Multidrug Resistance-Related Transport Proteins in Isolated Human Brain Microvessels and in Cells Cultured from These Isolates

Abstract: The multidrug transporter, P-glycoprotein (Pgp), at the blood-brain barrier is thought to be important for limiting access of toxic agents to the brain, but controversy surrounds its cellular location, whether on endothelium or on adjacent astrocyte foot processes. In the present study, the distribution of protein and mRNA for Pgp and for another transporter, multidrug resistance-associated protein (MRP), is compared with that for the endothelial marker, platelet-endothelial cell adhesion molecule-1 (PECAM-1) and for the astrocyte-derived glial fibrillary acidic protein (GFAP) in microvessels isolated from human brain and in cells grown from these microvessels. Activities of the multidrug transporters are assessed in the cultured cells from the effects of transport inhibitors on intracellular [³H]vincristine accumulation. The isolated microvessels show strong immunocytochemical staining for Pgp and PECAM-1 and little or no staining for GFAP and MRP, and they contain mRNAs detectable by RT-PCR encoding only Pgp and PECAM-1, but not GFAP or MRP. Thus, Pgp may well be synthesised and expressed on cells within the microvessels rather than on adherent astrocyte foot processes. In cells grown from the microvessels, although PECAM-1 remains, Pgp expression decreases and MRP appears. Evidence suggests these multidrug transporters are functionally active in the cultured cells.     

Functional Coupling of Endogenous Serotonin (5-HT1B) and Calcitonin (C1a) Receptors in CHO Cells to a Cyclic AMP-Responsive Luciferase Reporter Gene

Abstract: The hypothesis that P-glycoprotein plays a functional role at the brain capillary endothelium, which makes up the blood-brain barrier in vivo, is based largely on immunocytochemical studies showing immunoreactive P-glycoprotein localized to either isolated brain microvessels or microvessels within tissue sections. The present studies use the MRK16 monoclonal antibody to human P-glycoprotein to demonstrate that the pattern of immunolocalization of P-glycoprotein in microvessels of human or primate brain is similar to the pattern of immunolocalization of an astrocyte protein, glial fibrillary acidic protein. In contrast, the discontinuous staining pattern of MRK16 is not colocalized with the continuous immunostaining of the brain endothelial GLUT1 glucose transporter. The MRK16 antibody was radiolabeled with [¹²⁵I]-iodine, and ¹²⁵I-MRK16 avidly bound isolated human brain capillaries via a saturable mechanism. However, the ¹²⁵I-MRK16 antibody was not taken up by primate brain capillaries in vivo following intravenous injection. In conclusion, these studies provide evidence that P-glycoprotein does not play a functional role at the luminal membrane of the brain capillary endothelium in vivo, and that a principal site of immunoreactive P-glycoprotein in brain microvasculature is localized to astrocyte foot processes.     

Nitric Oxide Contributes to Hypoxia-Reoxygenation-Induced P-Glycoprotein Expression in Rat Brain Endothelial Cells

Ischemia–reperfusion leads to increased levels at the blood–brain barrier of the multidrug efflux transporter, P-glycoprotein that provides protection to the brain by limiting access of unwanted substances. This is coincident with the production of nitric oxide. This present study using immortalized rat brain endothelial cells (GPNTs) examines whether following hypoxia-reoxygenation, nitric oxide contributes to the alterations in P-glycoprotein levels. After 6 h of hypoxia, both nitric oxide and reactive oxygen species, detected intracellularly using fluorescent monitoring dyes, were produced in the subsequent reoxygenation phase coincident with increased P-glycoprotein. The evidence that nitric oxide can directly affect P-glycoprotein expression was sought by applying S-nitroso-N-acetyl-dl-penicillamine that as shown increased the nitric oxide generation. Sodium nitroprusside, though more effective at increasing P-glycoprotein expression, appeared to produce different reactive species. Real time RT-PCR analysis revealed the predominant form of nitric oxide synthase in these cells to be endothelial, inhibition of which partially prevented the increase in P-glycoprotein during reoxygenation. These data indicate that the production of nitric oxide by endothelial nitric oxide synthase during reoxygenation can influence P-glycoprotein expression in cells of the blood-rat brain barrier, highlighting another route by which nitric oxide may protect the brain.     

n-3 Fatty acids modulate brain glucose transport in endothelial cells of the blood–brain barrier

We have previously shown that glucose utilization and glucose transport were impaired in the brain of rats made deficient in n-3 polyunsaturated fatty acids (PUFA). The present study examines whether n-3 PUFA affect the expression of glucose transporter GLUT1 and glucose transport activity in the endothelial cells of the blood–brain barrier. GLUT1 expression in the cerebral cortex microvessels of rats fed different amounts of n-3 PUFA (low vs. adequate vs. high) was studied. In parallel, the glucose uptake was measured in primary cultures of rat brain endothelial cells (RBEC) exposed to supplemental long chain n-3 PUFA, docosahexaenoic (DHA) and eicosapentaenoic (EPA) acids, or to arachidonic acid (AA). Western immunoblotting analysis showed that endothelial GLUT1 significantly decreased (−23%) in the n-3 PUFA-deficient microvessels compared to control ones, whereas it increased (+35%) in the microvessels of rats fed the high n-3 PUFA diet. In addition, binding of cytochalasin B indicated that the maximum binding to GLUT1 (Bmax) was reduced in deficient rats. Incubation of RBEC with 15 μM DHA induced the membrane DHA to increase at a level approaching that of cerebral microvessels isolated from rats fed the high n-3 diet. Supplementation of RBEC with DHA or EPA increased the [³H]-3-O-methylglucose uptake (reflecting the basal glucose transport) by 35% and 50%, respectively, while AA had no effect. In conclusion, we suggest that n-3 PUFA can modulate the brain glucose transport in endothelial cells of the blood–brain barrier, possibly via changes in GLUT1 protein expression and activity.     

Cytochalisin D exerts stimulatory and inhibitory effects on insulin-induced glucokinase mRNA expression in hepatocytes

Developing rat brain undergoes a series of functional and anatomic changes which affect its rate of cerebral glucose utilization (CGU). These changes include increases in the levels of the glucose transporter proteins, GLUT1 and GLUT3, in the blood-brain barrier as well as in the neurons and glia. 55 kDa GLUT1 is concentrated in endothelial cells of the blood-brain barrier, whereas GLUT3 is the predominant neuronal transporter. 45 kDa GLUT1 is in non-vascular brain, probably glia. Studies of glucose utilization with the 2-¹⁴C-deoxyglucose method of Sokoloffet al., (1977), rely on glucose transport rate constants, k₁ and k₂, which have been determined in the adult rat brain. The determination of these constants directly in immature brain, in association with the measurement of GLUT1, GLUT3 and cerebral glucose utilization suggests that the observed increases in the rate constants for the transport of glucose into (k₁) and out of (k₂) brain correspond to the increases in 55 kDa GLUT1 in the blood-brain barrier. The maturational increases in cerebral glucose utilization, however, more closely relate to the pattern of expression of non-vascular GLUT1 (45 kDa), and more specifically GLUT3, suggesting that the cellular expression of the glucose transporter proteins is rate limiting for cerebral glucose utilization during early postnatal development in the rat.     

Inflammatory Mediators and Modulation of Blood–Brain Barrier Permeability

1. Unlike some interfaces between the blood and the nervous system (e.g., nerve perineurium), the brain endothelium forming the blood–brain barrier can be modulated by a range of inflammatory mediators. The mechanisms underlying this modulation are reviewed, and the implications for therapy of the brain discussed.2. Methods for measuring blood–brain barrier permeability in situ include the use of radiolabeled tracers in parenchymal vessels and measurements of transendothelial resistance and rate of loss of fluorescent dye in single pial microvessels. In vitro studies on culture models provide details of the signal transduction mechanisms involved.3. Routes for penetration of polar solutes across the brain endothelium include the paracellular tight junctional pathway (usually very tight) and vesicular mechanisms. Inflammatory mediators have been reported to influence both pathways, but the clearest evidence is for modulation of tight junctions.4. In addition to the brain endothelium, cell types involved in inflammatory reactions include several closely associated cells including pericytes, astrocytes, smooth muscle, microglia, mast cells, and neurons. In situ it is often difficult to identify the site of action of a vasoactive agent. In vitro models of brain endothelium are experimentally simpler but may also lack important features generated in situ by cell:cell interaction (e.g. induction, signaling).5. Many inflammatory agents increase both endothelial permeability and vessel diameter, together contributing to significant leak across the blood–brain barrier and cerebral edema. This review concentrates on changes in endothelial permeability by focusing on studies in which changes in vessel diameter are minimized.6. Bradykinin (Bk)² increases blood–brain barrier permeability by acting on B₂ receptors. The downstream events reported include elevation of [Ca²⁺]_i, activation of phospholipase A₂, release of arachidonic acid, and production of free radicals, with evidence that IL-1 potentiates the actions of Bk in ischemia.7. Serotonin (5HT) has been reported to increase blood–brain barrier permeability in some but not all studies. Where barrier opening was seen, there was evidence for activation of 5-HT₂ receptors and a calcium-dependent permeability increase.8. Histamine is one of the few central nervous system neurotransmitters found to cause consistent blood–brain barrier opening. The earlier literature was unclear, but studies of pial vessels and cultured endothelium reveal increased permeability mediated by H₂ receptors and elevation of [Ca²⁺]_i and an H₁ receptor-mediated reduction in permeability coupled to an elevation of cAMP.9. Brain endothelial cells express nucleotide receptors for ATP, UTP, and ADP, with activation causing increased blood–brain barrier permeability. The effects are mediated predominantly via a P_2U (P2Y₂) G-protein-coupled receptor causing an elevation of [Ca²⁺]_i; a P2Y₁ receptor acting via inhibition of adenyl cyclase has been reported in some in vitro preparations.10. Arachidonic acid is elevated in some neural pathologies and causes gross opening of the blood–brain barrier to large molecules including proteins. There is evidence that arachidonic acid acts via generation of free radicals in the course of its metabolism by cyclooxygenase and lipoxygenase pathways.11. The mechanisms described reveal a range of interrelated pathways by which influences from the brain side or the blood side can modulate blood–brain barrier permeability. Knowledge of the mechanisms is already being exploited for deliberate opening of the blood–brain barrier for drug delivery to the brain, and the pathways capable of reducing permeability hold promise for therapeutic treatment of inflammation and cerebral edema.     

哈尔滨医科大学附属第一医院神经外科

血脑屏障的是人体自然屏障之一。其主要作用是阻止有害物质通过颅内血管进入脑实质,并同时辅助排出脑内代谢物质等。对相当多的颅内恶性肿瘤术后患者,血脑屏障在一定程度上阻碍了化疗药物进入脑实质,从而影响化疗效果。因此近年来越来越多的学者将研究重点放在如何开放血脑屏障这个问题上。血脑屏障构成主要为毛细血管的内皮细胞、基膜周细胞和星状胶质细胞的足突,其中血管内皮细胞处于最重要的地位。原因归结于它自身的一个特殊结构--紧密连接。紧密连接是否完整,功能是否可以正常发挥关系到内皮细胞的完整性,因此对血脑屏障的开放有着举足轻重的作用。维持紧密连接结构中功能蛋白功能的能量物质为葡萄糖。脑血管中的葡萄糖进入脑实质需载体或通道,脑组织负责此过程的物质为葡萄糖转运蛋白1(GLUT1)。本文作者通过松胞菌素B抑制葡萄糖转运蛋白1,降低能量供应从而影响紧密连接功能,最终引起血脑屏障开放角度做一综述。     

Neural Induction of the Blood–Brain Barrier: Still an Enigma

1. The study of the blood–brain barrier and its various realms offers a myriad of opportunities for scientific exploration. This review focuses on two of these areas in particular: the induction of the blood–brain barrier and the molecular mechanisms underlying this developmental process.2. The creation of the blood–brain barrier is considered a specific step in the differentiation of cerebral capillary endothelial cells, resulting in a number of biochemical and functional alterations. Although the specific endothelial properties which maintain the homeostasis in the central nervous system necessary for neuronal function have been well described, the inductive mechanisms which trigger blood–brain barrier establishment in capillary endothelial cells are unknown.3. The timetable of blood–brain barrier formation is still a matter of debate, caused largely by the use of varying experimental systems and by the general difficulty of quantitatively measuring the degree of blood–brain barrier tightness. However, there is a general consensus that a gradual formation of the blood–brain barrier starts shortly after intraneural neovascularization and that the neural microenvironment (neurons and/or astrocytes) plays a key role in inducing blood–brain barrier function in capillary endothelial cells. This view stems from numerous in vitro experiments using mostly cocultures of capillary endothelial cells and astrocytes and assays for easily measurable blood–brain barrier markers. In vivo, there are great difficulties in proving the inductive influence of the neuronal environment. Also dealt with in this article are brain tumors, the least understood in vivo systems, and the induction or noninduction of barrier function in the newly established tumor vascularization.4. Finally, this review tries to elucidate the question concerning the nature of the inductive signal eliciting blood–brain barrier formation in the cerebral microvasculature.     

Growth of endothelial cells on microfabricated silicon nitride membranes for an<Emphasis Type="Italic">in vitro</Emphasis> model of the blood-brain barrier

The blood-brain barrier (BBB) is composed of the brain capillaries, which are lined by endothelial cells displaying extremely tight intercellular junctions. Several attempts at creating anin vitro model of the BBB have been met with moderate success as brain capillary endothelial cells lose their barrier properties when isolated in cell culture. This may be due to a lack of recreation of thein vivo endothelial cellular environment in these models, including nearly constant contact with astrocyte foot processes. This work is motivated by the hypothesis that growing endothelial cells on one side of an ultra-thin, highly porous membrane and differentiating astrocyte or astrogliomal cells on the opposite side will lead to a higher degree of interaction between the two cell types and therefore to an improved model. Here we describe our initial efforts towards testing this hypothesis including a procedure for membrane fabrication and methods for culturing endothelial cells on these membranes. We have fabricated a 1 μm thick, 2.0 μm pore size, and ∼55% porous membrane with a very narrow pore size distribution from low-stress silicon nitride (SiN) utilizing techniques from the microelectronics industry. We have developed a base, acid, autoclave routine that prepares the membranes for cell culture both by cleaning residual fabrication chemicals from the surface and by increasing the hydrophilicity of the membranes (confirmed by contact angle measurements). Gelatin, fibronectin, and a 50/50 mixture of the two proteins were evaluated as potential basement membrane protein treatments prior to membrane cell seeding. All three treatments support adequate attachment and growth on the membranes compared to the control.     

Evaluation of the Role of P-Glycoprotein in Ivermectin Uptake by Primary Cultures of Bovine Brain Microvessel Endothelial Cells

The P-glycoprotein efflux system located on the apical membrane of brain capillary endothelial cells functions as part of the blood-brain barrier. In this study, primary cultures of bovine brain microvessel endothelial cells (BMECs) were investigated for the presence of a P-glycoprotein system and its contribution in regulating ivermectin distribution across the blood-brain barrier. Results of rhodamine 123 uptake studies with cyclosporin A and verapamil as substrates indicated that a functional efflux system was present on BMECs. Immunoblot analysis with the C219 monoclonal antibody to the product of the multidrug resistant member 1(MDR1) gene also confirmed the expression of MDR1 in the BMECs. Unbound ivermectin was shown to significantly increase the uptake of rhodamine 123 in BMECs, however, the drug only modestly enhanced the transcellular passage of rhodamine. The results of these studies affirmed that unbound ivermectin is an inhibitor of the MDR1 efflux system in BMECs.     

Functional expression of the P-glycoproteinmdr in primary cultures of bovine cerebral capillary endothelial cells

The P-glycoproteinmdr is expressed not only in tumoral cells, but also in nontransformed cells, including the specialized endothelial cells of brain capillaries which build up the blood-brain barrier. Since all previously identified blood-brain barrier markers are rapidly lost when cerebral capillary endothelial cells are maintained in primary culture, we have investigated whether P-glycoprotein (P-gp) would follow the same rule, in order to address the influence of the cerebral environment on the specific P-gp expression in the brain endothelium. As compared to freshly isolated purified cerebral capillaries, P-glycoprotein was detected by immunochemistry at a high level in 5–7 day primary cultures. In our culture conditions, P-glycoprotein was immunodetected at a lower molecular weight than that found in freshly isolated capillaries. Enzymatic deglycosylation led to the same 130 kDa protein for both fresh and cultured samples, suggesting that P-gp post-translational modifications were altered in primary cultures. However, studies on the uptake and efflux of the P-gp substrate [³H]vinblastine, and on the effect of variousmdr reversing agents on the uptake and efflux, clearly indicated that the efflux pump function of the P-glycoprotein was maintained in primary cultures of bovine cerebral capillary endothelial cells. P-Glycoprotein may thus represent the first blood-brain barrier marker which is maintained in cerebral endothelial cells cultured in the absence of factors originating from the brain parenchyma.Abbreviations BBB blood-brain barrier - BCEC brain capillary endothelial cells - -GT -glutamyltranspeptidase - HBSS Hank's balanced salt solution - Mab monoclonal antibody - mdr multidrug resistance - P-gp P-glycoprotein     

The drug cerebrolysin and its peptide fraction E021 increase the abundance of the blood-brain barrier GLUT1 glucose transporter in brains of young and old rats

The brain-derived peptidergic drug Cerebrolysin has been found to support the survival of neurons in vitro and in vivo. In the present study, we investigated the effects of Cerebrolysin and its peptide preparation E021 on spatial learning and memory, as well as on the abundance of the blood–brain barrier GLUT1 glucose transporter (GLUT1) in 2-month-old and 24-month-old rats. Young rats were treated with the drugs or saline (2.5ml/kg/day) daily on postnatal days 1–7, and old rats for 19 consecutive days. For behavioural testing the Morris water maze was used. The abundance of GLUT1 was determined in brain slices by immunocytochemistry. Quantification of the density of the GLUT1 immunostaining was performed using light microscopy and a computerised image analysing system. All drug-treated rats, young and old, exhibit shorter escape latencies in the water maze, on all testing days (p>0.01), indicating improved cognitive performance. Immunohistochemical data show an age-related decrease of the density of GLUT1 (p>0.05). In young animals, the administration of the drugs led to an increase of the abundance of GLUT1 in all experimental groups (p>0.01). In old rats, the treatment with Cerebrolysin, but not with E021, resulted in an increase in the immunoreactive GLUT1 (p>0.01).The elevated abundance of GLUT1 after the administration of both peptidergic substances might be supportive for the cognitive effects of this drug, by causing an improved nutritional supply of glucose to the neurons.     

Characterization and functional reconstitution of the multidrug transporter

P-Glycoprotein, the multidrug transporter, is isolated from the plasma membrane of CH^RC5 cells using a selective two-step detergent extraction procedure. The partially purified protein displays a high level of ATPase activity, which has a highK _M for ATP, is stimulated by drugs, and can be distinguished from that of other membrane ATPases by its unique inhibition profile. Delipidation completely inactivates ATPase activity, which is restored by the addition of fluid lipid mixtures. P-Glycoprotein was reconstituted into lipid bilayers with retention of both drug transport and ATPase activity. Proteoliposomes containing P-glycoprotein display osmotically sensitive ATP-dependent accumulation of³H-colchicine in the vesicle lumen. Drug transport is active, generating a stable 5.6-fold concentration gradient, and can be blocked by compounds in the multidrug resistance spectrum. Reconstituted P-glycoprotein also exhibits a high level of ATPase activity which is further stimulated by various drugs. P-Glycoprotein therefore functions as an active drug transporter with constitutive ATPase activity.     

n-3 Fatty acids modulate brain glucose transport in endothelial cells of the blood–brain barrier

We have previously shown that glucose utilization and glucose transport were impaired in the brain of rats made deficient in n-3 polyunsaturated fatty acids (PUFA). The present study examines whether n-3 PUFA affect the expression of glucose transporter GLUT1 and glucose transport activity in the endothelial cells of the blood–brain barrier. GLUT1 expression in the cerebral cortex microvessels of rats fed different amounts of n-3 PUFA (low vs. adequate vs. high) was studied. In parallel, the glucose uptake was measured in primary cultures of rat brain endothelial cells (RBEC) exposed to supplemental long chain n-3 PUFA, docosahexaenoic (DHA) and eicosapentaenoic (EPA) acids, or to arachidonic acid (AA). Western immunoblotting analysis showed that endothelial GLUT1 significantly decreased (−23%) in the n-3 PUFA-deficient microvessels compared to control ones, whereas it increased (+35%) in the microvessels of rats fed the high n-3 PUFA diet. In addition, binding of cytochalasin B indicated that the maximum binding to GLUT1 (Bmax) was reduced in deficient rats. Incubation of RBEC with 15 μM DHA induced the membrane DHA to increase at a level approaching that of cerebral microvessels isolated from rats fed the high n-3 diet. Supplementation of RBEC with DHA or EPA increased the [³H]-3-O-methylglucose uptake (reflecting the basal glucose transport) by 35% and 50%, respectively, while AA had no effect. In conclusion, we suggest that n-3 PUFA can modulate the brain glucose transport in endothelial cells of the blood–brain barrier, possibly via changes in GLUT1 protein expression and activity.     

A putative nicotine pump at the metabolic blood–brain barrier of the tobacco hornworm

In mammals, P-glycoprotein immunostaining at the blood–brain barrier has implicated the multidrug pump in the restricted movement of many cytotoxic agents into the central nervous system (NCS). Since many insects require as sophisticated blood–brain barrier system to protect their CNS from plant-derived neurotoxins, we have investigated the possibility that a P-glycoprotein homolog constitutes a component of the insect blood–brain barrier. We have used the nicotine-resistant tobacco hornworm (Manduca sexta) to address this issue. Manduca has been previously shown, in physiological studies, to have an alkaloid (nicotine/morphine/atropine) pump at its excretory malpighian tubules. We show (1) that the tubules are P-glycoprotein immunopositive, (2) that Manduca has a metabolic blood–brain barrier for nicotine, (3) that the barrier co-localizes with P-glycoprotein immunostaining, and (4) that detoxifying enzymes as well as the nicotine pump are likely to account for the metabolic blood–brain to nicotine. These findings may provide insights on two major fronts, the troublesome problem of multi-insecticide resistance, a phenomenon that parallels multidrug resistance in tumor cells, and the problem of tolerance to addictive neuroactive drugs like nicotine or morphine. 1994 John Wiley & Sons, Inc.     

Dexamethasone Regulation of P-Glycoprotein Activity in an Immortalized Rat Brain Endothelial Cell Line, GPNT

The blood-brain barrier (BBB) plays an important role in controlling the passage of molecules from the blood to the extracellular fluid environment of the brain. The multidrug efflux pump P-glycoprotein (P-gp) is highly expressed in the luminal membrane of brain capillary endothelial cells, thus forming a functional barrier to lipid-soluble drugs, notably, antitumor agents. It is of interest to develop an in vitro BBB model that stably expresses P-gp to investigate the mechanisms of regulation in expression and activity. The rat brain endothelial cell line, GPNT, was derived from a previously characterized rat brain endothelial cell line. A strong expression of P-gp was found in GPNT monocultures, whereas the multidrug resistance-associated pump Mrp1 was not expressed. The transendothelial permeability coefficient of the P-gp substrate vincristine across GPNT monolayers was close to the permeability coefficient of bovine brain endothelial cells cocultured with astrocytes, a previously documented in vitro BBB model. Furthermore, the P-gp blocker cyclosporin A induced a large increase in apical to basal permeability of vincristine. Thus, P-gp is highly functional in GPNT cells. A 1-h treatment of GPNT cells with dexamethasone resulted in decreased uptake of vincristine without any increase in P-gp expression. This effect could be mimicked by protein kinase C (PKC) activation and prevented by PKC inhibition, strongly suggesting that activation of P-gp function may involve a PKC-dependent pathway. These results document the GPNT cell line as a valuable in vitro model for studying drug transport and P-gp function at the BBB and suggest that activation of P-gp activity at the BBB might be considered in chemotherapeutic treatment of cancer patients.     

Brain-Targeted Delivery of Docetaxel by Glutathione-Coated Nanoparticles for Brain Cancer

Gliomas are some of the most aggressive types of cancers but the blood–brain barrier acts as an obstacle to therapeutic intervention in brain-related diseases. The blood–brain barrier blocks the permeation of potentially toxic compounds into neural tissue through the interactions of brain endothelial cells with glial cells (astrocytes and pericytes) which induce the formation of tight junctions in endothelial cells lining the blood capillaries. In the present study, we characterize a glutathione-coated docetaxel-loaded PEG-PLGA nanoparticle, show its in vitro drug release data along with cytotoxicity data in C6 and RG2 cells, and investigate its trans-blood–brain barrier permeation through the establishment of a Transwell cellular co-culture. We show that the docetaxel-loaded nanoparticle’s size enables its trans-blood–brain barrier permeation; the nanoparticle exhibits a steady, sustained release of docetaxel; the drug is able to induce cell death in glioma models; and the glutathione-coated nanoparticle is able to permeate through the Transwell in vitro blood–brain barrier model.KEY WORDS: blood–brain barrier, brain cancer, docetaxel, glutathione, nanoparticle     

A polarized localization of amino acid/carnitine transporter B(0,+) (ATB(0,+)) in the blood-brain barrier

Brain capillary endothelial cells control the uptake and efflux from the brain of many hydrophilic compounds due to highly specialized transporters often localized in a polarized way. Localization of Na⁺- and Cl⁻-dependent amino acid and carnitine transporter B^0,+ (ATB^0,+) was studied in a co-culture of bovine brain capillary endothelial cells (BBCEC) grown on filters above astrocytes (an in vitro blood-brain barrier model). Immunoblotting and three-dimensional immunocytochemistry analysis with anti-B^0,+antibodies demonstrated the presence of this transporter and its prevalent co-localization with P-glycoprotein i.e. at the apical side. The sensitivity of leucine uptake through the apical membrane to 2-aminobicyclo-[2.2.1]-heptane-2-carboxylic acid (BCH), d-serine as well as sodium and chloride replacement confirm the functioning of ATB^0,+ and suggests an important physiological role of ATB^0,+ in controlling the delivery of amino acids and carnitine to the brain.