Effect of monensin on fluid phase and receptor mediated endocytosis by rat hepatocyte monolayers

Isolated rat hepatocytes acquire iron from lactoferrin by endocytosis

The iron-binding protein lactoferrin (Lf) present in blood is metabolized by the liver. Isolated rat hepatocytes vigorously endocytose bovine Lf via recycling Ca2(+)-dependent binding sites, but the uptake of iron from Lf by hepatocytes has not been examined. In this study, isolated rat hepatocytes were incubated with radiolabelled bovine Lf (125I-Lf, 59Fe-Lf or 125I-59Fe-Lf) at 37 degrees C, then washed at 4 degrees C in the presence of dextran sulphate with either Ca2+ or EGTA to distinguish between total bound and internal radioactivity respectively. Cells internalized 125I-Lf protein and Lf-bound 59Fe at maximal endocytic rates of 1700 and 480 mol.cell-1.s-1 respectively. When Lf was normalized for 59Fe content, these endocytic rates were equivalent and reflected an uptake potential of at least 3400 mol of iron.cell-1.s-1. Cells prebound with 125I-59Fe-Lf to Ca2+(-)dependent sites at 4 degrees C internalized more than 80% of both 125I-Lf protein and Lf-bound 59Fe approx. 6 min after warming to 37 degrees C at similar rates (125I-Lf: k(in) = 0.276 min-1, 59Fe: k(in) = 0.303 min-1). Within 4 h at 37 degrees C, cells had released 25% or less internalized Lf protein in the form of acid-soluble 125I-by-products but retained all the Lf-delivered 59Fe. Hyperosmotic disruption of clathrin-dependent endocytosis blocked the uptake of 125I-Lf and Lf-bound 59Fe. Incubation of cells with 125I-59Fe-Lf and a 100 molar excess of diferric transferrin reduced slightly the endocytosis of 125I-Lf protein and 59Fe accumulation. Treatment of cells with the ferric chelator desferrioxamine did not alter uptake of 125I-Lf protein or Lf-bound 59Fe, but the ferrous chelator bathophenanthroline disulphonate slightly elevated endocytosis of 125I-Lf protein and Lf-bound 59Fe. These findings indicate that Lf does not release its bound iron before endocytosis. It was concluded from this study that hepatocytes take up iron from Lf at high rates by a process that requires endocytosis of Lf-iron complexes.

Investigations on the cellular uptake of hexadecylphosphocholine

The uptake of [(9,10)-3H]hexadecylphosphocholine (HePC) in six tumor cell lines was studied. All cell lines incorporated HePC in similar amounts, with the exception of the epidermoid cancer cell line KB, which took up higher amounts of HePC. The uptake of HePC at 37 degrees C was shown to be time and concentration dependent. At 20 degrees C, uptake was drastically reduced and at 4 degrees C it was blocked completely. Binding of HePC, at 4 degrees C, was not saturable at concentrations between 5 micrograms/mL (11.8 microM) and 100 micrograms/mL (235.3 microM), indicating that cell surface binding is not receptor-mediated. Furthermore, the effects of inhibitors of endocytosis were investigated. We observed a pronounced inhibitory effect by monensin and cytochalasin B. Colchicine was somewhat less effective whereas chloroquine was almost without effect. From these data we conclude that uptake of HePC is most probably mediated via a receptor-independent endocytotic mechanism.

Effects of lactate on pathways of glycogen formation in the perfused rat liver

In order to investigate the roles of lactate as substrate and regulator of hepatic glycogen synthesis, two groups of rat livers were perfused with oxygenated blood for 2 h. The initial perfusate glucose and lactate concentrations of Group I and II were 245 +/- 6.8 and 254 +/- 12.9 mg/dl and 49 +/- 2.6 and 54 +/- 2.2 mg/dl respectively. Labelled glucose was added to the perfusate to assess direct glycogen formation. Either additional glucose (Group I) or lactate (Group II) was added (1 mg/min) to a recirculating liver-perfusion system. Initial lactate uptake and glucose formation was identical in the two groups of studies. For Group I, both glucose and lactate uptake by the liver fell to nearly zero, in spite of increasing glucose concentrations. However, with lactate infusion (Group II), its uptake by the liver was maintained at 0.89 +/- 0.14 mg/min after 120 min. In total, 6.2 +/- 0.7 mg (Group I) or 20.2 +/- 3.9 mg (Group II) of glycogen was formed, 4.0 +/- 0.7 mg or 9.2 +/- 2.0 mg by direct synthesis from glucose and 2.2 +/- 0.3 mg or 11.0 +/- 2.1 mg by gluconeogenic formation, in Groups I and II respectively. With the provision of additional lactate, its uptake by the perfused liver tripled, as did glycogen synthesis. Glucose production doubled when lactate was added instead of glucose. Gluconeogenic formation of glycogen increased by 400%. Surprisingly, direct synthesis from glucose also rose by 130%. These data indicate that continued lactate uptake by the liver with gluconeogenic glycogen formation determines the amount of glycogen formed not only by this route, but also by direct synthesis from glucose.

Multiple pathways for ligand internalization in rat hepatocytes. II: Effect of hyperosmolarity and contribution of fluid-phase endocytosis

In a companion report (Moss and Ward: J. Cell. Physiol 149:313-318, 1991) evidence was presented for multiple pathways for insulin internalization based on differences between the internalization of insulin and that of two other ligands, asialofetuin (Afet) and epidermal growth factor (EGF), in the presence of several perturbations of endocytosis. In the present study we have explored the characteristics of three internalization pathways and the contribution of each to overall insulin uptake. Freshly isolated hepatocytes were incubated with radiolabeled ligands in the presence of hyperosmolar sucrose, treatment that is thought to inhibit the coated pit pathway of endocytosis. Insulin internalization was decreased approximately 39%, but much greater decreases were observed with Afet (86%) and EGF (62%). Competition between uptake of radiolabeled and unlabeled insulin was observed in hyperosmolar-treated cells, suggestive of endocytosis by a receptor-mediated noncoated-pit pathway. Uptake of radiolabeled insulin that persisted in the presence of hyperosmolarity and high concentrations of unlabeled insulin suggested a third uptake pathway: fluid-phase endocytosis. A rate of fluid-phase endocytosis of 7.2 microL/hr/10(6) cells was determined from the uptake of the fluid-phase marker lucifer yellow. At high insulin concentrations (greater than or equal to 250 ng/ml), fluid-phase endocytosis appears to be the predominant pathway for insulin uptake, but at lower insulin concentrations (physiological) the coated pit and noncoated pit pathways are the primary routes for insulin internalization.

Glycerophospholipids and cholesterol composition of bile in bile-fistula rats treated with monensin

Data regarding the action of monensin on the concentrations of glycerophospholipids and cholesterol in bile of rats subjected to total biliary diversion for 3 h are reported. After monensin their concentration in bile drops significantly in the first 60 min collections with respect to the control. Differences seem to be produced between the rates of transport to the bile of glycerophospholipids and cholesterol, not sufficiently explained by the inhibition of bile salt uptake determined by monensin at the sinusoidal pole of the hepatocyte.