Immunoelectron microscopic visualization of the transcytosis of low density lipoproteins in perfused rat arteries

A postembedding labeling technique was employed to visualize human native low density lipoproteins (LDL) during transcytosis in rat arterial endothelium. For this purpose human LDL was perfused through rat vasculature before fixation and processing for immunoelectron microscopy. The LDL particles were located on sections by anti-human apolipoprotein B-100 (LDL) antibodies and secondary antibodies or protein-A conjugated to 10-nm colloidal gold. LDL molecules were seen in plasmalemmal vesicles as well as in the subendothelial space. No colloidal gold was found in the intercellular junctions. Perfusion with reductively methylated LDL, which cannot bind to the LDL receptor, gave a similar labeling pattern, indicating that transcytosis of LDL via plasmalemmal vesicles is most likely receptor independent. Furthermore, the passage of LDL through intact vascular endothelium is a vesicular transport rather than an intercellular diffusion process.     

Filipin-sensitive caveolae-mediated transport in endothelium: reduced transcytosis, scavenger endocytosis, and capillary permeability of select macromolecules

Caveolae or noncoated plasmalemmal vesicles found in a variety of cells have been implicated in a number of important cellular functions including endocytosis, transcytosis, and potocytosis. Their function in transport across endothelium has been especially controversial, at least in part because there has not been any way to selectively inhibit this putative pathway. We now show that the ability of sterol binding agents such as filipin to disassemble endothelial noncoated but not coated plasmalemmal vesicles selectively inhibits caveolae-mediated intracellular and transcellular transport of select macromolecules in endothelium. Filipin significantly reduces the transcellular transport of insulin and albumin across cultured endothelial cell monolayers. Rat lung microvascular permeability to albumin in situ is significantly decreased after filipin perfusion. Conversely, paracellular transport of the small solute inulin is not inhibited in vitro or in situ. In addition, we show that caveolae mediate the scavenger endocytosis of conformationally modified albumins for delivery to endosomes and lysosomes for degradation. This intracellular transport is inhibited by filipin both in vitro and in situ. Other sterol binding agents including nystatin and digitonin also inhibit this degradative process. Conversely, the endocytosis and degradation of activated alpha 2- macroglobulin, a known ligand of the clathrin-dependent pathway, is not affected. Interestingly, filipin appears to inhibit insulin uptake by endothelium for transcytosis, a caveolae-mediated process, but not endocytosis for degradation, apparently mediated by the clathrin-coated pathway. Such selective inhibition of caveolae not only provides critical evidence for the role of caveolae in the intracellular and transcellular transport of select macromolecules in endothelium but also may be useful for distinguishing transport mediated by coated versus noncoated vesicles.     

Endocytosis and exocytosis of protein in capillary endothelium

The transport of proteins across continuous capillary endothelium is believed to be mediated by micropinocytic vesicles which shuttle molecules between the lumenal and abluminal plasma membrane. We have studied the ability of capillary endothelial cells isolated from rat epididymal fat to endocytose fluorescently labelled ovalbumin within micropinocytic vesicles. Net association of fluorescent ovalbumin with endothelial cells reaches an equilibrium after 40 minutes of incubation. This equilibrium is presumably due to a balance between endocytosis and subsequent exocytosis of this protein. Capillaries equilibrated with fluorescent ovalbumin exhibited rapid exocytosis of this protein when it was removed from the external medium. The rate of endocytosis was concentration dependent and obeyed the kinetics expected for adsorptive phase endocytosis. High concentrations of ovalbumin stimulated the ingestion of 14C-sucrose, a marker of fluid endocytosis, suggesting that protein can affect the movement of vesicles within the endothelial cytoplasm. These results imply that capillary endothelium isolated from rat epididymal fat exhibits the ability to endocytose and subsequently exocytose protein. This demonstrates that the two components of endothelial vesicular transport or transcytosis can be observed and studied in a system of isolated capillary endothelium.     

Receptor-mediated transcytosis of follicle-stimulating hormone through the rat testicular microvasculature

Accumulated data suggest that endothelial cells express specific receptors for several peptide and (glyco)protein hormones that may transport hormones across the cell to be delivered to the interstitial fluid and tissue target cells. Surprisingly, very little information is available on the actual endothelial organelles involved in this cellular process. In the present study the transfer of follicle-stimulating hormone (FSH) through the endothelial barrier of rat testes was examined by analysing the binding and transport of gold-tagged recombinant human (rh)FSH under various conditions using electron microscopy. At 4 degrees C the probe bound specifically to the luminal surface of the endothelial cells without internalization. The use of 125I-rhFSH, which allows precise quantitation of the binding, confirmed the specificity of hormone interaction with the testicular microvasculature. At 37 degrees C the hormone was internalized via coated pits and vesicles into an extensive subluminal tubulo-vesicular compartment and was transported across the endothelium via a system of tubules and vesicles. Moreover, monoclonal antibodies against the FSH receptor ectodomain coupled to colloidal gold followed the same route. In contrast, a non specific, fluid-phase uptake via caveolae was observed for a major plasma protein - rat serum albumin and a fluid-phase tracer - peroxidase. These results suggest that FSH transcytosis across the testicular endothelial barrier is receptor-mediated and involves luminal uptake via coated pits/vesicles, sorting at the level of luminal early endosomes, and transcellular transport through transcytotic tubulo-vesicular organelles. Similar receptor-mediated pathways are likely to be involved in the physiological functioning of a number of other protein and peptide hormones that must translocate specifically from blood to the target cells.     

Transendothelial transport (transcytosis) of iron-transferrin complex in the bone marrow

To determine the transport pathway of iron-transferrin complex (Fe-TF) across the marrow-blood barrier, we labeled Fe-TF with colloidal gold and perfused rat femoral marrow with this probe. At 4 degrees C, the probe bound to the luminal surface of marrow sinus endothelium. The binding was inhibitable in the presence of excess native Fe-TF indicating the specificity of the binding. At 37 degrees C, the probe was internalized largely via a system of coated pits and vesicles and transported across the endothelium via a system of tubules and endosomal vesicles. It could not be ascertained if all Fe-TF was still associated with the colloidal gold probe within the endothelium, but the probe appeared to be externalized on the abluminal side into the interstitium where it subsequently bound to the surface of marrow erythroblasts and was internalized. Endothelium appeared to store part of the probe within a large vesicular system. No transport of Fe-TF was noted through diaphragmed fenestrations, diaphragmed vesicles, or interendothelial junctions. No endothelial uptake of this magnitude was noted when native gold particles or gold-labeled bovine serum albumin was used. Our findings indicate that in the bone marrow, gold-labeled Fe-TF is first taken up by sinus endothelium through a receptor-mediated mechanism and is possibly transported transendothelially via a vesicular system (transcytosis).     

Fatty acids binding to albumin increases its uptake and transcytosis by the lung capillary endothelium

To determine whether uptake and transcytosis of albumin (A) in continuous capillary endothelia are modified when this protein carries fatty acids, the transport of albumin-oleic acid and albumin-palmitic acid complexes was compared with that of defatted albumin. The probes, either radioiodinated or tagged with 5-nm gold particles (Au), or both, were perfused in situ or injected in vivo; after 3 or 30 min lung fragments were radioassayed or examined by electron microscopy. Both in situ and in vivo, the uptake of fatty acid-carrying albumin (A-FA) was consistently 2 to 3 times higher than that of defatted A. Electron microscopy revealed that A-FA complexes tagged with gold were taken up and transported across the endothelium by plasmalemmal vesicles. Morphometric analysis showed that as compared with A-Au, at 3 min the density of (A-FA)Au bound to plasmalemmal vesicles was 2 to 3 times higher, and the extent of transcytosis was increased. Uptake of the iodinated albumin was more effectively competed by A-FA complexes than by defatted A, suggesting a higher affinity of the former for the albumin binding sites of the endothelium. The results indicate that when carrying fatty acids, albumin is taken up specifically and with high affinity by the capillary endothelium, a process that may play a role in the transport of fatty acids from the plasma to the cells where they are metabolized.     

Zinc transport across an endothelium includes vesicular cotransport with albumin

Bovine pulmonary arterial endothelial cells (BPAEC) were grown on permeable polycarbonate membrane filters suspended between two compartments representing the blood vessel lumen and the interstitium. This in vitro model of an endothelium was subjected to a battery of tests to unravel the mechanisms of zinc transport from the blood into peripheral tissues. Transport of ⁶⁵Zn across BPAEC from media containing zinc concentrations up to 50 μmol/L exhibited both saturable and nonsaturable kinetics. V_max of the saturable component was 246 ± 43 pmol/(h × cm²) and K_m was 2.3 ± 1.3 μmol/L. Transport was pH and temperature sensitive and substantially influenced by albumin and histidine concentrations, but not influenced by analogous minerals or metabolic inhibitors. Inhibition of coated vesicle formation by depletion of intracellular potassium reduced ⁶⁵Zn transport. Albumin carrying a zinc ion crossed the endothelium more rapidly than zinc-free albumin. When evaluated together, this body of evidence supports the existence of two major pathways of zinc transport across the pulmonary endothelium, but neither involves entry into the endothelial cells. One pathway involves receptor-mediated cotransport with albumin by transcytotic vesicles. The other is nonsaturable and involves cotransport with albumin and low molecular weight ligands, principally histidine, through intercellular junctions and nonselective, bulk-fluid transcytosis. © 1996 Wiley-Liss, Inc.     

Specific binding sites for albumin restricted to plasmalemmal vesicles of continuous capillary endothelium: receptor-mediated transcytosis

The interaction of homologous and heterologous albumin-gold complex (Alb-Au) with capillary endothelium was investigated in the mouse lung, heart, and diaphragm. Perfusion of the tracer in situ for from 3 to 35 min was followed by washing with phosphate-buffered saline, fixation by perfusion, and processing for electron microscopy. From the earliest time examined, one and sometimes two rows of densely packed particles bound to some restricted plasma membrane microdomains that appeared as uncoated pits, and to plasmalemmal vesicles open on the luminal front. Morphometric analysis, using various albumin-gold concentrations, showed that the binding is saturable at a very low concentration of the ligand and short exposure. After 5 min, tracer-carrying vesicles appeared on the abluminal front, discharging their content into the subendothelial space. As a function of tracer concentration 1-10% of plasmalemmal vesicles contained Alb-Au particles in fluid phase; from 5 min on, multivesicular bodies were labeled by the tracer. Plasma membrane, coated pits, and coated vesicles were not significantly marked at any time interval. Heparin or high ionic strength did not displace the bound Alb-Au from vesicle membrane. No binding was obtained when Alb-Au was competed in situ with albumin or was injected in vivo. Gold complexes with fibrinogen, fibronectin, glucose oxidase, or polyethyleneglycol did not give a labeling comparable to that of albumin. These results suggest that on the capillary endothelia examined, the Alb-Au is adsorbed on specific binding sites restricted to uncoated pits and plasmalemmal vesicles. The tracer is transported in transcytotic vesicles across endothelium by receptor-mediated transcytosis, and to a lesser extent is taken up by pinocytotic vesicles. The existence of albumin receptors on these continuous capillary endothelia may provide a specific mechanism for the transport of albumin and other molecules carried by this protein.     

Endothelial transcytosis in health and disease

The visionaries predicted the existence of transcytosis in endothelial cells; the cell biologists deciphered its mechanisms and (in part) the molecules involved in the process; the cell pathologists unravelled the presence of defective transcytosis in some diseases. The optimistic perspective is that transcytosis, in general, and receptor-mediated transcytosis, in particular, will be greatly exploited in order to target drugs and genes to exclusive sites in and on endothelial cells (EC) or underlying cells. The current recognition that plasmalemmal vesicles (caveolae) are the vehicles involved in EC transcytosis has moved through various phases from intial considerations of caveolae as unmovable sessile non-functional plasmalemma invaginations to the present identification of a multitude of molecules and a crowd of functions associated with these ubiquitous structures of endothelial and epithelial cells. Further understanding of the molecular machinery that precisely guides caveolae through the cells so as to reach the target membrane (fission, docking, and fusion), to avoid lysosomes, or on the contrary, to reach the lysosomes, and discharge the cargo molecules will assist in the design of pathways that, by manipulating the physiological route of caveolae, will carry molecules of choice (drugs, genes) at controlled concentrations to precise destinations.     

G-protein ligands inhibit in vitro reactions of vacuole inheritance

In many organs the vascular endothelium forms a barrier which impedes the free diffusion of large molecules. The mechanism by which protein hormones are transported through the endothelial cells to reach their target cells is unknown. We have examined the transport of human chorionic gonadotropin (hCG) in rat testicular microvasculature by electron microscopy and by analysing the transfer of radiolabeled hormone and antibodies. Surprisingly, we have observed that the same receptor molecule which is present in target Leydig cells is also involved in transcytosis through the endothelial cells. The hormone was internalized by coated pits and vesicles on the luminal side of the endothelium. It was then localized in the endosomal compartment and subsequently appeared to be delivered by smooth vesicles into the subendothelial space. Moreover, anti-LH/hCG receptor antibodies were efficiently transported via the same system and delivered into the interstitial space. If generalized, these observations may define a new level of modulation of hormone action and may be of importance for drug targeting into the numerous organs which are responsive to the various protein hormones.     

Endothelial transcytotic machinery involves supramolecular protein-lipid complexes

We have demonstrated that the plasmalemmal vesicles (caveolae) of the continuous microvascular endothelium function as transcytotic vesicular carriers for protein molecules > 20 A and that transcytosis is an N-ethylmaleimide-sensitive factor (NSF)-dependent, N-ethylmaleimide-sensitive process. We have further investigated NSF interactions with endothelial proteins to find out 1) whether a complete set of fusion and targeting proteins is present in the endothelium; 2) whether they are organized in multimolecular complexes as in neurons; and 3) whether the endothelial multimolecular complexes differ from their neuronal counterparts, because of their specialized role in transcytosis. To generate the complexes, we have used myc-NSF, cultured pulmonary endothelial cells, and rat lung cytosol and membrane preparations; to detect them we have applied coimmunoprecipitation with myc antibodies; and to characterize them we have used velocity sedimentation and cross-linking procedures. We have found that both cytosolic and membrane fractions contain complexes that comprise beside soluble NSF attachment proteins and SNAREs (soluble NSF attachment protein receptor), rab 5, dynamin, caveolin, and lipids. By immunogold labeling and negative staining we have detected in these complexes, myc-NSF, syntaxin, dynamin, caveolin, and endogenous NSF. Similar complexes are formed by endogenous NSF. The results indicate that complexes with a distinct protein-lipid composition exist and suggest that they participate in targeting, fusion, and fission of caveolae with the endothelial plasmalemma.     

LDL and HDL transfer rates across peripheral microvascular endothelium agree with those predicted for passive ultrafiltration in humans

The mechanisms by which LDLs and HDLs cross the vascular endothelium from plasma into interstitial fluid are not understood, and have never been studied in humans in vivo. We determined whether the plasma-to-lymph clearance rates of LDL and HDL conform with those predicted by passive ultrafiltration through intercellular pores, or if it is necessary to invoke an active process such as receptor-mediated transcytosis. Plasma and afferent peripheral lymph were collected under steady-state conditions from 30 healthy men, and assayed for seven globular proteins of molecular radii 2.89–8.95 nm, complement C3, and apo AI, apo AII, and apo B. Plasma-to-lymph clearance rates of the seven proteins fitted the relation expected for molecules of their size when transported through two populations of pores of radius 4.95 and 20.1 nm. The same model parameters were then found to accurately predict the clearance rates of both HDL and LDL. The apparent clearance of complement C3, previously shown to be secreted by cultured endothelium, exceeded that predicted by the model. We conclude that the transport of HDL and LDL from plasma into interstitial fluid across the peripheral vascular endothelium in healthy humans can be explained by ultrafiltration without invoking an additional active process such as transcytosis.     

Quantitative immunocytochemical studies of endogenous albumin in rat aortic endothelial and mesothelial cells

Endogenous albumin was revealed over cellular structures of rat ascendent aorta endothelia and mesothelium, with high resolution and specificity, by applying the protein A-gold immunocytochemical approach. This approach allows albumin distribution to be studied under steady-state conditions. The cellular layers evaluated were the aortic endothelium, the capillary endothelium (vasa vasorum), and the mesothelium externally lining the aorta at this level. Gold particles, revealing albumin antigenic sites, were preferentially located over plasmalemmal vesicles and intercellular clefts of endothelial and mesothelial cells, though with different labeling intensities. The interstitial space was also labeled. Morphometrical evaluation of plasmalemmal vesicles demonstrated a higher surface density for these structures in capillary endothelial cells (12%) compared with those in aortic endothelial (5%) and mesothelial cells (2%). Quantitation of gold labeling intensities over these structures revealed a higher labeling over plasmalemmal vesicles of capillary endothelium than over those of aortic endothelium and mesothelium. This result, together with the higher surface density of plasmalemmal vesicles found in capillary endothelium, suggest an important role of these structures in the transendothelial passage of endogenous albumin, particularly for capillary endothelium. On the other hand, labeling densities over mesothelial clefts were found to be higher than those of capillary and aortic endothelia. Results from this study concur with the proposal of a differential passage of albumin according to the cell lining considered, and suggest to a role for mesothelial intercellular clefts in contributing to the presence of albumin in interstitial spaces.     

Visualizing caveolin-1 and HDL in cholesterol-loaded aortic endothelial cells

Caveolae are vesicular invaginations of the plasma membranes that regulate signal transduction and transcytosis, as well as cellular cholesterol homeostasis. Our previous studies indicated that the removal of cholesterol from aortic endothelial cells and smooth muscle cells in the presence of HDL is associated with plasmalemmal invaginations and plasmalemmal vesicles. The goal of the present study was to investigate the location and distribution of caveolin-1, the main structural protein component of caveolae, in cholesterol-loaded aortic endothelial cells after HDL incubation. Confocal microscopic analysis demonstrated that the caveolin-1 appeared to colocalize with HDL-fluorescein 1,1'-dioctadecyl 3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) conjugates on the cell surface. No free HDL-DiI conjugates were revealed in the cytoplasm. Immunoelectron microscopy further demonstrated that caveolin-1 gold (15 nm) conjugates colocalized with HDL gold (10 nm) conjugates in the plasmalemmal invaginations. These morphological results indicated that caveolae are the major membrane domains facilitating the transport of excess cholesterol to HDL on the cell surface of aortic endothelial cells.     

The effect of non-receptor-mediated uptake of cholesterol on intracellular cholesterol metabolism in human skin fibroblasts.

Unilamellar lipid vesicles of various cholesterol:phosphatidylcholine molar ratios were used to alter, via passive exchange at the plasma membrane, the cellular free cholesterol content of cultured human skin fibroblasts which had been preincubated in lipoprotein-deficient serum. The effects of these net surface transfers of cholesterol on cellular cholesterol biosynthesis, cholesterol esterification and low density lipoprotein (LDL) binding were determined and were compared with the effects of cholesterol delivered to the cell interior via the receptor-mediated endocytosis of LDL. Both LDL and cholesterol-rich lipid vesicles increased cell cholesterol within 6 h. Cells exposed to LDL also showed, within 6 h, decreased cholesterol synthesis, decreased LDL binding and increased cholesterol esterification. Cells incubated with the cholesterol-rich vesicles showed similar changes but these were delayed and did not occur until 24 h. Fibroblasts incubated with cholesterol-free phosphatidylcholine vesicles had decreased cell cholesterol, increased cholesterol synthesis, increased LDL binding, and decreased esterification, but only after 24 h of incubation. These results suggest that passive net transfers of cholesterol occurring at the cell surface can with time modulate intracellular cholesterol metabolism. These findings are consistent with the idea that the movement of cholesterol from the cell surface to the cell interior is a limited and relatively slow process.     

Glucagon receptors in endothelial and Kupffer cells of mouse liver

To determine whether hepatic sinusoidal cells contain glucagon receptors and, if so, to study the significance of the receptors in the cells, binding of [125I]-glucagon to nonparenchymal cells (mainly endothelial cells and Kupffer cells) isolated from mouse liver was examined by quantitative autoradiography and biochemical methods. Furthermore, the pathway of intracellular transport of colloidal gold-labeled glucagon (AuG) was examined in vivo. Autoradiographic and biochemical results demonstrated many glucagon receptors in both endothelial cells and Kupffer cells, and more receptors being present in endothelial cells than in Kupffer cells. In vivo, endothelial cells internalized AuG particles into coated vesicles via coated pits and transported the particles to endosomes, lysosomes, and abluminal plasma membrane. Therefore, receptor-mediated transcytosis of AuG occurs in endothelial cells. The number of particles present on the abluminal plasma membrane was constant if the amount of injected AuG increased. Therefore, the magnitude of receptor-mediated transcytosis of AuG appears to be regulated by endothelial cells. Kupffer cells internalized the ligand into cytoplasmic tubular structures via plasma membrane invaginations and transported the ligand exclusively to endosomes and lysosomes, suggesting that the ligand is degraded by Kupffer cells.     

Vesicle formation and trafficking in endothelial cells and regulation of endothelial barrier function

Endothelial barrier function is regulated in part by the transcellular transport of albumin and other macromolecules via endothelial caveolae (i.e., this process is defined as transcytosis). Using pulmonary microvascular endothelial cells, we have identified the specific interactions between a cell surface albumin-docking protein gp60 and caveolin-1 as well as components of the signaling machinery, heterotrimeric G protein (G(i))- and Src-family tyrosine kinase. Ligation of gp60 on the apical membrane induces the release of caveolae from the apical membrane and activation of endocytosis. The formed vesicles contain the gp60-bound albumin and also albumin and other solutes present in the fluid phase. Vesicles are transported in a polarized manner to the basolateral membrane, releasing their contents by exocytosis into the subendothelial space. The signaling functions of G(i) and Src are important in the release of caveolae from the plasma membrane. The Src-induced phosphorylation of caveolin-1 is crucial in regulating interactions of caveolin-1 with other components of the signaling machinery such as G(i), and key signaling entry of caveolae into the cytoplasm and endocytosis of albumin and other solutes. This review addresses the basis of transcytosis in endothelial cells, its central role as a determinant of endothelial barrier function, and signaling mechanisms involved in regulating fission of caveolae and trafficking of the formed vesicles from the luminal to abluminal side of the endothelial barrier.     

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

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

Low density lipoprotein binding induces asymmetric redistribution of the low density lipoprotein receptors in endothelial cells.

The uptake and transport of cholesterol-carrying low density lipoprotein (LDL) by the arterial wall is a continuous dynamic process, contributing to the cholesterol homeostasis in the plasma and in the cellular components of the vessel wall. Upon exposure to endothelial cells (EC), LDL interacts in part, with specific surface receptors (LDL-R). In this study we questioned: (i) the distribution of LDL receptors on the apical and basal cell membranes in endothelial cells; (ii) the role of LDL receptors in the control of cholesterol homeostasis and (iii) the translocation of LDL receptor across the EC. To this purpose bovine aortic EC were cultured on filters in a double-chamber system, in Dulbecco's medium supplemented either with 10% fetal calf serum (FCS) or with 10% lipoprotein-deficient serum (LPDS). The cells were exposed for 3h to 13H]acetate (40 microCi) added to both compartments of the cell culture inserts. The newly synthesized [3H]cholesterol was detected by thin layer chromatography and quantified by liquid scintillation counting. The LDL-R were detected in EC protein homogenates by immunoblotting using a monoclonal antibody against LDL-R (IgG-C7); the intracellular pathway of LDL-R was examined by electron microscopy using a complex made of protein A 5 nm or 20 nm colloidal gold particles and an anti-LDL receptor antibody (Au-PA-C7). To evaluate the distribution and the transport of LDL-R from one cell surface to the other, EC grown in LPDS were radioiodinated either on the apical or on the basolateral surface, incubated on the same surface with LDL, and subsequently biotinylated on the opposite non-radiolabeled surface. The EC were further solubilized and the protein extract immunoprecipitated with anti-LDL-R antibody or with mouse IgG (as control). The eluted antigen-antibody complexes were precipitated with streptavidin-agarose beads, solubilized, and subjected to SDS-PAGE. The results showed that: (a) the LDL-R were present on both endothelial cell fronts; (b) using the complex Au-PA-C7, the LDL-R were localized in endothelial plasmalemmal vesicles as well as coated pits and coated vesicles in multivesicular bodies and lysosomes, irrespective of the cell surface exposed to the complex; (c) biochemical assays indicated that upon ligand binding, the LDL-R were translocated preferentially from the apical to the basal plasma membrane.     

The blood-brain barrier transmigrating single domain antibody: mechanisms of transport and antigenic epitopes in human brain endothelial cells

Antibodies against receptors that undergo transcytosis across the blood-brain barrier (BBB) have been used as vectors to target drugs or therapeutic peptides into the brain. We have recently discovered a novel single domain antibody, FC5, which transmigrates across human cerebral endothelial cells in vitro and the BBB in vivo. The purpose of this study was to characterize mechanisms of FC5 endocytosis and transcytosis across the BBB and its putative receptor on human brain endothelial cells. The transport of FC5 across human brain endothelial cells was polarized, charge independent and temperature dependent, suggesting a receptor-mediated process. FC5 taken up by human brain endothelial cells co-localized with clathrin but not with caveolin-1 by immunochemistry and was detected in clathrin-enriched subcellular fractions by western blot. The transendothelial migration of FC5 was reduced by inhibitors of clathrin-mediated endocytosis, K+ depletion and chlorpromazine, but was insensitive to caveolae inhibitors, filipin, nystatin or methyl-beta-cyclodextrin. Following internalization, FC5 was targeted to early endosomes, bypassed late endosomes/lysosomes and remained intact after transcytosis. The transcytosis process was inhibited by agents that affect actin cytoskeleton or intracellular signaling through PI3-kinase. Pretreatment of human brain endothelial cells with wheatgerm agglutinin, sialic acid, alpha(2,3)-neuraminidase or Maackia amurensis agglutinin that recognizes alpha(2,3)-, but not with Sambucus nigra agglutinin that recognizes alpha(2,6) sialylgalactosyl residues, significantly reduced FC5 transcytosis. FC5 failed to recognize brain endothelial cells-derived lipids, suggesting that it binds luminal alpha(2,3)-sialoglycoprotein receptor which triggers clathrin-mediated endocytosis. This putative receptor may be a new target for developing brain-targeting drug delivery vectors.