Modification of the erythrocyte membrane by a non-specific lipid transfer protein

The non-specific phospholipid transfer protein purified from bovine liver has been used to modify the phospholipid content and phospholipid composition of the membrane of intact human erythrocytes. Apart from an exchange of phosphatidylcholine between the red cell and PC-containing vesicles, the protein appeared to facilitate net transfer of phosphatidylcholine from the donor vesicles to the erythrocyte and sphingomyelin transfer in the opposite direction. Phosphatidylcholine transfer was accompanied by an equivalent transfer (on a molar basis) of cholesterol. An increase in phosphatidylcholine content in the erythrocyte membrane from 90 to 282 nmol per 100 μl packed cells was observed. Phospholipase C treatment of modified cells showed that all of the phosphatidylcholine which was transferred to the erythrocyte was incorporated in the lipid bilayer. The nonspecific lipid transfer protein used here appeared to be a suitable tool to modify lipid content and composition of the erythrocyte membrane, and possible applications of this approach are discussed.     

植物非特异脂质转运蛋白研究现状与展望

植物非特异脂质转运蛋白(nsLTP)是一类含量丰富的小分子碱性蛋白, 能够在体外与多种疏水分子可逆地结合。目前已从多种植物中分离到9种类型的nsLTP基因。所有nsLTP蛋白质都具有8个半胱氨酸残基模体的保守结构, 它们的三维结构内部有一个具有脂质结合位点的疏水腔。根据基因结构、表达、调控和体外活性等研究, nsLTP被认为可能与蜡质合成与运输、抗逆、抗病以及生殖发育等重要生理过程有关。文章全面介绍nsLTP基因及其蛋白质研究的最新进展, 内容包括基本特征、分类、基因表达、基因克隆与功能研究等, 最后对今后的研究方向进行了讨论和展望。     

A non-specific lipid transfer protein from Arabidopsis is a cell wall protein.

Among the proteins that accumulate as plant seeds desiccate are several protein families that are composed principally of a tandemly repeated 11-mer amino acid motif. Proteins containing the same motif accumulate in the desiccating leaves of a desiccation-tolerant plant species. This motif is characterized by apolar residues in positions 1, 2, 5 and 9, and charged or amide residues in positions 3, 6, 7, 8 and 11. An α helical arrangement of the 11-mer repeating unit gives an amphiphilic helix whose hydrophobic stripe twists in a right-handed fashion around the helix. Should these proteins dimerize via binding of their hydrophobic faces, a right-handed coiled coil would be formed. Such a structure has not previously been observed. A conceivable function for these proteins in ion sequestration in the desiccated state is proposed.     

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.     

Modification of the erythrocyte membrane dielectric constant by alcohols

Summary Aliphatic alcohols are found to stimulate the transmembrane fluxes of a hydrophobic cation (tetraphenylarsonium, TPA) and anion (AN-12) 5–20 times in red blood cells. The results are analyzed using the Born-Parsegian equation (Parsegian, A., 1969,Nature (London) 221:844–846), together with the Clausius-Mossotti equation to calculate membrane dielectric energy barriers. Using established literature values of membrane thickness, native membrane dielectric constant, TPA ionic radius, and alcohol properties (partition coefficient, molar volume, dielectric constant), the TPA permeability data is predicted remarkably well by theory. If the radius of AN-12 is taken as 1.9 Å, its permeability in the presence of butanol is also described by our analysis. Further, the theory quantitatively accounts for the data of Gutknecht and Tosteson (Gutknecht, J., Tosteson, D.C., 1970,J. Gen. Physiol. 55:359–374) covering alcohol-induced conductivity changes of 3 orders of magnitude in artificial bilayers. Other explanations including perturbations of membrane fluidity, surface charge, membrane thickness, and dipole potential are discussed. However, the large magnitude of the stimulation, the more pronounced effect on smaller ions, and the acceleration of both anions and cations suggest membrane dielectric constant change as the primary basis of alcohol effects.     

Modification of the erythrocyte membrane by sulfhydryl group reagents

Summary In this study, the consequences of modification of human erythrocyte membrane sulfhydryl groups by N-ethyl maleimide (NEM), 5,5dithiobis-(2-nitrobenzoic acid) (DTNB) andp-hydroxymercuriphenyl sulfonate (PHMPS) were investigated. These reagents differ in chemical reactivity, membrane penetrability and charge characteristics.Results of sulfhydryl modification were analyzed in terms of inhibitory effects on activities of five membrane enzymes; Mg⁺⁺- and Na⁺, K⁺-ATPase, K⁺-dependent and independentp-nitrophenyl phosphatase (NPPase) and DPNase. Structural considerations involved in the sulfhydryl-mediated inhibition were evaluated by studying the changes in susceptibility to sulfhydryl alteration produced by shearing membranes into microvesicles and by the addition of the membrane modifiers, Mg⁺⁺ and ATP.Conclusions from the data suggest that the effects of NEM appeared to result from modification of a single class of sulfhydryls; DTNB interacted with two different sulfhydryl classes. Increasing concentrations of PHMPS resulted in the sequential modification of many types of sulfhydryls, presumably as a result of increasing membrane structural disruption. DTNB and PHMPS caused solubilization of about 15% of membrane protein at concentrations giving maximal enzyme inhibition.In contrast to the usually observed parallels between Na⁺, K⁺-ATPase and K⁺-dependent NPPase, activities of Mg⁺⁺-ATPase, Na⁺, K⁺-ATPase and K⁺-dependent NPPase varied independently as a result of sulfhydryl modification. We suggest complex structural and functional relationships exist among these components of the membrane ATP-hydrolyzing system.Our studies indicate that the effects of sulfhydryl group reagents on these membrane systems should not be ascribed to sulfhydryl modificationper se, but rather to the resulting structural perturbations. These effects depend upon the structural characteristics of the particular membrane preparation studied and on the chemical characteristics of the sulfhydryl group reagent used.     

Modification of TSH-stimulated adenylate cyclase activity of bovine thyroid by manipulation of membrane phospholipid composition with a nonspecific lipid transfer protein

The lipid composition of bovine thyroid plasma membranes was modified using the nonspecific lipid transfer protein from bovine liver. Incubation of plasma membranes with transfer protein and phosphatidylinositol-containing liposomes caused a strong, concentration dependent, inhibition of TSH-stimulated adenylate cyclase activity. Other phospholipids such as phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and phosphatidic acid were two to four times less effective as inhibitors of TSH-stimulation. The phosphatidylinositol-induced inhibition was not reversed when more than 80% of phosphatidylinositol incorporated was removed using phosphatidylinositol-specific phospholipase C. Incorporation of phosphatidylinositol in plasma membranes provoked no significant change in the fluorescence anisotropies of the fluorophores 1,6-diphenyl-1,3,5-hexatriene (DPH) and 1-(14-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH), indicating that the inhibition was not due to changes in membrane fluidity. At phosphatidylinositol concentrations causing a 66% reduction in TSH-stimulated adenylate cyclase activity cholera toxin- and forskolin-stimulated activity as well as basal activity were decreased by maximally 10%. Since TSH binding to bovine thyroid plasma membranes was not affected it is suggested that phosphatidylinositol can act as a negative modulator of the TSH activation of adenylate cyclase and this probably by interfering with the coupling between the occupied TSH receptor and the stimulatory GTP-binding regulatory protein of the adenylate cyclase complex.     

Isolation and characterization of a tomato non-specific lipid transfer protein involved in polygalacturonase-mediated pectin degradation

An important aspect of the ripening process of tomato fruit is softening. Softening is accompanied by hydrolysis of the pectin in the cell wall by pectinases, causing loss of cell adhesion in the middle lamella. One of the most significant pectin-degrading enzymes is polygalacturonase (PG). Previous reports have shown that PG in tomato may exist in different forms (PG1, PG2a, PG2b, and PGx) commonly referred to as PG isoenzymes. The gene product PG2 is differentially glycosylated and is thought to associate with other proteins to form PG1 and PGx. This association is thought to modulate its pectin-degrading activity in planta. An 8 kDa protein that is part of the tomato PG1 multiprotein complex has been isolated, purified, and functionally characterized. This protein, designated 'activator' (ACT), belongs to the class of non-specific lipid transfer proteins (nsLTPs). ACT is capable of 'converting' the gene product PG2 into a more active and heat-stable form, which increases PG-mediated pectin degradation in vitro and stimulates PG-mediated tissue breakdown in planta. This finding suggests a new, not previously identified, function for nsLTPs in the modification of hydrolytic enzyme activity. It is proposed that ACT plays a role in the modulation of PG activity during tomato fruit softening.     

A mechanism of membrane neutral lipid acquisition by the microsomal triglyceride transfer protein

The microsomal triglyceride transfer protein (MTP) and apolipoprotein B (apoB) belong to the vitellogenin (VTG) family of lipid transfer proteins. MTP is essential for the intracellular assembly and secretion of apoB-containing lipoproteins, the key intravascular lipid transport proteins in vertebrates. We report the predicted three-dimensional structure of the C-terminal lipid binding cavity of MTP, modeled on the crystal structure of the lamprey VTG gene product, lipovitellin. The cavity in MTP resembles those found in the intracellular lipid-binding proteins and bactericidal/permeability-increasing protein. Two conserved helices, designated A and B, at the entrance to the MTP cavity mediate lipid acquisition and binding. Helix A (amino acids 725-736) interacts with membranes in a manner similar to viral fusion peptides. Mutation of helix A blocks the interaction of MTP with phospholipid vesicles containing triglyceride and impairs triglyceride binding. Mutations of helix B (amino acids 781-786) and of N780Y, which causes abetalipoproteinemia, have no impact on the interaction of MTP with phospholipid vesicles but impair triglyceride binding. We propose that insertion of helix A into lipid membranes is necessary for the acquisition of neutral lipids and that helix B is required for their transfer to the lipid binding cavity of MTP.     

A non-specific lipid transfer protein with antifungal and antibacterial activities from the mung bean

A non-specific lipid transfer peptide (nsLTP) with antimicrobial activity was isolated from the mung bean (Phaseolus mungo) seeds. The procedure entailed aqueous extraction, ion exchange chromatography on CM-Sephadex and high performance liquid chromatography (HPLC) on POROS-HS-20. The peptide exhibited a molecular mass of 9.03 kDa in mass spectrometry. It exerted antifungal action toward Fusarium solani, Fusarium oxysporum, Pythium aphanidermatum and Sclerotium rolfsii, and antibacterial action against Staphylococcus aureus but not against Salmonella typhimurium. The lipid binding of this peptide was very similar to that of a previously described lipid transfer protein extracted from wheat seeds and maize seeds, indicating that it possessed lipid transfer activity. The present findings add to the scarcity of the literature on leguminous nsLTPs.     

Modulation of erythrocyte membrane proteins by membrane cholesterol and lipid fluidity.

Human erythrocyte membranes were enriched or depleted of cholesterol and effects on membrane proteins assessed with a membrane-impermeant sulfhydryl reagent, [35S]glutathione-maleimide. Reaction of the probe with intact cells quantifies exofacial sulfhydryl groups and reaction with leaky ghost membranes permits quantification of endofacial sulfhydryl groups. The mean endofacial sulfhydryl titer of cholesterol-enriched membranes exceeded that of cholesterol-depleted membrane by approximately 45 nmol/mg of protein or 64%. The corresponding exofacial titer of cholesterol-enriched cells was less than that of cholesterol-depleted cells by approximately 0.4 nmol/mg of protein, or 14%. Labeled membranes were examined by autoradiography of sodium dodecyl sulfate-polyacrylamide gel electropherograms to determine the labeling patterns of individual protein bands. Cholesterol enrichment enhanced the surface labeling of Coomassie brilliant blue stained bands 1,2,3, and 5, decreased the labeling of band 6, and did not change significantly that of band 4. The results demonstrate that changes in membrane cholesterol which influence lipid fluidity can alter the surface labeling of both intrinsic and extrinsic membrane proteins.     

Cholesterol metabolism and sterol carrier protein-2 (non-specific lipid transfer protein)

Hepatic sterol carrier protein-2 significantly enhances the microsomal conversion of cholesterol to 7 alpha-hydroxy-cholesterol. In the present work we have attempted to correlate the hepatic content of sterol carrier protein-2 with bile acid formation. We have determined the amount of this protein in a variety of physiological and experimental conditions, in which the rate of bile acid synthesis varies over a wide range, viz. during fetal development, in inbred strains of rats with different rates of bile acid synthesis, and in rats fed diets containing drugs which modify the rate of bile acid synthesis. The outcome of these experiments does not support the idea that sterol carrier protein-2 has any association with bile acid synthesis. From our data we further conclude that hepatic sterol carrier protein-2 is an adaptable protein because its level increases during development from the fetal to the post-weaning stage of the rat and since it can be modulated by oral administration of certain drugs. Furthermore, it is demonstrated that the level of sterol carrier protein-2 varies between six inbred strains of rats.     

The low-affinity lipid binding site of the non-specific lipid transfer protein. Implications for its mode of action.

The non-specific lipid transfer protein (nsL-TP) from bovine liver was studied by using the following fluorescent lipid analogs: phosphatidylcholine species with a sn-2-pyrenylacyl-chain of different length [Pyr(x)PC], sn-2-pyrenyldecanoyl-labelled phosphatidylinositol [Pyr(10)PI], -phosphatidylinositol 4-phosphate [Pyr(10)PIP], -phosphatidylinositol 4,5-bisphosphate [Pyr(10)PIP2] and dehydroergosterol. These analogs provided information on the effect of hydrophobicity and charge on lipid binding and transfer by nsL-TP. Binding of the Pyr(x)PC species decreased with increasing sn-2 acyl-chain length. Under equilibrium conditions, the fraction of nsL-TP that carried a PC molecule did not exceed 8%, which is consistent with a low affinity binding site. Also nsL-TP-mediated transfer of the Pyr(x)PC species decreased with increasing sn-2 acyl-chain length and was highly correlated with spontaneous transfer. Binding of the phosphoinositides increased in the order Pyr(10)PI less than Pyr(10)PIP less than Pyr(10)PIP2, indicating that an increase in lipid negative charge stimulates binding. The transfer of the phosphoinositides, however, decreased in the same order, which suggests that a high negative charge impairs the dissociation of the phospholipid from nsL-TP. Cholesterol, at concentrations up to 50 mol% in the donor membrane, hardly affected binding and transfer of Pyr(6)PC, strongly suggesting that nsL-TP has no high binding affinity for cholesterol. In agreement with this, binding of dehydroergosterol to nsL-TP was not detectable. Despite this apparently negligible affinity, nsL-TP-mediated transfer of dehydroergosterol was in the same order as that of Pyr(6)PC. The results are interpreted to indicate that transfer of lipids by nsL-TP involves the formation of a putative low-affinity lipid-protein complex. This formation is enhanced when lipid hydrophobicity decreases or lipid negative charge increases. Based on the binding and transfer data, the mode of action of nsL-TP is discussed in terms of change in free energy.     

Solvation study of the non-specific lipid transfer protein from wheat by intermolecular NOEs with water and small organic molecules

Intermolecular nuclear Overhauser effects (NOEs) were measured between the protons of various small solvent or gas molecules and the non-specific lipid transfer protein (ns-LTP) from wheat. Intermolecular NOEs were observed with the hydrophobic pocket in the interior of wheat ns-LTP, which grew in intensity in the order cyclopropane (saturated solution) < methane (140 bar) < ethane (40 bar) < acetonitrile (5% in water) < cyclohexane (saturated solution) < benzene (saturated solution). No intermolecular NOEs were observed with dioxane (5% in water). The intermolecular NOEs were negative for all of the organic molecules tested. Intermolecular NOEs between wheat ns-LTP and water were weak or could not be distinguished from exchange-relayed NOEs. As illustrated by the NOEs with cyclohexane versus dioxane, the hydrophobic pocket in wheat ns-LTP preferably binds non-polar molecules. Yet, polar molecules like acetonitrile can also be accommodated. The pressure dependence of the NOEs between methane and wheat ns-LTP indicated incomplete occupancy, even at 190 bar methane pressure. In general, NOE intensities increased with the size of the ligand molecule and its vapor pressure. NMR of the vapor phase showed excellent resolution between the signals from the gas phase and those from the liquid phase. The vapor concentration of cyclohexane was fivefold higher than that of the dioxane solution, supporting the binding of cyclohexane versus uptake of dioxane.     

Solvation study of the non-specific lipid transfer protein from wheat by intermolecular NOEs with water and small organic molecules

Intermolecular nuclear Overhauser effects (NOEs) were measured between the protons of various small solvent or gas molecules and the non-specific lipid transfer protein (ns-LTP) from wheat. Intermolecular NOEs were observed with the hydrophobic pocket in the interior of wheat ns-LTP, which grew in intensity in the order cyclopropane (saturated solution) < methane (140 bar) < ethane (40 bar) < acetonitrile (5% in water) < cyclohexane (saturated solution) < benzene (saturated solution). No intermolecular NOEs were observed with dioxane (5% in water). The intermolecular NOEs were negative for all of the organic molecules tested. Intermolecular NOEs between wheat ns-LTP and water were weak or could not be distinguished from exchange-relayed NOEs. As illustrated by the NOEs with cyclohexane versus dioxane, the hydrophobic pocket in wheat ns-LTP preferably binds non-polar molecules. Yet, polar molecules like acetonitrile can also be accommodated. The pressure dependence of the NOEs between methane and wheat ns-LTP indicated incomplete occupancy, even at 190 bar methane pressure. In general, NOE intensities increased with the size of the ligand molecule and its vapor pressure. NMR of the vapor phase showed excellent resolution between the signals from the gas phase and those from the liquid phase. The vapor concentration of cyclohexane was fivefold higher than that of the dioxane solution, supporting the binding of cyclohexane versus uptake of dioxane.     

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.     

Characterization of the non-specific lipid transfer protein EP2 from carrot (Daucus carota L.)

The extracellular protein EP2 was previously identified as non-specific lipid transfer protein based on its cDNA-derived amino acid sequence. Here, the purification of the EP2 protein from the medium of somatic embryo cultures is described. After two cycles of ion-exchange and gel permeation chromatography, a single silver-stained protein band with an apparent molecular mass of 10 kDa was observed on SDS-PAGE. This protein band was recognized by the antiserum raised against a EP2--galactosidase fusion-protein. Employing a fluorescent phospholipid analog, it was shown that the purified EP2 protein is capable of binding phospholipids and is able to enhance their transfer between artificial membranes. Employing a gel permeation assay, it could be demonstrated that the EP2 protein is also capable of binding palmitic and oleic acid as well as oleyl-CoA. Because in plants these fatty acids are used as precursor molecules for cutin, these results are in support of the proposed role of the EP2 protein to transport cutin monomers from their site of synthesis through the cell wall of epidermal cells to sites of cutin polymerization.