Kinetic analysis of receptor-mediated endocytosis of epidermal growth factor by isolated rat hepatocytes

Optimization of a nanomedicine-based silicon phthalocyanine 4 photodynamic therapy (Pc 4-PDT) strategy for targeted treatment of EGFR-overexpressing cancers

The current clinical mainstays for cancer treatment, namely, surgical resection, chemotherapy, and radiotherapy, can cause significant trauma, systemic toxicity, and functional/cosmetic debilitation of tissue, especially if repetitive treatment becomes necessary due to tumor recurrence. Hence there is significant clinical interest in alternate treatment strategies like photodynamic therapy (PDT) which can effectively and selectively eradicate tumors and can be safely repeated if needed. We have previously demonstrated that the second-generation photosensitizer Pc 4 (silicon phthalocyanine 4) can be formulated within polymeric micelles, and these micelles can be specifically targeted to EGFR-overexpressing cancer cells using GE11 peptide ligands, to enhance cell-specific Pc 4 delivery and internalization. In the current study, we report on the in vitro optimization of the EGFR-targeting, Pc 4 loading of the micellar nanoformulation, along with optimization of the corresponding photoirradiation conditions to maximize Pc 4 delivery, internalization, and subsequent PDT-induced cytotoxicity in EGFR-overexpressing cells in vitro. In our studies, absorption and fluorescence spectroscopy were used to monitor the cell-specific uptake of the GE11-decorated Pc 4-loaded micelles and the cytotoxic singlet oxygen production from the micelle-encapsulated Pc 4, to determine the optimum ligand density and Pc 4 loading. It was found that the micelle formulations bearing 10 mol % of GE11-modified polymer component resulted in the highest cellular uptake in EGFR-overexpressing A431 cells within the shortest incubation periods. Also, the loading of ∼ 50 μg of Pc 4 per mg of polymer in these micellar formulations resulted in the highest levels of singlet oxygen production. When formulations bearing these optimized parameters were tested in vitro on A431 cells for PDT effect, a formulation dose containing 400 nM Pc 4 and photoirradiation duration of 400 s at a fluence of 200 mJ/cm(2) yielded close to 100% cell death.

Endocytosis and signalling: a meeting with mathematics

Although endocytosis has traditionally been understood as a signal attenuation mechanism, an emerging view considers endocytosis as an integral part of signal propagation and processing. On the short time scale, trafficking of endocytic vesicles contributes to signal propagation from the surface to distant targets, with bi-directional communication between signalling and trafficking. Mathematical modelling helps combine the mechanistic, molecular knowledge with rigorous analysis of the complex output dynamics of endocytosis in time and space. Simulations reveal novel roles for endocytosis, including the control of cell polarity, enhancing the spatial signal propagation, and controlling the signal magnitudes, kinetics, and synchronization with stimulus dynamics.

Reduction in alveolar macrophages attenuates acute ventilator induced lung injury in rats

OBJECTIVE

Alveolar macrophages are the sentinel cell for activation of the inflammatory cascade when the lung is exposed to noxious stimuli. We investigated the role of macrophages in mechanical lung injury by comparing the effect of high-volume mechanical ventilation with or without prior depletion of macrophages.

DESIGN AND SETTING

Randomized sham-controlled animal study in anesthetized rats.

METHODS

Lung injury was induced by 15 min of mechanical ventilation (intermittent positive pressure ventilation) using high peak pressures and zero end-expiratory pressure. The mean tidal volume was 40+/-0.7 ml/kg. One group of animals was killed immediately after this period of volutrauma (HV), while in a second group normoventilation was continued for 2 h at a tidal volume less than 10 ml/kg (HV-LV). One-half of the animals were depleted of alveolar macrophages by pretreatment with intratracheal liposomal clodronate (CL2MDP).

MEASUREMENTS

Arterial blood gas, blood pressure. After kill: lung static pressure volume curves, bronchoalveolar fluid concentration for protein, macrophage inflammatory protein 2, tumor necrosis factor alpha, and wet/dry lung weight ratio (W/D).

RESULTS

During HV and HV+LV oxygenation, lung compliance, and alveolar stability were better preserved in animals pretreated with CL2MDP. In both groups W/D ratio was significantly greater in ventilated than in nonventilated animals (4.5+/-0.6), but the increase in W/D was significantly less in CL2MDP treated HV and HV-LV groups (6.1+/-0.4, 6.6+/-0.6) than in the similarly ventilated nontreated groups (8.7+/-0.2 and 9.2+/-0.5).

CONCLUSIONS

Alveolar macrophages participate in the early phase of ventilator-induced lung injury.

Epidermal growth factor reduces hepatic sequelae in experimental necrotizing enterocolitis

BACKGROUND AND AIM

Neonatal necrotizing enterocolitis (NEC) is the most common gastrointestinal disease of premature infants. We recently demonstrated that the gut/liver axis plays an important role in the pathophysiology of NEC through the release of inflammatory mediators into the intestinal lumen. We have also shown that supplementation of formula with epidermal growth factor (EGF) dramatically decreases ileal pathology associated with experimental NEC. In this study, we examined the effects of EGF on the liver portion of the gut/liver axis in the neonatal rat model of NEC.

METHODS

Newborn rats were divided into three experimental groups, NEC, hand-fed with growth-factor free formula; NEC + EGF, hand-fed with formula supplemented with 500 ng/ml rat EGF; or DF, dam fed. All animals were exposed to asphyxia and cold stress twice daily for 4 days to develop NEC.

RESULTS

EGF receptor expression was significantly (p <or= 0.01) decreased in the NEC+EGF group compared to the NEC group. EGF supplementation significantly decreased Kupffer cell numbers (p <or= 0.01) as well as hepatic tumor necrosis factor (TNF)-alpha and interleukin-18 production (p <or= 0.05). Further, TNF-alpha in the intestinal luminal contents of the NEC+EGF group were normalized to levels observed in DF controls compared to the NEC group (p <or= 0.05). Activated nuclear factor-kappaB was also substantially decreased in the NEC+EGF group versus the NEC group.

CONCLUSION

The results of this study indicate that EGF normalizes cytokine overproduction in the liver of neonatal rats with NEC, which contributes to diminished intestinal damage during the development of experimental NEC. These data suggest that supplementation of formula with EGF can have beneficial effects on the gut/liver axis during NEC pathogenesis.

Are novel scavenger-like receptors involved in the hepatic uptake of heparin?

Heparin is an anionic macromolecular drug. It has been widely used as an anticoagulant, and numerous efforts to clarify the mechanism of its disposition in the body have been made to help expand its clinical applications, using its newly found biological activities, as well as to further improve its use in anticoagulant therapy. It has now been shown that heparin is taken up extensively not only by Kupffer cells but also by parenchymal cells in the liver, the major distribution organ, and a receptor-mediated endocytotic mechanism, which is shared by heparin analogs and various anionic macromolecules, is responsible for heparin uptake in both types of cells. Although the characteristics of the receptors for heparin in both cells have lots of similarities to those of scavenger receptors, the receptors in parenchymal cells do not accept acetylated low density lipoprotein (Ac-LDL) as a ligand, which is the only striking difference between them and major scavenger receptors. Although the receptors in Kupffer cells, which accept Ac-LDL as a ligand, may belong to class A scavenger receptors, this remains to be established. We therefore conclude at present that it is likely that novel scavenger-like receptors for heparin (heparin receptors) or unidentified scavenger receptors are responsible for heparin uptake in the liver.

Uptake of FH by two types of scavenger-like receptors in rat liver parenchymal cells in primary culture

Several anionic proteins that are known to be substrates of scavenger receptors documented in the literature were selected and tested for their effects on the uptake of fractionated heparin (FH), an anionic macromolecular drug. The tests were made in rat liver parenchymal cells to characterize scavenger-like receptors involved in FH uptake, probing into substrate recognition characteristics in comparison with those of scavenger receptors. Although the uptake of FH was completely inhibited by dextran sulfate, a typical substrate of scavenger receptors, suggesting that scavenger-like receptors that have affinity for some anionic macromolecules are responsible for the uptake, it was not inhibited by acetylated low density lipoprotein (Ac-LDL), another typical substrate. Thus, the scavenger-like receptors were suggested to be different from the major scavenger receptors of classes A and B that are known to be sensitive to Ac-LDL. The uptake of FH was only partially inhibited by maleylated bovine serum albumin (Mal-BSA), suggesting that the scavenger-like receptors can be classified into two types in terms of sensitivity to Mal-BSA. The Mal-BSA-sensitive receptor was also found to be sensitive to oxidized low density lipoprotein (Ox-LDL). Kinetic analysis revealed that the binding capacity (Bmax) of the Mal-BSA-insensitive receptor was significantly larger than that of the Mal-BSA-sensitive one, though their dissociation constants (Kd) and apparent internalization rate constants (kint,app) were comparable. Information obtained in this study should be helpful for understanding the disposition mechanism of FH and also of anionic macromolecules and for developing delivery strategies, although the physiological roles and molecular identity of each receptor need to be further clarified in the future.

Comparison of receptor-mediated endocytosis kinetics between wild-type t-PA and recombinant pamiteplase in isolated rat hepatocytes and liver cell plasma membranes

1. Differences in receptor-mediated endocytosis kinetics between pamiteplase, an engineered t-PA, and an unmodified rt-PA were examined using liver cell plasma membranes and isolated rat hepatocytes. 2. Whereas the binding site of pamiteplase on hepatocytes was the same as that of rt-PA, the Kd of pamiteplase was 5.1-7.7 times larger than that of rt-PA, indicating a lower affinity of pamiteplase for the t-PA receptor. 3. ke for pamiteplase measured using parenchymal cells or non-parenchymal cells was slightly smaller than that for rt-PA, whereas kon for pamiteplase were much lower than that of rt-PA, suggesting that the interaction between pamiteplase and the receptor is slower than that of rt-PA because of its structural modification. 4. Therefore, the difference in drug disposition between pamiteplase and rt-PA is mainly due to the difference in the hepatic clearance caused by a change in the interaction rate between the ligand and its cell-surface receptor.

Transport of L-valine by the chicken caecum

1. We have studied L-valine transport by the caecal segments of 6- to 8-week-old chickens. Isolated enterocytes from the proximal caecum incubated with 0.1 mM L-valine can accumulate the substrate against a concentration gradient. After 50 min incubation, the intracellular L-valine concentration reached 0.53 mM, a value higher than that observed in enterocytes from the jejunum (0.34 mM; P< 0.01). 2. Enterocytes from the medial and distal caccal regions are unable to transport L-valine uphill (cell concentration: 0.1 mM). 3. Amino acid accumulation by proximal caecal cells was Na+ -dependent and was inhibited by ouabain and 2,4-dinitrophenol. L-methionine inhibits L-valine uptake and a 2.5 mM concentration abolishes the capacity of enterocytes to accumulate the substrate. 4. The high accumulation ratios shown by the proximal caecum for L-valine suggest a role for this intestinal segment in the absorption of neutral amino acids present in the caecal chamber.

Retrograde transport and steady-state distribution of 125I-nerve growth factor in rat sympathetic neurons in compartmented cultures

We have used compartmented cultures of rat sympathetic neurons to quantitatively examine the retrograde transport of 125I-nerve growth factor (NGF) supplied to distal axons and to characterize the cellular events that maintain steady-state levels of NGF in cell bodies. In cultures allowed to reach steady-state 125I-NGF transport, cell bodies contained only 5-30% of the total neuron-associated 125I-NGF, whereas 70-95% remained associated with the distal axons. This was true over an 8 pM to 1.5 nM 125I-NGF concentration range, indicating that saturation of high affinity receptors could not account for the large fraction of 125I-NGF remaining in axons. Dissociation assays indicated that 85% of 125I-NGF associated with distal axons was surface-bound. At steady-state, only 2-25% of the distal axon-associated 125I-NGF was retrogradely transported each hour, with higher transport rates associated with younger cultures and lower 125I-NGF concentrations. The velocity of 125I-NGF retrograde transport was estimated at 10-20 mm/hr. However, as in a previous report, almost no 125I-NGF transport was observed during the first hour after 125I-NGF administration, indicating a significant lag between receptor binding and loading onto the retrograde transport system. During 125I-NGF transport through axons spanning an intermediate compartment in five-compartment cultures, little or no 125I-NGF was degraded or released from the axons. After transport, 125I-NGF was degraded with a half-life of 3 hr. In summary, although some cellular events promoted NGF accumulation in cell bodies, distal axons represented by far the principal site of NGF-receptor interaction at steady-state as a result of a low retrograde transport rate.

Cell density-dependent mitogenic effect and -independent cellular handling of epidermal growth factor in primary cultured rat hepatocytes

AIMS

Mitogenic effect and cellular handling of epidermal growth factor (EGF) were analyzed in primary cultured rat hepatocytes at several cell densities.

METHODS/RESULTS

DNA synthesis, assessed by the incorporation of 125I-deoxyuridine, was accelerated by EGF at a low cell density while that stimulated by EGF was relatively low at the highest cell density, suggesting a cell density-dependent regulation of mitogenic response to EGF. An equilibrium binding study of 125I-EGF in the presence of various concentrations of unlabeled EGF at 0 degree C revealed that the dissociation constant (Kd) was 0.47-0.88 nM while the specific binding capacity (n) was 86-96 fmol/mg protein at each cell density. No significant difference was observed in the time profiles of the surface-bound, internalized, and degradation products of 125I-EGF, assessed per mg protein, between different cell densities. Based on a kinetic analysis of the time-profiles, the internalization rate constant and the degradation rate constant were found to be independent of cell density.

CONCLUSIONS

These results indicate that the cellular binding and disposition of EGF are not regulated by cell density, and that the cell density-dependence of the mitogenic effect cannot be attributed to differences in the affinity or capacity of the EGF receptor, internalization, or degradation of EGF. We speculate that the cell density-dependent mitogenic response may be accounted for by the difference in other factors such as the signal transduction processes induced by the receptor binding of EGF, or the translocation of a small fraction of the total EGF to hepatocyte nuclei.

Pharmacokinetics and pharmacodynamics of a recombinant human granulocyte colony-stimulating factor

Granulocyte colony-stimulating factor (G-CSF), a hematopoietic growth factor, is a clinically effective drug used to promote neutrophil recovery in patients with chemo- or radiotherapy-induced neutropenia. We have reviewed the pharmacokinetic and pharmacodynamic properties of three kinds of G-CSFs: E. coli derived G-CSF, CHO-derived G-CSF, and mutein G-CSF. The clearances of G-CSFs are saturable and autoinducible in experimental animals and humans. That is, the systemic clearances of G-CSFs decrease as the dose injected increases and approaches a constant value. Both saturable and nonsaturable processes are involved in G-CSF elimination. Also, the systemic clearances of G-CSFs are increased by repeated administration of G-CSF. Although the relative bioavailability of G-CSFs after subcutaneous administration is approximately 60%, the increase in peripheral white blood cells or neutrophils is greater than that after intravenous administration at the same dose. The effects of G-CSFs seem to be time dependent rather than AUC dependent, considering that mean residence time of G-CSFs in the plasma is longer after subcutaneous administration than that after intravenous administration. There is a slight difference in the pharmacokinetics of E-coli- and CHO-G-CSF although they seem to be pharmacologically equivalent. The correlation between G-CSF clearance and peripheral neutrophil counts in the patients suggests that G-CSF receptors contribute to G-CSF clearance. Quantitative pharmacokinetic analysis using mutein G-CSF shows that the G-CSF receptor plays a major role in saturable G-CSF clearance, and that this saturable process accounts for approximately 80% of the total clearance at low doses. That is, the degradation following the receptor-mediated endocytosis in bone marrow might be a major clearance system of G-CSF at a physiological blood level. The G-CSF receptor in bone marrow might work not only as a signal transducer for differentiation and proliferation of granulopoietic precurcer cells but as a regulator of G-CSF levels in blood. In addition, at high doses, glomerular filtration in the kidneys is the major process for nonsaturable G-CSF clearance. At present, polyethylene glycol derivatives of G-CSF are being developed to reduce the frequency of G-CSF administration.

Hexose transport across the apical and basolateral membrane of enterocytes from different regions of the chicken intestine

The properties of hexose transport across the apical and basolateral membranes of chicken enterocytes have been studied in the small and large intestine. Results show that (a) isolated epithelial cells from all segments except the coprodeum can accumulate 3-O-methylglucose (Glc3Me) against a concentration gradient, by a Na(+)-dependent and phloridizin-sensitive mechanism. (b) The cell cumulative capacity for Glc3Me (control/phloridizin-incubated cells) is lower in the small intestine than in the large intestine (rectum = proximal caecum = ileum > jejunum > duodenum). (c) Theophylline enhances the cell Glc3Me cumulative capacity 2.9-fold in the duodenum and 2.4-fold in the jejunum but has no effect in the other segments studied. (d) Analysis of sugar uptake indicates that net hexose influx rates decrease from proximal to distal regions: jejunum > duodenum > ileum = proximal caecum = rectum for the apical transport system (alpha-methyl glucoside as substrate and phloridizin as inhibitor) and duodenum > jejunum > ileum = proximal caecum = rectum for the basolateral system (2-deoxyglucose; theophylline). (e) The duodenum and the jejunum show high apical and basolateral hexose transport rates, which confer a significant capacity for sugar absorption on the proximal intestine. More distal regions, including the ileum, the proximal caecum and the rectum, have transport systems analogous to those of the proximal intestine that keep a considerable potential capability to recover hexoses from the lumen.

The perfused liver is capable of producing all transferrin glycan variants found in the sera of intact rats

The single oligosaccharide attachment in rat transferrin exhibits marked structural microheterogeneity. In this study we examined whether all microheterogeneous forms of rat transferrin found in plasma are derived from a single organ, such as the liver. To this end we analyzed the glycans of rat transferrin synthesized by the isolated perfused rat liver by a method established earlier for rat transferrin isolated from rat plasma. Our observations provide evidence that the liver can and does produce all variant rat transferrin glycans present in plasma. However, this discovery does not preclude the possibility that extrahepatic sources with an active rat transferrin gene may contribute to the circulation rat transferrin molecules, which bear glycan variants identical to those made by the liver. The glycan spectra of rat transferrin in plasma and in liver perfusate compared closely with each other in a quantitative sense. Nevertheless, rat transferrin in the perfusate was sialylated to a lesser extent and fucosylated to a greater extent than rat transferrin in plasma. These differences could not be eliminated by supplementation of the medium with insulin, dexamethasone, pyruvate and adenine or adenosine either alone or in combinations, nor could it be eliminated by use of a fluorocarbon O2 carrier. In contrast, epidermal growth factor normalized both parameters. The pH of the perfusing medium also influenced sialylation and fucosylation in such a way that higher pH brought these parameters closer to their values in plasma rat transferrin. Lower pH, on the other hand, reduced sialylation and left the fucosylation index unchanged.

Existence of two pathways for the endocytosis of epidermal growth factor by rat liver: phenylarsine oxide-sensitive and -insensitive pathways

The effect of phenylarsine oxide (PAO) on the internalization rate of epidermal growth factor (EGF) was investigated using perfused rat liver and isolated rat hepatocytes. In perfused liver, a tracer concentration of 125I-EGF alone or with excess unlabeled EGF (20 nM) was perfused and the internalization rate constants (kint) were measured. In the absence of PAO, kint values did not differ significantly for either dose condition. However, with the addition of PAO to the perfusate, the kint value dropped to 4% of that of the control at the low concentration of EGF, while dropping to only 40% of that of the control at the high concentration of EGF. These results suggest the existence of a PAO-insensitive internalization pathway having a kint value comparable with that of the other pathway. Similar EGF concentration-dependent inhibition of 125I-EGF internalization caused by PAO was ascertained using isolated rat hepatocytes. PAO also decreased the cellular ATP content in isolated hepatocytes. However, when we lowered the cellular ATP content with rotenone, the cell-surface binding and internalization of EGF were comparable with the control levels. We concluded that there exist dual pathways for the internalization of EGF and that excess doses of EGF lead to EGF internalization not only through a PAO-sensitive pathway but also through a PAO-insensitive pathway, whereas at a tracer dose of EGF, the internalization occurs mainly via the PAO-sensitive pathway.

Comparison of the methods for determining cell-surface and intracellular receptors for epidermal growth factor in the rat liver

We compared methods for determining the distribution of epidermal growth factor (EGF) receptors between the cell surface and the cell interior in the rat liver. Incubation of isolated hepatocytes with 100 nM EGF for 20 min at 37 degrees C remarkably decreased the cell-surface EGF receptor density (internalization of receptors). The detergent Brij 35 was previously reported to permit assay of the intracellular latent EGF receptors in liver homogenates, but in the present investigation, Brij 35 lowered the affinity of EGF for the receptor depending on the detergent concentration, and the appearance of latent receptors was not observed. In contrast, permeabilization of the cells with digitonin, followed by an acid-washing procedure, increased the EGF binding capacity to close to the control level. Hence, the EGF receptors, internalized together with EGF molecules, were not degraded for at least 20 min, and the digitonin method is suitable for quantifying the intracellular EGF receptors. The binding capacities of the digitonin-treated and untreated control cells showed no difference upon digitonin treatment, suggesting that the bulk of EGF receptors exists on the cell surface. Further, cell-surface EGF receptor density was determined after the i.v. administration of EGF (300 micrograms/kg) to rats. Isolated hepatocytes prepared 30 min after the administration of EGF showed little binding for EGF on the cell surface, while the cell-surface EGF receptor density recovered to close to control values in cells prepared after 3 hr.