Liver endothelium mediates the hepatocyte''s uptake of ceruloplasmin

The mode of transport of ceruloplasmin (CP) into the liver was investigated in fractionated liver cell suspensions. Incubation of 125I-CP at 4 degrees C with these different fractions led to its binding only to endothelial cells but not Kupffer cells and hepatocytes. Incubation at 37 degrees C led to rapid uptake of 125I-CP by endothelium, but cell-associated radioactivity declined after 15 min, which suggests the release of the labeled substance. Internalization was confirmed by fractionation of surface-bound and internalized ligand. The released label now acquired binding potential for fresh target hepatocytes, and the binding was inhibitable with asialoceruloplasmin but not native CP. This suggested that the released molecule was modified in the endothelium by desialation. Desialation was confirmed by incubation of endothelium with double-labeled CP (3H label on sialic acid and 125I on the protein part). We conclude that in the liver, CP is first recognized and taken up by endothelial cells that are endowed with appropriate surface receptors for the protein. Endothelium then modifies the molecule by desialation to expose the penultimate galactosyl residues. The modified molecule is then released, recognized, and taken up by hepatocytes through their membrane galactosyl-recognition system. These findings are consistent with the role of endothelium as an active mediator of molecular transport between blood and tissue, and further assign a biological role for the galactosyl-recognition system in hepatocytes.     

Purification and partial characterization of ceruloplasmin receptors from rat liver endothelium

Ceruloplasmin (CP), a circulating glycoprotein, is known for its copper transport. Recently the spectrum of its activity has been increased to include numerous enzymatic functions. CP binds to the liver endothelium and is transported across the cell via a mechanism involving receptor-mediated endocytosis. To isolate CP receptors, we obtained purified preparations of liver endothelium in rats. The membrane was then isolated by ultracentrifugation and solubilized in Triton X-100. Membrane proteins were labeled with 125I and passed through an affinity column in which CP was covalently linked to Sepharose 4B. Most of the radioactivity was eluted with buffer during the first 5 days. When no more radioactivity was eluted with buffer, elution was done either competitively with cold excess CP or 1 M NaCl. By this technique, a sharp single peak of radioactivity was obtained and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing and nonreducing conditions. Under both conditions receptors appeared as a single band with Mr of 35,000 containing 3% carbohydrate and an isoelectric point of 5.2.     

Proteoglycan synthesis by cultured liver endothelium: the role of membrane-associated heparan sulfate in transferrin binding

Liver endothelium has been reported to possess membrane receptors for the iron-binding protein transferrin (Tf). Similarly, the core protein of proteoglycans (PG) associated with cell membrane in many cell systems can bind Tf. To find out if membrane-associated proteoglycans can explain Tf-binding ability of liver endothelium, we investigated the synthesis and distribution of proteoglycans by isolated, cultured liver capillary endothelium. Cells were isolated and cultured for 48 h in sulfate-free medium and pulse-labeled with 35SO4. The relative distribution of 35SO4-labeled macromolecules, determined in the extracellular (EC), membrane-associated (MA), and intracellular (IC) pools, was respectively 74, 15, and 10%. Membrane-associated proteoglycan (MA-PG) was further purified by ion exchange and gel chromatography. Glycosaminoglycan (GAG) chain characterization indicated about 78% chondroitin sulfate, 7% dermatan sulfate, and about 14% heparan sulfate (HS). Similar GAG chain characterization was made for PG in the EC and IC pools. Transferrin-binding ability of MA-PG was studied by affinity column chromatography, using CNBr-activated sepharose bound to transferrin. About 15% of the labeled MA-PG was specifically bound to Tf-affinity column and could be eluted by excess soluble Tf. This proportion was similar to the proportion of HS in the total membrane-associated pool. Moreover, the eluted labeled material was susceptible to pretreatment with heparitinase, confirming its HS nature. We conclude that the transport capillary endothelium of the liver can synthesize HS proteoglycans which are membrane-associated and this MA-HS pool can bind transferrin. The finding may provide a molecular basis for transferrin binding to liver endothelium and may explain the subsequent transendothelial transport of iron-transferrin complexes into the liver.     

The role of endosomal traffic in the transendothelial transport of ceruloplasmin in the liver

Through a process resembling receptor-mediated endocytosis, liver endothelium binds and internalizes the plasma glycoprotein ceruloplasmin (CP) on the luminal side. The protein is then transported via a vesicular system to the albuminal side where it is externalized to the space of Disse. In its path, the glycoprotein is fully desialylated. To determine if the endosomal compartment is involved in this transport, we used endosomal inhibitors NH4Cl, ethylamine as well as monensin to quantitatively measure the magnitude of radiolabeled CP transport across purified liver endothelial cells. All three reagents inhibited the transport of CP and its discharge by endothelium. The magnitude of inhibition was dose-related for all three reagents. We conclude that the endosomal compartment is involved in the transendothelial transport of CP across the liver endothelium.     

The uptake of radiocolloids by macrophages in vitro; a kinetic analysis with radioactive colloidal gold

Macrophages isolated from the rabbit peritoneal cavity extract radioactive colloidal gold from solutions in vitro. This reaction (ultraphagocytosis) involves two phases: the reversible adsorption of gold on the cell surface and the subsequent irreversible removal of surface-bound colloid into the cell. The latter process (called ingestion) appears to proceed at a rate which is proportional at any moment to the amount of gold attached to the cell surface; the latter in turn can be related to the concentration in extracellular fluid by a simple adsorption isotherm. In terms of rate, therefore, ingestion is related to the extracellular gold concentration in the same way that many enzyme reactions are related to the substrate concentration. Although enzyme kinetics are useful in describing rates of ultraphagocytosis, there is no evidence that enzymes participate in either adsorption or ingestion or that metabolic energy is required of the macrophage. Exudative leucocytes of the heterophilic series show little or no interaction with these finely dispersed gold sols (mean particle diameter 6 to 9 millimicrons). 37°C. three parameters are sufficient to characterize the reaction between gold and a suspension of macrophages, namely an affinity constant (1/K_s), an adsorption maximum (L), and a rate constant of ingestion (k₃). Although numerical values differed markedly among cells of different exudates, all three parameters were estimated in three instances. In these suspensions between 2 and 20 per cent of the surface-bound gold was ingested each minute (37°C., pH 7.4). Under conditions of surface saturation, it was estimated that tens of thousands of gold particles were attached to the surface of an average macrophage; this amount of colloid, however, occupied less than 1 per cent of the geometric area of the cell surface. Although surface saturation imposed an upper limit on the rate of ingestion, no practical limit was noted in the capacity of macrophages to continue the reaction. Optical measurements imply that within the cell agglutination of colloidal gold began promptly after its ingestion. These data are compared with published kinetic studies on the phagocytosis of microscopic particulates and on the parasitism of bacteria by virus.     

alpha 2-macroglobulin adsorbed to colloidal gold: a new probe in the study of receptor-mediated endocytosis

alpha 2-Macroglobulin (alpha 2 M) was adsorbed to colloidal gold and used as a new tool in the study of receptor-mediated endocytosis. alpha 2 M-gold is easy to prepare and is clearly visualized at the electron microscope level. When cells were incubated with alpha 2 M-gold at 0 degrees C, gold was visualized both diffusely over the cell surface and concentrated in coated pits. After cells to which alpha 2 M-gold had been bound at 0 degrees C were warmed, the gold was rapidly internalized into uncoated vesicles, previously termed receptosomes. After 30 min of incubation or longer, gold was found in small lysosomes and, later, in large lysosomes and very small vesicles in the region of the Golgi complex. This pattern of localization is similar to that previously described, using peroxidase-labeled anti-alpha 2 M antibodies. By incubating cells with both alpha 2 M-gold and vesicular stomatitis virus (VSV), we studied the internalization of these two markers simultaneously. VSV and alpha 2 M-gold rapidly clustered in the same coated pits and were internalized in the same receptosomes. Proteins and hormones adsorbed to gold may be useful in the study of receptor-mediated endocytosis.     

The multifunctional oxidase activity of ceruloplasmin as revealed by anion binding studies.

The effect of multiple binding of azide, N3-, on the structural and functional properties of ceruloplasmin (CP) has been reinvestigated by means of both spectroscopic and enzymatic techniques. High affinity binding of the anion to human CP resulted in a dramatic increase of the absorbance at 610 nm and in a concomitant decrease of the optical density at 330 nm. The oxidase activity toward Fe(II) was essentially unaffected, while turnover parameters versus nonferrous substrates dramatically changed, with an approximately 100-fold enhancement of the kcat/Km parameter. Chloride at physiological concentration proved to behave very similarly to N3- bound with high affinity, in that it not only induced the spectroscopic changes previously interpreted in terms of an intramolecular electron transfer from reduced type 1 to type 3 copper ions [Musci, G., Bonaccorsi di Patti, M.C. & Calabrese, L. (1995) J. Protein Chem. 14, 611-617], but it also enhanced some 60-fold the kcat/Km value. A different behavior was observed with chicken CP, where a decrease at 330 nm occurred without a concomitant modification at 603 nm. The chicken enzyme was less sensitive also in terms of enzymatic activity, which was nearly unchanged in the presence of either high affinity N3- or Cl-. At higher N3- concentrations, optical changes of both human and chicken CP were mainly focussed on the appearance of ligand-to-metal charge transfer bands below 500 nm, and the anion behaved as an inhibitor of the oxidase activity versus Fe(II) as well as noniron substrates. The well known bleaching of the blue chromophore could be observed, at neutral pH, only at very high N3-/CP ratios. The data presented in this paper are consistent with a mechanism of structural and functional modulation of CP by anions, that would be able to dictate the substrate specificity of the cuproprotein, and suggest the possibility that CP may act in vivo as a multifunctional oxidase.     

Triiodothyronine binding and norepinephrine uptake in the heart and liver

Administration of norepinephrine to thyroidectomized rats activates sharply the [125I]triiodothyronine binding by heart mitochondria and liver nuclei. Epinephrine stimulates the binding by the heart mitochondria and decreases the intensity of this process in the liver and heart nuclei and liver mitochondria As compared to norepinephrine, adrenoxyl is weaker in activation of [125I] triiodothyronine binding by the heart mitochondria and stronger in intensification of binding by the liver nuclei. Physiological concentrations of thyroxine like adrenoxyl administered to intact animals 2h before investigations intensify the uptake of [3H] norepinephrine by sections of the auricles, myocardium and liver. Hyperthyroidization induces contrary changes inthe uptake of [3H] norepinephrine. Norepinephrine administration decreases sharply the uptake of [3H] norepinephrine by sections of the auricles and myocardium. The blocking of beta-adrenoreceptors weakens the uptake.     

The hepatic binding and uptake kinetics of epidermal growth factor: studies with isolated rat hepatocytes

Hepatocytes are known to bind and internalize a variety of small molecular weight proteins by a process known as receptor-mediated endocytosis (RME). The purpose of this investigation was to characterize the binding and uptake kinetics of a small protein known to be taken up by the liver by RME, epidermal growth factor (EGF), using suspensions of freshly isolated rat hepatocytes. Rat hepatocytes accumulated 125I-EGF (90 pM) in a temperature-dependent fashion. Isolated hepatocytes incubated at 37 degrees C with 125I-EGF began to release a TCA-soluble radiolabeled material into the incubation medium with a lag period of 20 min. EGF uptake by isolated hepatocytes was linear for only 60 seconds and displayed saturation kinetics (apparent Km of 4 nM and a Vmax of 105 fM/min/10(6) cells). Hepatocytes incubated at 4 degrees C bound, but did not internalize, EGF. Under these conditions, EGF binding was saturable at concentrations above 8 nM. A Scatchard analysis revealed that the average number of receptors per hepatocyte was 7.7 X 10(4) with a dissociation constant of 2.6 nM. These data demonstrate that freshly isolated hepatocytes are capable of binding, internalizing and metabolizing EGF and thus are a good model to study RME of small molecular weight proteins.     

Zonal heterogeneity of rat hepatocytes in the in vivo uptake of 17 nm colloidal gold granules

The in vivo uptake in hepatocytes of intravenously injected colloidal gold granules with a diameter of 17 nm or 79 nm and coated with bovine serum albumin or with polyvinyl-pyrrolidone was studied. Irrespective of coating only the 17 nm granules were taken up in hepatocytes. Perivenous hepatocytes did take up much more gold granules than periportal hepatocytes. The gold granules were found in lysosomes around bile canaliculi. Two hours after injection hepatocytes contained the maximal amount of granules. At least a portion of the granules was discharged into the bile. The observed zonal gradient in the uptake of 17 nm gold granules might be caused by the greater supply of granules to the perivenous hepatocytes as a combined result of the higher porosity of the endothelial lining and the smaller number of Kupffer cells with a low endocytic activity in this zone.     

Zonal heterogeneity of rat hepatocytes in the in vivo uptake of 17 nm colloidal gold granules

Summary The in vivo uptake in hepatocytes of intravenously injected colloidal gold granules with a diameter of 17 nm or 79 nm and coated with bovine serum albumin or with polyvinyl-pyrrolidone was studied. Irrespective of coating only the 17 nm granules were taken up in hepatocytes. Perivenous hepatocytes did take up much more gold granules than periportal hepatocytes. The gold granules were found in lysosomes around bile canaliculi. Two hours after injection hepatocytes contained the maximal amount of granules. At least a portion of the granules was discharged into the bile. The observed zonal gradient in the uptake of 17 nm gold granules might be caused by the greater supply of granules to the perivenous hepatocytes as a combined result of the higher porosity of the endothelial lining and the smaller number of Kupffer cells with a low endocytic activity in this zone.     

The role of macrophages in the uptake of endotoxin by the mouse liver

The purpose of this investigation was to analyse the macrophage subpopulations involved in the uptake of endotoxin in the liver. The results show that in normal B10.D2 mice the liver macrophages constitute a heterogeneous population of cells which, depending on their state of differentiation, are distinguished by their differential distribution in the liver acinus and by their ability to phagocytose latex.     

Immunocytochemical localization of actin in dendritic spines of the cerebral cortex using colloidal gold as a probe

Immunocytochemical localization of actin in rat cerebral cortex embedded in the resin LR White was performed using 5 nm colloidal gold as a probe. Antigenicity is maintained throughout the embedding procedure and the low electron opacity of LR White permits fine filamentous structures to be visualized. Control experiments included incubating the sections with normal goat serum or mouse IgG instead of the primary antibody, preadsorbing the antibody with actin from bovine muscle or liver acetone powder, and heat treating the primary antibody. Immunoreactive actin was identified primarily in dendritic spines, particularly in the postsynaptic density (PSD), the subsynaptic web, and the spine apparatus and endothelial and smooth muscle cells of blood vessels. Within dendritic spines, actin which is labeled in the PSD is in continuity with the filaments of the subsynaptic web. These filaments, in turn, are in continuity with the spine apparatus and/or the spine membranes adjacent to the PSD. The PSD may therefore function like other submembranous filamentous arrays which communicate events occurring at the membrane, in this case, the postsynaptic membrane, to the underlying cytoskeletal network, i.e., the subsynaptic web of the spine. It is also suggested that the actin present in the spine may play a role in changes in spine shape and synaptic curvature. Some actin was also seen in the presynaptic process in association with synaptic vesicles, the filamentous network that is contiguous with the synaptic vesicle membrane, and the presynaptic dense projections. Actin may be involved in dynamic processes in the presynaptic ending which include vesicle translocation.     

The silver anniversary of gold: 25 years of the colloidal gold marker system for immunocytochemistry and histochemistry

Since 1971, when W.P. Faulk and G.M. Taylor published “An immunocolloid method for the electron microscope”, colloidal gold has become a very widely used marker in microscopy. It has been used to detect a huge range of cellular and extracellular constituents by in situ hybridization, immunogold, lectin-gold, and enzyme-gold labeling. Besides its use in light microscopic immunogold and lectin-gold silver staining, colloidal gold remains the label of choice for transmission electron microscopy studying thin sections, freeze-etch, and surface replicas, as well as for scanning electron microscopy. The year 1996 is the 25th anniversary of the introduction of colloidal gold as a marker in immunoelectron microscopy and this overview outlines some of the major milestones in the development of the colloidal gold marker system.