The influence of dolichol, dolichol esters, and dolichyl phosphate on phospholipid polymorphism and fluidity in model membranes

The effect of dolichols, polyprenols, dolichol esterified with fatty acids, and dolichyl phosphate on the structure and fluidity of model membranes was studied using 31P NMR, small-angle x-ray scattering, differential scanning calorimetry, and freeze-fracture electron microscopy. These studies suggest that dolichol and dolichol derivatives destabilize unsaturated phosphatidylethanolamine containing bilayer structures and promote hexagonal II phase formation; high concentrations of dolichol induce lipid structures characterized by "isotropic" 31P NMR and particulate fracture faces; dolichol, contrary to cholesterol, has no effect on the thermotropic behavior of membranes consisting of phosphatidylcholine, while dolichyl-P incorporation abolishes the transition from the gel to liquid crystalline phase in 1,2-dimyristoyl-sn-glycero-3-phosphocholine; both dolichol and dolichyl-P increase the fatty acid fluidity in phosphatidylethanolamine mixtures; the effect of dolichol on bilayer structure and fluidity is more pronounced with increasing number of isoprene residues; dolichol esters are only soluble to a limited extent in the bilayer and segregates into domains at low concentrations; the results are consistent with a localization of dolichyl-P in which the phosphate group is oriented to the water interphase. The induction of hexagonal II phase by dolichyl-P may elicit the transmembrane movement of glycosylated lipid intermediate.     

Metabolic labeling of dolichol and dolichyl phosphate in isolate hepatocytes

Isolated hepatocytes from rat liver were incubated with [3H]mevalonate, and the labeling of polyprenols in the microsomal fraction was followed. After a 1-min incubation the alpha-unsaturated forms of polyprenyl-P2, -P, and polyprenol were mainly labeled and at this time point only 2, 8, and 17%, respectively, of the label was associated with the saturated forms. In the case of the free alcohol 2 h of incubation was required before all the labeling was recovered in the saturated form. After 1 min polyprenols and polyprenyl-P with 20 and 21 isoprene residues demonstrated much higher specific labeling than the shorter compounds, but after 5 min these differences were greatly reduced. In experiments utilizing short incubation times and chasing no evidence has been obtained that the phosphorylated form is a precursor of the free alcohol or vice versa, that the free alcohol is a precursor of the phosphorylated form. In human liver about 1% of the dolichol is present in the alpha-unsaturated form. These experiments suggest that: 1) the alpha-unsaturated form is the precursor of the alpha-saturated free alcohol, 2) dolichol does not necessarily arise directly from dephosphorylation of the phosphorylated form, and 3) the free alcohol is for the most part not phosphorylated under in vivo conditions in rat liver.     

The half-lives of dolichol and dolichyl phosphate in rat liver

Rat liver dolichol and dolichyl-P were labeled by injection of [³H]mevalonate into the portal vein and their rates of synthesis and breakdown determined. In the initial phase the radioactivity appeared in -unsaturated polyprenols. Subsequent saturation required 90 min. The half-lives of dolichols in microsomes were between 80 and 118 h, and shorter dolichols had shorter values of T_1/2. The half-lives of dolichols in lysosomes were between 115 and 137 h, while microsomal dolichyl-P exhibited a T_1/2 of 32 h. Injected dolichol was recovered in the lysomes of hepatocytes and exhibited a rate of breakdown which was slower than that of the endogenous compound. These results indicate differences in the catabolism of dolichol at different subcellular locations, as well as differences between the catabolism of dolichol and dolichyl-P.     

Quantitation of excretion of dolichol and dolichyl phosphate from the rat

In order to gain information on the metabolism of dolichol, the rates of excretion of dolichol and doJichyl phosphate were determined in rats maintained on a dolichol-free diet for l0 days . Analysis of fecal samples collected every 49 h yielded mean output values of 9.0±1,4 and 20.7±3,0 g/rat/day of dolichot and dolichy] phosphate, respectively. Urinary output rates were 0.56±0.12 and 0.50±0.2g g/rat/ day of dolichol and dolichyt phosphate, respectively. Thus, excretion is one fate of endogenously synthesized dolichoI compounds in the rat.     

Extraction and quantitation of dolichol and dolichyl phosphate in soybean embryo tissue

A procedure for the quantitative extraction of both dolichol and dolichyl phosphate (Dol-P) in plant tissue (soybean embryos) into diethyl ether from an alkaline saponification mixture is described. A complete and quantitative separation of total dolichol and total Dol-P is then obtained based on their respective solubilities in diethyl ether and water. After separation dolichol and Dol-P can both be analyzed and quantitated directly by reverse-phase HPLC on C18 columns without additional purification. The two major homologs of dolichol and Dol-P are those with 17 and 18 isoprene units. The total dolichol and total Dol-P contents of dry embryos were 96.3 +/- 0.8 and 5.3 +/- 0.1 micrograms/g, respectively. The post-HPLC recoveries for dolichol and Dol-P were 101 +/- 2 and 84 +/- 3% respectively, using [1-14C]dolichol and Dol-P containing 20 isoprene units as recovery standards. Dol-P estimations could be carried out on material equivalent to as little as 65 mg embryo tissue.     

Effects of dolichol and dolichyl phosphate on in vitro differentiation of hematopoietic progenitors

The exogenous addition of dolichyl phosphate (Dol-P), an active form of dolichol (Dol) that carries oligosaccharide chains for protein-N-glycosylation, significantly enhanced colony formation of mouse bone marrow hematopoietic progenitors (CFU-e, BFU-e, and CFU-gm) was stimulated by erythropoietin (Epo) and colony-stimulating factor (CSF), but Dol enhanced colony formation of CFU-e only. The effects of Dol or Dol-P on these hematopoietic progenitors were fully dependent on stimulation by Epo or CSF. Other mevalonate-metabolites, such as cholesterol, coenzyme Q10, and isopentenyladenine, had no effect on hematopoietic progenitors. These studies suggest that exogenous Dol-P enhances the frequency of differentiation of hematopoietic progenitors stimulated by Epo or CSF, and there may be a diversity in cellular response of these progenitors to Dol.     

Separation and quantitative determination of dolichol and dolichyl phosphate in rat and trout liver

The dolichol concentrations in rat and trout liver were found respectively to be 50-59 and 16-21 micrograms/g using three experimental methods: densitometric scanning of thin-layer plates, colorimetric assay and HPLC analysis. By HPLC of benzoylated dolichols, the distribution of the dolichols according to the number of their isoprene residues, was determined in rat and trout liver. The major component was dolichol -18 in rat and dolichol -19 in trout liver. Dolichyl phosphate concentrations were found to be 6-7 micrograms/g of rat liver and 8-9 micrograms/g of trout liver by densitometric scanning of thin-layer plates.     

Time course of dolichol and dolichyl phosphate during chemical carcinogenesis in rat liver

Hyperplastic liver nodules were induced in rats by administration of an initiator (diethylnitrosamine or 3'-methyl-4-dimethylaminoazobenzene) and/or a promoter (phenobarbital) by the method reported by Tatematsu et al. (1983, Carcinogenesis 4, 381-386). The dolichol content in the liver and liver microsomes of the rats treated with the initiator were approx. 1.5-times higher than that of the control and rats treated with only the promoter. However, the composition of dolichols was not changed. The time course of the dolichyl phosphate concentration in the rat liver treated with both initiator and promoter showed a pattern different from that in the control liver, the initiator-treated liver or the promoter-treated liver. The main component of dolichyl phosphate in liver treated with both the initiator and promoter changed from that with 18 isoprene units to that with 19. It is suggested that the changes in liver dolichols and dolichyl phosphates may be related to the formation of hyperplastic liver nodules.     

Interaction of salt with ether- and ester-linked phospholipid bilayers

A distinguishing feature of Archaeal plasma membranes is that their phospholipids contain ether-links, as opposed to bacterial and eukaryotic plasma membranes where phospholipids primarily contain ester-links. Experiments show that this chemical difference in headgroup-tail linkage does produce distinct differences in model bilayer properties. Here we examine the effects of salt on bilayer structure in the case of an ether-linked lipid bilayer. We use molecular dynamics simulations and compare equilibrium properties of two model lipid bilayers in NaCl salt solution – POPC and its ether-linked analog that we refer to as HOPC. We make the following key observations. The headgroup region of HOPC “adsorbs” fewer ions compared to the headgroup region of POPC. Consistent with this, we note that the Debye screening length in the HOPC system is ∼ 10% shorter than that in the POPC system. Herein, we introduce a protocol to identify the lipid-water interfacial boundary that reproduces the bulk salt distribution consistent with Gouy-Chapman theory. We also note that the HOPC bilayer has excess solvent in the headgroup region when compared to POPC, coinciding with a trough in the electrostatic potential. Waters in this region have longer autocorrelation times and smaller lateral diffusion rates compared to the corresponding region in the POPC bilayer, suggesting that the waters in HOPC are more strongly coordinated to the lipid headgroups. Furthermore, we note that it is this region of tightly coordinated waters in the HOPC system that has a lower density of Na⁺ ions. Based on these observations we conclude that an ether-linked lipid bilayer has a lower binding affinity for Na⁺ compared to an ester-linked lipid bilayer.     

Metabolic interconversion of dolichol and dolichyl phosphate during development of the sea urchin embryo

The in vivo and in vitro synthesis and turnover of dolichol and dolichyl phosphate have been studied over the course of early development in sea urchin embryos. Synthesis of dolichol and dolichyl phosphate was studied in vivo and in vitro using [3H]acetate and [14C] isopentenylpyrophosphate, respectively, as precursors. Both the in vivo and in vitro results indicate that the principal labeled end product of de novo synthesis is the free alcohol, and that this alcohol is subsequently phosphorylated to produce dolichyl phosphate. The presence of 30 microM compactin inhibits the de novo synthesis of dolichol from [3H]acetate by greater than 90%, but has no effect on the incorporation of 32Pi into dolichyl phosphate for more than 6 h, thus suggesting that during this time interval the major source of dolichyl phosphate is preformed dolichol. The rate of turnover of the [3H]acetate-labeled polyisoprenoid backbone of dolichyl phosphate is very slow (t1/2 = 40-70 h). In contrast, the rate of loss of the [32P]phosphate headgroup is more rapid (t1/2 = 5.7-7.7 h) and increases over the course of development. Finally, dolichyl phosphate phosphatase activity has been measured in vitro. The activity of this enzyme, which can be distinguished from phosphatidic acid phosphatase, was found to increase as a function of development, in qualitative agreement with the increased turnover of 32P from dolichyl phosphate observed in vivo. These results suggest that the phosphate moiety of dolichyl phosphate is in a dynamic state, and that dolichol kinase and dolichyl phosphate phosphatase play key roles in regulating the cellular level of dolichyl phosphate.     

Separation, quantitation and distribution of dolichol and dolichyl phosphate in rat and human tissues

Two procedures for quantitative determination of dolichol were studied and these were applied to analyze tissue and subcellular distribution. In the first procedure the dolichols were oxidized with Cr2O3 and reduced with NaB3H4. The radioactivity in the individual dolichols was measured using reversed-phase thin-layer chromatography. In the second procedure, dolichols were analyzed by high-pressure liquid chromatography. For determination of dolichyl phosphates the lipid extract was subjected to acid and alkaline hydrolysis, and after hydrolysis with acid phosphatase the distribution was determined by high-pressure liquid chromatography. Recovery was monitored by the addition of dolichol D15 and D23 phosphate to the homogenate. Rat spleen had the highest dolichol content (114 micrograms/g) followed by lower content in rat liver and brain. The distribution pattern was similar in all organs, with 18 and 19 isoprene residues as dominating components. Human organs contain considerably higher concentrations of dolichol, with the 19 and 20 isoprene residues as the main components. In rat liver, outer mitochondrial and Golgi membranes, lysosomes and plasma membranes contain considerable amounts of dolichol. A drastic increase in dolichol content was observed in rat liver hyperplastic nodules while human liver cirrhosis and hepatocarcinoma showed a marked decrease in dolichol. In the latter case, the distribution pattern was also changed. Of the total amount of dolichol present in the tissues, 2% was phosphorylated in human liver, 10% in human testis and 18% in rat liver. In rat liver mitochondria and in microsomes 4 and 31%, respectively, of the polyprenols were in activated form. The results demonstrated that dolichyl phosphate and dolichol concentrations were regulated by different mechanisms and that the two forms possessed an independent distribution.     

Characterization of dolichol and dolichyl phosphate phosphatase from soya beans (Glycine max).

A series of polyprenols, ranging in length from 15 to 22 isoprene units, has been isolated from soya beans (Glycine max) and purified by high-pressure liquid chromatography. N.m.r., i.r. and mass spectra of the compounds indicated that they are alpha-saturated polyprenols of the dolichol type. The amount present in dry seeds was about 9 mg/100 g, whereas dolichyl phosphate (Dol-P) was present only in trace amounts. Dol-P phosphatase activity was detected in the microsomal fraction of 5-day-old germinating soya-bean cotyledons. The Dol-P phosphatase activity was linear with respect to time and protein concentration and exhibited a broad pH optimum (pH 7-9). Triton X-100 was necessary for significant enzyme activity. Enzyme activity was slightly enhanced by EDTA, whereas dithiothreitol was without effect. An apparent Km of 5 microM was determined for Dol-P. Bivalent metal ions were not required for enzyme activity. A number of phosphorylated compounds tested as enzyme substrates (including a number of nucleoside phosphates, glucose 6-phosphate, sodium beta-glycerophosphate and Na4P2O7) did not compete with [1-3H]Dol-P as substrate. A number of phospholipids were also tested for their ability to act as Dol-P phosphatase substrates. At 1 mM concentration, phosphatidylcholine, phosphatidylethanolamine, phosphatidic acid and lysophosphatidic acid each inhibited enzymic activity. However, at 0.1 mM concentration, phosphatidylcholine and phosphatidylethanolamine were slightly stimulatory, whereas phosphatidic acid and lysophosphatidic acid were still inhibitory. Phosphatidic acid showed competitive inhibition.     

Submicrosomal distribution of dolichol kinase and dolichyl phosphate phosphatase in the microsomes of germinating soybeans

The availability of dolichyl phosphate is a major factor in the rate of formation of N-linked glycoproteins in mammalian cells. Recent studies in our laboratory suggested that glycoproteins required for seed germination and early plant development are formed via the dolichyl phosphate pathway. Soybean microsomes contain dolichol kinase and dolichyl phosphate phosphatase, enzymes that regulate dolichyl phosphate levels by interconversion of dolichyl phosphate and dolichol. In the present study, soybean microsomes were fractionated into rough and smooth endoplasmic reticulum and Golgi, and the activities of dolichol kinase and dolichyl phosphate phosphatase were measured in each. Submicrosomal fractions were obtained using a procedure developed for rat liver, and were characterized by marker enzymes, RNA content and electron microscopy. The site of N-glycosylation, the rough endoplasmic reticulum, contained high levels of both dolichol kinase and dolichyl phosphate phosphatase. This makes possible a mechanism whereby glycoprotein formation during seed germination is regulated by availability of dolichyl phosphate.     

Interaction of phospholipid bilayers with polyamines of different length

The tip-dip patch clamp method was used to study the effect of three polyamines, putrescine, spermidine and spermine, on bilayer lipid membrane (BLM) stability. Two kinds of mixed lipid-polyamine membranes were investigated. The poration voltage (V _p), and the closed (σ_cl) and open (σ_op) state conductances for pure and polyamine-treated lipid membranes were determined by the method of current-voltage surfaces. It was demonstrated that putrescine and spermidine destabilized lipid membranes under all circumstances. BLM stabilization by spermine was observed when it was added to preformed membranes. Received: 19 November 1999 / Revised version: 25 February 2000 / Accepted: 25 February 2000     

Interaction of amoebapores and NK-lysin with symmetric phospholipid and asymmetric lipopolysaccharide/phospholipid bilayers

Amoebapores from protozoan parasite Entamoeba histolytica and NK-lysin of porcine cytotoxic lymphocytes belong to the same family of saposin-like proteins. In addition to the structural similarity, amoebapores and NK-lysin are both highly effective against prokaryotic and eukaryotic target cells in that they permeabilize the target cell membranes. Here, we have investigated in detail the protein/lipid interaction for the three isoforms of amoebapore and NK-lysin. Results obtained from electrical measurements on planar bilayer membranes, including reconstitution models of the lipid matrix of the outer membrane of Escherichia coli and phospholipid membranes, fluorescence energy transfer spectroscopy with liposomes, and monolayer measurements on a Langmuir trough, provided information on lipid preferences, pH dependences, and membrane interaction mechanisms. The three amoebapores led to the formation of transient pores with similar characteristics in conductance, sublevels, and lifetime for the different isoforms. The conductance of the pores was dependent on the polarity of the applied clamp voltage, and the distribution of the sublevels was affected by the value of the clamp voltage. The size of the pores and distribution of conductance sublevels differed between symmetric phospholipid and asymmetric lipopolysaccharide/phospholipid bilayers. Notably, NK-lysin caused the formation of well-defined pores, which were lipid- and voltage-dependent, and their characteristics differed from those induced by amoebapores; e.g., the protein concentration necessary to induce pore formation was 20 times higher. The biophysical data give important information on the mode of action of these small effector proteins, which may further lead to a better understanding of peptide-membrane interactions in general.     

Separation and purification of dolichol and dolichyl phosphate by anion-exchange paper chromatography: application to cultured cells.

Dolichyl phosphate, dolichol C80-105 (dolichol 17:dihydroheptadecaprenol-dolichol 21:dihydrohexeicosaprenol), and dolichol C55 (dolichol 11:dihydroundecaprenol) were separated by anion-exchange paper chromatography. Squalene, sterols, phospholipids, anionic glycolipids, and glycerol did not migrate as dolichyl phosphate, dolichol C80-105, and dolichol C55 under our elution conditions. However, since the Rf of triglycerides was similar to that of dolichol C80-105, saponification, prior to chromatography, removed traces of triglycerides. Silica gel thin-layer chromatography (TLC) allowed the separation of dolichol C80-105 from dolichol C55, whereas dolichyl phosphate was eluted with other lipids. Incubation of spontaneously transformed cells derived from rat astrocytes primary cultures with [2-14C]acetate, saponification of the extracted lipids, and anion-exchange paper chromatography revealed the presence of radioactive dolichyl phosphate and dolichol C80-105 (15 pmol/mg protein). Extraction of labeled dolichyl phosphate followed by acid phosphatase treatment and subsequent analysis on TLC confirmed the identity of dolichyl phosphate since all the radioactivity was associated with dolichol C55. Treatment of the transformed cells with 30 microM 7-ketocholesterol or 7 beta-hydroxycholesterol stimulated markedly (two- to threefold) the incorporation of [2-14C]-acetate in both dolichol C80-105 and dolichyl phosphate. These data demonstrate that anion-exchange paper chromatography is technically suitable for the separation and analysis of dolichol C55, dolichol C80-105, and dolichyl phosphate in cultured cells prelabeled with radioactive precursors.     

Interaction of the mitochondria-targeted antioxidant MitoQ with phospholipid bilayers and ubiquinone oxidoreductases

MitoQ(10) is a ubiquinone that accumulates within mitochondria driven by a conjugated lipophilic triphenylphosphonium cation (TPP(+)). Once there, MitoQ(10) is reduced to its active ubiquinol form, which has been used to prevent mitochondrial oxidative damage and to infer the involvement of reactive oxygen species in signaling pathways. Here we show MitoQ(10) is effectively reduced by complex II, but is a poor substrate for complex I, complex III, and electron-transferring flavoprotein (ETF):quinone oxidoreductase (ETF-QOR). This differential reactivity could be explained if the bulky TPP(+) moiety sterically hindered access of the ubiquinone group to enzyme active sites with a long, narrow access channel. Using a combination of molecular modeling and an uncharged analog of MitoQ(10) with similar sterics (tritylQ(10)), we infer that the interaction of MitoQ(10) with complex I and ETF-QOR, but not complex III, is inhibited by its bulky TPP(+) moiety. To explain its lack of reactivity with complex III we show that the TPP(+) moiety of MitoQ(10) is ineffective at quenching pyrene fluorophors deeply buried within phospholipid bilayers and thus is positioned near the membrane surface. This superficial position of the TPP(+) moiety, as well as the low solubility of MitoQ(10) in non-polar organic solvents, suggests that the concentration of the entire MitoQ(10) molecule in the membrane core is very limited. As overlaying MitoQ(10) onto the structure of complex III indicates that MitoQ(10) cannot react with complex III without its TPP(+) moiety entering the low dielectric of the membrane core, we conclude that the TPP(+) moiety does anchor the tethered ubiquinol group out of reach of the active site(s) of complex III, thus explaining its slow oxidation. In contrast the ubiquinone moiety of MitoQ(10) is able to quench fluorophors deep within the membrane core, indicating a high concentration of the ubiquinone moiety within the membrane and explaining its good anti-oxidant efficacy. These findings will facilitate the rational design of future mitochondria-targeted molecules.     

Topography of dolichyl phosphate synthesis in rat liver microsomes. Transbilayer arrangement of dolichol kinase and long-chain prenyltransferase

The topography of the dolichyl phosphate biosynthetic enzymes within the plane of rat liver microsomes was investigated by the use of two impermeant inhibitors of enzyme activity: trypsin and mercury-dextran. Mercury-dextran was found to inactivate over 50% of the activities of the CTP-dependent dolichol kinase and the long-chain prenyltransferase. Trypsin caused over 90% inactivation of the long-chain prenyltransferase and 60% inactivation of the dolichol kinase. In addition, the CTP-dependent dolichol kinase was inhibited over 90% by CDP applied externally to sealed microsomes. Inactivation of the dolichyl phosphate biosynthetic enzymes by the impermeant probes occurred under conditions where the mannose-6-phosphatase activity was highly latent. It was concluded that the active sites of these two enzymes are located on the external surface of the microsomal membranes and that dolichyl phosphate biosynthesis occurs asymmetrically on the cytoplasmic surface of the endoplasmic reticulum.     

Interaction of statins with phospholipid bilayers studied by solid-state NMR spectroscopy

Statins are drugs that specifically inhibit the enzyme HMG-CoA reductase and thereby reduce the concentration of low-density lipoprotein cholesterol, which represents a well-established risk factor for the development of atherosclerosis. The results of several clinical trials have shown that there are important intermolecular differences responsible for the broader pharmacologic actions of statins, even beyond HMG-CoA reductase inhibition. According to one hypothesis, the biological effects exerted by these compounds depend on their localization in the cellular membrane. The aim of the current work was to study the interactions of different statins with phospholipid membranes and to investigate their influence on the membrane structure and dynamics using various solid-state NMR techniques. Using ¹H NOESY MAS NMR, it was shown that atorvastatin, cerivastatin, fluvastatin, rosuvastatin, and some percentage of pravastatin intercalate the lipid-water interface of POPC membranes to different degrees. Based on cross-relaxation rates, the different average distribution of the individual statins in the bilayer was determined quantitatively. Investigation of the influence of the investigated statins on membrane structure revealed that lovastatin had the least effect on lipid packing and chain order, pravastatin significantly lowered lipid chain order, while the other statins slightly decreased lipid chain order parameters mostly in the middle segments of the phospholipid chains.     

The submicrosomal distribution of dolichyl phosphate and dolichyl phosphate phosphatase in rat liver

Rat liver microsomes were isolated and fractionated into Golgi, smooth endoplasmic reticulum (SER), and rough endoplasmic reticulum (RER), and the purity of these preparations was determined. The dolichyl phosphate (Dol-P) content of whole microsomes and of each of the submicrosomal fractions was estimated using high pressure liquid chromatography. Dol-P accounts for 4 and 40% of the sum of the alcohol, the fatty acyl esters of dolichol, and monophosphate forms present in whole liver and in purified microsomes, respectively. Concentrations equal to 58, 77, and 108 ng of Dol-P/mg of protein were found in Golgi, SER, and RER, respectively. These values represent 3, 36, and 54% of the sum of the alcohol, the fatty acyl esters of dolichol, and monophosphate forms present in each of these same fractions, respectively. Increases in the Dol-P content of rat liver were observed as early as 12 h after turpentine-induced inflammation and increased 2-fold over 36 h. In this system, Dol-P accounts for no more than 50% of the sum of all phosphorylated and pyrophosphorylated dolichol intermediates present. The specific activity for dolichyl phosphate phosphatase was highest by more than a factor of 2 in Golgi membrane. Specific activities obtained for SER and RER were 42 and 11% of those present in Golgi. The major requirement for Dol-P is thought to be for the saccharide and oligosaccharide transferase reactions which are presumed to take place in RER. The discovery of significant quantities of Dol-P in Golgi and SER is consistent with a possible role of Dol-P in the transport of sugars required for glycoprotein synthesis and processing from a cytosolic to luminal orientation.