Quantitation of two pathways for cholesterol excretion from the brain in normal mice and mice with neurodegeneration

Although the pool of cholesterol in the adult central nervous system (CNS) is large and of constant size, little is known of the process(es) involved in regulation of sterol turnover in this pool. In 7-week-old mice, net excretion of cholesterol from the brain equaled 1.4 mg/day/kg body weight, and from the whole animal was 179 mg/day/kg. Deletion of cholesterol 24-hydroxylase, an enzyme highly expressed in the CNS, did not alter brain growth or myelination, but reduced sterol excretion from the CNS 64% to 0.5 mg/day/kg. In mice with a mutation in the Niemann-Pick C gene that had ongoing neurodegeneration, sterol excretion from the CNS was increased to 2.3 mg/day/kg. Deletion of cholesterol 24-hydroxylase activity in these animals reduced net excretion only 22% to 1.8 mg/day/kg. Thus, at least two different pathways promote net sterol excretion from the CNS. One uses cholesterol 24-hydroxylase and may reflect sterol turnover in large neurons in the brain. The other probably involves the movement of cholesterol or one of its metabolites across the blood-brain barrier and may more closely mirror sterol turnover in pools such as glial cell membranes and myelin.     

Cholesterol metabolism in the brain

The central nervous system accounts for only 2% of the whole body mass but contains almost a quarter of the unesterified cholesterol present in the whole individual. This sterol is largely present in two pools comprised of the cholesterol in the plasma membranes of glial cells and neurons and the cholesterol present in the specialized membranes of myelin. From 0.02% (human) to 0.4% (mouse) of the cholesterol in these pools turns over each day so that the absolute flux of sterol across the brain is only approximately 0.9% as rapid as the turnover of cholesterol in the whole body of these respective species. The input of cholesterol into the central nervous system comes almost entirely from in situ synthesis, and there is currently little evidence for the net transfer of sterol from the plasma into the brain of the fetus, newborn or adult. In the steady state in the adult, an equivalent amount of cholesterol must move out of the brain and this output is partly accounted for by the formation and excretion of 24S-hydroxycholesterol. This cholesterol turnover across the brain is increased in neurodegenerative disorders such as Alzheimer's disease and Niemann-Pick type C disease. Indirect evidence suggests that large amounts of cholesterol also turn over among the glial cells and neurons within the central nervous system during brain growth and neuron repair and remodelling. This internal recycling of sterol may involve ligands such as apolipoproteins E and AI, and one or more membrane transport proteins such as members of the low density lipoprotein receptor family. Changes in cholesterol balance across the whole body may, in some way, cause alterations in sterol recycling and apolipoprotein E expression within the central nervous system, which, in turn, may affect neuron and myelin integrity. Further elucidation of the processes controlling these events is very important to understand a variety of neurodegenerative disorders.     

Effect of maternal hypercholesterolemia on fetal sterol metabolism in the Golden Syrian hamster.

The fetus obtains a significant amount of cholesterol from de novo synthesis. Studies have suggested that maternal cholesterol may also contribute to the cholesterol accrued in the fetus. Thus, the present studies were completed to determine whether diet-induced maternal hypercholesterolemia would affect fetal sterol metabolism. To accomplish this, maternal plasma cholesterol concentrations were increased sequentially by feeding hamsters 0.0%, 0.12%, 0.5%, and 2.0% cholesterol. At 11 days into a gestational period of 15.5 days, cholesterol concentrations and sterol synthesis rates were measured in the three fetal tissues: the placenta, yolk sac, and fetus. In the placenta and yolk sac, the cholesterol concentration increased significantly when dams were fed as little as 0.12% cholesterol (P < 0.0167), and sterol synthesis rates decreased in dams fed at least 0.5% or 2% cholesterol, respectively (P < 0.0167). In the fetus, changes in fetal cholesterol concentration and sterol synthesis rates occurred only when dams were fed at least 0.5% cholesterol, which corresponded to a greater than 2-fold increase in maternal plasma cholesterol concentrations. When the cholesterol concentration in the fetal tissues in each animal was plotted as a function of maternal plasma cholesterol concentration, a linear relationship was found (P < 0.001).These studies demonstrate that sterol homeostasis in fetal tissues, including the fetus, is affected by maternal plasma cholesterol concentration in a gradient fashion and that sterol metabolism in the fetus is dependent on sterol homeostasis in the yolk sac and/or placenta.     

Cholesterol domains in biological membranes

Membrane cholesterol is distributed asymmetrically both within the cell or within cellular membranes. Elaboration of intracellular cholesterol trafficking, targeting and intramembrane distribution has been spurred by both molecular and structural approaches. The expression of recombinant sterol carrier proteins in L-cell fibroblasts has been especially useful in demonstrating for the first time that such proteins actually elicit intracellular and intra-plasma membrane redistribution of sterol. Additional advances in the use of native fluorescent sterols allowed resolution of transbilayer and lateral cholesterol domains in plasma membranes from cultured fibroblasts, brain synaptosomes and erythrocytes. In all three cell surface membranes, cholesterol is enriched in the inner, cytofacial leaflet. Up to three different cholesterol domains have been identified in the lateral plane of the plasma membrane: a fast exchanging domain comprising less than 10% of cholesterol, a slowly exchanging domain comprising about 30% of cholesterol, and a very slowly or non-exchangeable sterol domain comprising 50–60.

Of plasma membrane cholesterol. Factors modulating plasma membrane cholesterol domains include polyunsaturated fatty acids, expression of intracellular sterol carrier proteins, drugs such as ethanol, and several membrane pathologies (systemic lupus erythematosus, sickle cell anaemia and aging). Disturbances in plasma membrane cholesterol domains after transbilayer fluidity gradients in plasma membranes. Such changes are associated with decreased Ca²⁺ -ATPase and Na ⁺, K⁺ -ATPase activity. Thus, the size, dynamics and distribution of cholesterol domains within membranes not only regulate cholesterol efflux/influx but also modulate plasma membrane protein functions and receptor-effector coupled systems.     

Cholesterol homeostasis in the guinea pig. The importance of quantitating net tissue accumulation of cholesterol in sterol balance studies

Sterol balance measurements of whole body cholesterol synthesis were performed in guinea pigs to determine the relative quantitative importance of dietary cholesterol intake, endogenous cholesterol synthesis, fecal steroid excretion and net tissue accumulation in cholesterol homeostasis of a rapidly growing animal. Sterol inputs were from diet (33%) and endogenous synthesis (67%); sterol outputs, as fecal neutral and acidic steroids, accounted for 60% of the total input, the remainder being used for the demands of tissue growth. The data demonstrate that the measurement of total body cholesterol synthesis can be grossly underestimated in this rapidly growing animal if net tissue accumulation of cholesterol is not considered in the balance measurement.     

Cholesterol transport between cells and high-density lipoproteins

Various types of studies in humans and animals suggest strongly that HDL is anti-atherogenic. The anti-atherogenic potential of HDL is thought to be due to its participation in reverse cholesterol transport, the process by which cholesterol is removed from non-hepatic cells and transported to the liver for elimination from the body. Extensive studies in cell culture systems have demonstrated that HDL is an important mediator of sterol transport between cells and the plasma compartment. The topic of this review is the mechanisms that account for sterol movement between HDL and cells. The most prominent and easily measured aspect of sterol movement between HDL and cells is the rapid bidirectional transfer of cholesterol between the lipoprotein and the plasma membrane. This movement occurs by unmediated diffusion, and in most situations its rate in each direction is limited by the rate of desorption of sterol molecules from the donor surface into the adjacent water phase. The net transfer of sterol mass out of cells occurs when there is either a relative enrichment of sterol within the plasma membrane or a depletion of sterol in HDL. Recent studies suggest that certain minor subfractions of HDL (with pre-beta mobility on agarose gel electrophoresis and containing apoprotein A-I but no apo A-II) are unusually efficient at promoting efflux of cell sterol. To what extent efflux to these HDL fractions is balanced by influx from the lipoprotein has not yet been established clearly. The prevention and reversal of atherosclerosis require the mobilization of cholesterol from internal (non-plasma membrane) cellular locations. To some extent, this may involve the retroendocytosis of HDL. However, most mobilization probably involves the transport of internal sterol to the plasma membrane, followed by desorption to extracellular HDL. Several laboratories are investigating the transport of sterol from intracellular locations to the plasma membrane. Studies on biosynthetic sterol (probably originating mostly in the smooth endoplasmic reticulum) suggest that there is rapid transport to the plasma membrane in lipid-rich vesicles. Important features of this transport are that it bypasses the Golgi apparatus and may be positively regulated by the specific binding of HDL to the plasma membrane.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of distal cholesterol biosynthesis inhibitors on cell proliferation and cell cycle progression

Cholesterol is a major lipid component of the plasma membrane in animal cells. In addition to its structural requirement, cholesterol is essential in cell proliferation and other cell processes. The aim of the present study was to elucidate the stringency of the requirement for cholesterol as a regulator of proliferation and cell cycle progression, compared with other sterols of the cholesterol biosynthesis pathway. Human promyelocytic HL-60 cells were cultured in cholesterol-free medium and treated with different distal inhibitors of cholesterol biosynthesis (zaragozic acid, SKF 104976, SR 31747, BM 15766, and AY 9944), which allow the synthesis of isoprenoid derivatives and different sets of sterol intermediates, but not cholesterol. The results showed that only the inhibition of sterol Delta7-reductase was compatible with cell proliferation. Blocking cholesterol biosynthesis upstream of this enzyme resulted in the inhibition of cell proliferation and cell cycle arrest selectively in G2/M phase.     

Changes in cholesterol absorption and cholesterol synthesis caused by ezetimibe and/or simvastatin in men

This study evaluates changes in cholesterol balance in hypercholesterolemic subjects following treatment with an inhibitor of cholesterol absorption or cholesterol synthesis or coadministration of both agents. This was a randomized, double blind, placebo-controlled, four-period crossover study to evaluate the effects of coadministering 10 mg ezetimibe with 20 mg simvastatin (ezetimibe/simvastatin) on cholesterol absorption and synthesis relative to either drug alone or placebo in 41 subjects. Each treatment period lasted 7 weeks. Ezetimibe and ezetimibe/simvastatin decreased fractional cholesterol absorption by 65% and 59%, respectively (P < 0.001 for both relative to placebo). Simvastatin did not significantly affect cholesterol absorption. Ezetimibe and ezetimibe/simvastatin increased fecal sterol excretion (corrected for dietary cholesterol), which also represents net steady state cholesterol synthesis, by 109% and 79%, respectively (P < 0.001). Ezetimibe, simvastatin, and ezetimibe/simvastatin decreased plasma LDL-cholesterol by 20, 38, and 55%, respectively. The coadministered therapy was well tolerated. The decreases in net cholesterol synthesis and increased fecal sterol excretion yielded nearly additive reductions in LDL-cholesterol for the coadministration of ezetimibe and simvastatin.     

Sterol absorption by the small intestine

PURPOSE OF REVIEW: Cholesterol absorption is a selective process in that plant sterols and other non-cholesterol sterols are absorbed poorly or not at all. Recent research on the sterol efflux pumps adenosine triphosphate-binding cassette transporter G5 and adenosine triphosphate-binding cassette transporter G8 has not only provided an explanation for this selectivity, but also, together with the discovery of a new class of cholesterol absorption inhibitor, has yielded new insights into the mechanisms that potentially regulate the flux of cholesterol across the enterocyte. This review discusses these recent developments and their importance to the regulation of whole body cholesterol homeostasis. RECENT FINDINGS: Adenosine triphosphate-binding cassette transporters G5/8 regulate plant sterol absorption and also the secretion into bile of cholesterol and non-cholesterol sterols. Loss of adenosine triphosphate-binding cassette transporter G5/8 function results in sitosterolemia. Ezetimibe, a novel, potent and selective inhibitor of cholesterol absorption which is effective in milligram doses, lowers plasma plant sterol concentrations in sitosterolemic subjects, thus suggesting that this drug might be inhibiting the activity of a putative sterol permease in the brush border membrane of the enterocyte that actively facilitates the uptake of cholesterol as well as other non-cholesterol sterols. SUMMARY: Intestinal cholesterol absorption represents a major route for the entry of cholesterol into the body's miscible pools and therefore can potentially impact the plasma LDL-cholesterol concentration. The combined use of agents that inhibit the absorption and synthesis of cholesterol provides a powerful new approach to the prevention and treatment of atherosclerosis.     

Plasma Membrane Sterols Are Essential for Sensing Osmotic Changes in the Halotolerant Alga Dunaliella

The halotolerant alga Dunaliella responds to hyperosmotic stress by synthesis of massive amounts of glycerol. The trigger for this osmotic response is the change in cell volume, but the mechanism that senses volume changes is not known. Preincubation of Dunaliella salina with tridemorph, a specific inhibitor of sterol biosynthesis, inhibits glycerol synthesis and volume recovery. The inhibition is associated with suppression of [14C]bicarbonate incorporation into sterols and is correlated with pronounced depletion of plasma membrane sterols. Incubation of sterol-depleted cells with cholesterol hemisuccinate restores the capacity for volume regulation in response to hyperosmotic stress. Tridemorph as well as lovastatin also inhibit volume changes that are induced by high light in Dunaliella bardawil, a species that responds to high light intensity by synthesis of large amounts of [beta]-carotene. These volume changes result from accumulation of glycerol and are associated with de novo synthesis of sterols. The major plasma membrane sterol in D. salina and the high-light-induced sterol in D. bardawil co-migrate with ergosterol on thin-layer chromatography and on reversed-phase high-performance liquid chromatography. These results suggest that the osmosensory mechanism in Dunaliella resides in the plasma membrane, and that sterols have an important role in sensing osmotic changes.     

The liver plays a key role in whole body sterol accretion of the neonatal Golden Syrian hamster

Neonates have a significant requirement for cholesterol. From -1 to 25 days of age, the liver accrues 6.9 mg cholesterol and the extra-hepatic tissues accrue 107.7 mg cholesterol in the hamster. It is currently unknown if each of these body compartments synthesizes their own cholesterol or if they have alternative source(s) of sterol. Using (3)H(2)O, in vivo hepatic sterol synthesis rates (per g liver per animal) increased between -1 and 5 days of age, decreased by 10 days of age, and increased again by 15 days of age. HMG-CoA reductase (HMGR) expression levels paralleled in vivo synthesis rates. Extra-hepatic sterol synthesis rates followed the same pattern as sterol synthesis rates in the liver. When sterol synthesis rates were converted to the mass of sterol synthesized per day, the liver synthesized 38.9 and the extra-hepatic tissues synthesized 63.9 mg cholesterol in the 26-day neonatal period. Comparing the amount of cholesterol accrued to that synthesized, one can conclude that the liver is a major source of sterol for the whole body during the neonatal period of the hamster. These results may help elucidate the cause(s) of reduced growth rates in neonates with liver disease or in neonates with compromised sterol synthesis rates.     

Cholesterol for Synthesis of Myelin Is Made Locally, Not Imported into Brain

Abstract: We examined whether cholesterol needed for myelin formation is locally synthesized or whether it comes from the circulation. The experimental design was to inject [³H]water and to use incorporation of label into brain cholesterol as a measure of the rate of accumulation of newly synthesized cholesterol in brain. The contribution of the circulation to this labeled cholesterol pool was minimized by repressing liver synthesis of cholesterol with a high cholesterol diet. The rate of accumulation of total cholesterol was calculated from the increasing amounts of sterol in brain regions at successive time intervals during development. Thus, accumulating cholesterol not explained as being newly synthesized (radioactive) could be assumed to have come from the circulation. Long-Evans rats, ranging in age from birth to 35 days, were injected intraperitoneally with [³H]water (0.3–1.0 mCi/g of body weight) and killed 2 h later. The brain was dissected into brainstem, cerebellum, and cerebral hemispheres, and total lipids were extracted. Cholesterol and its precursors were quantified by HPLC. The radioactivity associated with the sterol fractions and the specific activity of body water determined from serum were used to calculate the absolute amount of newly synthesized sterol. The rates of cholesterol synthesis were compared with the rates of accumulation of total cholesterol in each brain region. The rate of accumulation of total sterol (cholesterol and desmosterol) closely followed that of newly synthesized total sterol in all brain regions from the second through the fifth postnatal weeks. Thus, all sterol accumulation in brain during the period of rapid myelination can be explained by local synthesis; neither diet nor production of cholesterol by other organs plays a direct role in supplying cholesterol for myelination in brain.     

Rates of sterol synthesis in the liver and extrahepatic tissues of the SHR/N-corpulent rat, an animal with hyperlipidemia and insulin-independent diabetes

The SHR/N-corpulent rat is a new genetically obese strain that exhibits both insulin-independent diabetes and hyperlipidemia. The present studies were undertaken to characterize various parameters of cholesterol metabolism in this model. At 11 weeks of age, the obese animals had markedly elevated plasma cholesterol, triglyceride, glucose, and insulin concentrations and elevated hepatic triglyceride concentrations compared to their lean littermates. The additional cholesterol in plasma was carried in the fractions of density less than 1.006, 1.020-1.055, 1.055-1.095, and 1.095-1.21 g/ml. In the obese rats the level of free cholesterol in the liver was decreased significantly while that of cholesteryl ester showed little change. Hepatic sterol synthesis was markedly suppressed in the obese animals. However, the rate of sterol synthesis in the small intestine and other extrahepatic tissues generally remained unchanged. Although hepatic synthesis was suppressed, whole animal sterol synthesis in the obese rats was similar to that in the lean controls. This resulted because, in the obese animals, not only was the reduced rate of hepatic synthesis partly balanced by a greater than 70% increase in liver mass, but the mass of the small intestine and adipose tissue was also increased more than 30% and 4-fold, respectively, thereby making these tissues quantitatively more important sites of sterol synthesis. When obese rats were pair-fed to the intake of their lean littermates for 10 weeks, there was only a modest reduction in body weight and plasma cholesterol concentration, and the rate of hepatic sterol synthesis remained very low. The suppression of synthesis in the liver also persisted when the obese rats were fed surfomer, a drug that specifically blocks cholesterol absorption. In contrast, feeding cholestyramine restored the rate of hepatic sterol synthesis to that found in lean animals. Bile acid pool size in the obese males and females was 2.5-fold greater than in their lean controls. The suppression of hepatic sterol synthesis in this model may be due to a change in the entero-hepatic circulation of bile acids arising from an expanded pool or, alternatively, it may represent a compensatory response to overproduction of sterol and its precursors in the intestinal and adipose compartments.     

High density lipoprotein stimulates sterol translocation between intracellular and plasma membrane pools in human monocyte-derived macrophages

Binding of high density lipoprotein (HDL) to its receptor on cultured fibroblasts and aortic endothelial cells was previously shown to facilitate sterol efflux by initiation of translocation of intracellular sterol to the plasma membrane. After cholesterol-loaded human monocyte-derived macrophages were incubated with either [3H]mevalonolactone or lipoprotein-associated [3H]cholesteryl ester to radiolabel intracellular pools of sterol, incubation with HDL3 led to stimulation of 3H-labeled sterol translocation from intracellular sites to the cell surface which preceeded maximum 3H-labeled sterol efflux. A similar pattern was demonstrated for macrophages that were preloaded with cholesterol derived from either low density lipoprotein (LDL), acetyl-LDL, or phospholipase C-modified LDL. However, in macrophages that were not loaded with cholesterol, HDL3 stimulated net movement of 3H-labeled sterol from the plasma membrane into intracellular compartments, the opposite direction from that seen for cholesterol-loaded cells. A similar influx pattern was found in nonloaded macrophages and fibroblasts that were labeled with trace amounts of exogenous [3H]cholesterol. Cholesterol translocation from intracellular pools to the cell surface of cholesterol-loaded macrophages appeared to be stimulated by receptor binding of HDL, since chemical modification of HDL with tetranitromethane (TNM), which abolishes its receptor binding, reduced its ability to stimulate 3H-labeled sterol translocation and efflux. In nonloaded cells, however, the ability of HDL3 to stimulate sterol efflux and movement of sterol from the plasma membrane into intracellular pools was unaffected by TNM modification. Thus, binding of HDL to its receptor on cholesterol-loaded macrophages appears to promote translocation of intracellular cholesterol to the plasma membrane followed by cholesterol efflux into the medium. However, in nonloaded macrophages, HDL stimulates sterol movement from the plasma membrane into intracellular pools by a receptor-independent process.     

Cholesterol homeostasis in guinea pigs fed saturated and polyunsaturated fat diets

Whole body sterol balance, hepatic 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase activity, hepatic low-density lipoprotein (LDL) receptor levels and net tissue cholesterol concentrations were determined in guinea pigs fed either a corn oil- or lard-based purified diet for 6-7 weeks. In comparison to the saturated lard diet, the polyunsaturated corn oil diet resulted in a 34% reduction in plasma total cholesterol levels (P less than 0.02) and a 40% lower triacylglycerol level (P less than 0.02). Feeding the corn oil diet altered very-low-density lipoprotein (VLDL) and LDL composition; the percent cholesterol ester in both particles was decreased and the relative percentages of VLDL triacylglycerol and LDL phospholipid increased. The ratio of surface to core components of LDL from corn oil-fed guinea pigs was significantly higher compared to LDL from animals fed lard. Dietary fat quality had no effect on fecal neutral or acidic steroid excretion, net tissue accumulation of cholesterol, whole body cholesterol synthesis or gallbladder bile composition. Consistent with these results was the finding that fat quality did not alter either expressed (non-phosphorylated) or total hepatic HMG-CoA reductase activities. The hepatic concentrations of free and esterified cholesterol were significantly increased in corn oil-fed animals, as were cholesterol concentrations in intestine, adipose tissue, muscle and total carcass. Analysis of receptor-mediated LDL binding to isolated hepatic membranes demonstrated that the polyunsaturated corn-oil based diet caused a 1.9-fold increase in receptor levels (P less than 0.02). The data indicate that the hypocholesterolemic effects of dietary polyunsaturated fat in the guinea pig are not attributable to changes in endogenous cholesterol synthesis or catabolism but rather may result from a redistribution of plasma cholesterol to body tissue due to an increase in tissue LDL receptors.     

Fluorescence and multiphoton imaging resolve unique structural forms of sterol in membranes of living cells

Although cholesterol is an essential component of mammalian membranes, resolution of cholesterol organization in membranes and organelles (i.e. lysosomes) of living cells is hampered by the paucity of nondestructive, nonperturbing methods providing real time structural information. Advantage was taken of the fact that the emission maxima of a naturally occurring fluorescent sterol (dehydroergosterol) were resolvable into two structural forms, monomeric (356 and 375 nm) and crystalline (403 and 426 nm). Model membranes (sterol:phospholipid ratios in the physiological range, e.g. 0.5-1.0), subcellular membrane fractions (plasma membranes, lysosomal membranes, microsomes, and mitochondrial membranes), and lipid rafts/caveolae (plasma membrane cholesterol-rich microdomain purified by a nondetergent method) contained primarily monomeric sterol and only small quantities (i.e. 1-5%) of the crystalline form. In contrast, the majority of sterol in isolated lysosomes was crystalline. However, addition of sterol carrier protein-2 in vitro significantly reduced the proportion of crystalline dehydroergosterol in the isolated lysosomes. Multiphoton laser scanning microscopy (MPLSM) of living L-cell fibroblasts cultured with dehydroergosterol for the first time provided real time images showing the presence of monomeric sterol in plasma membranes, as well as other intracellular membrane structures of living cells. Furthermore, MPLSM confirmed that crystalline sterol colocalized in highest amounts with LysoTracker Green, a lysosomal marker dye. Although crystalline sterol was also detected in the cytoplasm, the extralysosomal crystalline sterol did not colocalize with BODIPY FL C(5)-ceramide, a Golgi marker, and crystals were not associated with the cell surface membrane. These noninvasive, nonperturbing methods demonstrated for the first time that multiple structural forms of sterol normally occurred within membranes, membrane microdomains (lipid rafts/caveolae), and intracellular organelles of living cells, both in vitro and visualized in real time by MPLSM.     

Influence of sterol structure on yeast plasma membrane properties

Fluorescence anisotropy measurements indicated that physical changes occured in the lipids of plasma membranes of yeast sterol mutants but not in the plasma membrane of an ergosterol wild-type. Parallel experiments with model membrane liposomes verified that the physical changes in lipids observed in the sterol mutants are dependent on the sterol present and not the phospholipid composition. In addition, the physical changes in lipids observed in liposomes derived from wild-type phospholipids were eliminated by addition of ergosterol but persisted in the presence of cholesterol, cholestanol, ergostanol, or sterols from the sterol mutants. No physical changes in lipids were observed, however, in plasma membranes from a sterol auxotroph, even when the auxotroph was grown on cholesterol or cholestanol. The lack of physical changes in lipids in the sterol auxotroph may reflect the ability of the auxotroph to modify its phospholipid composition with respect to its sterol composition. These results indicate that high specificity ‘sparking’ sterol is not required for the regulation of overall bulk lipid properties of the plasma membrane.