MRI characteristics and oncological follow-up of patients with ISUP grade group 4 or 5 prostate cancer.

OBJECTIVES: To analyze multiparametric MRI (mpMRI) characteristics of patients with International Society of Urological Pathology (ISUP) grade group (GG) 4 or 5 prostate cancer (PC) and to correlate MRI parameters with the occurrence of biochemical recurrence (BCR) after radical prostatectomy (RPE). METHODS: In this single-center cohort study consecutive patients with mpMRI and ISUP GG 4 or 5 PC were retrospectively analyzed. Clinical, MR-guided biopsy, and diagnostic mpMRI parameter were assessed. A subcohort of patients with RPE and follow-up was analyzed separately. A univariate and multivariate analyses were performed to determine parameters that are associated to patients with BCR after RPE. RESULTS: 145 patients (mean age 70y, median PSA 10.9 ng/ml) were analyzed. 99% had a PI-RADS classification of 4 or 5, 48% revealed MRI T3 stage, and median diameter of the MRI index lesion (IL) was 15 mm. IL showed a median ADC value of 668 ×10-6 mm2/s and exhibited contrast enhancement in 94% of the cases. For patients with follow-up after RPE (n = 82; mean follow-up time 68 ± 27 m), MRI parameters were significantly different for contact length of the IL to the pseudocapsule (LCC), MRI T3 stage, and IL localization (p < 0.05). Higher PSAD and MRI T3 stage were independent parameters for the risk of BCR when incorporating clinical, biopsy, and MRI parameters. CONCLUSION: ISUP GG 4 or 5 PC has distinctive characteristics on mpMRI and were detected on MRI in all cases. In addition, higher PSAD and MRI T3 stage were significant predictors for BCR after RPE.

Multiparametric MRI characteristics of prostatitis and atrophy in the peripheral zone in men without prostate cancer.

PURPOSE: To analyse multiparametric magnetic resonance imaging (mpMRI) characteristics and appearance of histopathologically proven non-cancerous intraprostatic findings focussing on quantity of prostatitis and atrophy in the peripheral zone. METHOD: In this retrospective analysis consecutive patients with mpMRI followed by MRI/TRUS-fusion biopsy comprising targeted (TB) and systematic biopsy (SB) cores without prostate cancer (PC) at histopathology were included. Subgroup analysis was performed in younger men (≤50 years). The proportions of prostatitis and atrophy were quantified for each biopsy core based on histopathology. MRI findings in the peripheral zone (PZ) and index lesions (IL, most suspicious/representative lesion) were characterized regarding changes in T2w, ADC value, and enhancement of dynamic contrast enhancement (DCE) and correlated with quantity of prostatitis and atrophy. RESULTS: Seventy-two patients were analysed. The median baseline characteristics were PSA 5.4 ng/ml (4.0-7.9), PI-RADS classification 3 (2-4), prostate volume 43 ml (33-57), and PSA density 0.13 ng/ml2 (0.10-0.19). Prostatitis was found in 44 % (n = 32) and atrophy in 65 % (n = 47) of cases. The quantity of atrophy demonstrated a significant correlation to T2w changes, ADC increase and DCE enhancement (p = 0.05, p = 0.05, p = 0.01), whereas quantity of prostatitis did not show any significant correlation to the MRI changes (p = 0.68, p = 0.58, p = 0.95). Quantity of prostatitis and atrophy increased with PI-RADS classification. Younger men had lower PSA (4.4 vs. 7.8 ml/ng; p < 0.001), smaller prostate volume (40 vs. 59 ml; p = 0.001), and lower PI-RADS classification (2-3 vs. 3-4; p = 0.005) and prostatitis and atrophy were less frequently observed (p ≤ 0.01, p = 0.03). CONCLUSIONS: Quantity of atrophy and prostatitis had different influence on MRI characteristics and increased within higher PI-RADS classification. Younger men had diffuse hypointense changes at T2w images, but less quantity of prostatitis and atrophy.

Overexpression of monocarboxylate transporter and lactate dehydrogenase alters insulin secretory responses to pyruvate and lactate in beta cells.

Previous investigations revealed low activities of lactate dehydrogenase (LDH) and plasma membrane monocarboxylate transporters (MCT) in the pancreatic beta cell. In this study the significance of these characteristics was explored by overexpressing type A LDH (LDH-A) and/or type 1 MCT (MCT-1) in the clonal INS-1 beta cells and isolated rat islets. Inducible overexpression of LDH-A resulted in an 87-fold increase in LDH activity in INS-1 cells. Adenovirus-mediated overexpression of MCT-1 increased lactate transport activity 3.7-fold in INS-1 cells. Although overexpression of LDH-A, and/or MCT-1 did not affect glucose-stimulated insulin secretion, LDH-A overexpression resulted in stimulation of insulin secretion even at a low lactate concentration with a concomitant increase in its oxidation in INS-1 cells regardless of MCT-1 co-overexpression. Adenovirus-mediated overexpression of MCT-1 caused an increase in pyruvate oxidation and conferred pyruvate-stimulated insulin release to isolated rat islets. Although lactate did not stimulate insulin secretion from control or MCT-1-overexpressing islets, co-overexpression of LDH-A and MCT-1 evoked lactate-stimulated insulin secretion with a concomitant increase in lactate oxidation in rat islets. These results suggest that low expression of MCT and LDH is requisite to the specificity of glucose in insulin secretion, protecting the organism from undesired hypoglycemic actions of pyruvate and lactate during exercise and other catabolic states.

Accelerative exchange diffusion kinetics of glucose between blood and brain and its relation to transport during anoxia.

An earlier study showed that unidirectional glucose transport from blood to brain decreases during perfusion with anoxic blood (Betz, A. L., Gilboe, D. D. and Drewes, L. R. (1974) Brain Res. 67, 307-316). Brain glucose levels also decrease during anoxia. Therefore, the present study was designed to investigate whether the decreased transport might be the result of decreased accelerative exchange diffusion when brain glucose levels are low. The rate of undirectional transport into brain (v) of D-[6-3H]glucose was studied in 22 isolated, perfused dog brains by means of an indicator dilution technique using 22Na as the intravascular reference. The kinetics of transport were determined over a range of blood glucose concentrations (S1) at each of five different brain glucose levels (S2). The existence of accelerative exchange diffusion for glucose was indicated by a decrease in the intercept (increase of apparent V) of a double reciprocal plot (1/v versus 1/S1) as S2 increased. This phenomenon is consistent with a model for facilitated diffusion in which the mobility of the loaded carrier is greater than that of the unloaded carrier. Although the data predict a decrease in glucose transport during anoxia, the predicted decrease (5%) is less than the observed decrease (35%). It is concluded that the simple mobile-carrier model for facilitated diffusion cannot, by itself, describe all properties of blood-brain glucose transport.

Inhibition of glucose transport into brain by phlorizin, phloretin and glucose analogues.

An indicator dilution technique with 22Na+ as the intravascular marker was used to measure unidirectional transport of D-[6-3H]glucose from blood into the isolated, perfused dog brain. 18 compounds which are structurally related to glucose were tested for their ability to inhibit glucose transport. The data suggest that no single hydroxyl group is absolutely required for glucose transport, but rather that glucose binding to the carrier probably occurs through hydrogen bonding at several sites (hydroxyls on carbons 1, 3, 4 and 6). In addition, alpha-D-glucose has higher affinity for the carrier than does beta-D-glucose. A separate series of experiments demonstrated that phlorizin and phloretin are competitive inhibitors of glucose transport into brain; however, phloretin is partially competitive and inhibits at lower concentrations than does phlorizin. Inhibition by phlorizin and phloretin is mutually competitive, indicating that these compounds compete for binding to the glucose carrier. Comparison with the results reported in the literature for similar studies using the human erythrocyte demonstrates a fundamental similarity between glucose transport systems in the blood-brain barrier and erythrocyte.

Cytochalasin B inhibition of brain glucose transport and the influence of blood components on inhibitor concentration.

The effect of cytochalasin B on cerebral glucose transport and metabolism was investigated in 19 isolated perfused dog brain preparations. Cytochalasin B is a potent, non-competitive inhibitor of glucose transport at the blood-brain interface. Both glucose transport into (Ki = 6.6 +/- 1.9 micrometer) and out of the capillary endothelial cell are inhibited. The inhibition is readily reversible by perfusion with blood containing no cytochalasin B. After 2 min of exposure to 30 micrometer cytochalasin B, the cerebral oxygen consumption decreases by 31% probably due to decreased availability of glucose for oxidative metabolism. About one-half of the cytochalasin B that is dissolved in blood is bound to erythrocytes and other blood components while the remainder is free.

Factor(s) released by glucose-deprived astrocytes enhance glucose transporter expression and activity in rat brain endothelial cells.

Glucose transporter (GLUT) expression and regulation were studied in rat brain endothelial cells in primary culture (RBEC) and in immortalised RBE4 cells. Immunoblotting analysis showed a low expression of the endothelium-specific GLUT1 in RBEC and RBE4 cells compared to isolated brain capillaries. RBEC and RBE4 cells also expressed the GLUT3 isoform, whereas it was not present in isolated brain capillaries. No change in GLUT expression was observed in endothelial cells treated with astrocyte-conditioned medium. However, treatment with conditioned medium obtained from glucose-deprived astrocytes increased endothelial GLUT1 expression and glucose uptake. These results suggest that astrocytes submitted to hypoglycaemic conditions may release factor(s) that increase glucose uptake through the blood-brain barrier.

Chronic seizures increase glucose transporter abundance in rat brain.

Pentylenetetrazole and kainic acid, seizure-inducing agents that are known to increase glucose utilization in brain, were used to produce chronic seizures in mature rats. To test the hypothesis that increased brain glucose utilization associated with seizures may alter glucose transporter expression, polyclonal carboxyl-terminal antisera to glucose transporters (GLUT1 and GLUT3) were employed with a quantitative immunocytochemical method and immunoblots to detect changes in the regional abundances of these proteins. GLUT3 abundances in control rats were found to be correlated with published values for regional glucose utilization in normal brain. Following treatment with kainic acid and pentylenetetrazole, both GLUT3 and GLUT1 increased in abundance in a region and isoform-specific manner. GLUT3 was maximal at eight hours, whereas GLUT1 was maximal at three days. Immunoblots indicated that most of the GLUT3 increase was accounted for by the higher molecular weight component of the GLUT3 doublet. The rapid response time for GLUT3 relative to GLUT1 may be related to the rapid increase in neuronal metabolic energy demands during seizure. These observations support the hypothesis that glucose transporters may be upregulated in brain under conditions when brain glucose metabolism is elevated.

Quantitative immunocytochemistry (image analysis) of glucose transporters in the normal and postischemic rodent hippocampus.

The bilateral carotid occlusion model and a polyclonal antibody to the carboxyl terminus of the rat brain/human hepatoma glucose transporter were used to examine quantitatively changes in the transporter in gerbil hippocampal microvessels following 6-7.5 min of ischemia. The optical densities of immunocytochemically stained microvessels in the stratum lacunosum-moleculare (SLM) below the CA1 subfield were determined using image analysis of frozen sections from gerbils killed 2 h, 3 days, 6 days, 4 weeks, and 7 weeks after the ischemic episode. Microvessels were sparsely distributed in the stratum oriens, stratum pyramidale, and stratum radiatum. In contrast, the SLM was relatively well vascularized, and this distribution of microvessels persisted following ischemia. The SLM was identifiable based solely on microvessel distribution both in control gerbils and in gerbils that exhibited complete destruction of CA1 pyramidal cells. The abundance of the glucose transporter in SLM microvessels remained constant, suggesting that down-regulation of this protein cannot account for reported declines in brain glucose utilization and cell death following ischemia. Conversely, the presence and metabolic activity of CA1 pyramidal cells do not appear to be determinants of glucose transporter abundance in hippocampal microvessels. The brain/hepatoma glucose transporter was abundant in brain microvessels and the epithelial cells of the choroid plexus of gerbil and rat. Staining of hippocampal neuropil was less intense, poorly localized, and, at the light microscope level, not clearly associated with a particular cell type.

Expression of large amino acid transporter LAT1 in rat brain endothelium.

The expression of the large amino acid transporter, LAT1, was investigated in brain of adult Long-Evans rats. The LAT1 transcript was readily detected in brain microvessels and choroid plexus by reverse transcription polymerase chain reaction analysis using three different gene specific primer pairs. A polyclonal affinity purified antibody against the N-terminus of LAT1 was generated in chickens and used in immunoblot and immunocytochemical analyses of brain tissue sections of adult rats. On immunoblots, the antibody detected a peptide-inhibitable 45 kDa band in a rat brain microvessel membrane preparation. It also identified the same protein band in membrane preparations of different brain structures, as well as in heart and testis, whereas the protein was absent or only faintly detectable in muscle, kidney, and liver. In brain sections, the antibody intensely labeled the luminal and abluminal membranes of brain microvessel endothelial cells in all brain areas examined including cerebral cortex, cerebellum, hippocampus, and in gray and white matter regions. These results suggest that LAT1 is involved in transcellular transport and may play an important role in large, neutral amino acid transfer across the blood-brain barrier.

Formation of free choline in brain tissue during in vitro energy deprivation.

Free choline and ATP contents were measured in Mongolian gerbil hippocampal slices (tissue) and incubation media (media) during exposure to 30 min of aglycemia, high potassium, anoxia, or ischemia. Changes in choline levels reflected the degree of energy reduction, lower ATP levels being associated with high choline (4-fold increase during exposure to high potassium and anoxia, and 11-fold increase during ischemia). Media (extracellular) choline was particularly affected and increased about twofold during relatively mild energy depletion (e.g., aglycemia), but tissue choline content was less sensitive to energy reduction. A plot of choline vs. ATP levels indicated a nonlinear correlation, and the sharp increase in choline occurred when ATP values fell to about 2.5 nmol/mg of protein. Inhibition of acetylcholine sterase by 10 microM physostigmine during ischemia did not prevent an increase in choline contents but rather enhanced them, indicating that acetylcholine hydrolysis was not the source of free choline. Formation of free choline was Ca2+ independent. These findings suggest the involvement of phospholipase D and phosphatidylcholine hydrolysis in free choline formation during energy stress. The extent of choline formation may be an indicator of the degree of membranal damage, which in turn reflects damage to the metabolic machinery of the cell.

Canine brain glucose transporter 3: gene sequence, phylogenetic comparisons and analysis of functional sites.

There has been a sparsity of various mammalian neuronal glucose transporter 3-encoding sequences(Glut3) available for the purposes of alignment studies. We report here a 2355-bp sequence of canine Glut3 that encodes a deduced protein of 496 amino acids (aa). The full-length canine aa sequence was compared to those of the human, mouse and rat glucose transporter 3 (Glut3), and found to be 88.3, 84.9 and 84.3% identical, respectively. However, while mouse and rat identical C-termini, the canine nd human C-termini share markedly little identity or similarity to one another, or to that of rat/mouse. The canine Glut3 sequence also exhibits 74.5% aa identity with a non-mammalian chicken Glut3 sequence. These differences in the C-termini of Glut3 among the species may result in kinetic or mechanistic differences in transport of glucose. Computer searches were made for conserved functional motifs, and a brief review of ten sites is provided. This review includes the determination of their locations in two transmembrane (TM) motifs that have been proposed for glucose transporters. The nucleotide (nt) sequence of the 5'-untranslated region (UTR) of canine Glut3 was aligned with the comparable human glut3 region and was shown to be 70% identical over a region of 129 nt just prior to the ATG start codons. A similar comparison of the 3'-UTR shows 74% identity over 350 nt immediately following the stop codons. An adenosine-uridine-binding factor (AUBF) region, which has been identified as a region of importance in mRNA stabilization, is conserved in the 3'-UTR of both canine and human Glut3. The conservation in the UTR suggests that Glut3 may be post-transcriptionally regulated.

Distribution of monocarboxylate transporters MCT1 and MCT2 in rat retina.

Transport of lactic acid and other monocarboxylates such as pyruvate and the ketone bodies through cellular membranes is facilitated by specific transport proteins. We used chicken polyclonal antibodies to the monocarboxylate transporters-1 and -2 to determine their cellular and subcellular distributions in rat retina, and we compared these distributions to those of the glucose transporters-1 and -3. Monocarboxylate transporter-1 was most highly expressed by the apical processes of retinal pigment epithelium that surround the outer segments of the photoreceptor cells. In contrast to glucose transporter-1, monocarboxylate transporter-1 was not detected on the basal membranes of pigment epithelium. The luminal and abluminal endothelial plasma membranes in retina also exhibited heavy labeling by antibody to monocarboxylate transporter-1. In addition, this transporter was associated with the Müller cell microvilli, the plasma membranes of the rod inner segments, and all retinal layers between the inner and external limiting membranes. Monocarboxylate transporter-2 was found to be abundantly expressed on the inner (basal) plasma membrane of Müller cells and by glial cell processes surrounding retinal microvessels. This transporter was also present in the plexiform and nuclear layers but was not detected beyond the external limiting membrane. Recent studies have shown that lactic acid transport is of particular importance at endothelial and epithelial barriers where membranes of adjoining cells are linked by tight junctions. Our results suggest that monocarboxylate transporter-1 functions to transport lactate between the retina and the blood, both at the retinal endothelium and the pigment epithelium. The location of monocarboxylate transporter-2 on glial foot processes surrounding retinal vessels suggests that this transporter is also important in blood-retinal lactate exchange. In addition, the abundance of these transporters in Müller cells and synaptic (plexiform) layers suggests that they function in lactate exchange between neurons and glia, supporting the notion that lactate plays a key role in neural metabolism.

Localization of glucose transporter GLUT 3 in brain: comparison of rodent and dog using species-specific carboxyl-terminal antisera.

The carboxyl-terminal amino acid sequences of the canine and gerbil glucose transporter GLUT3 were determined and compared to the published rat sequence. Eleven of 16 amino acids comprising the carboxyl terminus of GLUT3 were found to be identical in rat and dog. However, the canine sequence "ATV" substitutes for the rat sequence "PGNA" at the end of the molecule. The gerbil sequence has 12 of 16 amino acids identical to the rat, including the PGNA terminus. Based on these sequences, four peptides were synthesized, and two polyclonal antisera (one to the canine sequence and one to the rat sequence) were raised to examine the distribution of GLUT3 in canine and rodent brain. Immunoblots of brain membrane preparations showed that both antisera identified peptide-inhibitable protein bands of molecular weight 45,000-50,000. Immunocytochemical studies demonstrated that binding sites for these antisera were abundantly distributed in neuropil in all brain regions. Areas rich in synapses and areas surrounding microvessels exhibited especially high reactivity. GLUT3 reactivity was similarly distributed in canine and rodent brain, except at the blood-brain barrier. GLUT3 was not detected in the blood-brain barrier in gerbil and rat but was present in many canine cerebral endothelial cells, particularly in cerebellum and brain stem. The carboxyl-terminal antisera employed in this study exhibited high degrees of species specificity, indicating that the three or four terminal amino acids of the immunizing peptides (ATV and PGNA) are important epitopes for binding the polyclonal antibodies. These antisera exhibited only minimal binding to brain tissue of non-target species, yet yielded similar staining patterns in neuropil of rodent and canine brain. This finding provides strong evidence that the observed staining patterns accurately reflect the distribution of GLUT3 in brain. In addition, the presence of vascular GLUT3 in dog brain suggests that the canine blood-brain barrier may be preferable to that of the rat as a model for studies of glucose transport relevant to human brain.

Light and electron microscopic localization of D-galactosyl residues in capillary endothelial cells of the canine cerebral cortex.

Ricinus communis agglutinin I (RCA-I), a lectin that binds to D-galactosyl residues, intensely stained capillaries in cryostat sections of canine cerebral cortex when evaluated by the avidin-biotin-peroxidase complex method. Of seven lectins tested, only RCA-I gave strong staining of vessels and capillaries with little staining of other cortical cells. Ultrastructural studies using ferritin-, biotin-, and peroxidase-labeled RCA-I indicated that this lectin was bound to the luminal membrane of the cerebral capillary endothelial cell and that lectin receptors were distributed continuously along this membrane. Plasmalemma invaginations that bound RCA-I were also present in endothelial cells. Primary cultures of cerebral capillary endothelial cells grown on plastic or gelatin-coated glass substrates demonstrated staining of the cell membrane and perinuclear structures which appeared to be the Golgi complex and secondary lysosomes. These staining characteristics were retained when the cells were subcultured and were confirmed by ultrastructural studies. In contrast, light microscopy showed that fibronectin was more widely distributed in the cytoplasm, a finding consistent with its occurrence in the endoplasmic reticulum. This work provides support for the concept that lectins may be useful endothelial cell markers in both intact tissue and cell culture.

Molecular architecture of the brain microvasculature: perspective on blood-brain transport.

Brain endothelial cells and their intercellular tight junctions form a cellular interface between the circulating blood and neural environment. All nutrients consumed by brain must traffic through this cellular space and its two limiting membranes. Additionally, the endothelial cell affects homeostasis by contributing or removing constituents from the interstitial space. These endothelial-cell functions are collectively accomplished with a rich complement of transporters and channels distributed, frequently asymmetrically, between the luminal and abluminal membranes. The identity and characterization of these proteins is rapidly advancing by application of molecular and cellular techniques. Knowledge of these molecular mechanisms will be beneficial in improving brain function and the treatment of neurological diseases.

GLUT1 and GLUT3 gene expression in gerbil brain following brief ischemia: an in situ hybridization study.

GLUT1 and GLUT3 mRNAs in normal and post-ischemic gerbil brains were examined qualitatively and semi-quantitatively using in situ hybridization in conjunction with image analysis. Coronal brain sections at the level of the anterior hippocampus were prepared three hours, one day, and three days after animals were subjected to six min of ischemia. The sections were hybridized with vector- and PCR-generated RNA probes labeled with 35S. Microscopic evaluation of hybridized brain sections coated with autoradiographic emulsion indicated that GLUT1 mRNA was associated with brain microvessels, choroid plexus, and some ependymal cells. GLUT1 mRNA was not observed in neurons, except that one day following ischemia, this mRNA was induced in neurons of the dentate gyrus. GLUT3 mRNA was detected only in neurons. Image analysis of film autoradiograms revealed that both the GLUT1 and GLUT3 messages increased following ischemia but returned nearly to control levels by day three. In the CA1 region of the hippocampus the increase in GLUT3 mRNA was not statistically significant, and by day three the level had fallen significantly below the control, coinciding with the degeneration of the CA1 neurons. Our results suggest that the brain possesses mechanisms for induction and up-regulation of glucose transporter gene expression.

Diet-induced ketosis increases monocarboxylate transporter (MCT1) levels in rat brain.

Monocarboxylate transporter (MCT1) levels in brains of adult Long-Evans rats on a high-fat (ketogenic) diet were investigated using light and electron microscopic immunocytochemical methods. Rats given the ketogenic diet (91% fat and 9% protein) for up to 6 weeks had increased levels of the monocarboxylate transporter MCT1 (and of the glucose transporter GLUT1) in brain endothelial cells and neuropil compared to rats on a standard diet. In ketonemic rats, electron microscopic immunogold methods revealed an 8-fold greater MCT1 labeling in the brain endothelial cells at 4 weeks. Abluminal endothelial membranes were twice as heavily labeled as luminal membranes. In controls, luminal and abluminal labeling was not significantly different. The endothelial cytoplasmic compartment was sparsely labeled (<8% of total endothelial labeling) in all brains. Neuropil MCT1 staining was more intense throughout the brain in ketonemic rats, especially in neuropil of the molecular layer of the cerebellum, as revealed by avidin-biotin immunocytochemistry. This study demonstrates that adult rats retain the capacity to upregulate brain MCT1 levels. Furthermore, their brains react to a diet that increases monocarboxylate levels in the blood by enhancing their capability to take up both monocarboxylates (MCT1 upregulation) and glucose (GLUT1 upregulation). This may have important implications for delivery of fuel to the brain under stressful and pathological conditions, such as epilepsy and GLUT1 deficiency syndrome.

Expression of monocarboxylate transporter MCT1 in normal and neoplastic human CNS tissues.

Expression of monocarboxylate transporter MCT1 was studied in archival tissues from human CNS using antibodies to the carboxyl-terminal end of MCT1. Sections of neocortex, hippocampus and cerebellum of brains from 10 adult autopsy patients who died from other than CNS disease, and from archival surgical biopsy specimens of 83 primary CNS and eight non-CNS tumors were studied. MCT1 immunoreactivity was present in microvessels and, ependymocytes of normal CNS tissues similar to that reported for MCT1 expression in rat brains. MCT1 immunoreactivity was strongest in ependymomas, hemangioblastomas and high grade glial neoplasms, and weakest in low grade gliomas. Increased MCT1 expression in high grade glial neoplasms may provide a potential therapeutic target for treatment of some CNS neoplasms.

Glucose transporters at the blood-nerve barrier are associated with perineurial cells and endoneurial microvessels.

The blood-nerve barrier consists of continuous layers of cells linked by tight junctions and includes the endothelial cells which line the endoneurial capillaries and the perineurial cells which surround fascicles of nerve fibers. A facilitated transport carrier protein allows D-glucose to penetrate the barrier. To determine the specific cellular location of the transport system, an antiserum to a synthetic peptide corresponding to the carboxyl-terminus of the glucose transporter protein was used for light and electron immunocytochemical analyses. Glucose transporters were abundant both in endoneurial capillaries and the perineurial sheath. In perineurium, transporters were located in the plasma membranes and cytoplasm of the perineurial cells. Approximately two-thirds of the transporters associated with perineurial cells were localized in the plasma membranes. Perineurial cells are thus similar to cerebral endothelial cells in that they lack a large intracellular pool of transporters which might be sensitive to hormonal regulation. The presence of hexose carriers in perineurium suggests that glucose transport from epineurium to endoneurium may play a significant role in the metabolism of peripheral nerve fibers. These results support the concept that the blood-nerve barrier serves as an important nutrient delivery system.