A Novel Self-Micro-Emulsifying Delivery System Enhances Enrichment of Eicosapentaenoic Acid and Docosahexaenoic Acid after Single and Repeated Dosing in Healthy Adults in a Randomized Trial

Background

A self-micro-emulsifying delivery system (SMEDS) promotes spontaneous emulsification of omega-3 (n-3) ethyl esters (EEs) into microdroplets in the stomach.

Objective

The objective was to compare the effect of SMEDS preparations of eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) EEs with standard EEs on EPA and DHA concentrations in the bloodstream after a single dose and repeated daily dosing.

Methods

Eighty healthy subjects aged 18-65 y were randomly assigned to SMEDS-EPA or EE-EPA (both providing more EPA than DHA) or SMEDS-DHA or EE-DHA (both providing more DHA than EPA). They consumed a single dose (1.23-1.33 g EPA+DHA) without a meal, and EPA and DHA were measured in plasma over the following 24 h. Participants continued to take a single dose each morning before breakfast for 12 wk. EPA and DHA were measured in fasting plasma, mononuclear cells (MNCs), and RBCs.

Results

EPA and DHA were higher in plasma in the 24 h after a single dose of SMEDS-EPA or SMEDS-DHA than after consuming the comparator EE (P < 0.001 for both). Compared with the EE form, repeated daily dosing of the SMEDS formulations for 12 wk resulted in higher concentrations of EPA and DHA in plasma (P = 0.086 and 0.005, respectively), MNCs (P < 0.001 and 0.020, respectively), and RBCs (both P < 0.001). The omega-3 index increased over 12 wk from 5.1 ± 0.9 to 7.9 ± 0.9 in the SMEDS-EPA group, from 5.3 ± 1.1 to 9.0 ± 1.2 in the SMEDS-DHA group, from 4.8 ± 0.8 to 6.4 ± 0.9 in the EE-EPA group, and from 5.2 ± 0.9 to 7.2 ± 1.0 in the EE-DHA group (all P < 0.001). The omega-3 index was higher with SMEDS than with the comparator EE at 12 wk (both P < 0.001).

Conclusions

Compared with standard EEs, a SMEDS results in greater incorporation of EPA and DHA into blood pools after a single dose and with repeated daily dosing in healthy adults. A SMEDS enhances delivery of bioactive ω-3 fatty acids. This trial was registered at www.isrctn.com as ISRCTN96459690.

Enhanced activity of lysosomal proteases in activated rat hepatic stellate cells is associated with a concomitant increase in the number of the mannose-6-phosphate/insulin-like growth factor II receptor

Activated hepatic stellate cells (HSCs) play a central role during hepatic tissue repair through their influence on extracellular matrix remodelling. We have determined whether the activity levels of cathepsin B and D are affected by in vitro activation of rat HSCs, and whether the enzymes were released from the cells. Furthermore, given the important role of the mannose-6-phosphate/insulin-like growth factor II receptor (M6P/IGF-IIR) in the intracellular transport of lysosomal enzymes, we have examined whether changes in the activity of these proteases were associated with parallel changes in the level of the M6P/IGF-IIR. The activity of cathepsin B and D increased ∼4 times between 2 and 8 days of HSC culture. This result was supported by analysing mRNA expression by RT-PCR. The cells released the enzymes into the culture medium, amounting to ∼10% of the cell-associated activity over 24 h. The release of enzymes was not affected by reducing medium pH from 7.4 to 6.2, indicating that the enzymes were transported to the medium independently of the M6P/IGF-II-R. The released cathepsin B was mostly in the inactive proenzyme form. HSC activation led to a particularly large increase in M6P/IGF-IIR expression. A large proportion of the receptors was located on the cell surface and was found to be very suitable for measuring endocytosis of (125) I-IGF-II. The results show that the endocytic activity increased in parallel with the increase in surface receptors and activity of lysosomal enzymes. Degradation of the ligand was reduced by inhibitors of lysosomal proteases and therefore took place in lysosomes.

The fate of Gd and chelate following intravenous injection of gadodiamide in rats

Objective

The biodistribution of gadolinium (Gd) and chelate was studied in rats injected intravenously with a commercially available gadodiamide magnetic resonance contrast agent spiked with trace amounts of ¹⁴C-labelled GdDTPA-BMA.

Methods

Biodistribution of the ¹⁴C-labelled ligand in whole animals was visualised using quantitative whole-body autoradiography, and quantified in individual tissue samples by analysing for radioactivity using beta-counting. Biodistribution of Gd was measured by inductively coupled plasma atomic emission spectroscopy (ICP-AES) and inductively coupled plasma sector field mass spectrometry (ICP-SF-MS).

Results

The injected dose was rapidly excreted, with only 1.0% remaining in the body at 24 h. The radioactivity thereafter was mainly associated with kidney cortex, liver, lung, muscle and skin, with a similar rate of clearance for both ligand and Gd from these tissues. The ratio between ¹⁴C-labelled substance and Gd was not significantly different from that of the injected substance in most tissue samples up to 24 h after injection; the ratio then slowly decreased.

Conclusions

The data clearly show that measurements of Gd concentration alone in tissue samples from animals injected with Gd-based contrast agents (GBCAs) cannot be used as a measure of Gd released from the ligand. To our knowledge, such measurements comparing Gd and ligand concentrations and distribution in tissue samples have not been published previously for any of the commercial GBCAs.

Radiosynthesis and biodistribution of cyclic RGD peptides conjugated with novel [18F]fluorinated aldehyde-containing prosthetic groups

Achieving high-yielding, robust, and reproducible chemistry is a prerequisite for the (18)F-labeling of peptides for quantitative receptor imaging using positron emission tomography (PET). In this study, we extend the toolbox of oxime chemistry to include the novel prosthetic groups [(18)F]-(2-{2-[2-(2-fluoroethoxy)ethoxy]ethoxy}ethoxy)acetaldehyde, [(18)F]5, and [(18)F]-4-(3-fluoropropoxy)benzaldehyde, [(18)F]9, in addition to the widely used 4-[(18)F]fluorobenzaldehyde, [(18)F]12. The three (18)F-aldehydes were conjugated to the same aminooxy-bearing RGD peptide and the effect of the prosthetic group on biodistribution and tumor uptake studied in mice. The peptide conjugate [(18)F]7 was found to possess superior in vivo pharmacokinetics with higher tumor to blood, tumor to liver, tumor to muscle, and tumor to lung ratios than either [(18)F]10 or [(18)F]13. The radioactivity from the [(18)F]7 conjugate excreted more extensively through the kidney route with 79%id passing through the urine and bladder at the 2 h time point compared to around 55%id for the more hydrophobic conjugates [(18)F]10 and [(18)F]13. The chemical nature of a prosthetic group can be employed to tailor the overall biodistribution profile of the radiotracer. In this example, the hydrophilic nature of the ethylene glycol containing prosthetic group [(18)F]5 clearly influences the overall excretion pattern for the RGD peptide conjugate.

NC-100717: a versatile RGD peptide scaffold for angiogenesis imaging

Targeting the molecular pathways associated with angiogenesis offers great potential in detecting disease pathology using in vivo imaging technologies. Initiation of angiogenesis requires activation and migration of endothelial cells in order for neovascularization to proceed. Endothelial cells associate with the extracellular matrix through specific interactions with a variety of cell adhesion receptors known as integrins. Peptides containing the tripeptide sequence RGD are known to bind with high affinity to the alphavbeta3 and alphavbeta5 integrins associated with angiogenesis. We present herein the synthesis and in vitro binding affinity of the RGD-containing peptide NC-100717 and a range of molecular probes derived from this intermediate.

Hepatic cellular distribution and degradation of iron oxide nanoparticles following single intravenous injection in rats: implications for magnetic resonance imaging

The purpose of this study was to determine the cellular distribution and degradation in rat liver following intravenous injection of superparamagnetic iron oxide nanoparticles used for magnetic resonance imaging (NC100150 Injection). Relaxometric and spectrophotometric methods were used to determine the concentration of the iron oxide nanoparticles and their degradation products in isolated rat liver parenchymal, endothelial and Kupffer cell fractions. An isolated cell phantom was also constructed to quantify the effect of the degradation products on the loss of MR signal in terms of decreased transverse relaxation times, T2*. The results of this study show that iron oxide nanoparticles found in the NC100150 Injection were taken up and distributed equally in both liver endothelial and Kupffer cells following a single 5 mg Fe/kg body wt. bolus injection in rats. Whereas endothelial and Kupffer cells exhibited similar rates of uptake and degradation, liver parenchymal cells did not take up the NC100150 Injection iron oxide particles. Light-microscopy methods did, however, indicate an increased iron load, presumably as ferritin/hemosiderin, within the hepatocytes 24 h post injection. The study also confirmed that compartmentalisation of ferritin/hemosiderin may cause a significant decrease in the MRI signal intensity of the liver. In conclusion, the combined results of this study imply that the prolonged presence of breakdown product in the liver may cause a prolonged imaging effect (in terms of signal loss) for a time period that significantly exceeds the half-life of NC100150 Injection iron oxide nanoparticles in liver.

Hepatic clearance of Sonazoid perfluorobutane microbubbles by Kupffer cells does not reduce the ability of liver to phagocytose or degrade albumin microspheres

This study has been performed to examine which cells are responsible for the hepatic clearance of the new ultrasound contrast agent Sonazoid and to study whether uptake of these gas microbubbles disturbs the function of the cells involved. Sonazoid was injected into rats and perfused fixed livers were studied by electron microscopy, which revealed that the Sonazoid microbubbles were exclusively internalised in Kupffer cells, i.e. by the macrophages located in the liver sinusoids, and not by parenchymal, stellate or endothelial cells. This is the first demonstration of intact phagocytosed gas microbubbles within Kupffer cells. Uptake of the Sonazoid perfluorobutane microbubbles by the Kupffer cells following injection of a dose corresponding to 20x the anticipated clinical dose for liver imaging did not result in measurable changes in the uptake and degradation of radioactively labelled albumin microspheres previously shown to be a useful indicator marker for Kupffer cell phagocytosis.

Distribution of liposome-encapsulated iodixanol in rat liver cells

Distribution of liposome-encapsulated [(125)I]iodixanol in different types of liver cells following intravenous injection was studied in rats. The data showed that liposome-encapsulated [(125)I]iodixanol was rapidly taken up by the liver; after 15 min, radioactivity corresponding to nearly 25% of the injected radioactivity could be recovered therein. After 4 hr, approximately 60% of the injected radioactivity was in the liver. One week after injection, nearly 30% of the encapsulated radioactivity could still be recovered in the liver. Liposome-encapsulated [(125)I]iodixanol was taken up both by hepatocytes and the Kupffer cells. On a per cell basis, the uptake of liposome-encapsulated [(125)I]iodixanol in Kupffer cells was more than 10-fold greater than that in hepatocytes, while the contribution of liver endothelial cells to uptake was negligible. Osmotic protection studies showed that iodixanol does not readily diffuse across lysosomal membranes, indicating that loss of iodixanol from the liver probably occurred by recycling rather than by diffusion across phagolysosomal and plasma membranes.

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.

Mangafodipir trisodium injection, a new contrast medium for magnetic resonance imaging: in vitro metabolism and protein binding studies of the active component MnDPDP in human blood

The binding to human serum proteins of MnDPDP (manganese(II) dipyridoxyl diphosphate), the active component of the magnetic resonance imaging contrast medium mangafodipir trisodium injection (Teslascan) was studied in ultrafiltration experiments. Sera from three males and three females were incubated with 86 microM [14C]MnDPDP for 60 min at room temperature (20-23 degrees C), followed by centrifugation through filters with a cut-off of 30 kDa. Analysis of the filtrates and the initial incubation mixtures for manganese, by ICP-AES, and for DPDP and its dephosphorylated metabolites DPMP (dipyridoxyl monophosphate) and PLED (dipyridoxyl ethylenediamine diacetate) by liquid scintillation counting, showed a clear difference in protein binding of manganese and the ligands under these conditions. Only 2.2 +/- 1.8% (mean +/- S.E.; n = 6) of DPDP, DPMP and PLED were bound to protein, whereas 26.9 +/- 2.9% (mean +/- S.E.; n = 6) of manganese was bound to protein. No binding of DPDP, DPMP or PLED to blood cells was observed when whole blood, containing either heparin or EDTA as anticoagulant, was spiked with [14C]MnDPDP and the cell-free fraction and the lysed cell fraction analysed by liquid scintillation counting. The extent of protein binding of manganese corresponded well with results from an in vitro metabolism study, in which MnDPDP was added to heparinized human whole blood, showing that approximately 25% of DPDP, DPMP or PLED were not bound to manganese. The in vitro metabolism study revealed that transmetallation with zinc was nearly complete within 1 min, and that dephosphorylation is a sequential process going from DPDP to the monophosphate DPMP, and then to the fully dephosphorylated compound PLED.

Retinol-binding protein and asialo-orosomucoid are taken up by different pathways in liver cells

The intracellular transport and degradation of in vivo endocytosed retinol-binding protein was compared with that of asialo-orosomucoid, a marker for receptor-mediated endocytosis through coated pits. The transport pathways were studied in rat liver cells by means of subcellular fractionation in Nycodenz and sucrose density gradients and by immunoelectron microscopy. Retinol-binding protein and asialo-orosomucoid were labeled by covalent attachment of radioiodinated tyramine cellobiose, an adduct which is incapable of crossing cellular membranes and thus provides a marker for the organelles where the protein has been taken up and degraded. The data obtained from subcellular fractionation studies, as well as from immunoelectron microscopy, showed that retinol-binding protein and asialo-orosomucoid were initially localized in different endocytic vesicles. Retinol-binding protein co-localized in density gradients with markers for potocytosis, an alternative endocytic pathway which uses internalization through caveolae instead of clathrin-coated pits. Later, retinol-binding protein and asialo-orosomucoid comigrated in the gradients and they were also observed in the same larger vesicles by immunoelectron microscopy. These data suggest that retinol-binding protein is taken up by liver cells by potocytosis and that a fraction of the retinol-binding protein is later transferred to larger vesicles located deeper in the cytoplasm where degradation takes place.

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.

Receptor-mediated endocytosis of retinol-binding protein by liver parenchymal cells: interference by radioactive iodination

Retinol-binding protein (RBP) was iodinated directly by radio-iodine substitution on the tyrosyl residues by the sodium hypochlorite (NaOCl) or the Enzymobead (EB) methods, or indirectly by linkage of 125I-tyramine-cellobiose (TC) or 125I-N-succinimidyl-3-(4- hydroxyphenyl)propionic acid ester (SHPP) adduct on to free amino residues of RBP. Binding, uptake and degradation of iodinated RBP were studied in isolated rat and rabbit liver parenchymal cells. The amount of ligand bound to cells at 4 degrees C was dependent on the type of labelling, in that the 125I-TC ligand was bound to a lesser extent than NaClO-labelled 125I-RBP, EB-labelled 125I-RBP and 125I-SHPP-RBP. At 37 degrees C, the 125I-SHPP-RBP and the EB-labelled 125I-RBP became cell-associated more rapidly than the other two ligands. The higher cell association at 37 degrees C than at 4 degrees C suggests that internalization of the ligand occurred at the higher temperature. The degradation of the ligands was also different. The EB-labelled 125I-RBP, the 125I-TC-RBP and the 125I-SHPP-RBP showed an apparent lag phase before a steady increase in acid-soluble radioactivity was observed. Much less of EB-labelled 125I-RBP and 125I-TC-RBP were degraded (about 6%) than of the other two ligands (about 16%) after 120 min. About 50% of the acid-soluble radioactivity in these experiments could be accounted for by degradation in the medium, suggesting that about half of the degradation observed was intracellular. The present study therefore shows that the different labelling techniques yield varying estimates of the cellular handling of RBP. In addition, a rapid release of RBP was observed in experiments where cells were pulsed with radioactive RBP at 4 degrees C, washed and incubated further at 37 degrees C. Between 50% and 70% was released after 5 min of incubation. By increasing the temperature during the pulse to 37 degrees C, or by lowering the temperature during the chase to 4 degrees C, much less RBP was released from the cells. These data suggest that the release process represents recycling of internalized ligand from an early endosome.

Rat hepatocyte hyaluronan/glycosaminoglycan binding proteins: evidence for distinct divalent cation-independent and divalent cation-dependent activities

We have previously shown (Biochemistry, 29, 10425, 1990) that hepatocytes contain intracellular specific binding sites for hyaluronan (HA). Although HA-binding activity is not dependent on divalent cations, it is increased in the presence of Ca+2. Here we report that a novel photoaffinity HA derivative (ASD-HA) crosslinks specifically to different proteins in permeable cells in the presence or absence of Ca+2. With Ca+2 present, two proteins of approximately 24 kD and 43 kD were labeled. Additionally, a broad zone of specific crosslinking was observed in the region of 40-100 kD. However, in the presence of the chelator EGTA this zone was absent and the 24 and 43 kD proteins were also not cross-linked to the HA photoaffinity derivative. In the absence of Ca+2, only a 54 kD protein was specifically labeled. The results indicate that different intracellular hepatocyte proteins are responsible for the Ca+2-independent and the Ca+2-dependent binding of HA.

Clearance of purified human liver γ-glutamyltransferase after intravenous injection in the rat

The clearance of gamma-glutamyltransferase was studied by injecting the purified human liver enzyme intravenously in the rat. The results show a biphasic clearance, with a rapid initial rate of removal. The initial uptake is more rapid for neuraminidase-treated GT. Liver accounts for the bulk organ uptake and the enzyme is almost exclusively taken up into the parenchymal cells. We suggest that the uptake of circulating GT is receptor mediated, most likely by the galactose receptor of the parenchymal cells.

Intracellular transport of ovalbumin afterin vivo endocytosis in rainbow trout liver

The intracellular handing of a mannose-terminated glycoprotein taken up in rainbow trout liver cells by receptor-mediated endocytosis has been studied. The intracellular transport and degradation of ovalbumin (OA) were studied by means of subcellular fractionation in Nycodenz gradients and by differential centrifugation following intravenous injection of the ligand. By using OA labelled with(125)I-tyramine cellobiose ((125)I-TC), the subcellular distribution of labelled degradation products could be studied, since they are trapped intracellularly in the organelle where the degradation takes place. (125)I-TC-OA was shortly after injection (45 min) localized in a homogenous population of endosomes. Labelled degradation products firs appeared in an organelle with the same density distribution as the endosomes. In livers homogenized 2h after injection the degradation products appeared in organelles with increasing size and density. After 24h, the degradation products were recovered in at least two populations of lysosomes with a distribution profile which coincided with that of the lysosomal enzyme β-acetylglucosaminidase.The heterogeneous distribution of the late degradation products seemed not to be due to uptake of ligand in different liver cell types as only the parenchymal liver cells took up labelled OA after intravenous injection of the ligand.

Internalization of retinol-binding protein in parenchymal and stellate cells of rat liver

We have studied uptake of retinol-binding protein (RBP) by rat liver cells. First, we compared the in vivo uptake in different liver cells of 125I-labeled RBP with that of other well-known ligands. We found that the ligands studied were recognized differently by the various cell types in the liver, and that RBP was most efficiently taken up by parenchymal and stellate cells. We then studied the in vivo uptake of RBP in liver cells by immunocytochemistry at the electron microscopic level using ultrathin cryosections. Ten min after injection, RBP was localized to parenchymal cells and stellate cells. In these cells, RBP was detected on the cell surface and in vesicles near the cell surface. RBP was observed mainly in association with the membrane in these vesicles. Two hours after injection, RBP was localized not only on the cell surface and in vesicles close to the cell surface, but also in larger vesicles located deeper in the cytoplasm of these cells. RBP in larger vesicles was observed at a distance from the vesicular membrane. Finally, we compared the distribution of endocytosed RBP in liver parenchymal cells with that of asialo-orosomucoid, a ligand known to be internalized by receptor-mediated endocytosis. We detected both ligands on the cell surface and in small vesicles located close to the cell surface and in larger vesicles located deeper in the cytoplasm. Asialo-orosomucoid and RBP were seldom observed in the same small vesicles, but the larger vesicles contained both ligands. These data suggest that RBP is internalized in parenchymal and stellate cells of the liver by receptor-mediated endocytosis.

The effect of vanadate on receptor-mediated endocytosis of asialoorosomucoid in rat liver parenchymal cells

Vanadate is a phosphate analogue that inhibits enzymes involved in phosphate release and transfer reactions (Simons, T. J. B. (1979) Nature 281, 337-338). Since such reactions may play important roles in endocytosis, we studied the effects of vanadate on various steps in receptor-mediated endocytosis of asialoorosomucoid labeled with 125I-tyramine-cellobiose (125I-TC-AOM). The labeled degradation products formed from 125I-TC-AOM are trapped in the lysosomes and may therefore serve as lysosomal markers in subcellular fractionation studies. Vanadate reduced the amount of active surface asialoglycoprotein receptors approximately 70%, but had no effect on the rate of internalization and retroendocytosis of ligand. The amount of surface asialoglycoprotein receptors can be reduced by lowering the incubation temperature gradually from 37 to 15 degrees C (Weigel, P. H., and Oka, J. A. (1983) J. Biol. Chem. 258, 5089-5094); vanadate affected only the temperature--sensitive receptors. Vanadate inhibited degradation of 125I-TC-AOM 70-80%. Degradation was much more sensitive to vanadate than binding; half-maximal effects were seen at approximately 1 mM vanadate for binding and approximately 0.1 mM vanadate for degradation. By subcellular fractionation in sucrose and Nycodenz gradients, it was shown that vanadate completely prevented the transfer of 125I-TC-AOM from endosomes to lysosomes. Therefore, the inhibition of degradation by vanadate was indirect; in the presence of vanadate, ligand did not gain access to the lysosomes. The limited degradation in the presence of vanadate took place in a prelysosomal compartment. Vanadate did not affect cell viability and ATP content.

Endocytosis mediated by the mannose receptor in liver endothelial cells. An immunocytochemical study

Immunocytochemical labeling of ultrathin cryosections from rat liver showed that mannose-terminated glycoproteins are removed rapidly from the blood stream mainly by the sinusoidal endothelial cells. The mannose-terminated glycoprotein ovalbumin was injected intravenously into rats 1 min, 6 min, and 24 min before perfusion fixation of the liver. Several minor and at least three major subcellular compartments were shown to be involved in the endocytic process. One minute after injection, ovalbumin was found at the cell surface, in coated pits, in coated vesicles, in tubular structures, and bound to the membrane of large early endosomes of which some showed a cisternal structure. After 6 min, ovalbumin was found in the lumen of large electron-lucent late endosomes and after 24 min in electron-dense structures, presumably lysosomes. The early endosomes have an ultrastructure which, together with the labeling pattern, indicates that this compartment has the same function as the CURL identified in parenchymal liver cells. The results are in accordance with recent biochemical findings indicating that ovalbumin endocytosed by endothelial cells is found sequentially in three different subcellular fractions depending on the time between injection and cooling for fractionation (G. M. Kindberg, T. Berg: Intracellular transport of endocytosed mannose terminated glycoproteins in rat liver endothelial cells. In: E. Wisse, D. L. Knook, K. Decker (eds.): Cells of the Hepatic Sinusoid. Vol. 2. pp. 120-124. Kupffer Cell Foundation. Rijswijk The Netherlands 1989).

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.

Heterogeneity of degradation of B-cell endocytosed monoclonal antibodies reacting with different sIgM epitopes

The degradation of a panel of monoclonal antibodies (MoAb) bound to surface IgM (sIgM) was studied in three human Burkitt's lymphoma cell lines. The panel included MoAb that recognize several distinct epitopes associated with the F(c mu)5 domain, the c mu 2 domain and kappa or lambda light chains. The amount of degraded MoAb and the rate of their degradation varied considerably between the various antibodies. Properties of MoAb such as avidity or ability to cross-link sIgM did not significantly influence their degradation. The most consistent correlation between rate of degradation and MoAb used was the location of the epitope recognized by the individual MoAb. Thus, 7 out of 8 anti-light chain MoAb were degraded at a higher rate than 5 out of 5 anti-F(c mu)5 MoAb. One anti-c mu 2 MoAb was degraded at a rate similar to the majority of anti-light chain MoAb. The intracellular transport of an anti-kappa light chain MoAb and an anti-F(c mu)5 MoAb was studied in detail by subcellular fractionation in sucrose gradients. We found that the anti-kappa light chain MoAb was transported more rapidly to lysosomes than the anti-F(c mu)5 MoAb, showing that they were sorted differently intracellularly.

Intracellular transport of formaldehyde-treated serum albumin in liver endothelial cells after uptake via scavenger receptors

Endocytosis of formaldehyde-treated serum albumin (FSA) mediated by the scavenger receptor was studied in rat liver endothelial cells. Suspended cells had about 8000 receptors/cell, whereas cultured cells had about 19,000 receptors/cell. Kd was 10(-8) M in both systems. Cell-surface scavenger receptors were found exclusively in coated pits by electron microscopy, by using ligand labelled with colloidal gold. Cell-surface-bound FSA could be released by decreasing the pH to 6.0; it was therefore possible to assess the rate of internalization of surface-bound ligand. This rate was very high: t1/2 for internalization of ligand prebound at 4 degrees C was 24 s. The endocytic rate constant at 37 degrees C, Ke, measured as described by Wiley & Cunningham [(1982) J. Biol. Chem. 257, 4222-4229], was 2.44 min-1, corresponding to t1/2 = 12 s. Uptake of FSA at 37 degrees C after destruction of one cell-surface pool of receptors by Pronase was decreased to 60%. This finding is compatible with a relatively large intracellular pool of receptors. The intracellular handling of 125I-tyramine-cellobiose-labelled FSA (125I-TC-FSA) was studied by subcellular fractionation in sucrose gradients, Nycodenz gradients or by differential centrifugation. The density distributions of degraded and undegraded 125I-TC-FSA after fractionation of isolated non-parenchymal cells and whole liver were similar, when studied in Nycodenz and sucrose gradients, suggesting that the subcellular distribution of the ligand was not influenced by the huge excess of non-endothelial material in a whole liver homogenate. Fractionation in sucrose gradients showed that the ligand was sequentially associated with organelles banding at 1.14, 1.17 and 1.21 g/ml. At 9-12 min after intravenous injection the ligand was in a degradative compartment, as indicated by the accumulation of acid-soluble radioactivity at 1.21 g/ml. A rapid transfer of ligand to the lysosomes was also indicated by the finding that a substantial proportion of the ligand could be degraded by incubating mitochondrial fractions prepared 12 min after intravenous injection of the ligand. The results indicate that FSA is very rapidly internalized and transferred through an endosomal compartment to the lysosomes. The endosomes are gradually converted into lysosomes between 9 and 12 min after injection of FSA. The rate-limiting step in the intracellular handling of 125I-TC-FSA is the degradation in the lysosomes.

Degradation of a monoclonal anti-mu chain antibody in a human surface IgM-positive B cell line starts in prelysosomal vesicle

The surface IgM-mediated endocytosis and intracellular transport of an anti-F(c mu)5 mAb was studied by using subcellular fractionation in sucrose gradients. The results of such experiments showed that antibody was initially endocytosed in vesicles of low density, and later transferred to a presumably lysosomal compartment of higher density. SDS-PAGE analysis of gradient fractions showed that high Mr degradation fragments of the endocytosed antibody were formed in the low density vesicles before terminal degradation could be recorded. The partial degradation of the antibody was not blocked by low temperature or enzyme inhibitors, such as leupeptin and benzyloxycarbonyl-phenylalanylalanine-diazomyethyl-ketone, all of which severely retarded terminal degradation. The data also suggested that the recycling of partially degraded antibody to the cell surface employed a pool of such low density prelysosomal vesicles.

Degradation of a monoclonal anti-mu chain antibody in a human surface IgM-positive B cell line starts in prelysosomal vesicle

The surface IgM-mediated endocytosis and intracellular transport of an anti-F(c mu)5 mAb was studied by using subcellular fractionation in sucrose gradients. The results of such experiments showed that antibody was initially endocytosed in vesicles of low density, and later transferred to a presumably lysosomal compartment of higher density. SDS-PAGE analysis of gradient fractions showed that high Mr degradation fragments of the endocytosed antibody were formed in the low density vesicles before terminal degradation could be recorded. The partial degradation of the antibody was not blocked by low temperature or enzyme inhibitors, such as leupeptin and benzyloxycarbonyl-phenylalanylalanine-diazomyethyl-ketone, all of which severely retarded terminal degradation. The data also suggested that the recycling of partially degraded antibody to the cell surface employed a pool of such low density prelysosomal vesicles.

Uptake of LDL in parenchymal and non-parenchymal rabbit liver cells in vivo. LDL uptake is increased in endothelial cells in cholesterol-fed rabbits

1. Hepatic uptake of low-density lipoprotein (LDL) in parenchymal cells and non-parenchymal cells was studied in control-fed and cholesterol-fed rabbits after intravenous injection of radioiodinated native LDL (125I-TC-LDL) and methylated LDL (131I-TC-MetLDL). 2. LDL was taken up by rabbit liver parenchymal cells, as well as by endothelial and Kupffer cells. Parenchymal cells, however, were responsible for 92% of the hepatic LDL uptake. 3. Of LDL in the hepatocytes, 89% was taken up via the B,E receptor, whereas 16% and 32% of the uptake of LDL in liver endothelial cells and Kupffer cells, respectively, was B,E receptor-dependent. 4. Cholesterol feeding markedly reduced B,E receptor-mediated uptake of LDL in parenchymal liver cells and in Kupffer cells, to 19% and 29% of controls, respectively. Total uptake of LDL in liver endothelial cells was increased about 2-fold. This increased uptake is probably mediated via the scavenger receptor. The B,E receptor-independent association of LDL with parenchymal cells was not affected by the cholesterol feeding. 5. It is concluded that the B,E receptor is located in parenchymal as well as in the non-parenchymal rabbit liver cells, and that this receptor is down-regulated by cholesterol feeding. Parenchymal cells are the main site of hepatic uptake of LDL, both under normal conditions and when the number of B,E receptors is down-regulated by cholesterol feeding. In addition, LDL is taken up by B,E receptor-independent mechanism(s) in rabbit liver parenchymal, endothelial and Kupffer cells. The non-parenchymal liver cells may play a quantitatively important role when the concentration of circulating LDL is maintained at a high level in plasma, being responsible for 26% of hepatic uptake of LDL in cholesterol-fed rabbits as compared with 8% in control-fed rabbits. The proportion of hepatic LDL uptake in endothelial cells was greater than 5-fold higher in the diet-induced hypercholesterolaemic rabbits than in controls.

Intracellular transport and degradation of chylomicron remnants in rat liver cells after in vivo endocytosis

The intracellular transport and degradation of in vivo endocytosed chylomicron remnants labelled with 125I in the protein moiety was studied in rat liver cells by means of subcellular fractionation in Nycodenz and sucrose density gradients. Initially, the radioactivity was located in low-density endosomes and was sequentially transferred to light and dense lysosomes. Data from gel filtration of the light and dense lysosomal fractions showed radioactive material with a molecular weight of about 1000-2000, representing short peptide fragments or amino acids which remain attached to iodinated tyramine cellobiose. In addition, undegraded apoproteins accumulated in both types of lysosome. Our data suggest that endocytosed chylomicron remnant apoproteins are first located in low-density endosomes and are sequentially transferred to light and dense lysosomes. Furthermore, the degradation process starts in the light lysosomes.

The relationship between autophagy and the intracellular degradation of asialoglycoproteins in cultured rat hepatocytes

The relationship between autophagy and the intracellular distribution of endocytosed asialoorosomucoid was studied in cultured rat hepatocytes. Overt autophagy was induced by shifting the cells to a minimal salt medium. Incubation in minimal salt medium led to the formation of buoyant lysosomes at the expense of denser lysosomes manifested as a dual distribution of these organelles in Nycodenz gradients. Asialoorosomucoid was labeled with 125I-tyramine cellobiose. The labeled degradation products formed from this ligand are trapped at the site of degradation and may therefore serve as markers for the subgroup of lysosomes involved in the degradation. In control cells the degradation of the ligand was initiated in a light prelysosomal compartment and continued in denser lysosomes. In cells with high autophagic activity, the degradation of labeled asialoorosomucoid took place exclusively in a buoyant group of lysosomes. These results suggest that degradation of endocytosed ligand takes place in the same secondary lysosomes as substrate sequestered by autophagic mechanisms. These light lysosomes represent a subgroup of active lysosomes which are gradually recruited from dense bodies. Data are also presented that indicate that insulin may prevent the change in buoyant density brought about by incubation in deficient medium.

Intracellular transport of asialoglycoproteins in rat hepatocytes. Evidence for two subpopulations of lysosomes

The intracellular transport and degradation of asialoorosomucoid (AOM) in isolated rat hepatocytes was studied by means of subcellular fractionation in Nycodenz gradients. The asialoglycoprotein was labelled by covalent attachment of a radioiodinated tyramine-cellobiose adduct ( [125I]TC) which leads to labelled degradation products being trapped intracellularly and thus serving as markers for the degradative organelles. The ligand was initially (1 min) in a slowly sedimenting (small) vesicle and subsequently in larger endosomes. Acid-soluble, radioactive degradation products were first found in a relatively light lysosome whose distribution coincided in the gradient with that of the larger endosome. Later (30 min) degradation products were found in denser lysosomes which banded in the same region of the gradient as the lysosomal enzyme, beta-acetylglucosaminidase. Colchicine, monensin and leupeptin all inhibited degradation of [125I]tyramine-cellobiose asialoorosomucoid ( [125I]TC-AOM) and reduced the formation of degradation products in both the light and the dense lysosomes. In presence of monensin and colchicine no undegraded ligand was seen in the dense lysosome, suggesting that uptake in these vesicles was inhibited. Leupeptin allowed accumulation of undegraded ligand in the dense lysosome. Therefore, transfer from light to dense lysosomes is not dependent on degradation as such. In the presence of monensin two peaks of undegraded ligand were found in the gradients. It seems possible that in the monensin-sensitive endosomes, dissociation of the ligand-receptor complex is inhibited, allowing ligand to recycle with the receptors in small vesicles.

Intracellular transport of endocytosed chylomicron [3H]retinyl ester in rat liver parenchymal cells. Evidence for translocation of a [3H]retinoid from endosomes to endoplasmic reticulum

The intracellular transport of chylomicron remnants labeled with [3H]retinyl ester was studied in rat liver parenchymal cells by means of subcellular fractionation in Nycodenz and sucrose density gradients. The data presented indicate that endocytosed chylomicron remnant [3H]retinyl ester initially is located in low density endosomes. Radioactivity is subsequently transferred to a denser vesicle. Equilibrium as well as rate zonal centrifugation suggest that this denser [3H] retinoid-containing vesicle may represent endoplasmic reticulum. We have compared the intracellular transport of chylomicron remnant [3H]retinyl ester and 125I-asialofetuin. The receptor-mediated endocytosis of asialoglycoproteins in rat liver parenchymal cells is a thoroughly studied system. Our results suggest that the [3H] retinoid and 125I-asialofetuin follow the same path initially to the endosomes. After transit in endosomes, the intracellular transport differs. While asialofetuin is transported to the lysosomes, the retinoid is probably transferred to the endoplasmic reticulum.

Retinol esterification in cultured rat liver cells

Retinol esterification was examined in cultured hepatocytes and stellate cells from the rat. Esterification of [3H]retinol was linear for 2 h in both cell types. By increasing the concentration of retinol in the medium, there was a marked increase in retinol esterification in both cell types. The capacity for esterification of retinol was in the same order of magnitude in the two cell types at 3.5 microM-retinol in the medium. This represents a rate of retinol esterification which far exceeds that required to esterify the amount of retinol absorbed in the intestine. It was demonstrated in particulate homogenates from cultured hepatocytes that the esterification of retinol was dependent on acyl-CoA. Addition of 25-hydroxycholesterol or mevalonolactone promoted an increase in cholesterol esterification, whereas retinol esterification was unaffected, suggesting that cholesterol and retinol are esterified by two different enzymes. Some 80% of vitamin A in cultured hepatocytes is retinyl esters, mostly retinyl palmitate. By adding 87 microM-retinol in the medium the cells accumulated 100-fold free retinol and 2.5-3.0-fold retinyl esters within 1 h. When retinol-loaded cells were incubated without retinol, there was a marked decrease especially in free but also in esterified retinol. In the presence of 1 mM-oleic acid in the medium the amount of retinyl oleate was twice that in control cells.

Separation of endocytic vesicles in Nycodenz gradients

The endocytosis of 125I-labeled asialofetuin by rat hepatocytes was studied using Nycodenz/sucrose gradients. It was shown in pulse chase experiments that the ligand endocytosed initially (after 1/2 to 1 min) was in small, slow-sedimenting vesicles of similar sizes. The vesicles containing the ligand increased in size, and after about 2.5 min 20-30% of the ligand was recovered in larger, faster-sedimenting vesicles. After 15 min almost all internalized ligand was recovered in the fast-sedimenting vesicles. The initial, small endocytic vesicles and the later, larger endocytic vesicles have similar buoyant densities; the maturation of the endosomes can only be revealed by rate sedimentation, not by isopycnic centrifugation. Dissociation of ligand from receptor was found to occur in the larger, faster-sedimenting vesicles. The presence of ammonia inhibited the increase in size of the ligand-containing endosomes. The methods employed here offer the possibility of obtaining endocytic vesicles at various stage of their development for further studies.