Accumulation and transport of amino acids by the frog choroid plexus

Facilitated transport of prostaglandins across the blood-cerebrospinal fluid and blood-brain barriers

1. Ventriculo-cisternal perfusions were performed on rabbits with artificial cerebrospinal fluid containing blue dextran and tritium-labelled prostaglandin F(2alpha) ([(3)H]PGF(2alpha)). In order to study the nature of prostaglandin (PG) transfer across the blood-brain barrier, high concentrations of PGF(2alpha) or potential PG transport inhibitors were added to the perfusion fluid after the normal rate of [(3)H]PGF(2alpha) clearance was established.2. The [(3)H]PGF(2alpha) clearance was inhibited by 10(-6) to 10(-3)M PGF(2alpha), PGF(2beta), probenecid, iodipamide or bromcresol green but not by perchlorate.3. The (3)H content of the brain, relative to the (3)H-activity in the ventricular system, was also increased by high concentrations of PGF(2alpha), iodipamide or bromcresol green.4. It is concluded that the removal of PGs from the extracellular fluids of the brain is mediated by saturable, facilitated transport processes across both the choroidal and extrachoroidal regions of the blood-brain barrier system. In the case of the mammalian brain, such facilitated PG transport appears to be the primary mechanism for the termination of the action of these potent, endogenously produced autacoids.

Peculiarities of vascular plexus structure in amphibian brain

Structural peculiarities of the epithelium and connective tissue stroma of vascular plexuses in amphibian brain are examined. Quantitative and qualitative characteristics of the pool of cell regulators of regional hemodynamics during normothermy and deep winter torpidity are determined.

Extracellular and cerebrospinal fluids

The mechanism of formation of extracellular fluid is first described, followed by an explanation of the relation between osmotic force, reflection coefficient and molecular size. The possible mechanism of brain extracellular fluid formation is then proposed in relation to the restriction offered by the blood-brain barrier. The functions and compositions of cerebrospinal fluid (CSF) are then described followed by sections on the process of formation of CSF, the non-electrolytes and proteins in CSF, the drainage mechanisms and protein synthesis by the choroid plexus.

The steady-state amino acid fluxes across the perfused choroid plexus of the sheep

The steady-state flux of labelled amino acids was investigated across the isolated perfused choroid plexus of the sheep. The extraction of anionic, cationic, small and large neutral amino acids by the blood side of the choroid plexus was demonstrated. However, there was no uptake of the analogue MeAIB, confirming the absence of the 'A' carrier system on this side of the blood--CSF barrier. The direction of the net flux of amino acids across the tissue varied depending on the amino acid and its concentration. At a concentration of 0.01 mM the net movement for phenylalanine, serine, aspartate and glycine was from blood to CSF. When the concentration of amino acid was increased to 0.1 mM, the net flux of phenylalanine and serine remained from blood to CSF whereas the net flux of the transmitters, aspartate and glycine, was in the opposite direction, from CSF to blood. When the level was raised further, to 1 mM, all four amino acids showed a net CSF to blood flux. The concentration of amino acids is newly formed CSF was calculated from the blood to CSF fluxes and was found to be between 2 and 200 microM, similar to that found in mammalian bulk phase CSF.

Biochemical study of prolactin binding sites in Xenopus laevis brain and choroid plexus

The occurrence of prolactin binding sites in some brain structures (telencephalon, ventral hypothalamus, myelencephalon, hypophysis, and choroid plexus) from Xenopus laevis (anuran amphibian) was studied by the in vitro biochemical technique. The higher binding values were obtained at the level of the choroid plexus and above all of the hypothalamus. On the bases of hormonal specificity and high affinity, these binding sites are very similar to those of prolactin receptors of classical target tissues as well as of those described by us in other structures from Xenopus. To our knowledge, the present results provide the first demonstration of the occurrence of prolactin specific binding sites in Xenopus laevis choroid plexus cells.

Neutral amino acid uptake by the isolated perfused sheep choroid plexus

1. The uptake of neutral amino acids from the blood into the cells of the choroid plexus was studied by means of the rapid (less than 40 s) single-circulation paired-tracer dilution technique in the isolated perfused choroid plexus of the sheep. 2. The study provides the first direct evidence for the carrier-mediated entry of neutral amino acids from blood into the cells of the choroid plexus. 3. In the terms of Christensen's classification the presence of L-amino acid carrier systems for large neutral amino acids with bulky side chains has been demonstrated. 4. No measurable uptake of [14C]methyl amino isobutyric acid ([14C]MeAIB) during a single passage through the choroid plexus circulation was demonstrated which indicates the probable absence of a significant 'A' transport system. 5. The uptake of small neutral amino acids such as glycine and L-alanine was shown to be carrier-mediated. Results suggest that these amino acids are mainly transported by the glycine and ASC carrier systems, respectively. 6. The results suggest that there is a similarity between the transport systems for neutral amino acids on the blood side of both the blood-brain barrier and blood-cerebrospinal fluid barrier, the exception being for the presence of a glycine carrier on the blood side of the choroid plexus.

Third ventricle choroid plexus function and its response to acute perturbations in plasma chemistry

The homeostatic role of the third ventricle choroid plexus (3VCP) in the maintenance of CSF electrolytes was investigated by quantifying alterations in CP epithelial ion concentrations induced by chemical perturbations of plasma in adult Sprague-Dawley rats. Significant regional differences (third vs fourth (4VCP) and lateral ventricle CP (LVCP] were found in epithelial content of Na+ and K+, with respect to baseline levels as well as alterations caused by 5-60 min of systemic metabolic acidosis. 3VCP, which comprises ca. 10% of total choroidal tissue, has a water content, extracellular fluid volume and vascularity comparable to 4VCP and LVCP; yet 3VCP is characterized by relatively high and low values for cellular [Na+] (68 mM) and [K+] (118 mM). Compared to time-matched controls, acute metabolic acidosis (i.p. NH4Cl) effected a response, i.e. increases [K+] and decreases [Na+], in 3VCP that was less than in 4VCP, and substantially smaller than in LVCP. The onset and duration of induced electrolyte changes were qualitatively similar among the 3 plexus regions. Although systemic acidosis severely altered CP electrolyte concentrations, it did not compromise CSF homeostasis of [K+] and [Na+]. The function of 3VCP is discussed in terms of secretory capacity, embryological origin, and innervation. Overall, the findings indicate that transport/permeability phenomena which mediate transmembrane distribution of Na+ and K+ in 3VCP differ quantitatively from other regions of the blood-CSF barrier.

Steady-state distribution of cycloleucine and alpha-aminoisobutyric acid between plasma and cerebrospinal fluid

Estimates of the steady-state distribution ratios of two nonmetabolizable amino acids, alpha-aminoisobutyric acid and aminocyclopentane carboxylic acid (cycloleucine), between plasma and cerebrospinal fluid were made with a view to establishing whether or not the low values found with metabolizable amino acids, such as glycine or leucine, could be accounted for by uptake and metabolism by the brain. The estimates, based on the ratios found after i.p. injections either in bolus form or by implantation of "osmotic pumps" containing the labeled amino acids, were comparable with those found for metabolizable amino acids.

Permeability of the blood-cerebrospinal fluid and blood-brain barriers to thyrotropin-releasing hormone

The permeability of the blood-cerebrospinal fluid (CSF) barrier to 3H-labelled thyrotropin-releasing hormone (TRH), was studied at the blood-tissue interface of the isolated perfused choroid plexus of the sheep, using a rapid (less than 30 s), single circulation paired-tracer dilution technique, in which D-[14C]mannitol serves as an extracellular marker. Arterio-venous loss of 14C radioactivity reflects the percentage of the D-mannitol dose that crosses the blood-CSF barrier using a non-specific pathway. This loss suggests that the choroidal epithelium is moderately leaky. Cellular uptake of TRH, estimated by directly comparing venous dilution profiles of [3H]TRH and D-[14C]mannitol was independent of this leakiness. The unidirectional transport of TRH could not be saturated with unlabelled TRH at a concentration as high as 10 mM, but was markedly reduced by 10 mM proline and by the inhibitor of amidase and aminopeptidase activity, bacitracin (2 mM). Permeability of the blood-brain barrier to [3H]TRH was studied in the adult rat, employing the intracarotid injection technique of Oldendorf in which [14C]butanol served as an 'internal standard'. Brain-uptake of 3H radioactivity corrected for residual vascular space indicated a low extraction from the blood of TRH during a 15 s period of exposure to the peptide. Self-inhibition of [3H]TRH uptake by unlabelled TRH (10 mM) could not be demonstrated, but L-proline (10 mM) and bacitracin (2 mM) strongly inhibited this uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

The transport of sugars across the perfused choroid plexus of the sheep

The blood-perfused choroid plexuses from the lateral ventricles of the sheep were used to determine the nature of sugar exchanges between blood and cerebrospinal fluid (c.s.f.). There was a net entry of sugars from blood to c.s.f. at all concentrations of sugars which were used and this net entry was seen when the sugars were measured either directly by enzymic analysis or by the use of isotopically labelled sugars. From competition experiments the order of affinity of the transporting system from both blood to c.s.f. and c.s.f. to blood was the same, i.e. 2-deoxy-D-glucose much greater than D-glucose greater than 3-O-methyl-D-glucose much greater than D-galactose. The transport of sugars from c.s.f. to blood and blood to c.s.f. consists in both cases of a non-saturable and a saturable component. However, the affinity of the two systems is markedly different, the blood to c.s.f. being a system of low affinity and high capacity while that of the c.s.f. to blood has a high affinity and a low capacity. The concentration of glucose in the newly formed c.s.f. was estimated from the rate of c.s.f. secretion and the net flux of glucose across the choroid plexus. The concentration of glucose in this fluid was some 45-60% of that in plasma and so the low glucose concentration observed in bulk c.s.f. would appear to be a result of the entry process and not that of cerebral metabolism.

Neutral amino acid transport by plasma membrane vesicles of the rabbit choroid plexus

Uptakes of neutral L-amino acids into rabbit choroid plexus apical membrane vesicles were studied using L-[14C]amino acids. Apical membrane vesicles were prepared using Ca2+ precipitation and uptakes of 14C-labeled substrates were measured by a rapid mixing and filtration procedure. Na-dependent, concentrative uptake was observed for proline, histidine and methylaminoisobutyric acid (MeAIB). Phenylalanine and D-glucose uptakes showed no significant Na dependence. Proline uptake was a saturable function of the proline concentration with Jmax 3.5 nmol/(mg min) and Kt 0.3 mM. Competition experiments in the presence of Na indicated that proline and MeAIB are mutually competitive. Proline uptake was also inhibited 25% by phenylalanine, but MeAIB uptake was relatively unaffected. Neither proline nor MeAIB transport was significantly inhibited by glycine. We conclude that proline uptake across rabbit choroid plexus apical membrane vesicles in via an Na-dependent pathway which is shared by MeAIB and, to a minor extent, by phenylalanine, but from which glycine is excluded. Histidine uptake was inhibited by glycine, GABA, phenylalanine, proline and MeAIB. This suggests that histidine may utilize a different pathway in addition to that shared with proline and MeAIB. These transporters should play an active role in the regulation of amino acids in the CSF.

Transport of alpha-aminoisobutyric acid across brain capillary and cellular membranes

The transport of alpha-aminoisobutyric acid (AIB), N-methyl-AIB (MeAIB), and diethylenetriaminepentaacetic acid (DTPA) from blood to brain was measured over different experimental periods in eight regions of the rat brain. Unidirectional transfer rate constants were determined from multiple-time/graphical and single-time analysis of the experimental data; values of 0.0018, 0.00057, and 0.000021 ml g-1 min-1, respectively, were obtained for the thalamus by graphical analysis. The initial distribution volume of AIB and MeAIB in brain tissue was several-fold greater than that of DTPA and the tissue plasma volume, and this difference was not accounted for by red blood cell uptake. This discrepancy could be due to rapid transport of AIB and MeAIB into brain endothelial cells in addition to the relatively rapid uptake by choroidal, meningeal, and ependymal associated tissues that was demonstrated by autoradiography. Thus, it may be misleading and erroneous to consider the blood-brain barrier (BBB) to be a simple, single-membrane structure when analyzing the blood-brain transfer data of solutes such as amino acids. The data from the ventriculocisternal perfusion experiments and previously published AIB uptake data in mouse brain slices were used to estimate the transfer rate constants across brain cell membranes. These studies indicated that the transport of AIB into brain cells was approximately 110 to 265 times greater than that across normal brain capillaries per unit mass of brain tissue, and that the BBB limits blood-to-brain cell transport of this amino acid. These observations (low rate of transport across normal brain capillaries and rapid concentrative uptake by brain cells) indicate that AIB is a good marker for measuring moderate to large increases in BBB permeability by experiments that require unidirectional flux of the tracer.

Ventriculo-cisternal perfusion of twelve amino acids in the rabbit

The clearances of twelve amino acids from the ventricles during ventriculo-cisternal perfusion in the rabbit have been measured; uptake by the brain was also measured and this permitted the separate computation of loss to brain and loss to blood during the perfusion. Clearance under carrier-free conditions was greater than when a concentration of 5mM unlabeled amino acid was present in the perfusion fluid. Brain uptake was also usually reduced by the presence of unlabeled amino acid due presumably to suppression of accumulation by brain cells. Reduction of transport across the blood-brain barrier would tend to increase brain uptake, and there was some evidence for a balance between the two opposing tendencies. Inhibition of clearance of a given labeled amino acid could be brought about by unlabeled amino acids of different molecular species. In general, the amino acids fell into three categories: neutral, acidic, and basic, and there was some overlap between them; of the neutral amino acids the A- and L-classification of Christensen was valid, although once again there was some overlap. If, during ventriculo-cisternal perfusion of a labeled amino acid, the activity of this labeled amino acid in the blood was raised well above that in the inflowing perfusion fluid, the labeled amino acid continued to be cleared from the perfusion fluid, suggesting uphill transport. On this basis it was suggested that the normally low concentrations of amino acids in the cerebrospinal fluid (CSF), by comparison with those in plasma, were due to an active transport from the CSF to the blood. Substrate-facilitated transport, whereby the penetration of labeled amino acid into the perfusion fluid from blood could be accelerated by adding unlabeled amino acid to the perfusion fluid, or vice versa, was demonstrated.

Electrical properties and structure of the frog arachnoid membrane

We have used an in vitro preparation of the frog arachnoid membrane to study the role of this membrane in the maintenance of the "blood-cerebrospinal fluid (csf) barrier". Electron microscopy showed that the membrane was made up of 10-15 layers of flat epithelial cells joined together by numerous cell junctions. The electrical resistance of the preparation was about 2000 ohms cm2. The steady-state transmural potential difference (pd) ranged up to 45 mV, csf positive, and this eliminated by either the addition of ouabain to the csf, or by replacing the NaC1 with TEA C1. The pd across the membrane increased when bicarbonate was added to the external bathing solutions. We conclude that this pd is due to the active transport of sodium from the subural fluid to the csf. In some preparations the transmural pd was reversed, i.e., csf negative, and this was also abolished by the addition of ouabain to the csf, or by replacing chloride with isethionate. We conclude that this pd is related to active chloride transport. These, and other experiments, lead us to the conclusion that the arachnois membrane is involved in the production of the cerebrospinal fluid and the maintenance of the blood-cerebrospinal fluid barrier.

Active amino-acid and sugar uptake by gall bladder epithelium in dog, guinea-pig and man

Slices of dog gall bladder are capable of accumulating amino-acids and sugars against considerable concentration gradients across the luminal membrane of the cell. The epithelium of the common bile duct also absorbs these substrates. The transport systems are sodium-dependent, saturable and inhibited by ouabain and metabolic poisons. The specificity of the mechanisms is more reminiscent of kidney than of intestinal transport. Glycine is preferentially transported across dog gall bladder from the mucosa to the serosa, but the net flux is small. It is concluded that the contraluminal membrane of the epithelial cell might be relatively impermeable to the amino-acid. concentrative uptake also occurs in guinea-pig gall bladder; however it appears to be practically non-existent in rabbit tissue. Human gall bladders, obtained at random from the operating room, also displayed active accumulation. The gall bladder epithelium is remarkably resistant to anoxia. Furthermore, following obstruction of the common bile duct for 2 weeks in dogs, the gall bladder is still able to concentrate amino-acids and sugars, but the extent of the uptake is significantly reduced.

Active transport of iodide and other anions across the choroid plexus

1. An in vitro preparation of the frog choroid plexus was used to study mechanisms of anion transport.2. It was observed that, in the absence of electrochemical potential gradients, there were net fluxes of I(-), SCN(-), TcO(4) (-), and Br(-) across the plexus, from the ventricular to the serosal surface. The net flux of I(-) reached a maximum at a concentration of 250 muM.3. On the basis of competition effects it was concluded that the affinity of the transport process for anions was: ClO(4) > ReO(4) approximately BF(4) > SCN approximately SeCN > I > NO(3) > Br > Cl.4. Ouabain, oligomycin, phloretin and 2,4-DNP inhibited the net transport of anions, but phlorrhizin, furosemide, 2,4,6-trinitro-m-cresolate, reducing agents, and antithyroid agents did not. Ouabain and phloretin were only effective on the ventricular side of the preparation.5. Anion transport required the presence of both Na and K. The requirement for Na was specific, but Rb, and to a lesser extent Cs, could substitute for K. Na in either the ventricular or the serosal fluids could partially stimulate anion transport, but K was only effective in the ventricular solution.6. TcO(4) (-), SCN(-) and I(-) were accumulated within the choroidal epithelium from the ventricular fluid, but not from the serosal fluid. Accumulation was inhibited by ouabain and ClO(4) (-).7. The unidirectional influx of I(-) across the apical cell membrane was about an order of magnitude greater than the flux across the epithelium. This flux was inhibited by ClO(4) (-), ouabain, and Na-free solutions.8. These experiments suggest the following mechanism for anion transport across the plexus: anions are actively transported into the epithelium, by a ouabain sensitive, Na/K dependent pump located in the brush border membrane. The anions are accumulated within the epithelium, and, finally, they pass into the serosal fluid down their electrochemical potential gradient. Relations between anion transport, Na/K transport, and Na/K ATPases are discussed.