Elevated expression of glucose transporter-1 in hypothalamic ependymal cells not involved in the formation of the brain-cerebrospinal fluid barrier

Glucose transporters play an essential role in the acquisition of glucose by the brain. Elevated expression of glucose transporter-1 has been detected in endothelial cells of the blood-brain barrier and in choroid plexus cells of the blood-cerebrospinal fluid barrier. On the other hand, there is a paucity of information on the expression of glucose transporters in the ependymal cells that line the walls of the cerebral ventricles. The tanycytes are specialized ependymal cells localized in circumventricular organs such as the median eminence that can be segregated into at least three types, alpha, beta1 and beta2. The beta2 tanycytes form tight junctions and participate in the formation of the cerebrospinal fluid-median eminence barrier. Using immunocytochemistry and in situ hybridization, we analyzed the expression of hexose transporters in rat and mouse hypothalamic tanycytes. In both species, immunocytochemical analysis revealed elevated expression of glucose transporter-1 in alpha and beta1 tanycytes. Intense anti-glucose transporter-1 staining was observed in cell processes located throughout the arcuate nucleus, in the end-feet reaching the lateral sulcus of the infundibular region, and in cell processes contacting the hypothalamic capillaries. On the other hand, there was very low expression of glucose transporter-1 in beta2 tanycytes involved in barrier function. In contrast with the results of the cytochemical analysis, in situ hybridization revealed that tanycytes alpha, beta1, and beta2 express similar levels of glucose transporter-1 mRNA. Further analysis using anti-glial fibrillary acidic protein antibodies to identify areas rich in astrocytes revealed that astrocytes were absent from areas containing alpha and beta1 tanycytes, but were abundant in regions containing the barrier-forming beta2 tanycytes. Overall, our data reveal a lack of correlation between participation in barrier function and expression of glucose transporter-1 in hypothalamic tanycytes. Given the virtual absence of astrocytes in areas rich in alpha and beta1 tanycytes, we speculate whether the tanycytes might have astrocyte-like functions and participate in the metabolic coupling between glia and neurons in the hypothalamic area.     

Cellular organization of the lateral and postinfundibular regions of the median eminence in the rat

Summary The structural organization of the rostral, lateral and postinfundibular regions of the median eminence (ME) of 5-day cyclic diestrous rats was studied with light and electron microscopic methods. The ependymal cells lining (i) the floor of the infundibular recess (IR) at rostral levels, (ii) the lateral extensions of the IR, and (iii) the floor of the premammillary recess appear to represent the same type of tanycyte ependyma (1 tanycytes). In the entire width of the rostral and postinfundibular palisade regions, as well as in the lateral palisade region of the preinfundibular ME, the processes of the 1 tanycytes form a continuous cuff. This cuff separates the nerve endings from the blood vessels and the pars tuberalis. At this level, synaptoid contacts between neurosecretory axons and the ependymal cuff can be observed. The ultrastructural characteristics of the 1 tanycytes are described and their ependymal endings tentatively classified into three types. In the lateral regions of the ME, the Golgi study revealed the presence of two fiber systems: (i) one possessing a latero-medial trajectory and distributed in the subependymal region; (ii) the other formed by a loose longitudinal tract originating from neurons of the arcuate nucleus. Some functional implications of the cellular organization of the rat ME are discussed.Supported by Grants from PLAMIRH (92.171.2.77) and from the Dirección de Investigaciones, Universidad Austral (S-77-28)The authors wish to thank Miss Rosario Andrade, Mrs. Elizabeth Santibáñez and Mr. Armando Bilbao for their assistance     

大鼠第三脑室室管膜NADPH-d阳性伸展细胞的形态与分布

应用 Ｎ Ａ Ｄ Ｐ Ｈｄ 组织化学方法研究了大鼠第三脑室视前区室管膜的伸展细胞⒚结果表明：１）第三脑室视前区室管膜存在 Ｎ Ａ Ｄ Ｐ Ｈｄ 阳性的伸展细胞,其基突伸向视前区并与神经元或毛细血管相接触;２） Ｎ Ａ Ｄ Ｐ Ｈｄ 阳性的伸展细胞在第三脑室侧壁常见、室底少见、室顶未发现其存在;３） Ｎ Ａ Ｄ Ｐ Ｈｄ 阳性的伸展细胞的形态与分布,在雌、雄大鼠间不存在明显的性别差异⒚尽管 Ｎ Ａ Ｄ Ｐ Ｈｄ 阳性的伸展细胞的生理功能不十分清楚,但本研究为伸展细胞作为脑脑脊液环路的一部分,介导下丘脑对脑脊液中化学变化的感受提供了形态学依据,并提示一氧化氮可能参与了这一过程⒚     

A micromorphological and histoenzymological study on the third ventricular ependyma of the teleost Clarias batrachus (L.).

The circum ventricular region of C. batrachus is highly vascular and the ependymal cells appear differently when stained with haematoxylin, silver impregnation and Golgi-Cox techniques. The ventricule has PAS and AF positive material and some ependymal cells themselves are PAS positive. Few AF positive peptidergic and several AF negative small neurons have liquor contacting terminals. Golgi-Cox preparations reveal a variety of forms among the tanycytes. Their basal processes which are barbed or studded with varicosities, usually end on blood vessels and other neuronal elements. These basal processes themselves are often seen in direct morphological contact. Smaller silver positive cells without basal processes are also evident. Some tanycytes have apical processes resembling broadened endfeet. Few neurosecretory tracts are Golgi-Cox positive and can be differentiated from the tanycytic processes by their smooth surface. Varying degrees of ascorbic acid activity are noticed inside the ventricle, among the tanycytes and in the neurons of the NLT. Some of the latter neurons have liquor contacting terminals as well. The ChE activity noticed in some parts of the ependyma and in some NLT cells suggest their probable differential cholinergic control. Presence of SDH, NADPH and NADH diaphorases and cytochrome oxidase in varying quantities in the ependymal cells suggests that they are metabolically active. Presence of MAO positive tracts bridging the subependyma and ventricle suggests the degradation of monoamines at these sites. The presence of various enzymes and the morphological relationship of the tanycytes described in this species are comparable to those of the mammals. It is significant as this species is reported to have a median eminence morphologically resembling the tetrapods.     

Localization of immunoreactive prolactin in ependyma and circumventricular organs of rat brain

Summary Immunoreactive prolactin (IMP) has been localized in the male rat brain using the soluble peroxidase-anti-peroxidase (PAP) technique. In normal untreated animals, reaction product was seen in choroid plexus (CP) and in ependymal cells of the ventricular lining with heaviest concentrations of positively staining cells in the 3rd ventricle near the subcommisural organ (SCO), in the lateral ventricles near the subfornical organ (SFO), and in the 4th ventricle near the area postrema (AP). IMP was also present in numerous ependymal cells resembling tanycytes in the cerebral aqueduct, central canal of the spinal cord at the level of the AP, the organum vasculosum of the lamina terminalis (OVLT) and the floor of the infundibular recess. Immunoreactive cells resembling neurons were localized within the substance of the AP, SCO, and OVLT. IMP was also present in fibers of the zona externa of the median eminence and infundibular stalk; a few cells of the pars tuberalis contained reaction product. Hypophysectomized rats and bromocriptine-treated rats exhibited a similar staining pattern except that bromocriptine treatment eliminated IMP from most CP cells. Hypophysectomy, bromocriptine or estrogen treatment enhanced staining for IMP in cells of the pars tuberalis; estrogen treatment or hypophysectomy produced an increase in the number and distribution of immunoreactive cells as well as increased density of reaction product in cells of the medial habenular nucleus. The functional relevance of prolactin in these locations in the brain, the possible routes of transport of prolactin from the pituitary gland to the central nervous system, and the strong suggestion of extra-pituitary sites of synthesis of a prolactin-like hormone are discussed.     

Correlative scanning-transmission electron microscopic examination of the perinatal rat brain

Summary The ultrastructural organization of the perinatal hypothalamus and the dynamics of neuronal and ependymal growth and plasticity were examined in this investigation. The brains of fetal rats 16, 17 and 18 days in utero and those of postnatal rats 1–16 days post partum were fixed with aldehyde fixatives and prepared for combined SEM/TEM analysis. By day 17 in utero the ventricular (ependymal) surfaces of the fetal thalamic wall, cerebral vesicle and rhomboid fossa were relatively well differentiated with cilia and microvilli. Type II histiocytes were the first supraependymal cell to appear upon the ventricular lumen and were evident by day 17 in utero. In contrast, the apical surfaces of tanycytes of the infundibular recess as well as those of most other circumventricular organs were poorly differentiated and unremarkable. Tanycytes of the infundibular recess exhibited a simple hexagonal mosaic pattern of apposed plasmalemmata and even by day 1 post partum few cilia or microvilli were evident.By day 5–6 post partum Type I supraependymal neurons and axonal processes began to make their appearance with some emerging from the underlying parenchyma of the median eminence. By day 16 post partum the ventricular surface of the infundibular recess was comparable with that of the adult.The Type I supraependymal neurons are remarkably similar in their ultrastructural organization with parvicellular neurosecretory neurons elsewhere in the endocrine hypothalamus. Their emergence at day 5–6 post partum suggests a possible correlation with the critical period of sexual differentiation and a potential receptor role for this cell line. On the contrary this phenomenon may simply be a developmental anomaly. Nonetheless, the mergence of such elements upon the lumen of the third cerebral ventricle underscores a remarkable degree of neuronal plasticity in the perinatal hypothalamus.Supported by USPHS Program Project Grant NS 11642-04 and USPHS-BRSG Grant RR-05403.The authors wish to thank N. Kutryeff for her excellent technical assistance     

The structure of the hypothalamic inferior lobes of the blacktip reef shark: Scanning and transmission electron microscopic observations

The inferior lobes of the shark hypothalamus were examined with light, transmission and scanning electron microscopy. The cells bordering the floor of the lateral recess appear to be typical liquor-contacting neurons. With scanning electron microscopy (SEM) the apical ends of these cells are seen to bulge into the ventricular lumen. In contrast, the roof is lined by a more typical ependymal cell characterized by numerous cilia and microvilli. In addition, SEM reveals several kinds of supraependymal cells with processes that appear to penetrate the ventricular lining. A periventricular nucleus underlies the ependymal cells. Neurons of the periventricular nucleus contain numerous lipofuchsin granules. The rest of the inferior lobe consists of many neuronal fibers. The morphology of the hypothalamic inferior lobe is discussed in relation to its possible role in feeding and aggressive behavior in both elasmobranchs and teleosts.     

Light and electron microscopic studies of the ventricular wall

Summary Electron microscopic data confirm the results gained with rapid Golgi preparations of adult rodent brains that tanycytes occur in clusters along the lateral wall of the third ventricle. The cytoplasmic matrix of these cells is considerably denser than that of typical ependymal cells. They have filaments and microtubules throughout their cytoplasm along with mitochondria and polysomes. At the surface is a compact group of microvilli which suggest that tanycytes might selectively absorb material from the ventricle.The tanycytes are segregated from neuropil by other tanycyte processes, by neighboring ependymal cells and by astrocytes. Yet there are gaps in this sheath. At these points tanycytes either abut upon or surround nonglial components of the neural fabric.Their cytological features and relations with the neuropil suggest that tanycytes selectively absorb material from the ventricle and release it along the basal process, primarily affecting those segments of neurons immediately adjacent to the tanycyte.Supported by: NINDS Grants 5 R01 NS 09001-02 NEUA, 5T01 NB 5309, and GM 00958, and by the Eleanor Roosevelt Cancer Foundation Research Institute.Acknowledgements: This work was initiated in the Anatomy Department of the Harvard Medical School with facilities provided by Prof. S. L. Palay (U.S. Public Health Service Grant No. NB 05591). Dr. R. B. Wuerker kindly and patiently provided the instruction and orientation to electron microscopy. The major portion of the study was completed in the Neurology Department of the University of Utah with the extremely competent, challenging assistance of Dee Lerdahl, Nina Belgarian, Keith Johnson and Lynn Kendricks.     

Accessibility of low‐molecular‐mass molecules to the median eminence and arcuate hypothalamic nucleus of adult mouse

Blood‐derived molecules are able to access to the median eminence (ME) and arcuate hypothalamic nucleus (Arc) due to the lack of the blood–brain barrier. In the present study, we examined the accessibility of low‐molecular‐mass (LMM) molecules into parenchyma in the ME and Arc of adult mice by administration of Dextran 3000 (Dex3k), Dex10k, Evans blue (EB) and fluorescein isothiocyanate (FITC). In the external zone of the ME, the fluorescence of Dex3k, EB and FITC tracers generated an intensity gradient from fenestrated capillary, but that of Dex10k was detected only between the inner and outer basement membrane of pericapillary space. The fluorescence of FITC in the external zone of the ME was closely associated with axonal terminals and surrounded by cellular processes of tanycytes‐like cells and astrocytes. In the ependymal/internal zone of the ME and Arc, the fluorescence of all LMM tracers was seen at tanycytes‐like cells and neurons. The fluorescence of EB and FITC in these regions was not detected when brains were fixed during or before the administration of tracers. The inhomogeneity of accessibility for fluorescent tracers depended on routes for tracer administration. Thus, the present study indicates that the accessibility of LMM blood‐derived molecules to parenchyma depends on fenestration of the capillary in the external zone of the ME and active transport of ependymal cells in the ependymal/internal zone of the ME and Arc. Copyright © 2013 John Wiley & Sons, Ltd.     

Fine structure of neurons of the arcuate nucleus and median eminence of the hypothalamus of the golden hamster following immobilization

Summary The fine structure of arcuate neurons of the arcuate nucleus, the ependymal tanycytes and the contact zone of the median eminence was examined following immobilization, an acute stress which significantly activated the hypothalamo-pituitary-adrenal (HPA) axis. Arcuate neurons of immobilized adult male hamsters displayed morphological indications of heightened activity; the number of lysosomes and dense core vesicles (80–120 nm) was increased. A markedly greater number of dense core vesicles was present in axon terminals of the contact zone of the mid-central median eminence and the ventral proximal stalk.Tanycytes of the median eminence exhibited an augmented number of electron dense bodies in both perikarya and end processes. These results indicate that the arcuate neurons, the axons of the contact zone, and the ependymal tanycytes of the hamster medial basal hypothalamus (MBH) may be involved in the response to immobilization.This work was supported by Program Project Grant #NS-11642     

Antibodies obtained by xenotransplantation of organ-cultured median eminence specifically recognize hypothalamic tanycytes

Tanycytes are specialized ependymal cells lining the infundibular recess of the third ventricle of the cerebrum. Early and recent investigations involve tanycytes in the mechanism of gonadotropin-releasing hormone (GnRH) release to the portal blood. The present investigation was performed to obtain a specific immunological marker of tanycytes and to identify the compound(s) responsible for this labeling. After 30 days of organ culture, explants of bovine median eminence formed spherical structures mostly constituted by tanycytes. These tanycyte spheres were xenotransplanted to rats, and the antibodies raised by the host animals against the transplanted living tanycytes were used for immunochemical studies of the bovine and rat median eminence. This antiserum immunoreacted with two compounds of 60 kDa and 85 kDa present in extracts of bovine and rat median eminence. The individual immunoblotting analysis of rat medial basal hypothalami showed a decrease in the amount of the 85-kDa compound in castrated rats as compared to control rats processed at oestrus and dioestrus. The antiserum, labeled as anti-P85, when used for immunostaining of sections throughout the rat central nervous system, immunoreacted specifically with the hypothalamic tanycytes. Within tanycytes, P-85 immunoreactivity was exclusively present in the basal processes. It is suggested that the 85-kDa and 60-kDa compounds correspond to two novel proteins selectively expressed by tanycytes. The possibility that they are secretory proteins involved in GnRH release is discussed. Anti-P85 appears to be the first specific marker of hypothalamic tanycytes.     

Ependymoneuronal specializations between LHRH fibers and cells of the cerebroventricular system

Summary Light-and electron-microscopic immunocytochemistry (LM-ICC and EM-ICC) were used to visualize luteinizing hormone-releasing hormone (LHRH) in fibres associated with ventricular ependyma and tanycytes of the median eminence. LM-ICC suggests that LHRH fibers appear to enter the third ventricle. However, with EM-ICC, LHRH fibers are in fact found within ependymal canaliculi formed by adjacent ependymal cells. The canaliculi contain other myelinated and unmyelinated axons in addition to immunoreactive LHRH fibers. Thin slips of ependymal and tanycyte processes project into the canaliculi and enclose axons to varying degrees. At the median eminence many LHRH fibers bend sharply downwards from their ventricular course and travel with tanycytic processes towards their common destination — the perivascular space of the hypophysial-portal vascular system. Here, EM-ICC reveals that LHRH fibers closely contact basal processes of tanycytes. Lateral processes from tanycytes form glioplasmic sheaths which surround some individual LHRH fibers. A few LHRH terminals contact the perivascular space directly but more often are separated from the perivascular space by intervening glia. It is hypothesized that: (1) glia of this region responds to the physiological state of the animal and may determine the degree of LHRH secretion by varying the extent of glial investment of LHRH terminals; and (2) may play a role during development by providing direction and support for LHRH fibers similar to that described for radial and other glial cells.     

Golgi-like immunostaining of pituicytes and tanycytes positive for glial fibrillary acidic protein in the neurohypophysis of the Mongolian gerbil (Meriones unguiculatus)

Summary Glial cells that contain the glial fibrillary acidic protein (GFAP; the major protein constituent of glial filaments) were stained immunohistochemically in thick frozen sections of the neurohypophysis of the Mongolian gerbil (Meriones unguiculatus). The resulting Golgi-like images provided informations on cytological features and distributional patterns of tanycytes and pituicytes. In the proximal median eminence, numerous bundled processes of tanycytes were revealed. They emerged from the ependymal and subependymal layer and mostly reached the brain surface. Several tanycytic processes extended into the anatomical neural stalk. In the whole neural lobe, a dense network of GFAP-immunoreactive pituicyte processes was visualized. Stained pituicytes were highly asymmetric and exhibited a great morphological variability. Immunopositive fibers which were encountered in the intermediate lobe might be derived from pituicytes. Electron-microscopically further evidence was obtained that GFAP-positive pituicytes correspond to filament-rich fibrous pituicytes at the ultrastructural level.     

Ependyma and meninges of the spinal cord of the mouse

Summary In addition to ependymal epithelial cells, numerous tanycytes are found along the entire central canal of the mouse. These tanycytes are arranged in clusters in the cervical, thoracic and lumbar segments of the spinal cord. In the conus medullaris, tanycytes separate and ensheath bundles of myelinated and unmyelinated axons; their processes take part in the formation of the stratum marginale gliae. In the caudal part of the spinal cord, the ventral wall of the central canal is thin and some areas are reduced to a single-cell thickness. In this region, ependymal cells participate directly in the formation of the stratum marginale gliae.The meninges consist of the intima piae, the pia mater, the arachnoid, a subdural neurothelium and the dura mater. The subarachnoid space appears occluded and opens only around the spinal roots. In the vicinity of the spinal ganglia, the dura mater, the subdural neurothelium and the arachnoid form a cellular reticulum.     

Golgi-like immunostaining of pituicytes and tanycytes positive for glial fibrillary acidic protein in the neurohypophysis of the Mongolian gerbil (Meriones unguiculatus)

Glial cells that contain the glial fibrillary acidic protein (GFAP; the major protein constituent of glial filaments) were stained immunohistochemically in thick frozen sections of the neurohypophysis of the Mongolian gerbil (Meriones unguiculatus). The resulting Golgi-like images provided informations on cytological features and distributional patterns of tanycytes and pituicytes. In the proximal median eminence, numerous bundled processes of tanycytes were revealed. They emerged from the ependymal and sub-ependymal layer and mostly reached the brain surface. Several tanycytic processes extended into the anatomical neural stalk. In the whole neural lobe, a dense network of GFAP-immunoreactive pituicyte processes was visualized. Stained pituicytes were highly asymmetric and exhibited a great morphological variability. Immunopositive fibers which were encountered in the intermediate lobe might be derived from pituicytes. Electron-microscopically further evidence was obtained that GFAP-positive pituicytes correspond to filament-rich fibrous pituicytes at the ultrastructural level.     

Differential immunocytochemical staining for glial fibrillary acidic (GFA) protein,S-100 protein and glutamine synthetase in the rat subcommissural organ,nonspecialized ventricular ependyma and adjacent neuropil

Summary Antibodies raised against glial fibrillary acidic protein (GFA), S-100 protein (S100) and glutamine synthetase (GS) are currently used as glial markers. The distribution of GFA, S100 and GS in the ependyma of the rat subcommissural organ (SCO), as well as in the adjacent nonspecialized ventricular ependyma and neuropil of the periaqueductal grey matter, was studied by use of the immunocytochemical peroxidase-antiperoxidase technique. In the neuropil, GFA, S100 and GS were found in glial elements, i.e., in fibrous (GFA, S100) and protoplasmic astrocytes (S100, GS). The presence of S100 in the majority of the ventricular ependymal cells and tanycytes, and the presence of GFA in a limited number of ventricular ependymal cells and tanycytes confirm the glial nature of these cells. The absence of S100, GFA and GS from the ependymocytes of the SCO, which are considered to be modified ependymal cells, suggests either a non-astrocytic lineage of these cells or an extreme specialization of the SCO-cells as glycoprotein-synthesizing and secreting elements, a process that may have led to the disappearance of the glial markers.     

Ependyma: phylogenetic evolution of glial fibrillary acidic protein (GFAP) and vimentin expression in vertebrate spinal cord

The phylogenetic evolution was studied of both glial fibrillary acidic protein (GFAP) and vimentin expression in the ependyma of the adult vertebrate spinal cord. Eleven species from different vertebrate groups were examined using different fixatives and fixation procedures to demonstrate any differences in immunoreactivity. GFAP expression in the ependymal cells showed a clear inverse relation with phylogenetic evolution because it was more elevated in lower than in higher vertebrates. GFAP positive cells can be ependymocytes and tanycytes, although depending on their structural characteristics and distribution, the scarce GFAP positive ependymal cells in higher vertebrates may be tanycytes. Ependymal vimentin expression showed a species-dependent pattern instead of a phylogenetic pattern of expression. Vimentin positive ependymal cells were only found in fish and rats; in fish, they were tanycytes and were quite scarce, with only one or two cells per section being immunostained. However, in the rat spinal cord, all the ependymocytes showed positive immunostaining for vimentin. The importance of the immunohistochemical procedure, the cellular nature of GFAP positive ependymal cells and the relationship between tanycytes and ependymocytes are discussed, as well as GFAP and vimentin expression.     

Immunohistochemical localization of basic fibroblast growth factor in ependymal cells of the rat lateral and third ventricles.

The presence of basic fibroblast growth factor (bFGF) in the third and the lateral ventricular ependyma of the rat has been investigated under the light microscope using a polyclonal antibody against bFGF, through the unlabelled peroxidase-antiperoxidase procedure; bFGF-immunoreactivity (bFGF-IR) is observed in the entire ependymal cell layer of ventricles. Also ependymal tanycytes within the inferior portion of the wall and floor of the third ventricle show bFGF-IR. Tanycytic processes are in close contact with hypothalamic capillaries. The present study strongly suggests that brain ependymal bFGF plays unidentified roles unrelated to its angiogenic or mitogenic capacities.     

Supraependymal cells occurrence in ventricular system of small ruminants. Scanning electron microscopy study

The third cerebral ventricle ependymal lining including eminentia medians was studied by means of SEM in 20 sheep, 13 goats and one goat hermaphrodite. Supraependymal cells in addition to the usual supraependymal structures were observed. In sheep, they occurred in the infundibular low part only in females during oestrus. In goats, they were present in almost every case with the exception of male animals during the "rest" period (April). The number, topography and-to some extent--the appearance of the goat supraependymal cells were in relation to the animal's sex, and the females to the ovarian cycle phase. The supraependymal cells were found on the eminentia mediana surface only in the goats. In small ruminants, the processes of most supraependymal cells formed the ruffled membranes and only the eminentia mediana supraependymal cells--and in hermaphrodite also in the infundibular rostral part--resembled more neurons.     

Hypothalamic ependymal cells express the glucose transporter GLUT2, a protein involved in glucose sensing

Kinetic analysis of vitamin C uptake has demonstrated that specialized cells take up ascorbic acid (AA), the reduced form of vitamin C, through sodium-AA cotransporters. Recently, two different isoforms of sodium-vitamin C cotransporters (SVCT 1, 2) that mediate high affinity Na⁺-dependent l -ascorbic acid have been cloned. SVCT2 was detected mainly in choroid plexus cells and neurons, however, there are no evidences of SVCT2 expression in glial cells. High concentrations of vitamin C has been demonstrated in brain hypothalamic area. The hypothalamic glial cells, known as alpha and beta tanycytes, are specialized ependymal cells that bridge the cerebrospinal fluid and the portal blood of the median eminence. Our hypothesis postulates that tanycytes take up reduced vitamin C from the portal blood and cerebrospinal fluid generating an high concentration of this vitamin in brain hypothalamic area. In situ immunohistochemical analyses demonstrated that SVCT2 transporter is selectively expressed in apical region of tanycytes. A newly developed primary culture of mouse hypothalamic tanycytes was used to confirm the expression and function of SVCT2 isoform in these cells. Reduced vitamin C uptake was temperature and sodium dependent. Kinetic analysis showed an apparent Km of 20 μ m and a Vmax of 45 pmol/min per million cells for the transport of ascorbic acid. The expression of SVCT2 was confirmed by immunoblots and RT–PCR. Tanycytes may perform a neuroprotective role concentrating the vitamin C in the hypothalamic area.
Acknowledgements:   Supported by Grands FONDECYT 1010843 and DIUC-GIA 201.034.006-1.4 from Concepción University.