Uptake and processing of liposomal phospholipids by Kupffer cells in vitro

We investigated the intracellular metabolic fate of [Me-14C]choline-labeled phosphatidylcholines and sphingomyelin taken up by rat Kupffer cells in maintenance culture during interaction with large unilamellar liposomes composed of cholesterol, labeled choline-phospholipid and phosphatidylserine (molar ration 5:4:1). With both labeled compounds only small proportions of water-soluble radioactivity were found to accumulate in the cells and in the culture medium, suggesting limited phospholipid degradation. However, after a lag period of 30 min progressively increasing proportions of cell-associated liposomal phospholipid were found to be converted to cellular phospholipid, nearly all of which was phosphatidylcholine. This conversion as well as the limited release of water-soluble label from the cells was inhibited by the lysosomotropic agents ammonium chloride and chloroquine. With [Me-14C]choline-labeled lysophosphatidylcholine, label was found to become cell-associated far in excess of an encapsulated liposomal label, [3H]inulin. Without a lag period virtually all of this was rapidly converted to phosphatidylcholine, a process which was not inhibited by the lysosomotropic agents. It is concluded that Kupffer cells, after endocytosis of liposomes, degrade the liposomal phospholipids effectively but reutilize the choline moiety for de novo synthesis of cellular phosphatidylcholine.     

Intrahepatic uptake and processing of intravenously injected small unilamellar phospholipid vesicles in rats

Small unilamellar vesicles consisting of sphingomyelin, cholesterol and phosphatidylserine in a molar ratio of 4:5:1 containing [³H]inulin as a marker of the aqueous space or [Me-¹⁴C]choline-labeled sphingomyelin as a marker of the lipid phase were injected intravenously into rats. After separation of the non-parenchymal cells into a Kupffer cell fraction and an endothelial cell fraction by elutriation centrifugation analysis of the radioactivity contents demonstrated that Kupffer cells were actively involved in the uptake of the vesicles whereas endothelial cells did not contribute at all. Uptake by total parenchymal cells was also substantial but, on a per cell base, significantly lower than that by the Kupffer cells. By comparising the fate of the [³H]inulin label and the [¹⁴C]sphingomyelin label it was concluded that release of liposomal lipid degradation products especially occurred from Kupffer cells rather than from parenchymal cells. In both cell types, however, substantial proportions of the ¹⁴C-label accumulated in the phosphatidylcholine fraction, indicating intracellular degradation of sphingomyelin and subsequent phosphatidylcholine synthesis. Treatment of the animals with the lysosomotropic agent chloroquine prior to liposome injection effectively blocked the conversion of the choline-labeled sphingomyelin into phosphatidylcholine in both cell types. This observation indicates that uptake of the vesicles occurred by way of an endocytic mechanism.     

Interaction of liposomes with Kupffer cells in vitro

We investigated the interaction of liposomes with rat Kupffer cells in monolayer maintenance culture. The liposomes (large unilamellar vesicles, LUV) were composed of 14C-labelled phosphatidylcholine, cholesterol and phosphatidylserine (molar ratio 4:5:1) and contained either 3H-labelled inulin or 125I-labelled bovine serum albumin as a non-degradable or a degradable aqueous space marker, respectively. After 2-3 days in culture the cells exhibited optimal uptake capacity. The uptake process showed saturation kinetics, maximal uptake values amounting to 2 nmol of total liposomal lipid/h/10(6) cells. This is equivalent to 1500 vesicles per cell. The presence of fetal calf serum (FCS) during incubation increased uptake nearly two-fold, whereas freshly isolated rat serum had no effect. The binding of the liposomes to the cells caused partial release of liposomal contents (about 15-20%) both at 4 degrees C and at 37 degrees C. In the presence of metabolic inhibitors the uptake at 37 degrees C was reduced to about 20% of the control values. Inulin and lipid label became cell-associated at similar rates and extents, whereas the association of albumin label gradually decreased after attaining a maximum at relatively low values. When, after 1 h incubation, the liposomes were removed continued incubation for another 2 h in absence of liposomes led to an approx. 30% release of cell-associated lipid label into the medium in water-soluble form. Under identical conditions as much as 90% of the cell-associated albumin label was released in acid-soluble form. Contrarily, the inulin label remained firmly cell-associated under these conditions. From these results we conclude that Kupffer cells in monolayer culture take up liposomes primarily by way of an adsorptive endocytic mechanism. This conclusion was confirmed by morphological observations on cells incubated with liposomes containing fluorescein isothiocyanate (FITC) dextran or horseradish peroxidase as markers for fluorescence microscopy and electron microscopy, respectively.     

Effects of ammonium chloride and chloroquine on endocytic uptake of liposomes by Kupffer cells in vitro

In this study we investigated the interaction of liposomes with rat Kupffer cells in maintenance culture by using the lysosomotropic amines ammonium chloride and chloroquine as inhibitors of intralysosomal degradation. The liposomes (large unilamellar vesicles) contained either the metabolically inert ³H-labeled inulin or the degradable ¹²⁵I-labeled bovine serum albumin. In control incubations, the cells released nearly all accumulated protein label and about 30% of the lipid label when they were incubated in the absence of liposomes, after an initial uptake period of 1 h in the presence of liposomes. This release of label was, for the greater part, suppressed in the presence of ammonia or chloroquine. When the inhibitors were present during the initial uptake period, a several-fold increase in the amount of protein label accumulating in the cells and a smaller, but still marked, increase in lipid label accumulation were observed. The effect of ammonia when present during uptake was readily reversible in contrast to that of chloroquine. Experiments with encapsulated inulin revealed that both lysosomotropic agents also affected the uptake process per se to some extent, probably as a result of impaired membrane/receptor recycling. Labeled liposomes adsorbed to the cells at 4°C were effectively internalized and processed intracellulary after shifting the temperature to 37°C, even when a 500-fold excess of unlabeled liposomes was present in the medium during the 37°C incubation. The observed effects of ammonia and chloroquine indicate that, after uptake, the liposomes are degraded within lysosomes, thus confirming our previous conclusion that endocytosis is the major uptake mechanism at 37°C. From the temperature-change experiments we conclude that, at 4°C, the liposomes are bound with high affinity to the cells, remaining firmly attached to the cell-surface structures which initiate their internalization when the temperature is raised to 37°C.     

Processing of different liposome markers after in vitro uptake of immunoglobulin-coated liposomes by rat liver macrophages

We compared the metabolic fate of [³H]cholesteryl[¹⁴C]oleate, [³H]cholesteryl hexadecylether, ¹²⁵I-labeled bovine serum albumin and [³H]inulin as constituents of large immunoglobulin-coupled unilamellar lipid vesicles following their internalization by rat liver macrophages (Kupffer cells) in monolayer culture. Under serum-free conditions, the cholesteryl oleate that is taken up is hydrolyzed, for the greater part, within 2 h. This occurs in the lysosomal compartment as judged by the inhibitory effect of the lysosomotropic agents monensin and chloroquin. After hydrolysis, the cholesterol moiety is accommodated in the cellular pool of free cholesterol and the oleate is reutilized for the synthesis mainly of phospholipids and, to a lesser extent of triacylglycerols. During incubation in plasma, however, substantial proportions of both the cholesterol and the oleate are shed from the cells, predominantly in the unesterified form. When the liposomes are labeled with the cholesteryl ester analog [³H]cholesteryl hexadecylether only a very small fraction of the label is released from the cells, even in the presence of plasma. Similar to the label remaining associated with the cells, the released label is identified in that case as unchanged cholesteryl ether. The liposomal aqueous phase marker ¹²⁵I-labeled bovine serum albumin is also readily degraded intralysosomally and the radioactive label is rapidly released from the cells in a trichloroacetic acid-soluble form. Also, as much as 20% of the aqueous phase marker [³H]inulin that becomes cell-associated during a 2-h incubation with inulin-containing liposomes, is released from the cells during a subsequent 4-h incubation period in medium or rat plasma. The usefulness of the various liposomal labels as parameters of liposome uptake and intracellular processing is discussed.     

Interaction of immunoglobulin-coupled liposomes with rat liver macrophages in vitro

The interaction between liposomes coated with covalently linked rabbit immunoglobulin (RbIg-liposomes), and rat liver macrophages (Kupffer cells) in monolayer culture was studied biochemically with radioactive tracers and morphologically by electron microscopy. The attachment of immunoglobulin (Ig) to liposomes caused a five-fold increase in liposome uptake by the Kupffer cells at 37 degrees C, in comparison with uncoated liposomes. The uptake was linear with time for at least 4 h and linear with liposome concentration up to a lipid concentration of 0.2 mM. At 4 degrees C uptake, probably representing cell surface-bound liposomes, was reduced to a level of approx. 20% of the 37 degrees C values. Involvement of the Fc receptor in the uptake process was indicated by the reduction of RbIg-liposome uptake by more than 75% as a result of preincubating the cells with heat-aggregated human or rabbit Ig at concentrations (less than 2 mg/ml) at which bovine serum albumin (BSA) had virtually no effect on uptake. At high concentrations (10-35 mg/ml), however, albumin also reduced liposome uptake significantly (20-30%), which suggests an interaction of the RbIg-liposomes with the Kupffer cells that is partially non-specific. RbIg-liposome uptake was dependent on the amount of RbIg coupled to the liposomes. Maximal uptake values were reached at about 200 micrograms RbIg/mumol liposomal lipid. Electron microscopic observations on cells incubated with horseradish peroxidase-containing RbIg-liposomes demonstrated massive accumulation of peroxidase reaction product in intracellular vacuoles, showing that the uptake observed by label association represents true internalization.     

Monensin intercalation in liposomes: effect on cytotoxicities of ricin, Pseudomonas exotoxin A and diphtheria toxin in CHO cells.

Monensin, a carboxylic ionophore was intercalated in liposomes (liposomal monensin) and its effect on cytotoxicities of ricin, Pseudomonas exotoxin A and diphtheria toxin in CHO cells was studied. Intercalation of monensin in liposomal bilayer is found to have no effect on its stability and interaction with cells. Liposomal monensin (1 nM) substantially enhance the cytotoxicities of ricin (62-fold) and Pseudomonas exotoxin A (11.5-fold) while it has no effect on diphtheria toxin. This observed effect is highly dependent on the liposomal lipid composition. The potentiating ability of monensin (1 nM) in neutral vesicles is significantly higher (2.2-fold) as compared to negatively charges vesicles. This ability is drastically reduced by incorporation of stearylamine in liposomes and is found to be dependent on the density of stearylamine as well as on the concentration of serum in the medium. Monensin in liposomes containing 24 mol% stearylamine has a very marginal effect on the cytotoxicity of ricin (7.5-fold) which is further reduced (1.5-fold) in the presence of 20% serum. The uptake of 125I-gelonin from neutral vesicles is significantly higher (approximately 2.0-fold) than that from the negative vesicles. The uptake from positive vesicles is highly dependent on the concentration of stearylamine. The reduction in the lag period (30 min) of ricin action by monensin in neutral and negative vesicle is comparable with free monensin. However, monensin in positive vesicle has no effect on it. These studies have suggested that liposomes could be used as a delivery vehicle for monensin for selective elimination of tumor cells in combination with hybrid toxins.     

Monensin intercalation in liposomes: effect on cytotoxicities of ricin,Pseudomonas exotoxin A and diphtheria toxin in CHO cells

Monensin, a car☐ylic ionophore was intercalated in liposomes (liposomal monensin) and its effect on cytotoxicities of ricin, Pseudomonas exotoxin A and diphtheria toxin in CHO cells was studied. Intercalation of monensin in liposomal bilayer is found to have no effect on its stability and interaction with cells. Liposomal monensin)(1 nM) substantially enhance the cytotoxicities of ricin (62-fold) and Pseudomonas exotoxin A (11.5-fold) while it has no effect on diphtheria toxin. This observed effect is highly dependent on the liposomal lipid composition. The potentiating ability of monensin (1 nM) in neutral vesicles is significantly higher (2.2-fold) as compared to negatively charged vesicles. This ability is drastically reduced by incorporation of stearylamine in liposomes and is found to be dependent on the density of stearylamine as well as on the concentration of serum in the medium. Monensin in liposomes containing 24 mol% stearylamine has a very marginal effect on the cytotoxicity of ricin (7.5-fold) which is further reduced (1.5-fold) in the presence of 20% serum. The uptake of ¹²⁵I-gelonin from neutral vesicles is significantly higher (∼ 2.0-fold) than that from the negative vesicles. The uptake from positive vesicles is highly dependent on the concentration of stearylamine. The reduction in the lag period (30 min) of ricin action by monensin in neutral and negative vesicle is comparable with free monensin. However, monensin in positive vesicle has no effect on it. These studies have suggested that liposomes could be used as a delivery vehicle for monensin for selective elimination of tumor cells in combination with hybrid toxins.     

Interaction of liposomes with human leukocytes in whole blood

The uptake of multilamellar liposomes into human leukocytes in whole blood in vitro was evaluated on the basis of the cellular association of liposomal markers (3H-labelled cholesterol, lipid phase; [14C]inulin, aqueous phase). The entry of liposomes into human blood leukocytes was linear for 60 min and was mediated by a saturable mechanism displaying affinity constants of 0.28 +/- 0.17 and 0.16 +/- 0.05 mM liposomal lipid (means +/- S.E.) for liposomal lipid and aqueous phase markers, respectively. Amicon filtration analysis of incubation mixtures containing blood and liposomes (phosphatidylcholine:dicetyl phosphate:cholesterol, 70:20:10) showed that 34% of [14C]inulin was lost (neither liposome-associated nor cell-associated) after 60 min. By preincorporating sphingomyelin (35 mol%) into multilamellar liposomes, the leakage of the model aqueous phase marker inulin was reduced to 8% after 60 min, thus enhancing the drug carrier potential of liposomes in blood. As a consequence of their interaction with liposomes, the polymorphonuclear leukocytes in whole blood decreased in apparent buoyant density, while maintaining their viability. These results indicate that blood leukocytes in their natural milieu of whole blood are capable of interacting with, and taking up multilamellar liposomes.     

Association of Methotrexate Encapsulated in Negatively Charged Liposomes with Cells at Nanomolar Lipid Concentrations

Abstract

An in vitro liposome-cell association system has been developed that will allow the study of uptake and metabolism of liposomes by cultured cells at nanomolar lipid concentrations. The fate of cell associated liposomes is followed through the liposome encapsulated marker, methotrexate. Detection is based on the inhibition of dihydrofolate reductase by methotrexate, after its release from cells through boiling. Methotrexate in phospha-tidylglycerol (PG) liposomes is taken up by cells and then subsequently lost from the cells. Uptake is partially blocked by monensin. Loss from the cells is blocked by metabolic inhibitors, monensin, ammonium chloride, and chloroquine. Methotrexate in distearoylphosphatidylglycerol (DSPG) liposomes is taken up by cells slowly, and there is minimal lost of methotrexate after uptake. Pulse studies show that metabolism of PG liposomes after endocytosis is occurring at a much higher rate than that of DSPG liposomes, and substantial retention of encapsulated methotrexate occurs for both liposome compositions.     

The involvement of parenchymal,Kupffer and endothelial liver cells in the hepatic uptake of intravenously injected liposomes effects of lanthanum and gadolinium salts

¹²⁵I-labeled albumin or poly(vinyl pyrrolidone) encapsulated in intermediate size multilamellar or unilamellar liposomes with 30–40% of cholesterol were injected intravenously into rats. In other experiments liposomes containing phosphatidyl[Me-¹⁴C]choline were injected. 1 h after injection parenchymal or non-parenchymal cells were isolated. Non-parenchymal cells were separated by elutriation centrifugation into a Kupffer cell fraction and an endothelial cell fraction. From the measurements of radioactivities in the various cell fractions it was concluded that the liposomes are almost exclusively taken up by the Kupffer cells. Endothelial cells did not contribute at all and hepatocytes only to a very low extent to total hepatic uptake of the ¹²⁵I-labels. Of the ¹⁴C-label, which orginates from the phosphatidylcholine moiety of the liposomes, much larger proportions were recovered in the hepatocytes. A time-dependence study suggested that besides the involvement of phosphatidylcholine exchange between liposomes and high density lipoprotein, a process of intercellular transfer of lipid label from Kupffer cells to the hepatocytes may be involved in this phenomenon. Lanthanum or gadolinium salts, which effectively block Kupffer cell activity, failed to accomplish an increase in the fraction of liposomal material recovered in the parenchymal cells. This is compatible with the notion that liposomes of the type used in these experiments have no, or at most very limited, access to the liver parenchyma following their intravenous administration to rats.     

Release of Active Drug from Intracellular Liposomal Prodrug Depots in Macrophages Controlled by Liposome Composition

Abstract

Several drugs have limited potency due to their rapid elimination or inactivation. The anticancer drug 5-fluoro-deoxyuridine (FUdR), which is frequently used in therapeutic treatment of liver metastases from colon tumors, is an example of such drugs. It is rapidly eliminated from circulation and metabolized, mainly by the hepatocytes in the liver. Over the past few years we have investigated the possibility to keep the drug away from the hepatocytes and to save it from rapid inactivation by encapsulating it in liposomes. In this way the liposomal drug is expected to accumulate in the macrophages of the liver (Kupffer cells), which form a major target site for intravenously administered liposomes. There, as the liposomal structure is gradually degraded by lysosomal enzymes, the drug will be released, initially within the lysosomal compartment, while subsequently it will leak out of the lysosomes and eventually out of the cells so as to become available for uptake by intrahepatically situated tumor cells. In this contribution we describe this system for the prodrug dipalmitoyl-FUdR, incorporated in the liposomal bilayer, requiring an additional step for the drug to become available, i.e. the enzymatic deacylation of the prodrug. It is demonstrated that the rate of intralysosomal degradation of liposomes in Kupffer cells varies substantially with liposomal lipid composition and that the rate of release of active drug from the Kupffer cells parallels the rate of liposome degradation. In addition, it is demonstrated that in this way the antitumor activity of the FUdR can be enhanced by more than two orders of magnitude and that the degree of antitumor activity reflects, to a limited extent, the rate at which the liposomes are degraded.     

Differential uptake of liposomes varying in size and lipid composition by parenchymal and kupffer cells of mouse liver

Using liposomes differing in size and lipid composition, we have studied the uptake characteristics of the liver parenchymal and Kupffer cells. Desferal labeled with iron-59 was chosen as a radiomarker for the liposomal content, because Desferal in its free form does not cross cellular membranes. At various time intervals after an intravenous injection of liposomes into mice, the liver was perfused with collagenase, and the cells were separated in a Percoll gradient. It was found that large multilamellar liposomes (diameter of about 0.5 μm) were mainly taken up by the Kupffer cells. For these large liposomes, the rate of uptake by Kupffer cells was rapid, with maximum uptake at around 2 hours after liposome injection. Unexpectedly, small unilamellar liposomes (diameter of about 0.08 μm) were less effectively taken up by Kupffer cells, and the rate of uptake was slow, with a maximum uptake at about 10 hours after liposome injection. In contrast, parenchymal cells were more effective in taking up small liposomes and the uptake of large liposomes was negligible. In addition, liposomes made with a galactolipid as part of the lipid constituents appeared to have higher affinity to parenchymal cells than liposomes made without the galactolipid. These findings should be of importance in designing suitable liposomes for drug targeting.     

Effects of monensin on the synthesis, transport, and intracellular degradation of proteoglycans in rat ovarian granulosa cells in culture

Rat ovarian granulosa cells, isolated from immature female rats 48 h after stimulation with 5 IU of pregnant mare's serum gonadotropin, were maintained in culture. The effects of monensin, a monovalent cationic ionophore, on various aspects of proteoglycan metabolism were studied by metabolically labeling cultures with [35S]sulfate, [3H]glucosamine, or [3H]glucose. Monensin inhibited post-translational modification of both heparan sulfate (HS) proteoglycans and dermatan sulfate (DS) proteoglycans, resulting in decreased synthesis of completed proteoglycans [( 35S]sulfate incorporation decreased to 10% of control by 30 microM monensin, with an ED50 approximately 1 microM). Proteoglycans synthesized in the presence of monensin showed undersulfation of both DS and HS glycosaminoglycans and altered N-linked and O-linked oligosaccharides, suggesting that the processing of all sugar moieties is closely associated. Monensin caused a decrease in the endogenous sugar supply to the UDP-N-acetylhexosamine pool as indicated by an increased 3H incorporation into DS chains [( 3H]glucosamine as precursor) in spite of the decrease in glycosaminoglycan synthesis. Monensin reduced and delayed transport of both secretory and membrane-associated proteoglycans from the Golgi complex to the cell surface. It took 2-4 min for newly labeled proteoglycans to reach the main transport process inhibited by monensin. Monensin at 30 microM did not prevent internalization of cell surface 35S-labeled proteoglycans but almost completely inhibited their intracellular degradation to free [35S]sulfate (ED50 approximately 1 microM), resulting in intracellular accumulation of both DS and HS proteoglycans. Pulse-chase experiments demonstrated that one of the intracellular degradation pathways involving proteolysis of both DS and HS proteoglycans and limited endoglycosidic cleavage of HS continued to operate in the presence of monensin. These results suggest that the intracellular degradation of proteoglycans involve both acidic and nonacidic compartments with monensin inhibiting those processes that normally occur in such acidic compartments as endosomes or lysosomes by raising their pH.     

Uptake and processing of immunoglobulin-coated liposomes by subpopulations of rat liver macrophages

In vivo uptake and processing by liver macrophages (Kupffer cells) of liposomes, covalently coated with rabbit immunoglobulin (Ig liposomes) was studied following intravenous injection in rats. Rabbit Ig liposomes were labeled with trace amounts of cholesteryl[14C]oleate and [3H]cholesteryl hexadecyl ether. 1 h after injection of the liposomes, the non-parenchymal cells were isolated and subjected to centrifugal elutriation with stepwise-increasing flow rates; thus, five sub-fractions of Kupffer cells were obtained ranging in size from 9 to 14 micron in diameter. The cells were assayed for peroxidase activity and protein content. Rabbit Ig liposomes were taken up preferentially by Kupffer cells with diameters larger than 11 micron, which constitute less than 25% of the total Kupffer cell population. The intralysosomal degradation of the ingested liposomes was monitored by measuring the 3H/14C ratio of the cells. Due to the rapid release from the cells of the [14C]oleate formed from the cholesteryl[14C]oleate and the virtually complete retention of the non-metabolizable [3H]cholesteryl hexadecyl ether the 3H/14C ratio of the cells increases with proceeding hydrolysis of the liposomes. Thus, we were able to show that, in vivo, the Kupffer cells of the larger size classes, are not only more active in liposome uptake, but are also substantially more active in liposome degradation than smaller cells. The maintenance of the observed heterogeneity of rat liver Kupffer cells, with respect to liposome uptake under in vitro culture conditions, was examined. Subfractions were maintained in monolayer culture for 2 days and incubated with rabbit Ig liposomes. Binding and uptake of liposomes by the cells was monitored by measuring cell-associated radioactivity at 4 degrees C and 37 degrees C, respectively. In contrast to our in vivo results, we observed maximal in vitro liposome binding and uptake in those subfractions containing small cells (10-11 micron diameter), while the fractions containing cells larger than 12 micron, which were more active in vivo, were substantially less active than the smaller cells. The maximum we observed was even more pronounced when the liposome concentration was increased. We conclude that liver macrophage subfractions that barely participate in liposome uptake from the bloodstream in vivo, possess the potential to develop the capacity in vitro to phagocytose rabbit Ig-coated liposomes to extents equal to or even higher than the cells belonging to those subfractions containing the phagocytically most active cells under in vivo conditions.     

Insulin processing and signal transduction in rat adipocytes

A glycine-HCl buffer (glycine, 50 mM/NaCl, 0.15 M/HCl, pH 3.5) was used to strip insulin bound to adipocyte cell surfaces. Adipocytes retained their integrity in the glycine buffer and their binding capacity for [125I]iodoinsulin could be completely recovered on transfer of the cells to physiological media. At 37 degrees C, [125I]iodoinsulin binds rapidly to plasma membrane receptors; maximal binding occurs within 10 min. At this temperature, the initial binding is followed by rapid internalization, degradation of the hormone and subsequent loss of label. Insulin treatment, at 37 degrees C, induced internalization of 37% of the plasma membrane insulin receptors. Phenylarsine oxide (PAO), a confirmed inhibitor of protein internalization, allowed insulin binding but completely inhibited degradation of the hormone. Monensin, a carboxylic ionophore which impairs uncoupling hormone-receptor complexes, effectively restricted insulin degradation over short time periods (less than 30 min). Addition of monensin to insulin-stimulated cells did not impair D-glucose uptake. It has previously been reported that PAO inhibits hexose transport through the direct interaction with the glucose transporters and low concentrations of PAO (1 microM) transiently inhibit insulin-stimulated glucose uptake. This recovery phenomenon was again observed when PAO was added to insulin-stimulated, monensin-treated adipocytes. The data suggests that lysosomal degradation of insulin is not requisite for signal transduction.     

Influence of liposome charge on the association of liposomes with Kupffer cells in vitro. Effects of divalent cations and competition with latex particles

We studied the interaction of large unilamellar liposomes carrying different surface charges with rat Kupffer cells in maintenance culture. In addition to 14C-labeled phosphatidylcholine, all liposome preparations contained either 3H-labeled inulin or 125I-labeled bovine serum albumin as a non-degradable or a degradable aqueous space marker, respectively. With vesicles carrying no net charge, intracellular processing of internalized liposomes caused nearly complete release of protein label into the medium in acid-soluble form, while phospholipid label was predominantly retained by the cells, only about one third being released. The presence of the lysosomotropic agent, ammonia, inhibited the release of both labels from the cells. At 4 degrees C, the association and degradation of the vesicles were strongly reduced. These results are very similar to what we reported on negatively charged liposomes (Dijkstra, J., Van Galen, W.J.M., Hulstaert, C.E., Kalicharan, D., Roerdink, F.H. and Scherphof, G.L. (1984) Exp. Cell Res. 150, 161-176). The interaction of both types of vesicles apparently proceeds by adsorption to the cell surface followed by virtually complete internalization by endocytosis. Similar experiments with positively charged vesicles indicated that only about half of the liposomes were taken up by the endocytic route, the other half remaining adsorbed to the cell-surface. Attachment of all types of liposomes to the cells was strongly dependent on the presence of divalent cations; Ca2+ appeared to be required for optimal binding. Neutral liposomes only slightly competed with the uptake of negatively charged vesicles, both at 4 degrees and 37 degrees C, whereas negatively charged small unilamellar vesicles and negatively charged latex beads were found to compete very effectively with the large negatively charged liposomes. Neutral vesicles competed effectively for uptake with positively charged ones. These results suggest that neutral and positively charged liposomes are largely bound by the same cell-surface binding sites, while negatively charged vesicles attach mainly to other binding sites.     

In vivo potentiation of ricin toxicity by monensin delivered through liposomes.

Monensin, a carboxylic ionophore, which is known to raise intravesicular pH, was intercalated in liposomes and its effect on the toxicity of ricin in mice was studied. The toxicity of ricin in vivo was found to be significantly enhanced by the administration of monensin intercalated in liposomes (liposomal monensin). The observed enhancement of the toxicity of ricin by monensin was highly dose-dependent and was maximal when ricin was injected within 60 min of monensin injection. The survival time was found to be reduced in the range of 8-20 h, depending on the dose of ricin used, by liposomal monensin. Stability of liposomes containing monensin as inferred from the release of entrapped calcein or FITC-dextran under both in vivo and in vitro conditions was comparable to that observed for liposomes without monensin. Liposomal monensin remains in circulation for 2 h and was cleared from the blood stream after 4 h. In contrast, 15 min was required for the clearance of monensin when administered in free form. Studies on the distribution of liposomal monensin and 125I-ricin in various tissues have revealed that monensin is mainly localized in the liver and spleen which are also the major sites for ricin accumulation. Our observation on the substantial enhancement of ricin toxicity in vivo by liposomal monensin strongly supports the potential usefulness of the latter as a potentiating agent in the enhancement of the toxicity of immunotoxin or hormonotoxin for selective elimination of cancer cells.     

Endocytosis of liposomes by macrophages: binding, acidification and leakage of liposomes monitored by a new fluorescence assay

The interaction of liposomes with macrophage cells was monitored by a new fluorescence method (Hong, K., Straubinger, R.M. and Papahadjopoulos, D., J. Cell Biol. 103 (1986) 56a) that allows for the simultaneous monitoring of binding, endocytosis, acidification and leakage. Profound differences in uptake, cell surface-induced leakage and leakage subsequent to endocytosis were measured in liposomes of varying composition. Pyranine (1-hydroxypyrene-3,6,8-trisulfonic acid, HPTS), a highly fluorescent, water-soluble, pH sensitive dye, was encapsulated at high concentration into the lumen of large unilamellar vesicles. HPTS exhibits two major fluorescence excitation maxima (403 and 450 nm) which have a complementary pH dependence in the range 5-9: the peak at 403 nm is maximal at low pH values while the peak at 450 nm is maximal at high pH values. The intra- and extracellular distribution of liposomes and their approximate pH was observed by fluorescence microscopy using appropriate excitation and barrier filters. The uptake of liposomal contents by cells and their subsequent exposure to acidified endosomes or secondary lysosomes was monitored by spectrofluorometry via alterations in the fluorescence excitation maxima. The concentration of dye associated with cells was determined by measuring fluorescence at a pH independent point (413 nm). The average pH of cell-associated dye was determined by normalizing peak fluorescence intensities (403 nm and 450 nm) to fluorescence at 413 nm and comparing these ratios to a standard curve. HPTS-containing liposomes bound to and were acidified by a cultured murine macrophage cell line (J774) with a t1/2 of 15-20 min. The acidification of liposomes exhibited biphasic kinetics and 50-80% of the liposomes reached an average pH lower than 6 within 2 h. A liposomal lipid marker exhibited a rate of uptake similar to HPTS, however the lipid component selectively accumulated in the cell; after an initial rapid release of liposome contents, 2.5-fold more lipid marker than liposomal contents remained associated with the cells after 5 h. Coating haptenated liposomes with antibody protected liposomes from the initial release. The leakage of liposomal contents was monitored by co-encapsulating HPTS and p-xylene-bis-pyridinium bromide, a fluorescence quencher, into liposomes. The time course of dilution of liposome contents, detected as an increase in HPTS fluorescence, was coincident with the acidification of HPTS. The rate and extent of uptake of neutral and negatively charged liposomes was similar; however, liposomes opsonized with antibody were incorporated at a higher rate (2.9-fold) and to a greater extent (3.4-fold).(ABSTRACT TRUNCATED AT 400 WORDS)     

High sensitivity towards monensin of receptor-mediated endocytosis of formaldehyde treated albumin by liver endothelial cells

Endocytosis of formaldehyde-treated serum albumin (f-albumin) in isolated liver sinusoidal endothelial cells was studied. Uptake occurs via the scavenger receptor and was found to be very sensitive to the ionophore monensin. Binding at 4 degrees C of f-albumin was reduced to 50% of control values by preincubation for 2 min with 2 microM monensin. Both uptake and degradation of f-albumin were more sensitive to monensin. No lag-phase in the inhibitory effect on uptake and degradation was detected. A concentration of 0.1 microM monensin reduced uptake of f-albumin by 50%. Degradation of internalized f-albumin was reduced by 50% in the presence of 0.2 microM monensin. Since uptake and degradation of f-albumin were very sensitive to monensin, the effect of introducing the drug during endocytosis of the ligand was tested. All processing of f-albumin stopped instantly upon addition of monensin; hence, there seems to be no step in the endocytic process beyond which monensin is ineffective. The data suggest that the scavenger receptor of liver endothelial cells is internalized and recycled very rapidly.