The non-specific lipid transfer protein (sterol carrier protein 2) from rat and bovine liver

The non-specific lipid transfer protein (nsL-TP) purified from rat and bovine liver accelerates the transfer of all common diacylglycerophospholipids, cholesterol as well as glycosphingolipids and gangliosides between membranes. These proteins have molecular weights in the order of 14 500 and are highly basic (isoelectric points between 8.5 and 9.5). The primary structure of nsL-TP from bovine liver has been elucidated yielding a single polypeptide chain of 121 aminoacid residues. The protein contains one cysteine residue, essential for transfer activity, a single tryptophan residue and lacks histidine, arginine and tyrosine residues. Rat liver nsL-TP was found to be identical to sterol carrier protein 2, stimulating the microsomal conversion of intermediates between lanosterol and cholesterol. Evidence was presented that nsL-TP binds cholesterol, suggesting that it acts as a carrier. On the other hand, failure to bind phospholipids disagrees with this proposed mode of action. A sensitive enzyme immunoassay was developed to determine levels of nsL-TP in rat tissues. By use of this assay, nsL-TP was found to be most prominently present in liver and intestinal mucosa (0.78 and 0.46 microgram nsL-TP per mg protein in 105 000 X g supernatant, respectively). Subfractionation studies showed that approx. 70% of nsL-TP was present in the membrane-free cytosol. However, application of an immunosorbent-purified antibody and protein A-linked gold particles to rat liver slices demonstrated a concentration of label over the peroxisomes. By way of immunoblotting it was shown that nsL-TP was absent from peroxisomes and that the immunoreactive material was a protein of mol. wt. 58 000. nsL-TP is capable of mediating net transfer of cholesterol to membranes, deficient in this lipid. Under such conditions of net transfer, nsL-TP stimulated the microsomal esterification of cholesterol and its conversion to pregnenolone by adrenal mitochondria. Levels of nsL-TP in Reuber H35 hepatoma cells was six per cent of that found in rat hepatocytes. This very low level of nsL-TP had no effect on de novo cholesterol biosynthesis and intracellular cholesterol esterification. These results raise doubts as to whether nsL-TP has a function in in situ cholesterol metabolism.     

Nonspecific lipid transfer protein (sterol carrier protein-2) is located in rat liver peroxisomes

Intracellular localization of nonspecific lipid transfer protein (nsLTP) in rat hepatocytes was investigated by immunoblot analysis of the subcellular fractions and immunoelectron microscopy, using affinity-purified antibody against nsLTP. Immunoblot analysis showed that the protein exists in the peroxisomal and cytosolic fractions. Further study indicated that nsLTP exists in the soluble subfraction of the peroxisomes. Immunoelectron microscopic observation revealed that nsLTP is highly concentrated in the matrices of the peroxisomes. From these results, we concluded that nsLTP mainly exists in the matrix of the peroxisomes. The role of nsLTP is discussed.     

Nonspecific lipid transfer protein (sterol carrier protein-2) defective in patients with deficient peroxisomes

The biosynthesis and intracellular localization of nonspecific lipid transfer protein (nsLTP) in control human subjects and in patients with peroxisome-deficient disorders were investigated. The molecular mass of human nsLTP was indistinguishable from that of rat nsLTP (13 kDa) by immunoblot analysis. Intracellular localization was identical with that of catalase, a marker enzyme of peroxisomal matrix, by a double immunofluorescence study. The nsLTP was deficient in liver tissues or fibroblasts from patients with peroxisome-deficient disorders such as Zellweger syndrome and neonatal adrenoleukodystrophy (ALD). Pulse-chase experiments showed that nsLTP was synthesized as a large precursor in both the control and Zellweger fibroblasts. However, the processing to the 13 kDa mature protein was disturbed and the degradation was rapid in Zellweger fibroblasts. After somatic cell fusion using Zellweger fibroblasts from different genetic groups, the processing was normalized. These results suggest that the biosynthesis and localization of human nsLTP are similar to those of rat nsLTP and that the defect of nsLTP in peroxisome-deficient disorders is a phenomenon secondary to an abnormal transport mechanism of peroxisomal proteins. The defect of nsLTP may play an important role in metabolic disturbances in bile acid synthesis and steroidogenesis in peroxisome-deficient disorders.     

The occurrence of soluble and membrane-bound non-specific lipid transfer protein (sterol carrier protein 2) in rat tissues

The occurrence and subcellular distribution of the non-specific lipid transfer protein (nsL-TP; sterol carrier protein 2) in rat tissues was investigated by the immunoblotting technique using the affinity purified antibody against rat liver nsL-TP. Highest levels of the protein were found in the homogenates of liver, lung and adrenals, whereas it could hardly be detected in brain. In other tissues (i.e., testis, kidney, heart and intestine) the protein was present at intermediate concentrations. Analysis of subcellular fractions obtained by differential centrifugation demonstrated that in all tissues except for the liver, nsL-TP was predominantly present in the particulate fractions. In the particulate fractions of all tissues, an immunoreactive 58 kDa-protein was detected. Density centrifugation of a nuclear-free homogenate from liver and testis indicated that the 58 kDa-protein did, and nsL-TP did not, cofractionate with catalase. This suggests that in these tissues the bulk of nsL-TP is extraperoxisomal. Membrane-bound nsL-TP in testis was sensitive to trypsin treatment, suggesting that it is exposed to the cytosol. Release of nsL-TP by washing the membranes with 0.1 M Na2CO3 (pH 11.5), indicated that nsL-TP is a periferal protein. It was shown by chromatofocussing that nsL-TP extracted from membrane fractions was more basic than nsL-TP present in the cytosol fraction from rat liver (isoelectric point of 8.7).     

Plants express a lipid transfer protein with high similarity to mammalian sterol carrier protein-2

This is the first report describing the cloning and characterization of sterol carrier protein-2 (SCP-2) from plants. Arabidopsis thaliana SCP-2 (AtSCP-2) consists of 123 amino acids with a molecular mass of 13.6 kDa. AtSCP-2 shows 35% identity and 56% similarity to the human SCP-2-like domain present in the human D-bifunctional protein (DBP) and 30% identity and 54% similarity to the human SCP-2 encoded by SCP-X. The presented structural models of apo-AtSCP-2 and the ligand-bound conformation of AtSCP-2 reveal remarkable similarity with two of the structurally known SCP-2s, the SCP-2-like domain of human DBP and the rabbit SCP-2, correspondingly. The AtSCP-2 models in both forms have a similar hydrophobic ligand-binding tunnel, which is extremely suitable for lipid binding. AtSCP-2 showed in vitro transfer activity of BODIPY-phosphatidylcholine (BODIPY-PC) from donor membranes to acceptor membranes. The transfer of BODIPY-PC was almost completely inhibited after addition of 1-palmitoyl 2-oleoyl phosphatidylcholine or ergosterol. Dimyristoyl phosphatidic acid, stigmasterol, steryl glucoside, and cholesterol showed a moderate to marginal ability to lower the BODIPY-PC transfer rate, and the single chain palmitic acid and stearoyl-coenzyme A did not affect transfer at all. Expression analysis showed that AtSCP-2 mRNA is accumulating in most plant tissues. Plasmids carrying fusion genes between green fluorescent protein and AtSCP-2 were transformed with particle bombardment to onion epidermal cells. The results from analyzing the transformants indicate that AtSCP-2 is localized to peroxisomes.     

Ultrastructural localization of a peroxisomal protein in rat liver using the specific antibody against the non-specific lipid transfer protein (sterol carrier protein 2)

An antibody against the non-specific lipid transfer protein from rat liver was purified by immunoabsorbent affinity chromatography. This antibody in conjunction with protein A-colloidal gold was used to localize the transfer protein in rat liver by electron microscopy. Labeling by this immunocytochemical technique was found to be mainly restricted to the peroxisomes; low labeling was observed in the cytoplasm. Subsequent analysis of isolated peroxisomes by immunoblotting indicated that the non-specific lipid transfer protein (mol. wt. 14800) was absent from this organelle and that a protein of molecular weight 58000 was responsible for the immunological response. Immunoblotting of the membrane-free cytosol showed the presence of both proteins. It remains to be established to what extent the non-specific lipid transfer protein in the cytosol and the high-molecular weight protein in the peroxisomes are related.     

The primary structure of the nonspecific lipid transfer protein (sterol carrier protein 2) from bovine liver

The primary structure of the nonspecific lipid transfer protein (sterol carrier protein 2) from bovine liver has been determined. The protein consists of a single polypeptide chain of 121 amino acid residues with serine as the amino-terminal and alanine as the carboxy-terminal residue. The protein contains one single cysteine and tryptophan residue and lacks tyrosine, histidine and arginine.     

Chinese hamster ovary cells deficient in peroxisomes lack the nonspecific lipid transfer protein (sterol carrier protein 2)

Chinese hamster ovary cells deficient in intact peroxisomes were compared with wild type cells for the presence of the nonspecific lipid transfer protein (nsL-TP; sterol carrier protein 2). With the immunoblotting technique using the affinity purified antibody against rat liver nsL-TP, this protein was shown to be present in the homogenates from wild type cells, but could not be detected in mutant cells. In agreement with a previous study using livers from Zellweger patients it appears that there is a positive, as yet unknown, correlation between peroxisomes and the occurrence of nsL-TP in the cell. As a control using the affinity-purified antibody against the phosphatidylinositol transfer protein from bovine brain, levels of this protein were found to be normal in mutant cells. By use of metrizamide density gradients, nsL-TP was shown to cosediment with a membrane fraction different from peroxisomes. A protein of 58,000 daltons cross-reactive with the antibody against nsL-TP did cosediment with the peroxisomes in wild type cells and possibly with a "peroxisomal remnant" in the mutant cells. Incubation of wild type and mutant cells with L-[3-14C]serine showed that the biosynthesis of phosphatidylserine and the subsequent conversion into phosphatidylethanolamine was comparable in both cell types. This indicates that nsL-TP is not involved in the translocation of phosphatidylserine from the endoplasmic reticulum to the mitochondria as the site of decarboxylation.     

Role of the sterol carrier protein-2 N-terminal membrane binding domain in sterol transfer

Previous studies showed that the N-terminal 32 amino acids of sterol carrier protein-2 ((1-32)SCP(2)) comprise an amphipathic alpha-helix essential for SCP(2) binding to membranes [Huang et al. (1999) Biochemistry 38, 13231]. However, it is unclear whether membrane interaction of the (1-32)SCP(2) portion of SCP(2) is in itself sufficient to mediate intermembrane sterol transfer, possibly by altering membrane structure. In this study a fluorescent sterol exchange assay was used to resolve these issues and demonstrated that the SCP(2) N-terminal peptide (1-32)SCP(2) did not by itself enhance intermembrane sterol transfer but potentiated the ability of the SCP(2) protein to stimulate sterol transfer. Compared with SCP(2) acting alone, (1-32)SCP(2) potentiated the sterol transfer activity of SCP(2) by increasing the initial rate of sterol transfer by 2.9-fold and by decreasing the half-time of sterol transfer by 10-fold (from 11.6 to 1.2 min) without altering the size of the transferable fractions. The ability of a series of SCP(2) mutant N-terminal peptides to potentiate SCP(2)-mediated sterol transfer was directly correlated with membrane affinity of the respective peptide. N-Terminal peptide (1-32)SCP(2) did not potentiate intermembrane sterol transfer by binding sterol (dehydroergosterol), altering membrane fluidity (diphenylhexatriene) or membrane permeability (leakage assay). Instead, fluorescence lifetime measurements suggested that SCP(2) and (1-32)SCP(2) bound to membranes and thereby elicited a shift in membrane sterol microenvironment to become more polar. In summary, these data for the first time showed that while the N-terminal membrane binding domain of SCP(2) was itself inactive in mediating intermembrane sterol transfer, it nevertheless potentiated the ability of SCP(2) to enhance sterol transfer.     

The subcellular distribution of the nonspecific lipid transfer protein (sterol carrier protein 2) in rat liver and adrenal gland

The distribution of the nonspecific lipid transfer protein (i.e., sterol carrier protein 2) over the various subcellular fractions from rat liver and adrenal gland was determined by enzyme immunoassay and immunoblotting. This distribution is very different in each of these two tissues. In liver, 66% of the transfer protein is present in the membrane-free cytosol as compared to 19% in the adrenal gland. In the latter tissue, the transfer protein is mainly found in the lysosomal/peroxisomal and the microsomal fraction at a level of 1093 and 582 ng per mg total protein, respectively (i.e., 17% and 35% of the total), and to a lesser extent in the mitochondrial fraction (11% of the total). Of all the membrane fractions isolated, the microsomal fraction from the liver and the mitochondrial fraction from the adrenal gland have the lowest levels of the transfer protein (i.e., 168 ng and 126 ng per mg total protein, respectively). These low levels correlate poorly with the active role proposed for this transfer protein in the conversion of cholesterol into bile acids and steroid hormones in these fractions. Using immunoblotting, it was demonstrated that in addition to the transfer protein (14 kDa) a cross-reactive 58 kD protein was present in the supernatant and the membrane fractions of both tissues. Cytochemical visualization in adrenal tissue with specific antibodies against the nonspecific lipid transfer protein showed that immunoreactive protein(s) were present mainly in the peroxisome-like structures.     

The amino acid sequence of rat liver non-specific lipid transfer protein (sterol carrier protein 2) is present in a high molecular weight protein: evidence from cDNA analysis

The affinity-purified antibody against rat liver non-specific lipid transfer protein (nsL-TP; sterol carrier protein 2) was used to screen a lambda-gt11 rat liver cDNA library. Positive cDNA clones were further identified by Southern blot analysis and sequenced. The largest cDNA clone consisted of 1851 bp starting at the 5' end with an open reading frame of 1545 bp. The 369 bp located at the 3' end of this open reading frame corresponded with the amino acid sequence of nsL-TP.     

Synergistic roles of acyl‐CoA binding protein (ACBP1) and sterol carrier protein 2 (SCP2) in Toxoplasma lipid metabolism

Toxoplasma gondii relies on apicoplast‐localised FASII pathway and endoplasmic reticulum‐associated fatty acid elongation pathway for the synthesis of fatty acids, which flow through lipid metabolism mainly in the form of long‐chain acyl‐CoA (LCACoAs) esters. Functions of Toxoplasma acyl‐CoA transporters in lipid metabolism remain unclear. Here, we investigated the roles of acyl‐CoA‐binding protein (TgACBP1) and a sterol carrier protein‐2 (TgSCP2) as cytosolic acyl‐CoA transporters in lipid metabolism. The fluormetric binding assay and yeast complementation confirmed the acyl‐CoA binding activities of TgACBP1 and TgSCP2, respectively. Disruption of either TgACBP1 or TgSCP2 caused no obviously phenotypic changes, whereas double disruption resulted in defects in intracellular growth and virulence to mice. Gas chromatography coupled with mass spectrometry (GC–MS) results showed that TgACBP1 or TgSCP2 disruption alone led to decreased abundance of C18:1, whereas double disruption resulted in reduced abundance of C18:1, C22:1, and C24:1. ¹³C labelling assay combined with GC–MS showed that double disruption of TgACBP1 and TgSCP2 led to reduced synthesis rates of C18:0, C22:1, and C24:1. Furthermore, high performance liquid chromatography coupled with high resolution mass spectrometry (HPLC‐HRMS) was used for lipidomic analysis of parasites and indicated that loss of TgACBP1 and TgSCP2 caused serious defects in production of glycerides and phospholipids. Collectively, TgACBP1 and TgSCP2 play synergistic roles in lipid metabolism in T. gondii.     

Subcellular localization of the mosquito sterol carrier protein-2 and sterol carrier protein-x

Subcellular distribution of Aedes aegypti sterol carrier protein-2 (AeSCP-2) and AeSCP-x was studied using electron microscopy. In both cultured A. aegypti cells and in the larval midgut, AeSCP-2 was detected mostly in the cytosol, with some labeling mitochondria and nucleus, but not in membranous vesicles. The widespread distribution of AeSCP-2 in the midgut epithelium is consistent with its potential lipid transfer function in all phases of cholesterol absorption. In contrast, AeSCP-x was found mostly in the peroxisome. Differences in the subcellular distribution of AeSCP-2 and AeSCP-x suggest that these two members of the SCP-2 gene family are functionally distinct. Overexpression of AeSCP-2 in A. aegypti cells showed increased localization of AeSCP-2 to cytosol, mitochondria, and nucleus. This is the first report on the nuclear distribution of an SCP. Overexpression of AeSCP-2 resulted in increased cholesterol incorporation in cells, suggesting that AeSCP-2 enhances cholesterol uptake.     

Nonspecific lipid transfer protein (sterol carrier protein 2) is bound to rat liver mitochondria: its role in spontaneous intermembrane phospholipid transfer

In the present study we have investigated the transfer of phospholipids between vesicles and rat liver mitochondria. Transfer was measured by electron paramagnetic resonance spectroscopy using vesicles that contained spin-labeled phospholipids. A spontaneous transfer was observed which could be strongly inhibited by treating the mitochondria with the thiol reagent mersalyl. Transfer was also greatly reduced after a saline wash of the mitochondria; the transfer activity was then recovered in the wash. This activity was inhibited by tryptic digestion and mersalyl. By gel chromatography, enzyme immunoassay and immunoblotting it was demonstrated that the activity in the wash was due to the nonspecific lipid transfer protein (sterol carrier protein 2). We could estimate that up to 85% of the spontaneous phospholipid transfer between vesicles and rat liver mitochondria was mediated by this transfer protein.     

Acidic phospholipids strikingly potentiate sterol carrier protein 2 mediated intermembrane sterol transfer

A liposomal membrane model system was developed to examine the mechanism of spontaneous and protein-mediated intermembrane cholesterol transfer. Rat liver sterol carrier protein 2 (SCP2) and fatty acid binding protein (FABP, also called sterol carrier protein) both bind sterol. However, only SCP2 mediates sterol transfer. The exchange of sterol between small unilamellar vesicles (SUV) containing 35 mol % sterol was monitored with a recently developed assay [Nemecz, G., Fontaine, R. N., & Schroeder, F. (1988) Biochim. Biophys. Acta 943, 511-541], modified to continuous polarization measurement and not requiring separation of donor and acceptor membrane vesicles. As compared to spontaneous sterol exchange, 1.5 microM rat liver SCP2 enhanced the initial rate of sterol exchange between neutral zwwitterionic phosphatidylcholine SUV 2.3-fold. More important, the presence of acidic phospholipids (2.5-30 mol %) stimulated the SCP2-mediated increase in sterol transfer approximately 35-42-fold. Thus, acidic phospholipids strikingly potentiate the effect of SCP2 by 15-18 times as compared to SUV without negatively charged lipids. Rat liver FABP (up to 60 microM) was without effect on sterol transfer in either neutral zwitterionic or anionic phospholipid containing SUV. The potentiation of SCP2 action by acidic phospholipids was suppressed by high ionic strength, neomycin, and low pH. The results suggest that electrostatic interaction between SCP2 and negatively charged membranes may play an important role in the mechanism whereby SCP2 enhances intermembrane cholesterol transfer.     

Biosynthesis of nonspecific lipid transfer protein (sterol carrier protein 2) on free polyribosomes as a larger precursor in rat liver

The biosynthesis of nonspecific lipid transfer protein (nsLTP) was investigated. Total RNA of rat liver was translated in a rabbit reticulocyte lysate cell-free protein-synthesizing system with [35S]methionine as label. The immunoprecipitation of translation products with affinity-purified anti-nsLTP antibody yielded 14.5- and 60-kDa [35S]polypeptides. The molecular mass of the former polypeptide was approximately 1.5 kDa larger than that of the purified mature nsLTP (13 kDa). The site of synthesis of nsLTP was studied by in vitro translation of free and membrane-bound polyribosomal RNAs followed by immunoprecipitation. mRNA for both the 14.5- and 60-kDa polypeptides were found predominantly in the free polyribosomal fraction in both normal and clofibrate-treated rats. Clofibrate, a hypolipidemic drug that proliferates peroxisomes, did not increase the relative amount of nsLTP mRNA in rat liver. Pulse-chase experiments in rat hepatoma H-35 cells suggested that nsLTP was synthesized as a larger precursor of 14.5 kDa and converted to a mature form of 13 kDa. We have recently shown that nsLTP is highly concentrated in peroxisomes in rat hepatocytes [Tsuneoka et al. (1988) J. Biochem. 104, 560-564]. Taken together, these results suggest that nsLTP is synthesized as a larger precursor of 14.5 kDa on cytoplasmic free polyribosomes, then post-translationally transported to peroxisomes, where the precursor is presumably proteolytically processed to its mature form of 13 kDa. The relationship between the 13-kDa nsLTP and the 60-kDa polypeptide is also discussed.     

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.     

Identification of non-specific lipid transfer protein-1 as a calmodulin-binding protein in Arabidopsis

Although non-specific lipid transfer proteins (nsLTPs) are widely present in plants, their functions and regulations have not been fully understood. In this report, Arabidopsis nsLTP1 was cloned and expressed to investigate its binding to calmodulin (CaM). Gel overlay assays revealed that recombinant nsLTP1 bound to CaM in a calcium-independent manner. The association of nsLTP1 and CaM was corroborated using CaM-Sepharose beads to specifically isolate recombinant nsLTP1 from crude bacterial lysate. The CaM-binding site was mapped in nsLTP1 to the region of 69-80 amino acids. This region is highly conserved among plant nsLTPs, implicating that nsLTPs are a new family of CaM-binding proteins whose functions may be mediated by CaM signaling.     

Identification of mosquito sterol carrier protein-2 inhibitors

A mosquito sterol carrier protein-2, AeSCP-2, has been shown to aid in the uptake of cholesterol in mosquito cells. The discovery of chemical inhibitors of AeSCP-2 is reported here. AeSCP-2 inhibitors (SCPIs) belong to several chemotypes of hydrophobic compounds. Those inhibitors competed with cholesterol for AeSCP-2, binding with relatively high binding affinities. In cultured insect cells, SCPIs reduced cholesterol uptake by as much as 30% at 1-5 microM concentrations. SCPIs were potent larvicides to the yellow fever mosquito, Aedes aegypti, and to the tobacco hornworm, Manduca sexta, with 50% lethal doses (LD50s) of 5-21 microM and 0.013-15 ng/mg diet, respectively. The results indicate that sterol carrier protein-2 has functional similarity in two different insect species.