Monosialoganglioside liposome-entrapped enzyme uptake by hepatic cells

Monosialogangliosde liposomes are rapidly taken up by the liver as compared to dicetylphosphate, phosphatidic acid or neutral liposomes. Asialoganglioside G_{M 1} liposomes are taken up with the same avidity as ganglioside G_{M 1} liposomes. Competition experiments with asialofetuin suggest that this uptake is mediated by specific recognition of the terminal galactose residues of the glycolipid liposomes by the receptor present on the plasma membrane of the parenchymal cells of liver. Thus liposomes containing glycolipids with terminal β-galactosyl residues should provide an approach for specifically directing biologically active molecules to liver parenchymal cells.     

Monosialoganglioside liposome-entrapped enzyme uptake by hepatic cells.

Monosialoganglioside liposomes are rapidly taken up by the liver as compared to dicetylphosphate, phosphatidic acid or neutral liposomes. Asialoganglioside GM 1 liposomes are taken up with the same avidity as ganglioside GM 1 liposomes. Competition experiments with asialofetuin suggest that this uptake is mediated by specific recognition of the terminal galactose residues of the glyco-lipid liposomes by the receptor present on the plasma membrane of the parenchymal cells of liver. Thus liposomes containing glycolipids with terminal beta-galactosyl residues should provide an approach for specifically directing biologically active molecules to liver parenchymal cells.     

Tissue distribution of EDTA encapsulated within liposomes containing glycolipids or brain phospholipids

Multilamellar liposomes were prepared with various asialoglycolipids, gangliosides, sialic acid, or brain phospholipids in the liposome membrane and with ethylenediaminetetraacetic acid (EDTA) encapsulated in the aqueous compartments. The liposomes containing glycolipids or sialic acid were prepared from a mixture of phosphatidylcholine, cholesterol, and one of the following test substances: galactocerebroside, glucocerebroside, galactocerebroside sulfate, mixed gangliosides, monosialoganglioside G_M1, monosialoganglioside G_M2, monosialoganglioside G_M3, disialoganglioside G_D1a, or sialic acid. The liposomes containing brain phospholipids were mixtures of either sphingomyelin and cholesterol or a brain total phospholipid extract and cholesterol. Distribution of ¹⁴C-labeled EDTA were determined in mouse tissues from 15 min to 6 h or 12 h after a single injection of liposome prepartion. Liver uptake of encapsulated EDTA was lowest from all liposome preparations containing sialic acid or sialogangliosides regardless of the amount of sialic acid moiety present or the identity of the particular ganglioside; highest uptake of encapsulated EDTA by liver was from the liposomes containing galactocerebroside or brain phospholipids. Lungs and brain took up the largest amounts of EDTA from liposomes containing sphingomyelin and lesser amounts from liposomes containing G_D1a. Use of mouse brain phospholipid extract to prepare liposomes did not increase uptake of encapsulated EDTA by the brain. EDTA in liposomes containing monosialogangliosides, brain phospholipids, galactocerebroside, or sialic acid was taken up well by spleen and marrow. Highest thymus uptake of encapsulated EDTA was from liposomes containing G_D1a. These results demonstrate that inclusion of sialogangliosides in liposome membranes decreases uptake of liposomes by liver, thus making direction of encapsulated drugs to other organs more feasible. Liposomes containing glycolipids also have potential uses as probes of cell surface receptors.     

Tissue distribution of EDTA encapsulated within liposomes containing glycolipids or brain phospholipids.

Multilameller liposomes were prepared with various asialoglycolipids, gangliosides, sialic acid, or brain phospholipids in the liposome membrane and with ethylenediaminetetraacetic acid (EDTA) encapsulated in the aqueous compartments. The liposomes containing glycolipids or sialic acid were prepared from a mixture of phosphatidylcholine, cholesterol, and one of the following test substances: galactocerebroside, glucocerebroside, galactocerebroside sulfate, mixed gangliosides, monosialoganglioside GM1, monosialoganglioside GM2, monosialoganglioside GM3, disialoganglioside GD1a, or sialic acid. The liposomes containing brain phospholipids were mixtures of either sphingomyelin and cholesterol or a brain total phospholipid extract and cholesterol. Distributions of 14C-labeled EDTA were determined in mouse tissues from 15 min to 6 h or 12 h after a single injection of liposome preparation. Liver uptake up encapsulated EDTA was lowest from all liposome preparations containing sialic acid or sialogangliosides, regardless of the amount of sialic acid moiety present or the identity of the particular ganglioside; highest uptake of encapsulated EDTA by liver was from liposomes containing galactocerebroside or brain phospholipids. Lungs and brain took up the largest amounts of EDTA from liposomes containing sphingomyelin and lesser amounts from liposomes containing GD1a. Use of mouse brain phospholipid extract to prepare liposomes did not increase uptake of encapsulated EDTA by the brain. EDTA in liposomes containing monosialogangliosides, brain phospholipids, galactocerebroside, or sialic acid was taken up well by spleen and marrow. Highest thymus uptake of encapsulated EDTA was from liposomes containing GD1a. These results demonstrate that inclusion of sialogangliosides in liposome membranes decreases uptake of liposomes by liver, thus making direction of encapsulated drugs to other organs more feasible. Liposomes containing glycolipids also have potential uses as probes of cell surface receptors.     

Possible role of macrophage glycolipids as receptors for migration inhibitory factor (MIF).

Guinea pig peritoneal exudate cells incubated with water soluble glycolipids obtained from macrophages show an enhanced response to migration inhibitory factor. Incorporation of these glycolipids into liposomes greatly facilitates their interaction with indicator cells. Enhancement of peritoneal exudate cell responsiveness to migration inhibitory factor was specific for glycolipids from guinea pig macrophages. Glycolipids extracted from guinea pig brain and polymorphonuclear leukocytes as well as several bovine and porcine glycolipids had no effect. Specificity of enhancement was not due merely to a preferential association of macrophage glycolipids with indicator cells. The possible role of macrophage glycolipids as receptors for MIF is discussed.     

Interaction of liposomes with a varying lipid composition with hepatocytes in vitro

Interaction of liposomes from egg lecithin, phospholipids and gangliosides of rat liver with rat hepatocyte monolayers was investigated. It was shown that liposomes from phospho- and glycolipids of the liver were bound by rat hepatocytes to a far greater degree than lecithin liposomes. Liver gangliosides increased active endocytosis of liposomes by hepatocytes. Preincubation of hepatocytes with gangliosides reduced the binding of phosphoglycolipid liposomes by those cells.     

Incorporation of human liver and placental alkaline phosphatases into liposomes and membranes is via phosphatidylinositol

As assessed by incorporation into liposomes and by adsorption to octyl-Sepharose, the integrity of the membrane anchor for the purified tetrameric forms of alkaline phosphatase from human liver and placenta was intact. Any treatment that resulted in a dimeric enzyme precluded incorporation and adsorption. An intact anchor also allowed incorporation into red cell ghosts. The addition of hydrophobic proteins inhibited incorporation into liposomes to varying degrees. Alkaline phosphatase was 100% releasable from liposomes and red cell ghosts by a phospholipase C specific for phosphatidylinositol. There was no appreciable difference in the rates of release of placental and liver alkaline phosphatases, although both were approximately 250 x slower in liposomes and 100 x slower in red cell ghosts than the enzyme's release from a suspension of cultured osteosarcoma cells. Both enzymes were released by phosphatidylinositol phospholipase C as dimers and would not reincorporate or adsorb to octyl-Sepharose. However, the enzyme incorporated, resolubilized by Triton X-100, and cleansed of the detergent by butanol treatment was tetrameric by gradient gel electrophoresis, was hydrophobic, and could reincorporate into fresh liposomes. A monoclonal antibody to liver alkaline phosphatase inhibited the enzyme's incorporation into liposomes, and abolished its release from liposomes and its conversion to dimers by phosphatidylinositol phospholipase C.     

不同磷脂和糖脂对莱氏衣原体膜上Mg~（2＋）－ATPase活性的影响

莱氏衣原体膜上Ｍｇ~（２＋）－ＡＴＰａｓｅ用ＤＯＣ溶解后,经Ｓｅｐｈａｒｏｓｅ－６Ｂ和ＤＥＡＥ－ＣｅｌｌｕｌｏｓｅＤＥ－５２离子交换柱,得到了部分纯化的Ｍｇ~（２＋）ＡＴＰａｓｅ,并将此ＡＴＰａｓｅ与不同极性头部的磷脂和膜糖脂重组,研究了不同的极性头部的磷脂和膜糖脂对ＡＴＰａｓｅ活性的影响。此酶的活性不依赖酸性磷脂,ＰＧ、ＤＰＧ、大豆磷脂等明显抑制酶活性,中性磷脂ＤＭＰＣ、ＰＥ、ＰＣ则能增加酶活性,其中尤以非双层脂ＰＥ的作用最为明显。从莱氏衣原体膜上提取的糖脂（ＭＧＤＧ,ＤＧＤＧ）单独和ＡＴＰａｓｅ重组时,酶活性增加并不明显,当ＭＧＤＧ和ＤＧＤＧ以等比例混合时,能大大地增加酶活性。这表明Ｍｇ~（２＋）－ＡＴＰａｓｅ的活性很大程度上与磷脂的表面电荷及磷脂的组成相关。     

Reconstitution of purified Wistar rat liver bilirubin UDP-glucuronyltransferase into Gunn-rat liver microsomes.

1. Reconstitution of purified bilirubin UDP-glucuronyltransferase from Wistar-rat liver into Gunn-rat liver microsomes provides a better environment than phosphatidylcholine liposomes, such that the final specific activity of the Wistar-rat liver enzyme was increased up to 85 units/mg of protein. 2. Gunn- and Wistar-rat liver microsomes were equally effective for reconstitution of the purified enzyme. 3. The transferase activity does not appear to be fully expressed in the more rigid environment of foetal Wistar-rat liver microsomes. 4. These reconstitution experiments reveal a final specific activity for the purified bilirubin UDP-glucuronyltransferase consistent with the capacity of the whole rat liver to glucuronidate bilirubin and indicate that the absence of this enzyme activity in Gunn-rat liver microsomes is not due to an abnormal microenvironment.     

Design of liposomes for circumventing the reticuloendothelial cells.

Two different aspects of liposomal drug delivery to non-RES cells have been described. In one of the systems, by incorporating neutral glycolipids, with terminal beta-galactoside residue into liposomes, it is possible to target liposomes to the liver parenchymal cells, partially bypassing the RES. Asialoganglioside seems to be the most suited for this purpose. In another approach, various factors that prolong the lifespan of circulating liposomes have been discussed. It is possible to design such liposomes by imparting hydrophilicity to the liposomal surface. The effectiveness of a number of possible candidates, such as dextran, GM1 ganglioside and PEG, has been discussed in this context.     

Lectin-specific targeting of beta-glucocerebrosidase to different liver cells via glycosylated liposomes

Galactosylated and mannosylated liposomes were more efficient in transporting liposome-entrapped beta-glucocerebrosidase to liver compared to nonglycosylated liposomes. The enzyme entrapped to glycoside-bearing liposomes was found to be cleared at a much faster rate than that entrapped in liposomes having no sugar on their surface. Asialoorosomucoid and hydrolyzed mannan were found to inhibit both the clearance and the uptake of galactosylated and mannosylated liposomes, respectively, supporting involvement of lectin-sugar interaction. Further studies on the uptake of glucocerebrosidase by isolated liver cells revealed that the enzyme entrapped in mannosylated liposomes has much higher affinity for nonparenchymal cells whereas the assimilation of the entrapped enzyme into hepatocytes is clearly favored for liposomes having galactose on their surface.     

N-parinaroyl glycosphingolipids: synthesis and characterization of novel fluorescent probes of membrane structure

N-Parinaroylceramides and -glucocerebrosides were synthesized and characterized. These fluorescent glycolipids were found to be nonperturbing membrane lipid probes, which partitioned preferentially into fluid-phase phosphatidylcholine (PC) in liposomes containing both fluid and solid-phase PC. N-Parinaroylglucocerebroside, parinaroyl-PC, and free parinaric acid were used to analyze the motion and distribution of glucocerebroside and ganglioside GM1 in liposomes composed of these glycosphingolipids (GSL) and 1-stearoyl-2-oleoyl-PC (SOPC). Steady-state fluorescence anisotropy of these probes indicated that the neutral glucocerebroside formed solid-phase domains in SOPC liposomes; these domains contained little or no PC. In contrast, the negatively charged ganglioside GM1 was miscible with fluid-phase PC. Incorporation of GM1 into SOPC liposomes resulted in an increase in the transition temperature of the mixture; no transition was observed in either of the pure GSL used over the temperature range from 5 to 70 degrees C. These data indicate that the glucocerebroside probes may be specific for sphingolipid domains in mixed PC/GSL membranes.     

Liposomes as carriers for paramagnetic gadolinium chelates as organ specific contrast agents for magnetic resonance imaging (mri)

Abstract

Small unilamellar liposomes were used as carriers for chelates of gadolinium as organ specific magnetic resonance imaging (MRI) contrast agents. The pharmacokinetic and imaging properties of the lipophilic liposome membrane associated chelate diethylenetriaminepentaacetate-stearylamide (DTPA-SA) were investigated. Gadolinium-DTPA-SA liposomes accumulated in the liver of rats at a peak concentration of 60% of the injected dose 4 hours after application. The elimination half-life from the liver was 61 h. Tl-weighted MR images of this liposomal Gd-chelate in rats and dogs gave a strong signal enhancement of the abdominal organs, liver and spleen. High blood concentrations of the Gd-DTPASA liposomes, reaching 60% of the injected dose after 30 min., decreasing to 40% after 2 hours, suggest their potential as a contrast agent for the blood pool. The gadolinium chelate benzoyloxypropionictetraacetate (Gd-BOPTA) was entrapped in liposomes of different lipid composition. Pharmacokinetic studies of liposome preparations containing a poly(ethylene)glycol (PEG) modified lipid showed that high levels of 80 - 60 % of the injected dose remained in the blood, 15 to 60 minutes after application. Peak blood concentrations of liposomes without PEG reached only 30%, with a correspondingly higher uptake in the liver and the spleen. Thus, both the lipophilic chelate Gd-DTPA-SA, as well as Gd-BOPTA entrapped within the aqueous volume of liposomes possess not only a potential as a liver and spleen specific contrast agent, but also for the imaging of the vascular system.     

Enzyme replacement with liposomes containing beta-galactosidase from Charonia lumpas in murine globoid cell leukodystrophy (twitcher)

Enzyme replacement with liposomes containing beta-galactosidase obtained from charonia lumpas was carried out in murine globoid cell leukodystrophy (GLD). Charonia lumpas beta-galactosidase was able to hydrolyze galactocerebroside trapped into liposomes prepared from lecithin, cholesterol and sulfatide (molar ratio; 7:2:1). Liposomes containing charonia lumpas beta-galactosidase were successfully incorporated into the mouse tissues. 3H-galactocerebroside labeled liposomes were also incorporated into mouse liver, spleen and other tissues. The accumulation rate of 3H-galactocerebroside into twithcer mice liver and spleen was almost 40 to 100 times higher than those of controls and degraded to 70 to 80% of accumulated radioactivity of 3H-galactocerebroside by single injection of liposomes containing charonia lumpas beta-galactosidase. Results suggest that exogeneous enzyme trapped in liposomes can be useful for the correction of accumulated compound.     

A protein purified from pig brain accelerates the intermembranous translocation of mono- and dihexosylceramides,but not the translocation of phospholipids

By the use of an assay that measures the transfer of [³H]galactosylceramide from donor to acceptor liposomes, a protein has been purified 1683-fold from pig brain. The most purified fraction was purified to homogeneity as judged by electrophoresis on 15% polyacrylamide gel in the presence of sodium dodecyl sulfate. The protein has a molecular weight of 23000 as determined by the gel electrophoresis and 18500 as estimated by gel filtration through Sephadex G-75. The protein accelerates the transfer of labeled glycolipids at the following relative rates: 100 for glucosylceramide, 43 for lactosylceramide, 17 for galactosyldiglyceride, and 15 for galactosylceramide. The lipid-transfer stimulated by the protein is specific to glycolipids; the protein does not accelerate the transfer of labeled phosphatidylcholine and phosphatidylethanolamine from donor to acceptor liposomes.     

Specificity of human glucosylceramide beta-glucosidase towards synthetic glucosylsphingolipids inserted into liposomes. Kinetic studies in a detergent-free assay system

The behaviour of highly purified glucosylceramide beta-glucosidase (glucosylceramidase, EC 3.2.1.45) from human placenta [Furbish, F. S., Blair, H. E., Shiloach, J., Pentchev, P. G. & Brady, R. B. (1977) Proc. Natl Acad. Sci. USA 74, 3560-3563] was investigated in the absence of detergents with structurally modified glucosylceramides inserted into unilamellar liposomes. The reaction between the water-soluble enzyme and the liposomal substrates was significantly dependent on the structure of the lipophilic aglycon moiety of glycolipids: glucosyl-N-acetyl-sphingosines (D-erythro and L-threo) were better substrates than the corresponding glucosylceramides. The L-threo derivatives were poorer substrates with higher apparent Km values than the corresponding D-erythro derivatives. For glucosyl-3-keto-ceramide and glucosyl-dihydro-ceramide (D-erythro), higher Km values were found than for glucosylceramide. Sphingosine, glucosylsphingosine and glucosyl-N-acetyl-sphingosine were the most effective inhibitors of the hydrolysis of glucosylceramide. D-erythro-Ceramide and D-galactosyl-N-acetyl-D-erythro-sphingosine inhibited the hydrolysis of amphiphilic glucosylceramide but not that of water-soluble 4-methyl-umbelliferyl-beta-glucoside, suggesting a hydrophobic binding site of the enzyme for the aglycon moiety of its membrane-bound substrate. Dilution experiments suggested that at least a fraction of the enzyme associates with the liposomes and degrades the lipid substrate even in the absence of activator proteins. Acidic phospholipids incorporated into liposomes caused a powerful stimulation (30-40-fold) of the glucosylceramide beta-glucosidase, whereas acidic sphingolipids (sulphatide, gangliosides GM1 and GD1a) incorporated into liposomes stimulated this enzyme only moderately (3-10-fold).     

On the Molecular Mechanism of Steric Stabilization of Liposomes in Biological Fluids

Abstract

Liposomes with specific surface modification overcome rapid in vivo uptake by cells of the mononuclear phagocytic system (MPS) resulting in prolonged circulation in the blood. The structure-function relationship of this effect has been examined by measurements both in vitro and in vivo. The results are reviewed and compared with those from liposomes without surface modification. For example, in the best cases with polyethylene glycol-derivatized phosphatidylethanolamine (PEG-PE) up to 35% of the injected dose remains in the blood and less than 10% is taken up by the two major organs of the MPS, liver and spleen, after 24 hr. This compares with less than 1% in the blood and up to 40% uptake for liposomes without PEG-PE. Steric stabilization has been proposed as a theoretical basis for these results, and some initial results testing this basis have been reported. Here, we discuss steric stabilization in terms of the physico-chemical properties of the liposomes.     

Solubilization of microsomal phosphoethanolaminetransferase by octyl glucoside

Phosphoethanolaminetransferase of high specific activity was solubilized from rat liver microsomes with the non-ionic detergent octyl glucoside. The solubilization method is fast and simple, allowing for processing of large amounts of material. The solubilized enzyme is stable. It contains virtually no phosphocholinetransferase activity. A preliminary characterization of the enzyme, with both diacyl- and alkylacyl-glycerol as substrate, is given. For the reaction, the lipid substrates were incorporated into artificial phospholipid bilayers (liposomes).     

Threshold effects on the lectin-mediated aggregation of synthetic glycolipid-containing liposomes

Cholesterol analogs containing sugar residues linked by spacer groups to the cholesterol O can be incorporated into egg yolk lecithin small unilamellar liposomes. The synthetic glycolipid analogs distribute evenly on both sides of the bilayer. These liposomes are aggregated by the appropriate lectin. For example, when the sugar residue is a β-galactoside the liposomes are aggregated by ricin and when it is an α-mannoside they are aggregated by Con A. The lectin-mediated aggregation of these liposomes is reversed by the addition of the appropriate sugar. The rates but not the extents of aggregation of these liposomes are highly sensitive to the amount of glycolipid incorporated. Below approximately 5% glycolipid incorporation the rate of the lectin-mediated aggregation of these liposomes is exceedingly slow, whereas above this level rapid aggregation proceeds. At all concentrations studied the synthetic glycolipids are incorporated in a unimodal fashion so that the observed threshold effects cannot be based on possible differences in the manner in which the glycolipids are incorporated at different concentrations. This conclusion is based on (1) studies with galactose oxidase that show that the percentage of galactose oxidation in a liposome prepared from a galactosyl-containing glycolipid is independent of glycolipid concentration, and (2) studies on the aggregation of liposomes containing mixed glycolipids in which the glycolipids are shown to behave independently. The importance of a critical density of membrane-bound receptors in order for aggregation to occur is discussed.     

Inhibition by warfarin of prothrombin synthesis and of lipid-saccharide synthesis in rat liver

In vivo and in vitro studies using [³H]glucosamine incorporation into prothrombin and into glycolipids were conducted in rat liver to determine the role of lipid-saccharides in the biosynthesis of prothrombin.In vivo studies demonstrated that 10 mg warfarin/kg inhibited the incorporation of radiolabeled glucosamine into liver prothrombin and glycolipids. This inhibition was similar to the kinetics of inhibition of prothrombin synthesis in the liver.In vitro studies demonstrated a time-dependent increase in the incorporation of radiolabeled glucosamine into lipid-saccharides and prothrombin. This incorporation was inhibited 50% by 5 · 10^?4 M warfarin. Warfarin also inhibited the incorporation of radiolabeled glucosamine into glycolipids in a dose-related manner.In all studies, vitamin K-1 reversed the inhibition of glucosamine incorporation into glycolipids and into prothrombin.