Phagocytosis and chemiluminescence response of granulocytes to monodisperse latex particles of varying sizes and surface coats.

The response of human granulocytes to polystyrene latex beads of diameter 0.1-7 microm was measured by luminol-dependent chemiluminescence. In all instances, the response to beads of 3-7 microm was definitely higher than with smaller beads. In protein-free medium, the chemiluminescence response was slow compared to that of opsonized zymosan, and the highest response was only 9% of the response to opsonized zymosan. Scanning electron microscopy showed that granulocytes in suspension bound the particles, occasionally by extending rope-like protrusions. When the beads were coated with albumin, the chemiluminescence diminished to about 1/3 of that seen with uncoated beads; however, preincubating the beads in serum led to a large increase with beads of 1.1 microm (to 25% of the maximal response to opsonized zymosan) and 3.19 microm (to 42%), but with the smallest beads, no increase was noted. "Priming" of the cells with tumor necrosis factor-alpha caused a further increase with serum-coated beads. When uncoated beads of 1.1 microm were tested with "primed" cells, there was an increase of 6 times in the chemiluminescence compared to un-"primed" cells.

Uptake and degradation of radioactively labelled albumin microspheres as markers for Kupffer cell phagocytosis.

Rats were injected with liposomes containing iodixanol (CTP10 Injection; 100 mg iodine per kg body weight) followed by a second injection of 125I-tyramine-cellobiose-albumin microspheres. The amounts of phagocytosed and degraded labelled albumin in liver were measured. A reduced uptake and degradation of albumin microspheres was observed when the labelled microspheres were injected 2 h or 24 h after the liposomes compared with that obtained in control animals receiving saline. No effect on the uptake and degradation of labelled microspheres was observed when the time lag between the injection of liposomes and labelled microspheres was 1 week. The data show that the uptake and degradation of 125I-tyramine-cellobiose-albumin microspheres can be used as indicators of Kupffer cell phagocytotic function following drug uptake by these cells.

Biodistributions of air-filled albumin microspheres in rats and pigs.

The air-filled microspheres of the ultrasound-contrast agent Albunex are unique in that the walls consist of human serum albumin molecules which have been made insoluble by sonication of the albumin solution. The microspheres were isolated by flotation, and the washed microspheres were labelled with 125I. The labelled material was cleared from the circulation mainly as particles, not as soluble albumin molecules. In rats, 80% of intravenously injected microspheres were cleared from the blood within 2 min. Nearly 60% of the dose was recovered in the liver, only 5% in the lungs, 9% in the spleen, and negligible quantities in kidneys, heart and brain. Of the radioactivity in the liver, more than 90% was taken up by Kupffer cells (liver macrophages). The protein in the liver was degraded apparently with first-order kinetics (half-life 40 min). In pigs, over 90% of the intravenously injected dose was recovered in the lungs. The vastly increased recovery in pig lungs, compared with that in rats, is probably due to the pulmonary intravascular macrophages of the pig; macrophages are not normally found in this location in rats (or humans). In a separate series of experiments in rats, the biodistribution of shell material from the microspheres was examined. The microspheres were made to collapse by applying external pressure on the suspension, leaving sedimentable protein material consisting of layers of insoluble albumin from the 'shells' surrounding the air bubble. The 'shells' and the microspheres were cleared from the circulation and taken up by the liver with the same kinetics. In the lungs, a higher proportion (15%) of shells than of microspheres was recovered.

Uptake, intracellular transport, and degradation of polyethylene glycol-modified asialofetuin in hepatocytes.

Polyethylene glycol (PEG) is attached to proteins in order to increase their half-life in the circulation and reduce their immunogenicity in vivo. For many applications involving "targeting" molecules, it is important to know how PEG modification of the molecule affects its interaction with a receptor and the subsequent internalization, intracellular transport, and lysosomal degradation. As a model system, we used asialofetuin, which binds to the galactose receptor of hepatocytes, because removal of sialic acid exposes galactose residues. We modified asialofetuin by attaching various amounts of PEG of molecular weight 1900 or 5000. The preparations were labeled with 125I so that endocytosis and degradation could be followed in suspended hepatocytes. Depending on the number of PEG molecules attached, receptor-mediated uptake was affected to varying degrees. If two-thirds of the exposed amino groups of the asialofetuin molecule were modified, the rate of uptake decreased to less than one-fourth of controls; degradation of endocytosed molecules was 12% of controls. The reduction in endocytic uptake was due to a reduced rate of formation of the receptor-ligand complex. Subcellular frationation in density gradients showed that PEG-modified asialofetuin is transported intracellularly and degraded in the same manner as the native protein, but the rate of proteolysis is reduced. This observation explains the paradoxical result of experiments with injection of modified asialofetuin into rats in vivo: even though the clearance of one preparation of PEG-asialofetuin was much slower than that of the native protein, accumulation of radioactivity in the liver from the modified protein was twice as high. The hepatocytes accounted for 85% of the hepatic accumulation of either PEG-modified or native asialofetuin in vivo.

Luminal and basolateral uptake and degradation of insulin in the proximal tubules of the dog kidney.

In order to determine the major routes of insulin degradation in the body, insulin was labelled with a 'trapped' or 'residualizing' label: [125I]tyramine-cellobiose ([125I]TC) and injected intravenously in dogs. In contrast to conventional iodine-labelled insulin (131I-insulin), the [125I]TC-insulin allows measurements of total uptake in specific organs in vivo because the radioactive degradation products do not leave the cells. One h after the injection of trace doses, the amount of radioactivity recovered in the kidney from [125I]TC-insulin was nine times higher than when conventional [131I]insulin was used. In the blood, the amount of acid-precipitable radioactivity was the same for both labelled preparations, indicating similar clearance rates. A comparison of the uptake of insulin in filtering vs. non-filtering (ureter-occluded) kidneys indicated that the uptake of insulin is twice as high through the luminal than through the basolateral cell membrane; after 60 min, 8.9 +/- 0.8% of the injected [125I]TC-insulin dose remained in the filtering kidney and 3.2 +/- 0.2% of the dose was accumulated in the contralateral kidney, with occluded ureter but normal blood perfusion. In both filtering and non-filtering (ureter-occluded) kidneys, the subcellular distributions of [125I]TC-insulin were studied after various times by isopycnic sedimentation in sucrose gradients. No difference between peritubular and tubular uptake was discernible. The intracellular transport was rapid, leading to accumulation of radioactive label in dense lysosomes within 10 min.

Renal uptake and degradation of trapped-label calcitonin.

In order to quantitate the role of the kidneys in the clearance and degradation of calcitonin, a trapped-label procedure was used to label human calcitonin. In contrast to conventional [125I]calcitonin, the trapped-label preparation allows quantitative measurements of the extent of uptake as well as of degradation in vivo because the final degradation products do not leave the cells. Trapped-label calcitonin activated adenylate cyclase of bone cells and kidney, as did the native hormone. Ten minutes after intravenous injection into rats, 16% of a trace dose was found in the kidneys. Renal recovery increased to 20% after one hour; in addition, 14% of the injected dose was found in the urine. Eighty per cent of the radioactivity in the urine was in high-molecular weight material. After 90 min, the sum of the accumulated radioactivities in the kidneys and the urine reached 40% of the dose. More than 80% of the radioactivity was sedimentable by centrifuging in a density gradient, indicating that intact calcitonin, as well as the degradation products in the cells, were enclosed within membrane-bound vesicles. Two minutes after injection of trapped-label calcitonin, the peak of radioactivity was found in light gradient fractions associated with cell membrane marker enzymes. Between 5 and 15 min, the peak migrated from light fractions to heavy fractions containing lysosomal marker enzymes. After just 2.5 min, 61% of the renal radioactivity was in low-molecular weight degradation products, as determined by gel filtration. The kinetics of renal degradation of calcitonin indicate that substantial amounts of endocytosed calcitonin is degraded before the hormone reaches the lysosomes.

Lysosomal and endosomal heterogeneity in the liver: a comparison of the intracellular pathways of endocytosis in rat liver cells.

Air-filled albumin microspheres, asialoorosomucoid and formaldehyde-treated serum albumin are selectively taken up by endocytosis in rat liver Kupffer cells, parenchymal cells and endothelial cells, respectively. Intracellular transport and degradation of endocytosed material were studied by subcellular fractionation in sucrose and Nycodenz gradients after intravenous injection of the ligand. By using ligands labeled with 125I-tyramine-cellobiose, the subcellular distribution of labeled degradation products can be studied because they are trapped at the site of formation. The results show that the kinetics of intracellular transport are different in hepatic parenchymal, endothelial and Kupffer cells. In endothelial cells, the ligand is associated with two types of endosomes during the first minutes after internalization and then is transferred rapidly to the lysosomes. In parenchymal cells, 125I-tyramine-cellobiose-asialoorosomucoid was located in a relatively slowly sedimenting vesicle during the first minute after internalization and subsequently in denser endosomes. Degradation of 125I-tyramine-cellobiose-asialoorosomucoid in parenchymal cells started later than that of 125I-tyramine-cellobiose-formaldehyde-treated serum albumin in endothelial cells. Furthermore, the ligand seemed to be transferred relatively slowly from endosomes to lysosomes, and most of the undegraded ligand was in the endosomes. The rate-limiting step of proteolysis in parenchymal cells is probably the transport from endosomes to lysosomes. In Kupffer cells, most 125I-tyramine-cellobiose-microspheres are found as undegraded material in very dense endosomes up to 3 hr after injection. After 20 hr, most of the ligand is degraded in lysosomes distributed at a lower density than the endosomes in Nycodenz and sucrose gradients.

Reabsorption and intracellular transport of cytochrome c and lysozyme in rat kidney.

Renal uptake and degradation of cytochrome c and lysozyme were investigated, using preparations that were labelled by means of covalent coupling of either protein to iodinated tyramine-cellobiose. Following proteolytic digestion, the label remains 'trapped' within intracellular organelles. Within 15 min after intravenous injection, 43% of the [125I]tyramine-cellobiose-cytochrome c and 29% of the [131I]tyramine-cellobiose-lysozyme were recovered in the kidneys. Isopycnic sucrose-gradient fractionation indicates that the two proteins initially exhibit closely similar intracellular distributions, being associated with vesicles of an equilibrium density slightly lower than that of plasma membranes. However, within 5 min after injection, the two proteins exhibit distinctly different distribution profiles. The [125I]tyramine-cellobiose-cytochrome c is localized predominantly in the lysosomal fraction of the gradient. The [131I]tyramine-cellobiose-lysozyme is also translocated to the lysosomal fraction, but at a much lower rate. For both proteins, the rates of intracellular degradation correlate with their rates of translocation. The observed difference in their kinetics of intracellular movement suggests that the two proteins are translocated at different rates into transport vesicles.

Renal uptake and degradation of trapped-label insulin.

In order to study the kinetics of insulin degradation in the kidneys and liver, insulin was labelled by a trapped-label procedure and injected into rats. In contrast to conventional 125I-insulin, the trapped-label preparation allows quantitative measurements of the extent of degradation in vivo because the final degradation products do not leave the cells. One hour after injection, the amount of radioactivity in the kidneys from a trace dose of trapped-label insulin was 10 times higher that from conventionally labelled insulin; over 80% of the increase was due to low molecular weight degradation products which were retained in the kidneys. The amount of acid-precipitable radioactivity in the blood was the same for both labelled preparations, indicating that their rates of clearance were similar. In the kidney, we detected no degradation products of molecular weight intermediate between intact insulin and the end products of proteolysis. After 2 h, 33% of the injected dose remained in the kidneys and only 13% in the liver. Over 80% of the renal radioactivity was sedimentable in an isotonic density gradient, indicating that intact insulin, as well as degradation products in the cells, were enclosed within membrane-bound vesicles.

Effect of maleate on tubular protein reabsorption in dog kidneys.

To examine the effects on protein and electrolyte reabsorption of reducing the energy supply to the proximal tubules, an inhibitor of the citric acid cycle, maleate (600 mg.kg-1), was administered to anesthetized dogs during continuous ethacrynic acid infusion. One hour after infusion, maleate reduced renal oxygen consumption from 128 +/- 3 to 48 +/- 6 mumol.min-1. Comparisons at similar GFR showed that maleate reduced bicarbonate reabsorption by 65%, chloride reabsorption by 60% and phosphate reabsorption by 90%. Tubular reabsorption of lysozyme, determined by the 'trapped-label' method, was reduced by 97%. Total protein excretion in urine increased from 0.12 to 1.0 mg.min-1 and was not associated with a significant increase in brush border and lysosome marker enzymes. However, by superimposing a carbonic anhydrase inhibitor, acetazolamide (100 mg.kg-1), electrolyte reabsorption was slightly further reduced but protein excretion increased to 2.7 mg.min-1, coincidentally with a dramatic increase in enzyme excretion: approximately 20-fold in the brush border enzymes, alanine aminopeptidase and alkaline phosphatase, and 10-fold in the lysosomal enzymes, acid phosphatase and N-acetyl-beta-glucosaminidase. Our data indicate that maleate stops protein reabsorption without signs of acute tubular damage, whereas subsequent administration of acetazolamide results in tubular desquamation and albumin leakage.

Endocytosis of asialo-glycoproteins and attachment to asialo-glycoproteins of hepatocytes from carcinogen-treated rats.

Endocytosis and degradation of asialo-glycoprotein were investigated in hepatocytes from carcinogen-treated rats. The cells were isolated at an early stage of carcinogenesis after a sequential treatment with diethylnitrosamine and 2-acetylaminofluorene. Hepatocytes at this pre-nodular stage take up asialo-orosomucoid at a lower rate than hepatocytes from normal rats, whereas degradation of the protein occurs at a similar rate in the two populations. The lower rate of uptake appears to result from a decreased binding capacity in treated hepatocytes. The reduced binding capacity leads to slower kinetics of cell attachment to a substratum of asialo-glycoprotein. The lower number of receptors did not seem to be confined to a particular subpopulation of hepatocytes. Diploid and tetraploid hepatocytes, isolated by centrifugal elutriation, displayed the same reduction in binding capacity.

Isolation of carcinogen-induced diploid rat hepatocytes by centrifugal elutriation.

The majority of hepatocytes isolated from rats treated with carcinogens (diethylnitrosamine plus 2-acetylaminofluorene) were found to be diploid, whereas most of the hepatocytes from normal rats are tetraploid. The carcinogen-induced diploid hepatocytes were only one-half the size (protein content) of the tetraploid hepatocytes, and could therefore be separated from the latter by centrifugal elutriation. The elutriation technique thus makes it possible to isolate a relatively pure fraction of carcinogen-induced cells. The diploid cells had the same liver-specific enzymatic and functional properties as the tetraploid cells and were thus undoubtedly of hepatocytic origin.

Quantitative aspects of the uptake and degradation of lysozyme in the rat kidney in vivo.

Uptake and degradation of lysozyme in the rat kidney were studied in vivo. The protein was labeled with 125I by way of a moiety (tyramine-cellobiose or 'TC') which remained trapped inside the cells even after proteolysis of the peptide chain (in contrast, the label from conventionally labeled proteins escapes after degradation). Following the injection of 'trapped-label' lysozyme, the radioactivity in the kidneys represented the total amount of lysozyme that was taken up during the experiment. Proteolysis could be followed by determining the amount of acid-soluble degradation products. By adding the radioactivity in the urine to that in the kidneys, a measure of the total filtered load was obtained. When only a trace dose of 125I-labeled TC lysozyme was injected into rats, the amount of radioactivity in the kidneys increased on average by 0.09% per min, after the concentration in the blood had become nearly stable. After 100 min, 30% of the injected dose was recovered in the kidneys. The labeled protein was degraded to acid-soluble molecules of Mr less than 1000. There was apparently a 'lag period' between the endocytosis in the kidneys and the start of degradation. 40 min after the injection of a trace dose, about 0.6% of the 'trapped-label' lysozyme in the kidneys was degraded per min.; subsequently, there was a decline in the fraction which was degraded per min. The amount of lysozyme in the urine increased after the injection of increasing amounts of lysozyme, showing that the capacity of the uptake mechanism was being exceeded, but truly saturating levels of lysozyme could not be reached in vivo.

Use of [3H]raffinose as a specific probe of autophagic sequestration.

The trisaccharide [3H]raffinose, introduced into the cytosol of isolated rat hepatocytes by means of electropermeabilization, was sequestered autophagically and accumulated in lysosomes and pre-lysosomal vacuoles. In contrast to the disaccharide [14C]sucrose previously used as a sequestration probe, raffinose was not taken up by the mitochondria. The sequestration of raffinose was completely inhibited by the autophagy suppressor 3-methyladenine, stressing its potential utility as a specific probe of hepatocytic autophagy.

Use of digitonin extraction to distinguish between autophagic-lysosomal sequestration and mitochondrial uptake of [14C]sucrose in hepatocytes.

In isolated rat hepatocytes, electroinjected [14C]sucrose is sequestered both by mitochondria and by autophagosomes/lysosomes. Radioactivity can be selectively extracted from the latter organelles by low concentrations of digitonin, thereby providing a specific bioassay for autophagic sequestration. By including a digitonin extraction step in the assay procedure, autophagic [14C]sucrose sequestration could be shown to be virtually completely (greater than 90%) suppressed by the autophagy inhibitor 3-methyladenine (10 mM), whereas mitochondrial sugar uptake was unaffected. An amino acid mixture likewise suppressed autophagic sequestration very strongly, while having no detectable effect on the mitochondria.