desmosterol and lathosterol. In astrocyte membranes, desmosterol and cholesterol were the predominant sterols. Astrocytes derived from Niemann-Pick type C lipidosis (NPC1-/-) mice displayed late endosomal cholesterol deposits, but the secretion of biosynthetic sterols from the cells was not inhibited. Both wild-type and NPC1-/- astrocytes secreted the NPC2 protein. Size-exclusion chromatography combined with electron microscopy showed that the majority of sterols were secreted separately from NPC2 in heterogeneous spherical particles with an average diameter of 20 nm. These data suggest that NPC2 and the majority of sterols secreted from astrocytes are not released together and that the secretion of neither sterols nor NPC2 requires NPC1 function. In addition, the findings reveal a complexity of sterol species in astrocytes and bring up the possibility that some of the effects assigned to astrocyte cholesterol may be attributed to its penultimate precursors.     

Sterol affinity for bilayer membranes is affected by their ceramide content and the ceramide chain length

It is known that ceramides can influence the lateral organization in biological membranes. In particular ceramides have been shown to alter the composition of cholesterol and sphingolipid enriched nanoscopic domains, by displacing cholesterol, and forming gel phase domains with sphingomyelin. Here we have investigated how the bilayer content of ceramides and their chain length influence sterol partitioning into the membranes. The effect of ceramides with saturated chains ranging from 4 to 24 carbons in length was investigated. In addition, unsaturated 18:1- and 24:1-ceramides were also examined. The sterol partitioning into bilayer membranes was studied by measuring the distribution of cholestatrienol, a fluorescent cholesterol analogue, between methyl-β-cyclodextrin and large unilamellar vesicle with defined lipid composition. Up to 15 mol% ceramide was added to bilayers composed of DOPC:PSM:cholesterol (3:1:1), and the effect on sterol partitioning was measured. Both at 23 and 37 °C addition of ceramide affected the sterol partitioning in a chain length dependent manner, so that the ceramides with intermediate chain lengths were the most effective in reducing sterol partitioning into the membranes. At 23 °C the 18:1-ceramide was not as effective at inhibiting sterol partitioning into the vesicles as its saturated equivalent, but at 37 °C the additional double bond had no effect. The longer 24:1-ceramide behaved as 24:0-ceramide at both temperatures. In conclusion, this work shows how the distribution of sterols within sphingomyelin-containing membranes is affected by the acyl chain composition in ceramides. The overall membrane partitioning measured in this study reflects the differential partitioning of sterol into ordered domains where ceramides compete with the sterol for association with sphingomyelin.     

Pinocytosis in L cells: its dependence on membrane sterol and the cytoskeleton

Pinocytosis in L-cells, grown in serum-free medium, was depressed when cultures were treated with oxygenated derivatives of cholesterol which inhibited sterol synthesis and reduced the sterol concentration of the plasma membranes. Noninhibitory sterols, such as cholesterol or desmosterol counteracted the effects of the inhibitors. Treatment with polylysine increased the rate of pinocytosis in sterol-depleted cells to a level similar to the enhanced rate found in polylysine treated control cells. Drugs which interfere with cytoskeletal systems (microfilaments, microtubules) also depressed pinocytosis but their effect could not be overcome by treatment with polylysine.     

Constraints to growth of annual nettle (Urtica urens) in an elevated CO2 atmosphere: Decreased leaf area ratio and tissue N cannot be explained by ontogenetic drift or mineral N supply

Plant sterols differ from cholesterol in having an alkyl group at Δ-24, and, in the case of stigmasterol, also a Δ-22 double bond. The effects of 10 mol% of three plant sterols (campesterol, β -sitosterol, stigmasterol) and cholesterol on the molecular dynamics and phase behavior in multilamellar liposomes made from different phosphatidylcholine (PC) molecular species have been compared, utilizing the fluorescent probe Laurdan (2-dimethyl-amino-6-laurylnaphthalene). Laurdan reports the molecular mobility in the hydrophilic/hydrophobic interface of the membrane by determining the rate of dipolar relaxation of water molecules close to the glycerol backbone of PC. Our results showed that the Δ-24 alkyl group of plant sterols did not affect their ability to reduce molecular mobility in this region of the PC membranes. However, the plant sterols had a decreased capacity compared to cholesterol to inhibit formation of co-existing domains of gel and liquid-crystalline phases in membranes composed of equimolar dilauroyl-PC and dipalmitoyl-PC. The Δ-22 double bond present in stigmasterol decreased the ability of this sterol, compared to the other phytosterols, to reduce the molecular mobility at the hydrophobic/hydrophilic interface in membranes made of a saturated PC molecular species. However, in membranes made from 16:0/18:2-PC, a lipid species common in plant plasma membranes, stigmasterol was as efficient as other sterols in affecting the polarity and molecular mobility at the hydrophilic/hydrophobic interface of the membrane at 25°C, but was, in contrast to the other sterols, without effect at 0°C. Our results thus confirm as well as contradict the results of previous studies of the interactions between saturated PC and sterols, where other membrane regions were probed. The physiological relevance of the findings is discussed.     

Incorporation of L Cell Sterols into Vesicular Stomatitis Virus

The incorporation of host cell sterol into vesicular stomatitis virus can be effectively studied in an L cell system. The end product of de novo sterol synthesis in the L cell is desmosterol, and as the concentration of cholesterol in the medium is increased the cells incorporate the exogenous cholesterol and the synthesis of desmosterol decreases. L cells which contained desmosterol as their sole sterol produced virus whose sterol content was similarly composed of only desmosterol. Virus grown in L cells which had a constantly changing sterol ratio also contained a mixture of cholesterol and desmosterol, but the virus was found to be more enriched in cholesterol than in the L cells in which it was grown. Viral stability, growth, and plaquing efficiency were tested and found not to be affected by the alteration of its sterol composition, i.e., by partially or completely replacing cholesterol with desmosterol.     

Progestins block cholesterol synthesis to produce meiosis-activating sterols.

The resumption of meiosis is regulated by meiosis-preventing and meiosis-activating substances in testes and ovaries. Certain C29 precursors of cholesterol are present at elevated levels in gonadal tissue, but the mechanism by which these meiosis-activating sterols (MAS) accumulate has remained an unresolved question. Here we report that progestins alter cholesterol synthesis in HepG2 cells and rat testes to increase levels of major MAS (FF-MAS and T-MAS). These C29 sterols accumulated as a result of inhibition of Delta24-reduction and 4alpha-demethylation. Progesterone, pregnenolone, and 17alpha-OH-pregnenolone were potent inhibitors of Delta24-reduction in an in vitro cell assay and led to the accumulation of desmosterol, a Delta5,24 sterol precursor of cholesterol. A markedly different effect was observed for 17alpha-OH-progesterone, which caused the accumulation of sterols associated with inhibition of 4alpha-demethylation. The flux of 13C-acetate into lathosterol and cholesterol was decreased by progestins as measured by isotopomer spectral analysis, whereas newly synthesized MAS accumulated. The combined evidence that MAS concentrations can be regulated by physiological levels of progestins and their specific combination provides a plausible explanation for the elevated concentration of MAS in gonads and suggests a new role for progestins in fertility.     

Variations of hepatic cholesterol precursors during altered flows of endogenous and exogenous squalene in the rat

Hepatic and serum levels of cholesterol precursors were analyzed in rats under basal (control) conditions and when cholesterol synthesis was activated by feeding 1% squalene or 5% cholestyramine. Exogenous squalene stimulated the activity of acyl-coenzyme A:cholesterol acyltransferase (ACAT) but strongly inhibited the activity of hydroxymethylglutaryl-coenzyme A (HMG-CoA) reductase; cholestyramine did not affect ACAT but increased HMG-CoA reductase several-fold, indicating enhanced production of endogenous squalene. Activation of cholesterol synthesis by the two methods markedly increased the hepatic and serum contents of cholesterol precursor sterols. However, the sterol profiles were clearly different. Thus, exogenous squalene raised most significantly (up to 109-fold) free and esterified methyl sterols, and less so (up to 2-fold) demethylated C27 sterols (desmosterol and cholestenols) and also esterified cholesterol. Activation of endogenous squalene production by cholestyramine was associated with a depletion of esterified cholesterol and by a marked, up to 8-fold, increase of the free demethylated sterol precursor levels, whereas the increase of methyl sterols, up to 5-fold, was less conspicuous than during the squalene feeding. The changes were mostly insignificant for esterified sterols. The altered serum sterol profiles were quite similar to those in liver. Serum cholestenols and especially their portion of total serum precursor sterols were closely correlated with the hepatic activity of HMG-CoA reductase.     

The use of the Dhcr7 knockout mouse to accurately determine the origin of fetal sterols

Mice with a targeted mutation of 3beta-hydroxysterol Delta(7)-reductase (Dhcr7) that cannot convert 7-dehydrocholesterol to cholesterol were used to identify the origin of fetal sterols. Because their heterozygous mothers synthesize cholesterol normally, virtually all sterols found in a Dhcr7 knockout fetus having a Delta(7) or a Delta(8) double bond must have been synthesized by the fetus itself but any cholesterol had to have come from the mother. Early in gestation, most fetal sterols were of maternal origin, but at approximately E13-14, in situ synthesis became increasingly important, and by birth, 55-60% of liver and lung sterols had been made by the fetus. In contrast, at E10-11, upon formation of the blood-brain barrier, the brain rapidly became the source of almost all of its own sterols (90% at birth). New, rapid, de novo sterol synthesis in brain was confirmed by the observation that concentrations of C24,25-unsaturated sterols were low in the brains of all very young fetuses but increased rapidly beginning at approximately E11-12. Reduced activity of sterol C24,25-reductase (Dhcr24) in brain, suggested by the abundance of C24,25-unsaturated compounds, seems to be the result of suppressed Dhcr24 expression. The early fetal brain also appears to conserve cholesterol by keeping cholesterol 24-hydroxylase expression low until approximately E18.     

Effect of sterol structure on ordered membrane domain (raft) stability in symmetric and asymmetric vesicles

Sterol structure influences liquid ordered domains in membranes, and the dependence of biological functions on sterol structure can help identify processes dependent on ordered domains. In this study we compared the effect of sterol structure on ordered domain formation in symmetric vesicles composed of mixtures of sphingomyelin, 1, 2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) and cholesterol, and in asymmetric vesicles in which sphingomyelin was introduced into the outer leaflet of vesicles composed of DOPC and cholesterol. In most cases, sterol behavior was similar in symmetric and asymmetric vesicles, with ordered domains most strongly stabilized by 7-dehydrocholesterol (7DHC) and cholesterol, stabilized to a moderate degree by lanosterol, epicholesterol and desmosterol, and very little if at all by 4-cholesten-3-one. However, in asymmetric vesicles desmosterol stabilized ordered domain almost as well as cholesterol, and to a much greater degree than epicholesterol, so that the ability to support ordered domains decreased in the order 7-DHC > cholesterol > desmosterol > lanosterol > epicholesterol > 4-cholesten-3-one. This contrasts with values for intermediate stabilizing sterols in symmetric vesicles in which the ranking was cholesterol > lanosterol ~ desmosterol ~ epicholesterol or prior studies in which the ranking was cholesterol ~ epicholesterol > lanosterol ~ desmosterol. The reasons for these differences are discussed. Based on these results, we re-evaluated our prior studies in cells and conclude that endocytosis levels and bacterial uptake are even more closely correlated with the ability of sterols to form ordered domains than previously thought, and do not necessarily require that a sterol have a 3β-OH group.     

Inhibition of sterol synthesis by delta 5-sterols in a sterol auxotroph of yeast defective in oxidosqualene cyclase and cytochrome P-450

Synthesis of ergosterol is demonstrated in the GL7 mutant of Saccharomyces cerevisiae. This sterol auxotroph has been thought to lack the ability to synthesize sterols due both to the absence of 2,3-oxidosqualene cyclase and to a heme deficiency eliminating cytochrome P-450 which is required in demethylation at C-14. However, when the medium sterol was 5 alpha-cholestan-3 beta-ol, 5 alpha-cholest-8(14)-en-3 beta-ol, or 24 beta-methyl-5 alpha-cholest-8(14)-en-3 beta-ol, sterol synthesis was found to proceed yielding 1-3 fg/cell of ergosterol (24 beta-methylcholesta-5,7,22E-trien-3 beta-ol). Ergosterol was identified by mass spectroscopy, gas and high performance liquid chromatography, ultraviolet spectroscopy, and radioactive labeling from [3H]acetate. Except for some cholest-5-en-3 beta-ol (cholesterol) which was derived from the 5 alpha-cholestan-3 beta-ol, the stanol and the two 8(14)-stenols were not significantly metabolized confirming the absence of an isomerase for migration of the double bond from C-8(14) to C-7. Drastic reduction of ergosterol synthesis to not more than 0.06 fg/cell was observed when the medium sterol either had a double bond at C-5, as in the case of cholesterol, or could be metabolized to a sterol with such a bond. Thus, both 5 alpha-cholest-8(9)-en-3 beta-ol and 5 alpha-cholest-7-en-3 beta-ol (lathosterol) were converted to cholesta-5,7-dien-3 beta-ol (7-dehydrocholesterol), and the presence of the latter dienol depressed the level of ergosterol. The most attractive of the possible explanations for our observations is the assumption of two genetic compartments for synthesis of sterols, one of which has and one of which has not been affected by the two mutations. The ability, despite the mutations, to synthesize small amounts of ergosterol which could act to regulate the cell cycle may also explain why this mutant can grow aerobically with cholesterol (acting in the bulk membrane role) as the sole exogenous sterol.     

Comparative behavior of sterols in phosphatidylcholine-sterol monolayer films

The ability of sterols other than cholesterol (CHOL) to support membrane functions in membranes that normally contain CHOL as the primary, if not sole, sterol may be due, in part, to how well such sterols can mimic CHOL's behavior and physical properties in membranes. We compared the mixing properties of CHOL, 7-dehydrocholesterol (7DHC), and desmosterol (DES) in egg phosphatidylcholine-sterol monolayer films containing 10, 20, and 30 mol percent sterol, measuring pressure-area isotherms on a Langmuir-Blodgett trough with the aqueous, buffered subphase maintained at 37 degrees C. Under the conditions employed, the pressure-area isotherms for all three sterols were similar, with 7DHC exhibiting slightly larger molecular areas on the water surface at all compositions. These results are discussed in the context of the ability of sterols such as 7DHC and DES to substitute structurally and functionally for CHOL in biological membranes.     

Substrate specificity of cholesterol oxidase from Streptomyces cinnamomeus--a monolayer study.

The substrate specificity of cholesterol oxidase from Streptomyces cinnamomeus was examined in oriented sterol monolayers at the air/water interface. Of the cholesterol analogues with structural alterations in the A- or B-ring that were examined, it was observed that 5 alpha-cholestan-3 beta-ol was oxidized almost as fast as cholesterol itself. When the delta-5 double bond in cholesterol was instead at the delta-4 position, the oxidation rate became 3.2-fold slower. A similar reduction in the average oxidation rate was observed when the delta-5 double bond in cholesterol was instead at the delta-7 position (5 alpha-cholest-7-en-3 beta- ol). 5,7-Cholestadien-3 beta-ol was oxidized 5.1-fold slower compared to cholesterol, whereas 3 beta-hydroxy-5-cholesten-7-one and 5 beta-cholestan-3 beta-ol were not substrates of the enzyme (also verified from the lack of H2O2-production). With C(17) side chain analogues of cholesterol, it was observed that the complete lack of the C(17) side chain (5-androsten-3 beta-ol), or the insertion of an unsaturation at delta-24 (desmosterol), or even an ethyl group at C(24)(24b-ethyl-5,22- cholestadien-3 beta-ol) had no appreciable effects on sterol oxidation rate, implying that the enzyme did not recognize the side chain in oriented sterol monolayers. This study has shown that the sterol monolayer system is a good technique to examine sterol/cholesterol oxidase interactions, since both the orientation of the substrate molecules, and the quality of the interface can be mastered.     

Monolayers of sterols and phosphatidylcholines containing a 20-carbon chain

Pressure-area curves of monolayer films were measured for phosphatidylcholines (PC) in which the 1-position was occupied by palmitic acid and the 2-positions were occupied respectively by: 20 : 0, 20 : 1n9, 20 : 2n6, 20 : 3n3, 20 : 3n6, 20 : 3n9, 20 : 4n6 or 20 : 5n3 fatty acids. The interactions of these PC with cholesterol or desmosterol were studied.Fully saturated PC (16 : 0–20 : 0) displayed a relatively small molecular area. The presence of one double bond greatly increased the molecular area, but a second double bond resulted in only a small additional increase in area. A third double bond caused a further large expansion in area, but the presence of a fourth or fifth double bond had little additional effect.Condensation of molecular area was observed with all sterol/PC mixed films. Approximately equimolar mixtures of sterols and unsaturated PC condensed maximally, but 16 : 0–20 : 0 PC condensed most in mixtures containing 20–30 mol% of either sterol.The extent of condensation varied with surface pressure. The pressure at which maximum condensation occurred depended upon the structure of the PC and was always 20 dyn/cm or lower. The pressure at which maximum condensation with cholesterol occurred increased with increasing unsaturation of the PC.     

Distribution and movement of sterols with different side chain structures between the two leaflets of the membrane bilayer of mycoplasma cells

Mycoplasma gallisepticum was adapted to grow with delta 5-sterols modified in the aliphatic side chain, and stopped-flow kinetic measurements of filipin association were made to estimate the sterol distribution between the two leaflets of the membrane. Cholesterol derivatives with unsaturated side chains (desmosterol, cis- and trans-22-dehydrocholesterol, and cholesta-5,22E,24-trien-3 beta-ol) or an alkyl substituent (beta-sitosterol) were predominantly (86-94%) localized in the outer leaflet of the bilayer. However, cholesterol, 20-isocholesterol, and sterols with side chains of varying lengths (in the 20(R)-n-alkylpregn-5-en-3 beta-ol series where the alkyl group ranged from ethyl to undecyl) were distributed nearly symmetrically between the two halves of the bilayer. Kinetic measurements of beta-[14C]sitosterol and [14C]desmosterol exchange between M. gallisepticum cells and an excess of sonicated sterol/phosphatidylcholine vesicles confirmed the filipin-binding studies. More than 90% of these radiolabeled sterols underwent exchange at 37 degrees C with unlabeled sterols in vesicles over a period of 12-14 h in the presence of 2% (w/v) albumin. beta-[14C]Sitosterol exchange was characterized by biphasic exchange kinetics, indicative of two pools of sitosterol molecules in the cell membrane. Only a single kinetic pool was detected for [14C]desmosterol exchange. Stopped flow measurements of filipin binding to beta-sitosterol and stigmasterol also revealed an asymmetrical localization of these sterols in membranes of growing Mycoplasma. capricolum cells. When an early exponential culture of beta-sitosterol- or stigmasterol-adapted M. capricolum was transferred to a sterol-rich medium at 37 degrees C, approximately three-quarters of the beta-sitosterol or stigmasterol was localized in the outer leaflet after growth was continued for 6 h; in contrast, cholesterol was distributed symmetrically after about 1 h. The asymmetric localization of sterols with alkylated or unsaturated side chains suggests that growth-supporting sterols need not be translocated extensively into the inner leaflet of the bilayers of M. gallisepticum and M. capricolum.     

Oxygenation of desmosterol and cholesterol in cell cultures

In order to determine whether hydration of the delta 24 bond of desmosterol contributes to the formation of the regulatory oxysterol, 25-hydroxycholesterol, [3H]desmosterol was incubated with two cultured cell lines and the labeled products were analyzed. Small amounts of 25-hydroxycholesterol were formed with Chinese hamster lung (Dede) cell cultures, but not with mouse fibroblast (L) cell cultures. Apparently, desmosterol was converted into cholesterol, a process that does not occur in L cells, before 25-hydroxycholesterol takes place. No reliable evidence could be obtained for hydration of the delta 24 bond or for the reverse reaction upon incubation of [3H]25-hydroxycholesterol. Oxygenation of desmosterol occurred in both Dede and L cell cultures to give a mixture of 24(R)- and 24(S)-25-epoxy-cholesterol. This reaction, along with the production of 7-oxygenated sterols, may account for low levels of HMG-CoA reductase repressor activity previously found to be associated with delta 24 sterols.     

Heritability of plasma noncholesterol sterols and relationship to DNA sequence polymorphism in ABCG5 and ABCG8

The plasma concentrations of cholesterol precursor sterols and plant sterols vary over a 5- to 10-fold range among normolipidemic individuals, and provide indices of the relative rates of cholesterol synthesis and fractional absorption. In the present study, we examined the relative contributions of genetic and environmental factors to variation in the plasma concentrations and sterol-cholesterol ratios of five noncholesterol sterols, including the 5alpha-saturated derivative of cholesterol (cholestanol), two precursors in the cholesterol biosynthesis pathway (desmosterol and lathosterol), and two phytosterols (campesterol and sitosterol). Plasma sterol concentrations were highly stable in 30 individuals measured over a 48 week period. Regression of offspring sterol levels on the parental values indicated that plasma levels of all five noncholesterol sterols were highly heritable. Analysis of monozygotic and dizygotic twin pairs also indicated strong heritability of all five sterols. Two common sequence variations (D19H and T400K) in ABCG8, an ABC half-transporter defective in sitosterolemia, were associated with lower concentrations of plant sterols in parents, and in their offspring.Taken together, these findings indicate that variation in the plasma concentrations of noncholesterol sterols is highly heritable, and that polymorphism in ABCG8 contributes to genetic variation in the plasma concentrations of plant sterols.     

Microsomal synthesis of cholesterol from squalene, Lanosterol, and desmosterol. Evidence for the presence of two noncatalytic activator proteins in the 105,000 g supernatant fraction from brain, heart, and kidney

The biosynthesis of C₂₇ sterols (used as a generic term for 3 β-hydroxysterols containing 27 carbon atoms) from squalene and lanosterol, of cholesterol from desmosterol, and of lanosterol from squalene by microsomal fractions from adult rat heart, kidney, and brain was investigated. These conversions required the presence of 105,000g supernatant fraction. Heat treatment of the supernatant fractions resulted in a significant loss of their capacity to stimulate the conversion of squalene to sterols, but the capacity to stimulate conversion of lanosterol to C₂₇ sterols and desmosterol to cholesterol was unaffected. The stimulatory activity (for the conversion of all three substrates) of both the heated and unheated supernatant fractions was lost on treatment with trypsin. Thus the soluble fraction appears to contribute at least two essential protein components for the overall conversion of squalene to cholesterol; one a heat labile protein, which functions in the squalene to lanosterol sequence, and the other a heat-stable protein, which is operative in the pathway between lanosterol and cholesterol. Hepatic supernatant factors required for cholesterol synthesis by liver microsomal enzymes function with heart, kidney, and brain microsomal enzymes in stimulating sterol synthesis from squalene and sterol precursors. Moreover, heart, kidney, and brain supernatant fractions prepared in 100 mm phosphate buffer stimulated cholesterol synthesis from squalene and other sterol precursors by liver microsomes. The supernatant fractions of the extrahepatic tissues prepared in 20 mm phosphate buffer lacked the ability to stimulate the biosynthesis of lanosterol from squalene by liver microsomes but were able to stimulate the conversion of lanosterol to C₂₇ sterols or conversion of desmosterol to cholesterol. These findings indicate that the heat-stable protein factor present in the supernatant fractions from extrahepatic tissues is perhaps identical to that in liver, but that the heat-labile factor in extrahepatic tissues, which catalyzes the cyclization of squalene to lanosterol, differs in some respect from that in liver.