Effect of lipid composition on the transfer of sterols mediated by non-specific lipid transfer protein (sterol carrier protein2).

The rate of non-specific lipid transfer protein (nsLTP)-mediated exchange is independent of structure for dissimilar sterols: cholesterol, lanosterol, sitosterol and vitamin D-3. Conversely, the nsLTP-mediated exchange of cholesterol is markedly affected by the phospholipid composition of the donor liposome. Negatively charged phosphatidylglycerols strikingly increase cholesterol exchange in the presence of nsLTP while not altering the exchange in the absence of nsLTP. The presence of unsaturated acyl chains in the phospholipid enhances exchange. Sphingomyelin drastically decreases cholesterol exchange, as does di-O-alkylphosphatidylcholine. Decreased exchange produced by these substitutions can be reversed by addition of phosphatidylcholine. The presence of an acyl group and a negative charge in the phospholipid are critical for the nsLTP-mediated transfer of cholesterol. In addition to these studies on composition of the donor membrane, the charge on the membrane also appears critical. Maximal exchange rates accompany optimization of potential interaction of negatively charged surface and the basic nsLTP. The nsLTP also mediates an approximately equal rate of exchange of cholesterol and phosphatidylcholine. However, approaching equilibrium, only half of the phospholipid can be exchanged while there is exchange of about 90% of cholesterol. Thus, it appears that only the phospholipid in an outer membrane layer may be available whereas cholesterol is fully available. Therefore, in contrast to a 'carrier' model we suggest that nsLTP facilitates exchange by binding to the membranes, and binding is highly dependent upon lipid composition. Once bound, the protein functions as a bridge between membranes, thus, facilitating exchange.

Microsomal long chain fatty acyl-CoA transacylation: differential effect of sterol carrier protein-2.

The recent discovery that sterol carrier protein-2 (SCP-2) binds long chain++ (LCFA-CoA) with high affinity (A. Frolov et al., J. Biol. Chem. 271 (1997) 31878-31884) suggests new possible functions of this protein in LCFA-CoA metabolism. The purpose of the present investigation was to determine whether SCP-2 differentially modulated microsomal LCFA-CoA transacylation to cholesteryl esters, triacylglycerols, and phospholipids in vitro. Microsomal acyl-CoA:cholesterol acyltransferase (ACAT) activity measured with liposomal membrane cholesterol donors depended on substrate LCFA-CoA level, mol% cholesterol in the liposomal membrane, and total amount of liposomal cholesterol. As compared to basal activity without liposomes, microsomal ACAT was inhibited 30-50% in the presence of cholesterol poor (1.4 mol%) liposomes. In contrast, cholesterol rich (>25 mol%) liposomes stimulated ACAT up to 6.4-fold compared to basal activity without liposomes and nearly 10-fold as compared to cholesterol pool (1.4 mol%) liposomes. Increasing oleoyl-CoA reversed the inhibition of microsomal ACAT by cholesterol poor (1.4 mol%) liposomes, but did not further stimulate ACAT in the presence of cholesterol rich (35 mol%) liposomes. In contrast, high (100 microM) oleoyl-CoA inhibited ACAT nearly 3-fold. This inhibition was reversed by LCFA-CoA binding proteins, bovine serum albumin (BSA) and SCP-2. SCP-2 was 10-fold more effective (mole for mole) than BSA in reversing LCFA-CoA inhibited microsomal ACAT. Concomitantly, under conditions in which SCP-2 stimulated ACAT it equally enhanced transacylation of oleoyl-CoA into phospholipids, and 5.2-fold enhanced oleoyl-CoA transacylation to triacylglycerols. In summary, SCP-2 appeared to exert its greatest effects on microsomal transacylation in vitro by reversing LCFA-CoA inhibition of ACAT and by differentially targeting LCFA-CoA to triacylglycerols. These data suggest that the high affinity interaction of SCP-2s with LCFA-CoA may be physiologically important in microsomal transacylation reactions.

Cytosolic modulators of activities of microsomal enzymes of cholesterol biosynthesis. Effects of Acyl-CoA inhibition and cytosolic Z-protein.

Physiological concentrations of long-chain fatty acyl-CoAs have now been shown to inhibit microsomal methyl sterol oxidase. Acyl-CoA inhibition of hydroxymethylglutaryl-CoA reductase as well as methyl sterol oxidase can be either prevented or reversed by the addition of purified Z-protein (fatty acid-binding protein). Concomitantly, Z-protein addition decreases the extent of binding of radioactively labeled oleoyl-CoA to microsomal membranes. Free heme also inhibits hydroxymethylglutaryl-CoA reductase, and Z-protein reverses the extent of observed inhibition by binding heme analogous to the effect observed with acyl-CoAs. Similarly, Z-protein reverses substrate inhibition of acyl-CoA:cholesterol acyltransferase at high concentrations of acyl-CoA substrate. All these observations are consistent with the suggestion that, by binding acyl-CoAs and other enzyme effectors such as free heme, Z-protein modulates the effects of fluctuations of concentrations of major cellular metabolites. Furthermore, because the concentration of Z-protein is very low in rapidly growing hepatomas, such tumors may be very poorly buffered against the effects of acyl-CoAs, free fatty acids, heme and other effectors that may vary markedly by either altered metabolism or release of metabolites from necrotic tumor tissue.

Intracellular trafficking of sterols.

Cavalier-Smith (1981) has identified 22 characters that are universally present in eukaryotes but absent in prokaryotes. Of these, he argues that one, exocytosis, might have been the driving force behind the evolution of modern eukaryotic cells. Bloom and Mouritsen (1988) further argue that sterols may have removed an evolutionary bottleneck to cytosis. Therefore, the advent of sterols in membranes might have been the single feature that led to eukaryote evolution. The evolutionary advantage conferred by cholesterol is associated primarily with plasma membrane function, since the majority of cellular free cholesterol resides in that membrane. However, sterol synthesis occurs in the ER; therefore, the cell must have a mechanism for transporting sterol to the plasma membrane and its regulation. As has been pointed out in this review, much remains to be elucidated in the study of intracellular sterol trafficking. To date, neither diffusion nor vesicle-mediated transport can be fully confirmed or ruled out. Microtubule and microfilament involvement appears important in some routes (e.g., mitochondria) but not in others. In addition, trafficking roles of cytoplasmic lipoproteinlike particles have not been addressed. Finally, although some "sterol carrier proteins" demonstrate the ability to mediate intervesicular transfer of cholesterol in vitro, the true physiological role of these proteins remains obscure. Future research in this field awaits the refinement of available techniques. Particularly valuable would be cytochemical methods for detection of sterol at the ultrastructural level. Possibly, direct microscopic visualization of radiolabeled components in cells represents the necessary approach. Purification of elements carrying newly synthesized sterols would allow the proteins mediating transport to be identified. Continued analysis of mutants defective in transport, such as in type C Niemann-Pick disease, will shed light on this complex problem. The importance of extracellular trafficking of cholesterol owing to its involvement in the progression of atherosclerosis, has been emphasized in recent years. Little emphasis has been placed on intracellular trafficking of sterol; however, it can be argued that such transport also plays a major role in atherosclerosis, possibly by fueling retrotransport of cholesterol to the liver and secretion in the bile. Therefore, we hope this review will serve to stimulate research interest in this area.

Deletion of murine Arv1 results in a lean phenotype with increased energy expenditure.

BACKGROUND: ACAT-related enzyme 2 required for viability 1 (ARV1) is a putative lipid transporter of the endoplasmic reticulum that is conserved across eukaryotic species. The ARV1 protein contains a conserved N-terminal cytosolic zinc ribbon motif known as the ARV1 homology domain, followed by multiple transmembrane regions anchoring it in the ER. Deletion of ARV1 in yeast results in defective sterol trafficking, aberrant lipid synthesis, ER stress, membrane disorganization and hypersensitivity to fatty acids (FAs). We sought to investigate the role of Arv1 in mammalian lipid metabolism. METHODS: Homologous recombination was used to disrupt the Arv1 gene in mice. Animals were examined for alterations in lipid and lipoprotein levels, body weight, body composition, glucose tolerance and energy expenditure. RESULTS: Global loss of Arv1 significantly decreased total cholesterol and high-density lipoprotein cholesterol levels in the plasma. Arv1 knockout mice exhibited a dramatic lean phenotype, with major reductions in white adipose tissue (WAT) mass and body weight on a chow diet. This loss of WAT is accompanied by improved glucose tolerance, higher adiponectin levels, increased energy expenditure and greater rates of whole-body FA oxidation. CONCLUSIONS: This work identifies Arv1 as an important player in mammalian lipid metabolism and whole-body energy homeostasis.

Luteinized rat ovaries contain a sterol carrier protein.

Highly luteinized rat ovaries contain a soluble 13,000 mol wt factor which binds [3H]cholesterol and enhances cholesterol transfer from phospholipid vesicles to mitochondria. The ovarian cholesterol transfer protein was purified 1200-fold. It has a basic isoelectric point, is heat stable, and has an amino acid composition similar to that reported for rat liver sterol carrier protein2. Antisera raised against preparations of rat liver sterol carrier protein2 precipitated labeled cholesterol associated with the ovarian 13,000 mol wt fraction. A line of partial identity was obtained when the ovarian fractions and purified rat liver sterol carrier protein2 were run against these antisera in double immunodiffusion. We conclude that luteinized rat ovaries contain a sterol carrier protein with properties similar to hepatic sterol carrier protein2. This protein may facilitate the intracellular distribution of cholesterol in ovarian cells.

Differential capacity for cholesterol transport and processing in large and small rat luteal cells.

The aim of this investigation was to determine whether a specific luteal subpopulation is responsible for the hypertrophic development of the corpus luteum at midpregnancy in the rat and to determine whether there was an underlying cellular basis for the differential production of steroids by the luteal cell subtypes. To examine this, we have dispersed and separated rat luteal steroidogenic cell populations into small (< 20 microns) and large (> 30 microns) cell types by elutriation. Luteal cells were examined at early (day 3) and midpregnancy (day 14) for differences in protein content and for differential expression of proteins required for steroid production. Specific proteins examined include the P450side chain cleavage enzyme (P450scc), adrenodoxin and adrenodoxin reductase, proteins required for cholesterol conversion to progestagens in the corpus luteum, and sterol carrier protein-2 (SCP2), a protein thought to be involved in intracellular cholesterol transport. The cytochrome P450(17)alpha hydroxylase (P450(17)alpha), a key enzyme responsible for androgen biosynthesis was also examined in the isolated luteal cells. The large luteal cell population displayed an increase in total cellular protein content while the small cell type did not change with luteal development. In addition, the large luteal cells expressed proteins unique to or elevated in that cell type. Analysis by two-dimensional polyacrylamide gel electrophoresis revealed that the large cell-specific proteins had molecular masses of 23 K and 32 K and that a 14 kilodalton (kDa) protein was elevated in the large cell type relative to the small cells. The small luteal cell on day 3 of pregnancy expressed a 36 kDa protein which was barely detectable in the large cell. Immunocytochemical and Western analysis indicated that the large luteal cells contain 5.3-fold more SCP2 (P < 0.05) and 5.6-fold more P450scc (P < 0.001) relative to the small cell type. Immunocytochemical staining of adrenodoxin and adrenodoxin reductase indicate these proteins were elevated in the large cell as well. Human CG administration stimulated P450(17)alpha expression mainly in the large luteal cell population. The results of this investigation indicate, for the first time, that the large luteal cell of the rat, in contrast to the small cell type, undergoes a dramatic increase in protein content with luteal development, and that with this increase in cell size there is a concomitant increase in the large cell capacity to produce steroids. This occurs as a direct result of the enhanced expression of SCP2, P450scc, adrenodoxin and adrenodoxin reductase, proteins specifically required to transport and process cholesterol for steroid production in the large luteal cell.

Regulation of acyl coenzyme A:cholesterol acyltransferase in the luteinized rat ovary: observations with an improved enzymatic assay.

The corpus luteum of the rat stores large quantities of cholesteryl ester which is synthesized by acyl coenzyme A:cholesterol acyltransferase (ACAT), a microsomal enzyme. In previous studies of ACAT, assays that were probably substrate limited were employed. To reevaluate the regulation of ACAT in the ovaries of PMSG-hCG-primed rats, we used an improved assay in which exogenous cholesterol is provided as a dispersion in Triton WR-1339. Assayed in the absence of exogenous cholesterol, ACAT activity increased between days 1--8 post-hCG treatment and then declined between days 8--15. When exogenous cholesterol was included, a similar pattern of ACAT activity was found, but rates of cholesteryl ester formation were 2.5- to 4.5-fold greater. These changes in ACAT paralleled the previously reported levels of ovarian cholesteryl esters. Treatment of rats with 4-aminopyrazolopyrimidine, a drug that lowers blood cholesterol levels and reduces ovarian sterol ester stores, resulted in a lowered ACAT activity measured in the absence of exogenous sterol. However, enzyme activity was similar to that in controls when assayed in the presence of cholesterol. Inhibitors of steroidogenesis (aminoglutethimide and cycloheximide) promoted, within 4 h, ovarian sterol ester storage and resulted in increased ACAT activities measured in the absence of cholesterol. However, in the presence of exogenous sterol, the ACAT activities of controls were equal to those of drug-treated animals. When PMSG-hCG-primed animals received iv injections of hCG on day 8 post-hCG, ovarian sterol ester stores were markedly depleted within 2 h. The ovarian ACAT activity of hCG-treated rats measured without cholesterol was significantly lower than that of controls. With cholesterol, ACAT activities of hCG-treated rats were similar to those in controls. Our findings indicate that the entry of cholesterol into the ACAT substrate pool may be a major factor controlling the rates of cholesteryl ester synthesis in the rat corpus luteum.

Prostaglandin F2 alpha mediates ovarian sterol carrier protein-2 expression during luteolysis.

In the corpus luteum, prostaglandin F2 alpha (PGF2 alpha) appears to be a physiological agent with both antisteroidogenic and luteolytic actions. It is hypothesized that the antisteroidogenic action of PGF2 alpha acts through altered transport of cholesterol to the mitochondrial cytochrome P450 side-chain cleavage enzyme (P450scc). However, the effect of PGF2 alpha on the expression of the putative cholesterol transport protein, sterol carrier protein-2 (SCP2; 13.2 kilodaltons), has not been examined. In this study, the decline in serum progesterone after PGF2 alpha injection was examined in parallel with altered ovarian SCP2, P450scc, and 3 beta-hydroxysteroid dehydrogenase (3 beta HSD) protein and messenger RNA (mRNA) levels. Rats (28 days old) were treated with 8 IU PMSG to induce follicular development and ovulation. Ten days after ovulation, animals were treated with PGF2 alpha (single or multiple injections; 100-250 micrograms each) or left untreated. Ovarian SCP2, P450scc, and 3 beta HSD protein and mRNA levels were examined 0 (time zero), 4, and 8 h post-PGF2 alpha treatment using Western and Northern blot analysis. SCP2 mRNA levels were also examined using a highly sensitive ribonuclease protection assay that detects a 429-base pair SCP2-mRNA specific sequence. The results indicate that serum progesterone was significantly reduced 4 and 8 h after PGF2 alpha injections (P < 0.001; n = 6/time point). The decline in progesterone paralleled a 50-60% reduction in 3 beta HSD protein and mRNA levels by 4 h post-PGF2 alpha. Protein and mRNA levels for 3 beta HSD returned to control values by 8 h post-PGF2 alpha treatment. P450scc expression was also reduced at 4 h (44-54%), but by 8 h, both protein and mRNA levels had increased above the normal control levels (P < 0.02). In contrast, the 0.8-kilobase SCP2-specific mRNA transcript was reduced to 50% and 80% of the pre-PGF2 alpha treatment level at 4 and 8 h, respectively (P < 0.01). SCP2 ribonuclease protection assay analysis also indicated that SCP2 mRNA levels were reduced 65% (P < 0.03) and 85% (P < 0.01) by 4 and 8 h post-PGF2 alpha treatment compared to those in time zero ovarian tissue. Consistent with the loss of SCP2 mRNA expression, Western blot analysis indicated that a 15-kilodalton SCP2-immunoreactive protein (presumably the pro-SCP2 form) was significantly reduced or absent in the PGF2 alpha treated animals (P < 0.04).(ABSTRACT TRUNCATED AT 400 WORDS)

Differential expression of hepatic sterol carrier proteins in the streptozotocin-treated diabetic rat.

Sterol carrier protein-2 (SCP2) is a 13.2-kilodalton protein that has been implicated in intracellular cholesterol transport, whereas a related sterol carrier protein, sterol carrier protein-X (SCPx; 58 kilodaltons) has been suggested to function also in the beta-oxidation of fatty acids. Although diabetes-related hyperlipidemia and altered cholesterol metabolism have been extensively studied, the intracellular cholesterol transport capacity during hyperglycemic states has not been examined. The fact that beta-oxidation is increased in diabetes whereas hepatic cholesterol metabolism is reduced suggests that differential expression of these sterol carrier proteins may accompany diabetic dyslipidemia. In this study, SCP2 protein levels were reduced by 60% in mildly hypercholesterolemic (cholesterol, > 130 and < 150 mg/dl; P < 0.01) diabetic rats and by 90% in severely hypercholesterolemic (cholesterol, > 150 mg/dl; P < 0.002) diabetic animals. In contrast, hepatic SCPx protein expression increased (3.5-fold) after diabetes induction with streptozotocin (STZ). The decline in SCP2 was inversely related to serum cholesterol levels. Hepatic SCP messenger RNA levels examined by ribonuclease protection assay demonstrated that hepatic SCP messenger RNA was increased 2-fold in diabetic animals. Northern blot analysis indicated that both the 0.8-kilobase SCP2-specific and the 2.1-kilobase SCPx-specific transcripts increased after STZ injection. SCPx protein induction preceded the decline in SCP2 by 4-5 days. Insulin treatment reversed the increase in SCPx and prevented the decline in SCP2. We conclude that SCP2 and SCPx are differentially expressed in the STZ-diabetic rat and suggest that this change in SCP expression should be considered a potential contributing mechanism through which cholesterol metabolism may be altered in diabetes.

Protein kinase C catalyzed phosphorylation of sterol carrier protein 2.

The transport of cholesterol to the inner mitochondrial membrane, a key step in steroidogenesis, is subject to hormonal modulation that, at least in part, could be mediated by protein phosphorylation. This step is stimulated by sterol carrier protein 2 (SCP2) and Ca2+. To explore whether SCP2 itself is a potential control point for regulation by Ca2+-dependent phosphorylation we investigated whether highly purified SCP2 could serve as a substrate for major type Ca2+ and non-Ca2+-dependent protein kinases. Phosphorylation by calmodulin protein kinase II (CaM-PK II), myosin light chain kinase (MLCK), cAMP-dependent kinase (PKA) and protein kinase C (PKC) was monitored under optimal conditions for each enzyme. PKA, CaM-PK II and MLCK catalyzed the radiolabeling of histone 2A, synapsin I and myosin light chain (MLC), known substrates for these kinases, respectively, yet no phosphate transfer to SCP2 was observed. In contrast, PKC from two different sources (rat and calf brain) effectively catalyzed the phosphorylation of the highly purified SCP2. The phosphorylation of SCP2 depended on the addition of Ca2+ and phospholipids and was completely blocked by Polymyxin B, a PKC inhibitor. PKC catalyzed phosphorylation of SCP2 displayed a similar dependence on the concentration of ATP. Lineweaver Burk plots of the data indicate Km values for ATP of approximately 6 microM for the phosphorylation of SCP2. Our results, which have revealed for the first time that SCP2 is a substrate for PKC, are consistent with the possibilities that the control of steroidogenesis by tropic hormones and by PKC activation are mediated, at least in part, by the phosphorylation/dephosphorylation of SCP2.

Estradiol regulation of sterol carrier protein-2 independent of cytochrome P450 side-chain cleavage expression in the rat corpus luteum.

A major action of estradiol in the corpus luteum of the pregnant rat is to increase the supply of cholesterol substrate for progesterone production by stimulating both cholesterol synthesis and uptake. To determine whether this steroid also affects cholesterol metabolism and transport, estradiol's action on the expression of cytochrome P450 side-chain cleavage enzyme (P450scc) and the cholesterol transport protein, sterol carrier protein-2 (SCP2), was examined. Mitochondria isolated from corpora lutea of estradiol-treated rats secreted significantly more progestagen than mitochondria of control corpora lutea. Several findings indicate that estradiol enhances cholesterol transport and availability to the P450scc rather than affects the expression of this enzyme: 1) the difference in mitochondrial progestagen synthesis induced by estradiol was obliterated by the presence of 25-hydroxycholesterol; 2) immunoblotting of P450scc indicated no stimulatory effect of estradiol on the amount of enzyme; and 3) levels of P450scc mRNA were not increased by estradiol. Whereas estradiol had no stimulatory effect on P450scc it caused a mark (3-fold) increase in the mitochondrial content of SCP2. Thus, the increase in luteal progestagen synthesis stimulated by estradiol appears to be associated with an increase in mitochondrial SCP2 and is independent of luteal P450 content or message.

Design, synthesis, and structure--activity relationship studies for a new imidazole series of J774 macrophage specific acyl-CoA:cholesterol acyltransferase (ACAT) inhibitors.

Acyl-CoA:cholesterol acyltransferase (ACAT) is the primary enzyme involved in intracellular cholesterol esterification. Arterial wall infiltration by macrophages and subsequent uncontrolled esterification of cholesterol leading to foam cell formation is believed to be an important process which leads to the development of fatty streaks. Inhibitors of the ACAT enzyme may retard this atherogenic process. We have recently discovered a series of imidazoles which are potent in vitro ACAT inhibitors in the J774 macrophage cell culture assay. This paper will describe the design, synthesis, and structure--activity relationship for this very potent series of compounds.

Acyl CoA:cholesterol acyltransferase (ACAT) inhibitors: synthesis and structure-activity relationship studies of a new series of trisubstituted imidazoles.

A series of 4,5-diaryl-2-(substituted thio)-1H-imidazoles has been synthesized and demonstrated to be potent inhibitors of acyl-CoA:cholesterol acyltransferase (ACAT). The design, synthesis, and structure-activity relationships for this series are reported herein. One of the compounds from this series, N'-(2,4-difluorophenyl)-N-[5-[(4,5-diaryl-1H-imidazol-2- yl)thio]pentyl]-N-heptylurea (DuP 128), was selected for development as an intestinally active ACAT inhibitor. DuP 128 is a potent ACAT inhibitor in vitro and in vivo, inhibiting ACAT in rat hepatic microsomes with an IC50 = 10 nM and possessing potent antihypercholesterolemic activity in vivo.

Sterol carrier protein 2: a role in steroid hormone synthesis?

The intracellular movement of cholesterol is an important regulated step in the process of steroidogenesis. However, the molecular mechanisms by which cholesterol is translocated to key organelles, including the mitochondria, remains poorly understood. Lipid transfer proteins may have an important function in this process. One candidate lipid transfer protein is sterol carrier protein 2 (SCP2). This 13.2 kDa protein enhances the movement of cholesterol between vesicles and isolated mitochondria. It also stimulates mitochondrial pregnenolone synthesis. When introduced into intact cells, anti-SCP2 antibodies reduce steroid secretion. Moreover, expression of SCP2 in COS cells engineered to produce progestins increases steroid formation. SCP2 is abundant in steroidogenic glands and the pattern of SCP2 gene expression is consistent with a role for the protein in hormone synthesis: SCP2 transcripts are more prominent in the most steroidogenic compartments of the ovary and tropic hormones that stimulate steroidogenesis increase SCP2 gene expression. Other evidence that suggests that SCP2 plays important roles in cellular function includes a remarkable conservation of primary structure across species. The mechanisms by which SCP2 promotes intracellular sterol movement have not been elucidated. The protein appears to bind sterols and is synthesized with a 20 amino acid N-terminal "pro-" sequence that may serve to target SCP2 to mitochondria. In addition, the C-terminus of SCP2 contains a peroxisome-targeting sequence. SCP2 is derived from a large gene that encodes transcripts that are translated into larger proteins of 30 and 58 kDa. The 58 kDa protein, which has some structural homologies with thiolases, seems to be specifically targeted to peroxisomes whereas SCP2 has a broader subcellular distribution. The significance of the peroxisome association of SCP2 and steroidogenesis has not been disclosed. However, diseases of peroxisome function, including adrenoleukodystrophy and Zellweger syndrome, have notable deficits in steroid and bile acid metabolism, thus linking peroxisomes and steroidogenesis. SCP2 is deficient in fibroblasts of patients with these diseases.

Similarity between the amino-terminal portion of mammalian 58-kD sterol carrier protein (SCPx) and Escherichia coli acetyl-CoA acyltransferase: evidence for a gene fusion in SCPx.

A computer analysis of the amino acid sequences of rat and human 58-kD sterol carrier protein and Escherichia coli acetyl-CoA acyltransferase reveals that the two proteins have a segment of about 350 residues with strong sequence similarity. The ALIGN comparison scores for the rat and human sterol carrier proteins and the E. coli enzyme are 8.25 and 8.8 SD, respectively. The catalytically active cysteine of E. coli acetyl-CoA acyltransferase (cysteine 91) aligns with cysteine 93 and cysteine 94 on human and rat 58-kD sterol carrier protein, respectively.

Characterization of a cDNA encoding rat sterol carrier protein2.

Sterol carrier protein2 (SCP2) is a 13.2-kD protein that is thought to be involved in the intracellular transport of cholesterol. Using synthetic oligonucleotides based on the protein sequence of SCP2, a clone (SP43) was isolated from a rat liver cDNA library. The DNA sequence revealed that the cDNA could encode a polypeptide of 273 amino acids (28.9 kD) or 143 amino acids (15.3 kD) in which the carboxy-terminal 123 amino acids are identical to the SCP2 protein. RNA blot hybridization revealed that a variety of rat tissues contain a homologous RNA of a size similar to SP43 (approximately 1.5 kb). Levels of SCP2 mRNA increased in parallel with cytochrome P450scc mRNA in the immature gonadotropin-primed rat ovary. The isolation of a cDNA clone encoding SCP2 will facilitate studies on its role in cholesterol metabolism.

cDNAs encoding members of a family of proteins related to human sterol carrier protein 2 and assignment of the gene to human chromosome 1 p21----pter.

Sterol carrier protein 2 (SCP2) is believed to play a key role in intracellular lipid movement. Here we report the cloning and nucleotide sequences of cDNAs encoding SCP2-related proteins of 58.85 kD and 30.8 kD and the assignment of the SCP2 gene to human chromosome 1 p21-pter. The SCP2-related proteins share common deduced carboxyl amino acid sequences with SCP2 and the cDNAs have a common 3' untranslated nucleotide sequence. The mRNAs encoding these proteins increased in a coordinate fashion as human placental cytotrophoblasts differentiated into syncytiotrophoblasts in culture. Our observations document the existence of a family of related proteins encoded by the human SCP2 gene.

Sterol carrier protein-2 stimulates intermembrane sterol transfer by direct membrane interaction.

It is unclear how the cytosolic sterol carrier protein-2 (SCP-2) binds sterols and enhances sterol transfer between membranes. Therefore, human recombinant SCP-2 was used in conjunction with phase fluorometry, dialysis, and chemical labeling techniques to show if a direct membrane effect accounted for this activity. SCP-2 directly interacted with L-cell fibroblast plasma membrane vesicles as determined by increased fluorescence anisotropy of coumarin-labeled protein (CPM-SCP-2). Furthermore, a new fluorescence lifetime component due to plasma membrane-bound CPM-SCP-2 was observed. Dialysis studies with 3H- cholesterol loaded plasma membranes indicated that SCP-2, added to the donor compartment, stimulated sterol transfer whether or not the dialysis membrane was permeable to SCP-2. Nevertheless, ligand-binding experiments indicated that chemically blocking the SCP-2 sterol binding site inhibited the ability of SCP-2 to enhance sterol transfer between plasma membrane vesicles. SCP-2 did not stimulate plasma membrane fusion. Addition of SCP-2 to plasma membranes increased the anisotropy plasma membrane proteins covalently reacted with CPM, but not that of lipids labeled with the fatty acid analogue octadecyl rhodamine B. In conclusion, the data are consistent with SCP-2 stimulating intermembrane sterol transfer by direct interaction with sterol in the membrane and enhancing its desorption from the membrane.

A potential role for sterol carrier protein-2 in cholesterol transfer to mitochondria.

Mitochondrial cholesterol oxidation rapidly depletes cholesterol from the relatively cholesterol-poor mitochondrial membranes. However, almost nothing is known regarding potential mechanism(s) whereby the mitochondrial cholesterol pool is restored. Since most exogenous cholesterol enters the cell via the lysosomal pathway, this could be a source of mitochondrial cholesterol. In the present study, an in vitro fluorescent sterol transfer assay was used to examine whether the lysosomal membrane could be a putative cholesterol donor to mitochondria. First, it was shown that spontaneous sterol transfer from lysosomal to mitochondrial membranes was very slow (initial rate, 0.316 +/- 0.032 pmol/min). This was due, in part, to the fact that 90% of the lysosomal membrane sterol was not exchangeable, while the remaining 10% also had a relatively long half-time of exchange t(1/2) = 202 +/- 19 min. Second, the intracellular sterol carrier protein-2 (SCP-2) and its precursor (pro-SCP-2) increased the initial rate of sterol transfer from the lysosomal to mitochondrial membrane by 5.2- and 2.0-fold, respectively, but not in the reverse direction. The enhanced sterol transfer was due to a 3.5-fold increase in exchangeable sterol pool size and to induction of a very rapidly (t(1/2) = 4.1 +/- 0.6 min) exchangeable sterol pool. Confocal fluorescence imaging and indirect immunocytochemistry colocalized significant amounts of SCP-2 with the mitochondrial marker enzyme cytochrome oxidase in transfected L-cells overexpressing SCP-2. In summary, SCP-2 and pro-SCP-2 both stimulated molecular sterol transfer from lysosomal to mitochondrial membranes, suggesting a potential mechanism for replenishing mitochondrial cholesterol pools depleted by cholesterol oxidation.