Receptor-mediated Transcytosis of Lactoferrin through the Blood-Brain Barrier*

Carine FillebeenDagger , Laurence Descamps§, Marie-Pierre Dehouck§, Laurence Fenart§, Monique BenaïssaDagger , Geneviève SpikDagger , Roméo Cecchelli§, and Annick PierceDagger parallel

From the Dagger  Laboratoire de Chimie Biologique, Université des Sciences et Technologies de Lille, Unité Mixte de Recherche 111, CNRS, 59655 Villeneuve d'Ascq, the § Service d'Etude et de Recherche sur les Lipoprotéines et l'Athérosclérose, INSERM, Unité 325, Institut Pasteur, 59019 Lille, and the  Université d'Artois, Faculté Jean Perrin, 62307 Lens, France

    ABSTRACT
Top
Abstract
Introduction
References

Lactoferrin (Lf) is an iron-binding protein involved in host defense against infection and severe inflammation; it accumulates in the brain during neurodegenerative disorders. Before determining Lf function in brain tissue, we investigated its origin and demonstrate here that it crosses the blood-brain barrier. An in vitro model of the blood-brain barrier was used to examine the mechanism of Lf transport to the brain. We report that differentiated bovine brain capillary endothelial cells exhibited specific high (Kd = 37.5 nM; n = 90,000/cell) and low (Kd = 2 µM; n = 900,000 sites/cell) affinity binding sites. Only the latter were present on nondifferentiated cells. The surface-bound Lf was internalized only by the differentiated cell population leading to the conclusion that Lf receptors were acquired during cell differentiation. A specific unidirectional transport then occurred via a receptor-mediated process with no apparent intraendothelial degradation. We further report that iron may cross the bovine brain capillary endothelial cells as a complex with Lf. Finally, we show that the low density lipoprotein receptor-related protein might be involved in this process because its specific antagonist, the receptor-associated protein, inhibits 70% of Lf transport.

    INTRODUCTION
Top
Abstract
Introduction
References

Lactoferrin (Lf)1 (1) is a mammalian cationic iron-binding glycoprotein belonging to the transferrin (Tf) family. Despite some striking differences, mainly in the glycan moiety, there are marked sequence and conformational homologies among Lfs from different species, as well as similar general functions (for review, see Ref. 2). Many physiological roles have been ascribed to Lf, particularly in the host defense against infection and severe inflammation (for review, see Ref. 3). This broad spectrum of biological functions relies on the interaction of Lf with numerous cells. The binding of Lf to cells is independent of its degree of iron saturation and is mediated mainly via interaction of the cluster of basic amino acids at its NH2 terminus with sulfated molecules (4, 5). However, Lf is also targeted to specific cell receptors, and only a few of these involved in its uptake have been clearly identified. The 105-kDa Lf receptor characterized on activated human T-cells (6) is expressed at the cell surface of platelets (7), megacaryocytes (8), dopaminergic neurons, and mesencephalon microvessels (9). Lf receptor internalizes Lf, which is subsequently degraded (30-40%), whereas the remaining fraction is recycled (10). In addition, the low density lipoprotein receptor-related protein (LRP) displays a high affinity for Lf and is responsible for its clearance (11-14). This is inhibited by RAP, the receptor-associated protein known to be an antagonist for LRP (15). Transcytosis of Lf was described for HT29 cells (16) and was a minor pathway, up-regulated during iron deprivation (17).

Lf is produced by exocrine glands (1, 18) and is widely distributed in the body fluids. It is stored in specific granules of neutrophilic leukocytes (19) and is released during the inflammatory process. In addition, the concentration of Lf present in cerebrospinal fluids is enhanced in cases of acute cerebrovascular lesions (20, 21). Moreover, as an iron-binding protein, Lf has been implicated in the pathogenesis of brain lesions. Although practically absent from the normal human cerebral cortex (22), Lf was found in brains associated with aging and, more importantly, in increased amounts in the specific regions adversely affected in neurodegenerative disorders (22-24). In the mesencephalon, Lf is concentrated mainly in the dopaminergic neurons; in the case of Parkinson's disease (25), the surviving neurons accumulate higher concentrations of Lf. The origin and function of Lf within either the normal or pathological brain are as yet uncharted.

In situ synthesis of Lf occurs in brain, and Lf transcripts were found in human (26) and mouse brain tissues (27). Moreover, we have shown that Lf expression was up-regulated in mouse brain tissues treated with the neurotoxic agent 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine, which is used as a model for Parkinson's disease (27). Nevertheless, this up-regulation was slight and might not explain the large increase of Lf observed in the case of neurodegenerative disorders (22, 25). Moreover, the presence of Lf on the cerebral microvessels and its distribution in the vicinity of the inflammatory foci led us to investigate whether Lf may cross the blood-brain barrier (BBB).

The BBB is formed from specialized endothelial cells (ECs) that are sealed together by continuous complex tight junctions to form a polarized barrier that restricts the free exchange of most solutes between plasma and the extracellular fluid of the brain. Furthermore, even though brain capillary ECs contain no direct transendothelial passageways such as fenestrations or channels, specific transport mechanisms located in the cerebral ECs ensure that the central nervous system receives an adequate supply of nutrients. Such receptors have already been identified for proteins (28-30) and lipoproteins (31).

We have used an in vitro model of the BBB which imitates the in vivo situation by means of the co-culture of bovine brain capillary ECs (BBCECs) on one side of a porous filter and astrocytes plated at the bottom of six-well dish (32, 33) to provide direct evidence that after binding to BBCECs, Lf crosses the endothelial monolayer from the apical to the abluminal surface. Lf transcytosis is receptor-mediated, and our results indicate that LRP might be involved in this transcellular transport across the brain endothelium.

    EXPERIMENTAL PROCEDURES

Cell Culture-- BBCECs isolated and characterized as described previously (32, 33) were cloned, allowing us to obtain a pure EC population uncontaminated by pericytes. The cells were cultured in the presence of Dulbecco's modified Eagle's medium supplemented with 15% (v/v) heat-inactivated calf serum (Hyclone Laboratories), 2 mM glutamine, 50 µg/ml gentamycin, and 1 ng/ml basic fibroblast growth factor, added every other day. Nondifferentiated cells were obtained by growing BBCECs in the absence of astrocytes.

Primary cultures of mixed astrocytes were prepared from newborn rat cerebral cortex. After removing the meninges, the brain tissue was forced gently through a nylon sieve (34). Astrocytes were plated on six-well dishes (Nunclon; Nunc A/S) at a concentration of 1.2 × 105 cells/ml in 2 ml of Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum (Hyclone Laboratories). The medium was changed twice a week. 3 weeks after the seeding was completed, the purity of the astrocyte population was checked (33). Stabilized cultures contained more than 95% astrocytes that were glial fibrillary acidic protein-positive and were used for co-culture.

Establishing the in vitro model of BBB was performed using a co-culture of BBCECs and astrocytes. Prior to cell culture, plate inserts (Millicell-CM 0.4 µm; 30-mm diameter; Millipore Corp.) were coated on the upper side with rat tail collagen (35). They were then set in the six-multiwell dishes containing the astrocytes prepared as described above, and BBCECs were plated at a concentration of 4 × 105 cells/ml on the upper side of the filters in 1.5 ml of co-culture medium. This BBCEC medium was changed every other day. Under these conditions, differentiated BBCECs formed a confluent monolayer 7 days later (400,000 cells/cm2). Experiments were performed 5 days after confluence was reached. To be certain that differentiated BBCECs are a legitimate model for the BBB in vitro, the BBCEC phenotype was characterized and the tight junction network vizualized. Cells were stained with a filamentous actin probe (28, 31), and the localization to the plasma membrane of the tight junction-associated protein ZO-1 was carried out as described (31). Endothelial permeability was checked in each experiment and the permeability coefficient (Pe, in cm/min) calculated as described previously (33).

Preparation and Labeling of Bovine Lf (bLf)-- bLf was purified from bovine colostrum by ion-exchange chromatography as partially saturated bLf (36).

Fluorescent labeling of bLf on the glycan moiety was carried out by coupling 5-((2-(carbhydrazino)methyl)-thio)acetyl)aminofluorescein (Hyf) on aldehyde groups resulting from the mild periodate oxidation of N-acetylneuraminic acid residues (7).

Iodination of bLf was performed using the IODO-GEN reagent (Pierce). bLf (500 µg) was dissolved in phosphate-buffered saline and incubated with 0.2 mCi of Na125I (carrier-free, 100 mCi/ml, Amersham Pharmacia Biotech) for 15 min at 4 °C. Free iodine was removed on a Sephadex G-50 column (PD-10, Amersham Pharmacia Biotech). The specific activity range was 0.35-0.5 µCi/µg of protein; to avoid radiolysis, the iodinated protein was stored at 4 °C and used the same day.

Prior to 59Fe labeling, bLf was fully desaturated in formiate buffer (0.2 M formic acid-sodium formiate; containing 0.5 M NaH2PO4 and 25 mM EDTA) at pH 3.8 to give apobLf. 59Fe (18 nmol) (3-25 mCi/mg Fe, Amersham Pharmacia Biotech) was mixed with a solution containing 0.4 mM nitriloacetic acid and 0.05 M NaOH for 5 min at room temperature, and then the pH was adjusted to 8.2 with NaOH. ApobLf (37 nmol) dissolved in 0.1 M Tris-bicarbonate buffer (pH 7.6) was added to the iron solution and then incubated for 45 min at room temperature. Unbound 59Fe was captured mainly by adding 50 µl of Chelex 100 (Sigma) preequilibrated with 0.1 M Tris-bicarbonate buffer, and the remaining free 59Fe was further removed on a PD-10 column. This method gave an average specific activity of 5 µCi/mg protein and a yield of iron saturation equal to 99%.

For dual labeling of bLf, protein was first labeled with 59Fe and further iodinated with 0.05 mCi of Na125I for 500 µg of 59Fe-bLf, giving a specific activity of 0.1 µCi/µg protein for 125I and 4 µCi/mg protein for 59Fe.

Binding, Endocytosis, Internalization Kinetics, and Transcytosis-- All of these studies were performed only with BBCECs to avoid any interference from the astrocyte population. Moreover, to eliminate endogenous bLf, BBCECs were always incubated before each experiment for 2 h in medium without serum. Because Tf has been described as an effective blocking component, able to prevent high levels of nonspecific Lf binding (37), all buffers contained 0.2% bTf (Sigma). Each point was done in triplicate, and the data are represented as the means ± S.E. Nonspecific controls were carried out with a 100-fold excess of unlabeled protein.

Equilibrium binding was performed on differentiated and nondifferentiated BBCECs in Ringer-HEPES-bTf for 2 h at 4 °C, with a 125I-bLf concentration ranging from 0.2 to 200 µg/ml (2.5-2500 nM). The cells were washed carefully, and cell-associated radioactivity was determined by removing the membrane of the culture insert and counting it in a gamma counter. The results were analyzed using the Enzfitter nonlinear regression data analysis program (Elsevier-BIOSOFT, Cambridge, U. K.). Scatchard plots and kinetic analyses were performed using the same software.

Determination of the luminal uptake of Hyf-bLf was performed before cell fixation with 4% paraformaldehyde. The luminal compartment of the differentiated BBCECs was exposed to Hyf-bLf (50 µg/ml; 625 nM) in Ringer-HEPES-bTf and left in contact with the cells for 45 min at 37 or 4 °C. Fluorescence microscopy experiments were carried out as already described (28).

The time course of internalization of 125I-bLf by differentiated BBCECs was measured using 125I-bLf (30 µg/ml; 375 nM) which was presented to the luminal surface for 1 h at 4 °C prior to the experiment. After washing off the unbound bLf, filters covered with cells were incubated in prewarmed medium at 37 °C. At various times, filters were removed, and all subsequent steps were performed at 4 °C. The medium compartments were collected, and cells were treated with 0.1% Pronase E (Merck) in phosphate-buffered saline for 30 min at 4 °C. The surface-bound, internalized, released, and transported 125I-bLf was counted in the Pronase-sensitive eluate, the cell extract, and the trichloroacetic acid-precipitable fractions of incubation media of the upper and lower compartments, respectively.

Transcytosis experiments were performed as follows. One insert covered with BBCECs was set into a six-well dish with 2 ml of Ringer-HEPES-bTf added to each well at 37 °C. 125I-bLf (30 µg/ml), 59Fe-bLf (50 µg/ml), and 125I-59Fe-double-labeled bLf (50 µg/ml) were added to the upper side of the filter covered with cells. At various times, the insert was transferred to another well to avoid a possible reendocytosis of bLf by the abluminal side of the BBCECs. At the end of each experiment, intact bLf was assessed using trichloroacetic acid precipitation of lower media, and protein degradation was assessed with AgNO3 precipitation. For 125I-bLf studies, all results were expressed as 125I-bLf equivalent flux (ng/cm2), which represents trichloroacetic acid-precipitable radioactivity recovered in the lower compartments. The 59Fe equivalent flux (pg/cm2) corresponds to the total iron radioactivity found in the lower compartment.

The influence of temperature on the transport of 125I-bLf (30 µg/ml) was studied with the monolayers kept at 4 °C. In parallel, the paracellular passage of sucrose (0.1 µCi of [14C]sucrose) was assayed at 4 °C and 37 °C in the same conditions.

To demonstrate whether Lf transendothelial transport was directional, 125I-bLf (30 µg/ml) was added to the lower compartment of the wells, and the transcytosis experiment was conducted as above.

Effect of RAP on Lf Transcytosis-- The effect of RAP on the transendothelial transport of 125I-bLf across BBCECs was determined by adding 100 nM recombinant RAP to the upper side of the filter covered with cells for 1 h at 37 °C before experiments. Recombinant RAP was prepared in Escherichia coli as a fusion protein that contains the entire coding sequence of the 39-kDa protein fused to glutathione S-transferase (38). All experiments were then performed with 125I-bLf as described above.

Electrophoretic Characterization of bLf After Transcytosis-- After 2 h of transcytosis, the apical and basolateral compartment solutions were collected and analyzed by 10% SDS-polyacrylamide gel electrophoresis. After electrophoresis, the gel was dried and exposed for autoradiography 2 h at -80 °C (Kodak X-Omat AR film).

    RESULTS

Binding of bLf on BBCEC Monolayers-- Binding experiments were performed both on differentiated and nondifferentiated BBCECs (cultured in the absence of astrocytes) using radioiodinated ligand. Only the binding data of differentiated cells are represented in Fig. 1. The binding was found to be concentration-dependent, saturable, and inhibited by approximately 85% in the presence of a 100-fold molar excess of unlabeled bLf, suggesting that it was reversible and specific. The binding data, analyzed by the method of Scatchard, were consistent with a two-component binding curve. Fig. 1 shows the Scatchard analysis of data from a single typical experiment (of five carried out). At a low range of 125I-bLf concentrations, binding is determined primarily by high affinity sites (Fig. 1A). At a high range of 125I-bLf concentrations (Fig. 1B), low affinity sites account for most of the binding. At intermediate concentrations, binding is effected by both high and low affinity sites. These data, summarized in Table I, are in agreement with the presence of two binding sites on differentiated BBCECs: a high affinity binding site with a Kd of about 37.5 nM and 90,000 sites/cell and a low affinity binding site with a Kd of about 1,900 nM and 890,000 sites/cell. Both sites were specific for bLf. bLf binding to nondifferentiated BBCECs was also investigated (Table I). Scatchard analysis revealed that the affinity of bLf for these cells (Kd = 2, 100 nM) and the number of bLf binding sites (920,000/cell) were comparable to the low affinity binding site parameters found on the differentiated cells. These results suggest that only differentiated BBCECs are able to express high affinity binding sites for bLf.


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Fig. 1.   Scatchard analysis of the binding of 125I-bLf to differentiated BBCECs. bLf binding was performed on BBCECs at 4 °C, and increased concentrations of 125I-labeled bLf were added at the luminal side of the cells. Low (panel A) and high (panel B) concentration ranges of bLf were used. Specific binding was obtained after subtraction of the nonspecific binding in the presence of a 100-fold excess of unlabeled bLf from the total counts. The specific bound 125I-bLf was analyzed by the Scatchard procedure. B/F, bound:free ratio.

                              
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Table I
Dissociation constants (Kd) and numbers of bLf binding sites/cell on BBCECs
Values are means ± S.E. for two separate experiments conducted in triplicate.

Endocytosis of bLf in BBCEC Monolayers-- To determine whether bLf was internalized from the luminal surface of the BBCECs, Hyf-bLf was first used as a probe. Staining visualized with a fluorescent microscope is shown in Fig. 2A. Hyf-bLf was found as small, individual vesicles throughout the differentiated cells. This uptake was completely inhibited at 4 °C (Fig. 2B). The endocytosis process was then monitored using radiolabeled bLf. Cells were first incubated at 4 °C for 1 h until the binding site occupancy reached a steady state. After washing off the unbound ligand, cells were incubated at 37 °C and the distribution of surface-bound, internalized, released, and transported radioactivities was counted at various times. As shown in Fig. 3, the Pronase-resistant fraction increased rapidly and reached a maximum of 18% of the initially bound 125I-bLf, 3 min after the start of the incubation. The Pronase-resistant fraction decreased slowly thereafter, as 125I-bLf started to appear in the lower compartment a few minutes later, showing that transcytosis occurs. During the experiment, the Pronase-sensitive fraction decreased, and 125I-bLf appeared in the upper compartment, suggesting a marked dissociation from the cell surface or a release of 125I-bLf by the cells.


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Fig. 2.   Hyf-Labeled bLf endocytosis in BBCECs. BBCECs were incubated at 37 °C (panel A) or 4 °C (panel B) for 45 min with 50 µg/ml Hyf-bLf. After washing, the cells were fixed and processed for fluorescence microscopy as described under "Experimental Procedures." Bar = 20 µm.


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Fig. 3.   Internalization kinetics of 125I-bLf in BBCECs. The cells were incubated for 1 h at 4 °C in the presence of bLf (30 µg/ml 125I-bLf, 3 mg/ml unlabeled bLf). After washing off the unbound ligand, cells were incubated with 125I-bLf at 37 °C. At the indicated times, filters were removed, and the amounts of surface-bound, internalized, released, and transcytosed radioactivity were counted. Ordinates represent the percentage of the total radioactivity initially bound to BBCECs at 4 °C, which was segregated within the cells () and released into the lower incubation medium (black-square) or into the upper incubation medium (black-triangle) or associated with membranes (black-diamond ). The data are expressed as ng of 125I-bLf transported/cm2, which refers to the surface area of the cells. Each point is a mean of three different filters.

Apical to Basolateral Transport of bLf Across BBCEC Monolayers-- 125I-bLf was added to the luminal chamber of the culture, and its progressive transfer across the cell monolayer was followed for 90 min. A range of different bLf concentrations (10-100 µg/ml) was assayed, and no evidence of saturation was detected at concentrations lower than 100 µg/ml (data not shown). Fig. 4 shows the total, nonspecific and calculated specific bLf flux values as a function of time with a luminal concentration of 30 µg/ml bLf. Our results demonstrate that differentiated BBCECs are not a barrier for the passage of bLf. The transport of labeled bLf from the luminal to the abluminal compartment was reduced severely by an excess of unlabeled bLf, suggesting that bLf transport from the apical to the basal side of the cells was effected by specific receptor-mediated transport. The rate of transcytosis was evaluated, and about three to four bLf molecules were transported via one high affinity binding site in 1 h, suggesting that one bLf molecule crosses the BBCEC monolayer in 15-20 min. The possible toxicity of a high concentration of bLf (3 mg/ml) for the integrity of the BBCEC monolayer was assessed by calculating the permeability to sucrose. No leakiness in the barrier function occurred (Pe = (0.65 ± 0.02) × 10-3 and (0.67 ± 0.03) × 10-3 cm/min for the control and in the presence of 3 mg/ml of bLf, respectively).


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Fig. 4.   Apical to basolateral transport of 125I-bLf across BBCEC monolayers. bLf (30 µg/ml 125I-bLf, 3 mg/ml unlabeled bLf) was added to the luminal side of cells grown on porous filters coated with collagen. Intact 125I-bLf transport from the upper to the lower sides of the filter represents radioactivity that was trichloroacetic acid-precipitable in the lower compartments. Specific transport () was calculated by subtracting the radioactivity obtained in the presence of native bLf (black-triangle) from that obtained in the absence of native bLf (black-square). The data are expressed as ng of 125I-bLf transported/cm2, which refers to the surface area of the cells. Each point is a mean of three different filters.

The effect of temperature on bLf transport from the apical to basal surfaces of BBCECs is shown in Fig. 5. A decrease in the incubation temperature from 37 °C to 4 °C slightly affected the paracellular passage of sucrose (Fig. 5A), whereas a dramatic decrease in the bLf transport through the monolayer was observed (Fig. 5B), indicating that bLf is directed to the abluminal compartment by a transcellular route and that this transport system requires active mechanisms such as receptor-mediated transcytosis.


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Fig. 5.   Effect of a reduction in temperature from 37 °C () to 4 °C (black-square) on the transport of [14C]sucrose (panel A) and 125I-bLf (panel B) across BBCECs. Results are expressed as a percentage of sucrose recovered in the lower compartments. For bLf, data are expressed as an equivalent bLf flux (ng/cm2), and values are means of triplicate inserts.

Abluminal to luminal transport of bLf was assayed by added 125I-bLf to the lower chamber of the culture. No specific transport of bLf was detected across the cell monolayer in these conditions (data not shown), showing that the transport of bLf across BBCECs is unidirectional.

Effect of RAP on the Transendothelial Transport of 125I-bLf Across BBCECs-- To determine whether LRP might be involved in the receptor-mediated transport of bLf, transcytosis experiments were performed in the presence of RAP. RAP is known to interact with LRP and block the binding of any kind of LRP ligand. The fusion molecule with glutathione S-transferase was used because it has been shown that LRP does not bind glutathione S-transferase (15, 39).The integrity of the monolayer was evaluated, and no increase in the permeability of sucrose in the presence of recombinant RAP was detected (Pe = (0.52 ± 0.02) × 10-3 and (0.55 ± 0.03) × 10-3 cm/min for the control and in the presence of 100 nM RAP, respectively). As shown in Fig. 6, recombinant RAP decreases the rate of the passage of bLf through the BBCEC monolayer. A decrease of 70% of the initial transcytosis was observed, suggesting the involvement of LRP in this intracellular traffic.


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Fig. 6.   Effect of RAP on the transport of 125I-bLf across BBCEC monolayers. After incubation for 1 h at 37 °C with (black-square) or without () RAP (4 µg/ml), bLf (30 µg/ml 125I-bLf, 3 mg/ml unlabeled bLf) was added to the luminal side of the cells. The data are expressed as ng of 125I-bLf transported/cm2. Each point is a mean of three different filters.

Characterization of bLf After Transcytosis-- To determine whether bLf undergoes degradation within BBCECs during transcytosis, 125I-bLf recovery was followed by counting the trichloroacetic acid precipitate, and 125I-bLf degradation was followed by measuring the AgNO3 precipitate in the upper and lower compartments. Controls were carried out with filters coated with collagen and without cells as above. The results showed that 125I-bLf degradation was no more than 2 ± 0.5% either in the upper or in the lower compartment. Moreover, Fig. 7 shows that 125I-bLf was recovered as an intact protein after its transport through the BBCEC monolayers. These results suggest that bLf was transported across BBCECs via a specialized pathway that does not lead to degradation.


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Fig. 7.   Electrophoretic characterization of 125I-bLf after transcytosis across BBCEC monolayers. bLf (30 µg/ml 125I-bLf) was added to the luminal side of cells for 2 h at 37 °C. Lane 1, medium of the luminal compartment after transcytosis experiment; lane 2, medium of abluminal compartment after transcytosis experiment; lane 3, 125I-bLf before its addition to the luminal compartment. The arrow indicates the dye front.

Transendothelial Iron Transport Studies Using 59Fe-bLf and 125I-59Fe-Double-labeled bLf-- To determine whether iron-bound Lf might reach brain tissues, iron transport was studied across BBCECs. Transcytosis experiments were repeated with 59Fe-bLf. Fig. 8 represents specific transcytosis of 59Fe through BBCECs. This transport was reduced by an excess of unlabeled bLf, suggesting that 59Fe crosses the monolayer associated with bLf. To elucidate this point, experiments were then carried out with 125I-59Fe-double labeled bLf, and the data are summarized in Table II. 59Fe-bLf equivalent flux was calculated from 59Fe flux because one molecule of bLf binds two molecules of iron. The 59Fe-bLf equivalent flux (0.044 pmol cm-2 h-1), which is equal to one-half of the 59Fe flux (0.088 pmol cm-2 h-1), was very close to that of the 125I-bLf equivalent flux observed (0.046 pmol cm-2 h-1). These results suggest that iron found in the lower compartment crossed the BBCEC monolayers bound to bLf.


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Fig. 8.   Apical to basolateral transport of 59Fe-labeled bLf on BBCEC monolayers. bLf (50 µg/ml 59Fe-bLf, 3 mg/ml unlabeled bLf) was added to the luminal side of the cells. Specific transport () was calculated by subtracting the radioactivity obtained in the presence of unlabeled bLf (black-triangle) from that obtained with only labeled bLf (black-square). All values are means of triplicate inserts ± S.E. (bars; n = 3).

                              
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Table II
125I-59Fe-double-labeled Lf transport across BBCEC monolayers
Values are means ± S.E. for three different experiments.


    DISCUSSION

The purpose of the present study was to determine whether Lf was able to cross the BBB, which would explain its presence in brain tissues. We have demonstrated that Lf binding to BBCECs was followed by transcytosis of the protein from the luminal to the abluminal surface of brain capillary ECs in the absence of any demonstrable degradation. Using RAP as an antagonist of LRP, we have been able to show that this receptor might be involved in the intracellular traffic of Lf.

We have used an in vitro BBB model consisting of a co-culture of brain capillary EC and astrocytes. When cultured on permeable supports, these cells form a well polarized monolayer that mimics the in vivo situation (28, 31, 33) and displays remarkable phenotypic similarities to the in vivo BBB with respect to the expression of specific markers and characteristics such as tight junctions, electrical resistance, low paracellular permeability, specific enzymatic activities, and carrier-mediated transport (40, 41).

The binding parameters of Lf have already been published for numerous cells. The BBCEC constants are within the same range as those reported (4, 6) because the apical surface of differentiated BBCEC cells exhibited 9 × 104 high specificity binding sites/cell for bLf with a dissociation constant of about 37.5 nM. These high affinity binding sites represent one-tenth of the total number of binding sites and were not present on the nondifferentiated BBCECs, demonstrating that Lf receptors were acquired during differentiation.

Our data are equally consistent with the existence of low affinity binding sites on both types of BBCEC cells with a Kd of 2 µM and approximately 9 × 105 binding sites/cell. As already shown, Lf binds to various specific ligands at the cell surface. Its clearance from the circulation involves at least two classes of binding sites, a large number of low affinity binding sites and a smaller number of high affinity binding sites including LRP (39). Two classes of binding sites have also been described for Lf on human lymphoblastic Jurkat cells because treatment with chlorate, which inhibits the sulfation of the carbohydrate residues on intact cells (42), resulted in a 40% decrease of the total number of binding sites for native Lf, suggesting that part of the sites consist of cell-associated sulfate groups (4). The low affinity binding components present in large numbers on BBCECs may also be sulfated molecules such as glucosaminoglycans or proteoglycans, which are known to trap biologically active molecules and retain them until they are targeted to their specific receptors (43).

In this study we have shown that after binding to the cell surface, Lf enters the differentiated BBCECs. This uptake is a very dynamic, receptor-mediated process followed by transcytosis. Furthermore the transcytosis process itself seems highly regulated in that it is both receptor-mediated and independent of a high concentration of Lf. Accumulation of Lf occurs at the abluminal side of the BBCECs, and the passage of Lf through the BBB therefore potentially corresponds to a source of brain Lf. Lf was also found at the luminal side of the cells, and this mechanism might be the result of either cell surface dissociation or recycling. Because of the large numbers of low affinity binding sites, Lf bound to these sites could dissociate rapidly on equilibrium with extensive washes.

We next investigated the possibility that Lf might be internalized via LRP, which is a member of the LDL receptor family involved in the internalization and subsequently degradation of remnant chylomicron particles. LRP is a multiligand receptor also responsible for the cellular internalization of many ligands such as Lf, alpha 2-macroglobulin, Pseudomonas endotoxin, and both proteinases and proteinase-inhibitor complexes (for review, see Refs. 44 and 45). The functional involvement of LRP in bLf uptake by BBCECs was tested by inhibition experiments in the presence of RAP, the LRP universal antagonist (15). RAP is an endoplasmic reticulum resident protein (46) that functions intracellularly as a molecular chaperone for LRP and maintains LRP in an inactive, non-ligand binding state along the secretory pathway (47). We demonstrated that Lf transcytosis was mediated by LRP because 70% of the Lf traffic was inhibited by RAP. The distribution of LRP on ECs was reported previously (48, 49). It has also been studied in the central nervous system and was found associated with neurons (50, 51), weakly on some glial cells, and discontinously along the membranes of the capillaries (51). LRP was also associated with neurodegenerative disorders such as Alzheimer's disease (52) and was found in increased concentrations in some neurons. LRP might therefore be responsible for Lf accumulation in some specific brain areas.

Lf endocytosis (10, 13) and transcytosis (16, 17) have been reported previously, and partial or complete degradation of Lf always occurs. Lf released during neutrophil activation has a rapid turnover, and its clearance by the liver keeps its level in the plasma very low. Lf internalized by Jurkat cells accumulates in the endosomal compartment, and then both intact and degraded Lf is released, suggesting that part of the Lf is recycled (10). Lf is also endocytosed by the intestinal epithelial cells HT-29. In this case, transcytosis of 10% of Lf occurred, whereas 90% of the Lf followed a major degradative pathway (16). In the present study, we report that Lf is taken up and transported through the BBCECs without any degradation. The nondegradation of Lf during the transcytosis indicates that the transcytotic pathway in BBCECs is different from the classical Lf receptor pathways described above. The existence of a receptor-mediated process that bypasses lysosomes seems to be a feature of ECs; the absence of degradation of proteins such as insulin (29), albumin (30), Tf (28), and lipoproteins such as LDL (31) through ECs was reported previously. Microscopy studies also confirmed that no accumulation of LDL was observed in lysosomes (31). The precise transcellular pathway for the passage of blood-borne molecules across the BBB is not yet elucidated. One of the characteristics of brain capillaries ECs is the paucity of clathrin-coated pits, and previous studies strongly support the involvement of caveolae in endocytosis (53, 54). These structures seemed responsible for the uptake and transcellular transport of albumin (55) and human Tf (28). They have recently been implicated in the traffic of LDL through the brain microvascular endothelia leading to LDL accumulation in early endosomes and in multivesicular body structures (31). To determine whether Lf transport through BBCECs is caveolae-dependent, electron microscopy investigations are currently under way.

Alterations in iron metabolism occur in neurodegenerative diseases which lead to excessive iron deposits (56-58). The causes and consequences of such deposits in the brain are unknown, as is the nature of the responsible iron complex. Conflicting results have been reported on the implication of the proteins responsible for maintaining brain iron homeostasis, but no significant variation in the levels of expression of Tf, transferrin receptor, and ferritin have been found in pathological brain tissues (59, 60), whereas changes in the distribution, the amount (22-25), and the level of expression (27) of Lf were observed. In the case of inflammatory responses, high plasma levels of Lf are available, and larger amounts of Lf may cross the BBB and accumulate in the inflammatory foci. This process might explain why a strong labeling of Lf was observed on cerebral microvessels located in the vicinity of the neurodegenerative lesions (22). On the other hand, in response to local tissue injury or inflammation, additional transport pathways for large molecules may be opened and existing pathways modified or made less restrictive. It was shown recently that the intracellular traffic kinetics of Tf and LDL are disturbed in BBCECs in the presence of tumor necrosis factor alpha  (40).

The most striking characteristic of Lf is its high affinity for iron. In this study, we have been able to show that Lf crosses the BBB as both the iron-saturated and native forms. Under physiological conditions, Lf functions as a major specialized iron scavenger and acts as an antioxidant (61) rather than an iron donor. Sequestration of free iron by Lf may inhibit the iron-catalyzed formation of hydroxyl radicals, and the presence of Lf at sites where oxidative stress occurs may limit cell damage. Nevertheless, iron-saturated Lf may act as a prooxidant agent and contribute to cell injury (62). The precise role of Lf in the brain is not yet known, but we can hypothesize that in response to oxidative stress in brain tissue, Lf could have a beneficial effect in neurodegenerative disorders by capturing the iron in higher concentrations in some specific brain regions and act in this way as a natural scavenger of reactive oxidative species. Alternatively, its in situ synthesis at abnormal levels, its release from necrosing neurons, or its possible increased uptake and transcytosis by BBB ECs during the inflammatory process may exacerbate and amplify the lesions, leading to a cytotoxic effect resulting in an increase in neuronal death. Our current approach toward testing these conflicting hypotheses is to investigate Lf intracellular traffic in BBCECs in the presence of inflammatory mediators.

    ACKNOWLEDGEMENTS

We are indebted to Prof. Manfred Hüttinger from the University of Vienna (Institute of Medical Chemistry, Waehringerstrasse 10, A-1090 Vienna, Austria) who provided us with the recombinant RAP. We are grateful to Dr. R. J. Pierce for reviewing the manuscript.

    FOOTNOTES

* This investigation was supported in part by CNRS Unité Mixte de Recherche 111 (Relations Structure-Fonction des Constituants Membranaires), by the Université des Sciences et Technologies de Lille I, by INSERM Unité 325 (Service d'Etude et de Recherche sur les Lipoprotéines et l'Athérosclérose), by the Institut Pasteur de Lille, and by grants from the Conseil Régional Nord-Pas de Calais (Axe régional: maladies neurodégénératives et vieillissement).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

parallel To whom correspondence should be addressed: Laboratoire de Chimie Biologique, Université des Sciences et Technologies de Lille, 59655 Villeneuve d'Ascq Cedex, France. Tel.: 33-3-2033-7238; Fax: 33-3-2043-6555; Email: annick.pierce{at}univ-lille1.fr.

    ABBREVIATIONS

The abbreviations used are: Lf, lactoferrin; bLf, bovine lactoferrin; Tf, transferrin; bTf, bovine transferrin; LRP, low density lipoprotein receptor-related protein; RAP, receptor-associated protein; BBB, blood-brain barrier; EC, endothelial cell; BBCEC, bovine brain capillary endothelial cell; Pe, permeability coefficient; LDL, low density lipoprotein.

    REFERENCES
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Abstract
Introduction
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