Expression and possible role of creatine transporter in the brain and at the blood-cerebrospinal fluid barrier as a transporting protein of guanidinoacetate, an endogenous convulsant

Little is known about the cerebral distribution and clearance of guanidinoacetate (GAA), the accumulation of which induces convulsions. The purpose of the present study was to identify creatine transporter (CRT)-mediated GAA transport and to clarify its cerebral expression and role in GAA efflux transport at the blood-cerebrospinal fluid barrier (BCSFB). CRT mediated GAA transport with a K(m) value of 269 microM/412 microM which was approximately 10-fold greater than that of CRT for creatine. There was wide and distinct cerebral expression of CRT and localization of CRT on the brush-border membrane of choroid plexus epithelial cells. The in vivo elimination clearance of GAA from the CSF was 13-fold greater than that of d-mannitol reflecting bulk flow of the CSF. This process was partially inhibited by creatine. The characteristics of GAA uptake by isolated choroid plexus and an immortalized rat choroid plexus epithelial cell line (TR-CSFB cells) used as an in vitro model of BCSFB are partially consistent with those of CRT. These results suggest that CRT plays a role in the cerebral distribution of GAA and GAA uptake by the choroid plexus. However, in the presence of endogenous creatine in the CSF, CRT may make only a limited contribution to the GAA efflux transport at the BCSFB.     

Transport systems of serine at the brain barriers and in brain parenchymal cells

D-Serine is a co-agonist for NMDA-type glutamate receptors. Although D-serine levels in CSF and interstitial fluid (ISF) affect CNS function, the regulatory system remains to be fully understood. Therefore, the purpose of this study was to investigate d-serine transport across the blood-brain barrier (BBB) and blood-CSF barrier (BCSFB) and in brain parenchymal cells. D-Serine microinjected into the cerebrum was not eliminated, suggesting a negligible contribution of D-serine efflux transport at the BBB. In contrast, D-serine was taken up from the circulating blood across the BBB via a carrier-mediated process. D-Serine elimination clearance from CSF was fourfold greater than that of d-mannitol, which is considered to reflect CSF bulk flow. The characteristics of D-serine uptake by isolated choroid plexus were consistent with those of Na(+)-independent alanine-serine-cysteine transporter 1 (asc-1). Uptake of D-serine by brain slices appeared to occur predominantly via asc-1 and Na(+)-dependent alanine-serine-cysteine transporter 2. These findings suggest that the regulatory system of D-serine levels in ISF and CSF involves (i) asc-1 at the BCSFB, acting as a major pathway of D-serine elimination from the CSF, (ii) blood-to-brain and blood-to-CSF influx transport of D-serine across the BBB and BCSFB, and (iii) concentrative uptake of D-serine by brain parenchymal cells.     

Glutamine transport at the blood-brain and blood-cerebrospinal fluid barriers

Glutamine has multiple physiological and pathophysiological roles in the brain. Because of their position at the interface between blood and brain, the cerebral capillaries and the choroid plexuses that form the blood-brain barriers (BBB) and blood-cerebrospinal fluid (CSF) barriers, have the potential to influence brain glutamine concentrations. Despite this, there has been a paucity of data on the mechanisms and polarity of glutamine transport at these barrier tissues. In situ brain perfusion in the rat, indicates that blood to brain L-[14C]glutamine transport at the blood-brain barrier is primarily mediated by a pH-dependent, Na(+)-dependent, System N transporter, but that blood to choroid plexus transport is primarily via a pH-independent System N transporter and a Na(+)-independent carrier that is not System L. Transport studies in isolated rat choroid plexuses and primary cultures of choroid plexus epithelial cells indicate that epithelial L-[14C]glutamine transport is polarized (apical uptake>basolateral) and that uptake at the apical membrane is mediated by pH dependent System N transporters (identified as SN1 and SN2 by polymerase chain reaction) and the Na(+)-independent System L. Blood-brain barrier System N transport is markedly effected by cerebral ischemia and may be a good marker of endothelial cell dysfunction. The multiple glutamine transporters at the blood-brain and blood-CSF barriers may have role in meeting the metabolic needs of the brain and the barrier tissues themselves. However, it is likely that the main role of these transporters is removing glutamine, and thus nitrogen, from the brain.     

Active transport at the blood-CSF barrier contributes to manganese influx into the brain

Manganese is an essential trace element, and a contrast agent of potential interest for brain magnetic resonance imaging. Brain overexposure to manganese, however induces a neurodegenerative syndrome. Imaging data suggest that manganese appearance into the CSF precedes its accumulation into the cerebral parenchyma. We therefore investigated manganese uptake and transport at the blood-CSF barrier. Like lead, the non protein-bound divalent manganese accumulated into the rat choroid plexus. The metal accumulation was especially high in developing animals. Using a differentiated cellular model of the blood-CSF barrier, we demonstrated that manganese crosses the choroid plexus epithelium by a concentrating, unidirectional blood-to-CSF transport mechanism. This transport was inhibited by calcium, which is also transported into the CSF against its concentration gradient. The permeability barrier function towards lipid-insoluble compound and the organic anion transport property of the blood-brain interface were affected by exposure of the blood-facing membrane of choroidal cells to micromolar concentrations of manganese, but its antioxidant capacity was not. The unidirectional transport of manganese across the choroid plexus provides the anatomo-functional basis linking the systemic exposure to manganese with the spreading pattern of manganese accumulation observed in brain imaging, and explains the polarized sensitivity of choroidal epithelial cells to manganese toxicity.     

Glutaric aciduria type I and methylmalonic aciduria: Simulation of cerebral import and export of accumulating neurotoxic dicarboxylic acids in in vitro models of the blood–brain barrier and the choroid plexus

Intracerebral accumulation of neurotoxic dicarboxylic acids (DCAs) plays an important pathophysiological role in glutaric aciduria type I and methylmalonic aciduria. Therefore, we investigated the transport characteristics of accumulating DCAs – glutaric (GA), 3-hydroxyglutaric (3-OH-GA) and methylmalonic acid (MMA) – across porcine brain capillary endothelial cells (pBCEC) and human choroid plexus epithelial cells (hCPEC) representing in vitro models of the blood–brain barrier (BBB) and the choroid plexus respectively. We identified expression of organic acid transporters 1 (OAT1) and 3 (OAT3) in pBCEC on mRNA and protein level. For DCAs tested, transport from the basolateral to the apical site (i.e. efflux) was higher than influx. Efflux transport of GA, 3-OH-GA, and MMA across pBCEC was Na⁺-dependent, ATP-independent, and was inhibited by the OAT substrates para-aminohippuric acid (PAH), estrone sulfate, and taurocholate, and the OAT inhibitor probenecid. Members of the ATP-binding cassette transporter family or the organic anion transporting polypeptide family, namely MRP2, P-gp, BCRP, and OATP1B3, did not mediate transport of GA, 3-OH-GA or MMA confirming the specificity of efflux transport via OATs. In hCPEC, cellular import of GA was dependent on Na⁺-gradient, inhibited by NaCN, and unaffected by probenecid suggesting a Na⁺-dependent DCA transporter. Specific transport of GA across hCPEC, however, was not found. In conclusion, our results indicate a low but specific efflux transport for GA, 3-OH-GA, and MMA across pBCEC, an in vitro model of the BBB, via OAT1 and OAT3 but not across hCPEC, an in vitro model of the choroid plexus.     

The blood–brain barrier transport and cerebral distribution of guanidinoacetate in rats: involvement of creatine and taurine transporters

Although the cerebral accumulation of guanidinoacetate (GAA) contributes to neurological complications in S -adenosylmethionine:guanidinoacetate N -methyltransferase (GAMT) deficiency, how GAA is abnormally distributed in the brain remains unknown. The purpose of this study was to investigate the transport of GAA across the blood–brain barrier (BBB) and in brain parenchymal cells in rats. [¹⁴C]GAA microinjected into the rat cerebrum was not eliminated from the brain, implying the negligible contribution of GAA efflux transport across the BBB. In contrast, in vivo analysis and an uptake study by TR-BBB cells, a rat in vitro BBB model, revealed that GAA was transported from the circulating blood across the BBB most likely via a creatine transporter (CRT). Although CRT at the BBB is almost saturated by endogenous creatine under physiological conditions, the creatine level in the blood significantly decreases in GAMT deficiency. This might lead to the increase of CRT-mediated blood-to-brain transport of GAA at the BBB. Furthermore, [¹⁴C]GAA was taken up by brain parenchymal cells in a concentrative manner most likely via taurine transporter and CRT. These characteristics of GAA transport across the BBB and in the brain parenchymal cells could be the key factors that facilitate GAA accumulation in the brains of patients with GAMT deficiency.     

The movement of sulfate and thiosulfate into in vivo choroid plexus

The accumulation of sulfate (SO₄?) and thiosulfate (S₂O₃?) in the choroid plexus, brain, and cerebrospinal fluid (CSF) of the rat was measured at various plasma levels of these anions. Increasing the plasma SO₄ ? or S₂O₃ ? concentration levels 40- and 580-fold, respectively, resulted in a linear increase in CSF, brain and choroid plexus concentration of these ions. The relationship between the concentration of these ions in CSF and choroid plexus was also approximately linear over a wide CSF concentration range. In addition, S₂O₃? did not appear to influence the relation between the concentration of SO₄? in choroid plexus and CSF. The results seem to indicate that there is no saturation of the mechanism responsible for maintaining the low SO₄? or S₂O₃? concentration in CSF nor does there appear to be competition between these anions for clearance from the CSF. These findings are in conflict with data supporting the active transport of SO₄? and S₂O₃? from the CSF across the CSF-blood barrier (choroid plexus).     

Altered clearance of beta-amyloid from the cerebrospinal fluid following subchronic lead exposure in rats: Roles of RAGE and LRP1 in the choroid plexus

Formation of amyloid plaques is the hallmark of Alzheimer’s disease. Our early studies show that lead (Pb) exposure in PDAPP transgenic mice increases β-amyloid (Aβ) levels in the cerebrospinal fluid (CSF) and hippocampus, leading to the formation of amyloid plaques in mouse brain. Aβ in the CSF is regulated by the blood-CSF barrier (BCB) in the choroid plexus. However, the questions as to whether and how Pb exposure affected the influx and efflux of Aβ in BCB remained unknown. This study was conducted to investigate whether Pb exposure altered the Aβ efflux in the choroid plexus from the CSF to blood, and how Pb may affect the expression and subcellular translocation of two major Aβ transporters, i.e., the receptor for advanced glycation end-products (RAGE) and the low density lipoprotein receptor protein-1 (LRP1) in the choroid plexus. Sprague-Dawley rats received daily oral gavage at doses of 0, 14 (low-dose), and 27 (high-dose) mg Pb/kg as Pb acetate, 5 d/wk, for 4 or 8 wks. At the end of Pb exposure, a solution containing Aβ₄₀ (2.5 μg/mL) was infused to rat brain via a cannulated internal carotid artery. Subchronic Pb exposure at both dose levels significantly increased Aβ levels in the CSF and choroid plexus (p < 0.05) by ELISA. Confocal data showed that 4-wk Pb exposures prompted subcellular translocation of RAGE from the choroidal cytoplasm toward apical microvilli. Furthermore, it increased the RAGE expression in the choroid plexus by 34.1 % and 25.1 % over the controls (p < 0.05) in the low- and high- dose groups, respectfully. Subchronic Pb exposure did not significantly affect the expression of LRP1; yet the high-dose group showed LRP1 concentrated along the basal lamina. The data from the ventriculo-cisternal perfusion revealed a significantly decreased efflux of Aβ₄₀ from the CSF to blood via the blood-CSF barrier. Incubation of freshly dissected plexus tissues with Pb in artificial CSF supported a Pb effect on increased RAGE expression. Taken together, these data suggest that Pb accumulation in the choroid plexus after subchronic exposure reduces the clearance of Aβ from the CSF to blood by the choroid plexus, which, in turn, leads to an increase of Aβ in the CSF. Interaction of Pb with RAGE and LRP1 in choroidal epithelial cells may contribute to the altered Aβ transport by the blood-CSF barrier in brain ventricles.     

Retinal-specific ATP-binding cassette transporter (ABCR/ABCA4) is expressed at the choroid plexus in rat brain

ATP-binding cassette (ABC) transporter A4 is a member of the ABC transporter subfamily A which has been reported to be exclusively expressed in the retina. In contrast, a previous report has suggested a possible relationship between ABCA4 and CNS function. The purpose of the present study was to investigate the localization of ABCA4 mRNA and protein in rat brain. In situ hybridization analysis revealed that ABCA4 mRNA was localized in the lateral ventricles. RT-PCR analysis detected ABCA4 mRNA in isolated rat choroid plexus and conditionally immortalized rat choroid plexus epithelial cells (TR-CSFB). Furthermore, ABCA4 protein was also detected in the isolated rat choroid plexus at about 250 kDa by western blot analysis, and its apparent molecular size was reduced by N-glycosidase F treatment. These results suggest that glycosylated ABCA4 protein is expressed in rat choroid plexus epithelial cells. ABCA4 may play a role in the function of the blood-cerebrospinal fluid barrier and affect CSF conditions.     

The choroid plexus removes beta-amyloid from brain cerebrospinal fluid

beta-Amyloid (Abeta) concentration in the cerebrospinal fluid (CSF) of the brain may be regulated by the choroid plexus, which forms a barrier between blood and brain CSF. Abeta uptake from CSF was determined as its volume of distribution (V(D)) into isolated rat choroid plexus tissue. The V(D) of [125I]Abeta1-40 was corrected by subtraction of the V(D) of [14C]sucrose, a marker for extracellular space and diffusion. Abeta uptake into choroid plexus was time and temperature dependent. Uptake of [125I]Abeta was saturable. Abeta uptake was not affected by addition of transthyretin or apolipoprotein E3. In studies with primary culture monolayers of choroidal epithelial cells in Transwells, Abeta permeability across cells, corrected by [(14)C]sucrose, was greater from the CSF-facing membrane than from the blood-facing membrane. Similarly, cellular accumulation of [125I]Abeta was concentrative from both directions and was greater from the CSF-facing membrane, suggesting a bias for efflux. Overall, these results suggest the choroid plexus selectively cleanses Abeta from the CSF by an undetermined mechanism(s), potentially reducing Abeta from normal brains and the brains of Alzheimer's disease patients.     

Distribution of the Glucose Transporter in the Mammalian Brain

We used [3H]cytochalasin B as a specific ligand to study the glucose transporter of the following tissue preparations: (a) microvessels derived from the cerebral cortex and cerebellum of the rat and pig, (b) particulate fractions of the cerebral cortex and cerebellum of the rat and pig, (c) lateral, third, and fourth ventricular choroid plexus of the pig, and (d) synaptosomes from the pig cerebral cortex. Specific, D-glucose-displaceable binding of [3H]cytochalasin B was present in all the preparations studied. This binding was saturable and displayed the kinetics of a single class of binding sites, similar to the glucose transporter found in other mammalian tissues. The density of the glucose transporter was much higher in cerebral and cerebellar microvessels and choroid plexus than either in crude particulate fractions of the cerebrum and cerebellum or in cerebral synaptosomes. These findings agree with the physiologic function of brain microvessels that transport glucose, not only for their own use, but also for the much greater mass of the entire brain. In the pig, the density of the glucose transporter in cerebral microvessels was significantly higher than in cerebellar microvessels. Irreversible photoaffinity labeling of the glucose transporter of synaptosomal membranes with [3H]cytochalasin B followed by solubilization and polyacrylamide gel electrophoresis demonstrated a single region of radioactivity that corresponded to a molecular mass of 60,000-64,000 daltons.     

Organic anion transporter 3 is involved in the brain-to-blood efflux transport of thiopurine nucleobase analogs

Thiopurines are used as antileukemic drugs. However, during chemotherapy CNS relapses occur due to the proliferation of leukemic cells in the CNS resulting from restricted drug distribution in the brain. The molecular mechanism for this limited cerebral distribution remains unclear. The purpose of this study was to identify the transporter responsible for the brain-to-blood transport of thiopurines across the blood-brain barrier (BBB) using the brain efflux index method. [14C]6-Mercaptopurine (6-MP) and [3H]6-thioguanine were eliminated from rat brain in a time-dependent manner. The elimination of [14C]6-MP was inhibited by substrates of rat organic anion transporters (rOATs), including indomethacin and benzylpenicillin. rOAT1 and rOAT3 exhibited 6-MP uptake, while benzylpenicillin inhibited rOAT3-mediated uptake, but not that by rOAT1. rOAT3-mediated [14C]6-MP uptake was also inhibited by other thiopurine derivatives. Although methotrexate inhibited rOAT3-mediated [14C]6-MP uptake, the Ki value was 17.5-fold greater than the estimated brain concentration of methotrexate in patients receiving chemotherapy. Accordingly, 6-MP would undergo efflux transport by OAT3 from the brain without any inhibitory effect from coadministered methotrexate in the chemotherapy. In conclusion, rOAT3 is involved in the brain-to-blood transport of thiopurines at the BBB and is one mechanism of limited cerebral distribution.     

Expression of the neonatal Fc receptor (FcRn) at the blood-brain barrier

The blood-brain barrier (BBB) restricts transport of immunoglobulin G (IgG) in the blood to brain direction. However, IgG undergoes rapid efflux in the brain to blood direction via reverse transcytosis across the BBB after direct intracerebral injection. This BBB IgG transport system has the characteristics of an Fc receptor (FcR), but there is no molecular information on the putative BBB FcR. The present study uses confocal microscopy and an antibody to the rat neonatal FcR (FcRn), and demonstrates the expression of the FcRn at the brain microvasculature and choroid plexus epithelium. Co-localization with the Glut1 glucose transporter indicates the brain microvascular FcRn is expressed in the capillary endothelium. The capillary endothelial FcRn may mediate the 'reverse transcytosis' of IgG in the brain to blood direction.     

Efflux of iron from the cerebrospinal fluid to the blood at the blood-CSF barrier: effect of manganese exposure

The blood-cerebrospinal fluid (CSF) barrier (BCB) resides within the choroid plexus, with the apical side facing the CSF and the basolateral side towards the blood. Previous studies demonstrate that manganese (Mn) exposure in rats disrupts iron (Fe) homeostasis in the blood and CSF. The present study used a primary culture of rat choroidal epithelial cells grown in the two-chamber Transwell system to investigate the transepithelial transport of Fe across the BCB. Free, unbound Fe as [(59)Fe] was added to the donor chamber and the radioactivity in the acceptor chamber was quantified to determine the direction of Fe fluxes. Under the normal condition, the [(59)Fe] efflux (from the CSF to the blood) was 128% higher than that of the influx (P < 0.01). Mn exposure significantly increased the efflux rate of [(59)Fe] (P < 0.01) and the effect was inhibited when the cells were pre-incubated with the antibody against divalent metal transport 1 (DMT1). Moreover, when the siRNA knocked down the cellular DMT1 expression, the elevated Fe uptake caused by Mn exposure in the choroidal epithelial Z310 cells was completely abolished, indicating that Mn may facilitate Fe efflux via a DMT1-mediated transport mechanism. In vivo subchronic exposure to Mn in rats reduced Fe clearance from the CSF, as demonstrated by the ventriculo-cisternal brain perfusion, along with up-regulated mRNAs encoding DMT1 and transferrin receptor (TfR) in the same animals. Taken together, these data suggest that free Fe appears to be favorably transported from the CSF toward the blood by DMT1 and this process can be facilitated by Mn exposure. Enhanced TfR-mediated influx of Fe from the blood and ferroportin-mediated expelling Fe toward the CSF may compromise DMT1-mediated efflux, leading to an increased Fe concentration in the CSF as seen in Mn-exposed animals.     

Identification of the Cationic Amino Acid Transporter (System y+) of the Rat Blood-Brain Barrier

Abstract: Cationic amino acids are transported from blood into brain by a saturable carrier at the blood-brain barrier (BBB). The transport properties of this carrier were examined in the rat using an in situ brain perfusion technique. Influx into brain via this system was found to be sodium independent and followed Michaelis-Men-ten kinetics with half-saturation constants (K_m) of 50–100 μM and maximal transport rates of 22–26 nmol/min/g for L-lysine, L-arginine, and L-ornithine. The kinetic properties matched that of System y⁺, the sodium-independent cationic amino acid transporter, the cDNA for which has been cloned from the mouse. To determine if the cloned receptor is expressed at the BBB, we assayed RNA from rat cerebral microvessels and choroid plexus for the presence of the cloned transporter mRNA by RNase protection. The mRNA was present in both cerebral microvessels and choroid plexus and was enriched in microvessels 38-fold as compared with whole brain. The results indicate that System y⁺ is present at the BBB and that its mRNA is more densely expressed at cerebral microvessels than in whole brain.     

Involvement of organic anion transporters in the efflux of uremic toxins across the blood-brain barrier

Renal failure causes multiple physiological changes involving CNS dysfunction. In cases of uremia, there is close correlation between plasma levels of uremic toxins [e.g. 3-carboxy-4-methyl-5-propyl-2-furanpropionate (CMPF), hippurate (HA) and indoleacetate (IA)] and the degree of uremic encephalopathy, suggesting that uremic toxins are involved in uremic encephalopathy. In order to evaluate the relevance of uremic toxins to CNS dysfunction, we investigated directional transport of uremic toxins across the blood-brain barrier (BBB) using in vivo integration plot analysis and the brain efflux index method. We observed saturable efflux transport of [(3)H]CMPF, [(14)C]HA and [(3)H]IA, which was inhibited by probenecid. For all uremic toxins evaluated, apparent efflux clearance across the BBB was greater than apparent influx clearance, suggesting that these toxins are predominantly transported from the brain to blood across the BBB. Saturable efflux transport of [(3)H]CMPF, [(14)C]HA and [(3)H]IA was completely inhibited by benzylpenicillin, which is a substrate of rat organic anion transporter 3 (rOat3). Taurocholate and digoxin, which are common substrates of rat organic anion transporting polypeptide (rOatp), partially inhibited the efflux of [(3)H]CMPF. Transport experiments using a Xenopus laevis oocyte expression system revealed that CMPF, HA and IA are substrates of rOat3, and that CMPF (but not HA or IA) is a substrate of rOap2. These results suggest that rOat3 mediates brain-to-blood transport of uremic toxins, and that rOatp2 is involved in efflux of CMPF. Thus, conditions typical of uremia can cause inhibition of brain-to-blood transport involving rOat3 and/or rOatp2, leading to accumulation of endogenous metabolites and drugs in the brain.     

Vitamin transport and homeostasis in mammalian brain: focus on Vitamins B and E

With the application of genetic and molecular biology techniques, there has been substantial progress in understanding how vitamins are transferred across the mammalian blood-brain barrier and choroid plexus into brain and CSF and how vitamin homeostasis in brain is achieved. In most cases (with the exception of the sodium-dependent multivitamin transporter for biotin, pantothenic acid, and lipoic acid), the vitamins are transported by separate carriers through the blood-brain barrier or choroid plexus. Then the vitamins are accumulated by brain cells by separate, specialized systems. This review focuses on six vitamins (B(1), B(3), B(6), pantothenic acid, biotin, and E) and the newer genetic information including relevant 'knockdown' or 'knockout' models in mice and humans. The overall objective is to integrate this newer information with previous physiological and biochemical observations to achieve a better understanding of vitamin transport and homeostasis in brain. This is especially important in view of the newly described non-cofactor vitamin roles in brain (e.g. of B(1), B(3), B(6), and E) and the potential roles of vitamins in the therapy of brain disorders.     

Acidosis, Acetazolamide, and Amiloride: Effects on 22Na Transfer Across the Blood-Brain and Blood-CSF Barriers

Sprague-Dawley rats were given treatments, known to decrease 22Na movement into choroid plexus and CSF, to investigate their effect on 22Na transfer across the cerebral capillaries. Acidic salts, acetazolamide, or amiloride was injected intraperitoneally into bilaterally nephrectomized rats, and the rate of 22Na uptake into parietal cortex, pons-medulla, and CSF was determined at 12, 18, and 24 min. Severe acidosis (arterial pH 7.2), produced by HCl injection, decreased the rate of 22Na entry into both brain regions and CSF by 25%, whereas mild acidosis (pH 7.3) from NH4Cl injection reduced brain entry by 18%, but CSF entry by only 10%. Like HCl acidosis, amiloride reduced transport into both brain and CSF by 22%. Penetration of 22Na into parietal cortex was unchanged by acetazolamide, but that into CSF was slowed 30%. Since uptake of 22Na into cortical regions is primarily movement of tracer across the cerebral capillaries when tracer uptake time is less than 30 min, the results indicate that both metabolic acidosis and amiloride decrease Na+ permeativity at the cerebral capillaries as well as at the choroid plexus. Acetazolamide, on the other hand, alters Na+ movement only across the choroidal epithelium.