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.

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.

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.

Monocarboxylate transporter (MCT1) abundance in brains of suckling and adult rats: a quantitative electron microscopic immunogold study.

Transcellular transport of energy substrates across the vascular endothelial cells of the brain is accomplished by integral membrane carrier proteins, such as the glucose transporter GLUT1 and the monocarboxylic acid transporter MCT1. The abundance of these proteins may vary depending on age and nutritional status. In this study we compared the expression of MCT1 in cerebral cortex of suckling and adult rats to determine whether the former, which use considerably more monocarboxylates such as lactate and ketone bodies as fuel than do older rats, correspondingly express more MCT1 than adults. Using electron microscopic immunogold methods, we found that 17-day old suckling rat pups had 25 times more MCT1 labeling in the membranes of capillary endothelial cells than adults. This transporter was nearly equally distributed in luminal and abluminal membranes with less than 10% of the immunogold particles in the endothelial cytoplasmic compartment. The suckling rats also had 15 times more immunogold particles associated with pericyte membranes and 19 times heavier labeling of membranes associated with astrocytic end feet adjacent to microvessels. Neuropil and choroid plexus were lightly labeled. Some MCT1-positive astrocyte and neuron cell bodies were observed, suggesting active synthesis of MCT1 by these cells. The potential for regulation of expression of MCTs by dietary or other factors may have important consequences for the progression and treatment of cerebrovascular disorders and other diseases.

Expression of the monocarboxylate transporter MCT2 by rat brain glia.

The nucleotide sequence of the rat monocarboxylate transporter MCT2 was determined from brain-derived cDNA. A polyclonal antibody was raised in chickens against the carboxyl terminal end of the deduced amino acid sequence and affinity purified. The MCT2 antibody identified a 46-kDa band on immunoblots and labeled kidney, skeletal muscle, and stomach consistent with the reported cellular expression for this transporter. Light microscopic immunocytochemistry indicated that the MCT2 transporter was abundant in glial limiting membranes, ependymocytes, and neuropil, particularly in the lacunosum molecular layer of hippocampus and the molecular layer of cerebellum. Labeled astrocytes were commonly observed in white matter. The distribution of this transporter differed in several respects from that previously reported for MCT1. MCT2 was abundantly distributed in astrocyte foot processes and was usually not detected in other cells of the cerebrovasculature, including vascular smooth muscle cells, pericytes, and endothelium. In addition, the granular layer of cerebellum, which showed little MCT1 labeling, exhibited MCT2 labeling of cellular processes in the neuropil surrounding the granule and Purkinje cells. The results lend support to the concept that astrocytes play a significant role in cerebral energy metabolism by transporting lactate and other monocarboxylates.

Ultrastructural localization of GLUT 1 and GLUT 3 glucose transporters in rat brain.

Precise localization of glucose transport proteins in the brain has proved difficult, especially at the ultrastructural level. This has limited further insights into their cellular specificity, subcellular distribution, and function. In the present study, preembedding ultrastructural immunocytochemistry was used to localize the major brain glucose transporters, GLUTs 1 and 3, in vibratome sections of rat brain. Our results support the view that, besides being present in endothelial cells of central nervous system (CNS) blood vessels, GLUT 1 is present in astrocytes. GLUT 1 was detected in astrocytic end feet around blood vessels, and in astrocytic cell bodies and processes in both gray and white matter. GLUT 3, the neuronal glucose transporter, was located primarily in pre- and postsynaptic nerve endings and in small neuronal processes. This study: (1) affirms that GLUT 3 is neuron-specific, (2) shows that GLUT 1 is not normally expressed in detectable quantities by neurons, (3) suggests that glucose is readily available for synaptic energy metabolism based on the high concentration of GLUT 3 in membranes of synaptic terminals, and (4) demonstrates significant intracellular and mitochondrial localization of glucose transport proteins.

Expression of monocarboxylate transporter MCT1 by brain endothelium and glia in adult and suckling rats.

A polyclonal affinity-purified antibody to the carboxyl-terminal end of the rat monocarboxylate transporter 1 (MCT1) was generated in chickens and used in immunocytochemical studies of brain tissue sections from adult and suckling rats. The antibody identified a 48-kDa band on immunoblots and stained tissue sections of heart, cecum, kidney, and skeletal muscle, consistent with the reported molecular mass and cellular expression for this transporter. In tissue sections from adult brains, the antibody labeled brain microvessel endothelial cells, ependymocytes, glial-limiting membranes, and neuropil. In brain sections from 3- to 14-day-old rats, microvessels were much more strongly labeled and neuropil was weakly labeled compared with sections from adults. Immunoelectron microscopy indicated that labeling was present on both luminal and abluminal endothelial cell plasma membranes. These results suggest that MCT1 may play an important role in the passage of lactate and other monocarboxylates across the blood-brain barrier and that suckling rats may be especially dependent on this transporter to supply energy substrates to the brain.

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.

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.

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.

Neurons and microvessels express the brain glucose transporter protein GLUT3.

To elucidate glucose transport mechanisms in brain and to demonstrate the cellular expression of the brain-type glucose transporter (GLUT3), antisera to a synthetic peptide corresponding to the C terminus were prepared and used as probes for this isoform of the facilitative glucose transporter family. Immunocytochemistry of frozen sections of dog and rat brain demonstrated GLUT3 antigen in pyramidal cell bodies and processes, in microvessels, and in intima pia or glia limitans. Immunoanalysis of Western blots identified a protein (Mr, 45,000) that was present in both neuron/neuropil and microvessel fractions. The presence of the GLUT3 message in brain was confirmed by Northern blot analysis and by amplifying and partially sequencing GLUT3 cDNA by PCR. These findings demonstrate a neuron glucose transporter in tissue and suggest that GLUT3 may play an important role in brain metabolism under physiological and pathophysiological conditions.

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.

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.

Glucose transporter localization in brain using light and electron immunocytochemistry.

A polyclonal antibody to a synthetic 13 amino acidpeptide found at the carboxyl-terminal end of the glucose transporter protein was raised in rabbit and used in light and electron immunocytochemical studies of human and canine brain. This antibody identified a broad band of polypeptide of average Mr 55,000 on immunoblots (immunogold-silver stains) of electrophoresed membrane proteins from human red blood cells. A similar polypeptide band (Mr 45,000-60,000) was identified on immunoblots of microvessel membrane proteins isolated from canine cerebrum, suggesting that this antibody is a useful tool for studying the distribution and abundance of the glucose transporter protein in mammalian nervous tissue. Peroxidase antiperoxidase stains of cerebrum using this antibody demonstrated that transporters are abundant in the intima pia, in the endothelium of blood vessels in the subarachnoid space, and in the endothelium of arterioles, venules, and capillaries of gray and white matter. In cerebellum, reaction product was localized in the vessels of the subarachnoid space and in microvessels of the molecular layer, the granular layer, and the white matter. However, transporters were not found in the intima pia of cerebellum. In medulla oblongata, transporters were found in the intima pia, the endothelium of some subarachnoid vessels, and the microvessels of gray and white matter. In pituitary, microvessels in adenohypophysis contained no reaction product, but the antigen was detected in some microvessels in neurohypophysis. Electron microscopy of cerebral cortex using a protein A-gold technique demonstrated that glucose transporters are equally abundant on the luminal and abluminal membranes of microvessel endothelial cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Phorbol ester stimulates hexose uptake by brain microvessel endothelial cells.

Glucose uptake into cultured endothelial cells (EC) derived from brain microvessels was determined in the absence and presence of 12-O-tetradecanoylphorbol-13-acetate (TPA), EGTA, the calcium ionophore A23187, and insulin. EC were obtained from dog and human (autopsy) brain microvessels and maintained in culture for up to four passages. Monolayers of EC were treated with TPA and other compounds immediately prior to harvesting for hexose uptake measurements using 3-O-[3H]methyl-D-glucose, 2-[3H]deoxy-D-glucose, or D-[3H]glucose. Typically, treatment with TPA (0.1-100 ng/ml) resulted in hexose uptake levels 2 to 3 times those of controls, although occasionally levels 5 to 10 times those of controls were observed. Similar stimulation was observed with all radiolabeled hexoses. Stimulation by TPA was greatest in primary or first passage cells and was greatly diminished in older cells. Neither chelation of extracellular calcium with EGTA nor the presence of both EGTA and A23187 in the culture medium prevented the stimulatory effect of TPA. Insulin (1200 ng/ml) failed to stimulate hexose uptake. Treatment with 100 ng/ml TPA did not alter the appearance of actin filaments in canine EC as visualized with rhodamine phalloidin. These results, in combination with other recent studies, suggest that blood-brain glucose transport may be regulated by phorbol ester-activated protein kinase C.

Cultured human and canine endothelial cells from brain microvessels.

Cultures of endothelial cells (EC) derived from human (autopsy) and canine brain microvessels were characterized with respect to growth, morphology, and biochemical features. The endothelial nature of these cells was confirmed by analyses of angiotensin-converting enzyme activity, Factor VIII-related antigen, and ultrastructure. Human EC required coated substrates and tumor-conditioned medium to achieve rapid growth, and cells derived from human microvessels were morphologically diverse. In contrast, canine EC grew rapidly on plastic substrates and produced colonies of uniform morphology. Morphological variations of EC were associated with the use of heparin-containing medium and with the use of a commercially-prepared basement membrane extract (Matrigel). Lectin histochemistry demonstrated that human EC lack the abundant alpha-galactose residues characteristic of canine EC membranes and organelles and that canine EC lack the alpha-N-acetylgalactosamine residues which are associated with human EC. The lectin Ricinus communis agglutinin I may be useful for distinguishing canine EC from pericytes. Gel electrophoresis of membrane proteins revealed protein bands present in human EC at Mr 210,000 and 37,000-39,500 which were not present in canine EC. These proteins may be related to the presence of junctional complexes in cultures of human EC.

Characterization of the blood-brain barrier: glycoconjugate receptors of 14 lectins in canine brain, cultured endothelial cells, and blotted membrane proteins.

The avidin-biotinylated peroxidase complex (ABC) method was used to detect binding of 14 lectins in tissue, cultured cells, and nitrocellulose blots. When applied to frozen sections of canine cerebral cortex and pituitary and evaluated by light microscopy, these lectins produced distinct staining patterns as determined by their individual carbohydrate specificities. Major saccharide residues detected in the endothelium of these cerebral tissues include alpha- and beta-galactose, alpha-mannose and/or alpha-glucose, and N-acetylglucosamine. Application to cells cultured from the canine cerebral endothelium gave staining results similar to those of microvessels in tissue. Thus, these characteristics of intact capillaries are retained in cultured cells and define fundamental properties of the blood-brain interface. Visual comparison of these staining patterns to those obtained for electrophoretic blots of solubilized membrane proteins identified multiple glycoprotein receptors and illustrated the vast quantity and variety of surface carbohydrate residues and the complexity of the cerebral endothelial cell glycocalyx. This carbohydrate-rich layer, which extends into the capillary lumen, may be of significant importance to the unique function of the blood-brain barrier.

Butyrylcholinesterase in pericytes associated with canine brain capillaries.

The distribution of the enzyme butyrylcholinesterase (BChE) in dog brain cortex and cerebellum was studied by light and electron microscopy using a Hatchett's brown technique. Staining was found in neuron cell bodies and processes, the white matter of the cerebellum, and in capillaries and arterioles. Electron microscopy indicated that the enzyme activity associated with vessels was present in pericytes. Reaction product was found at the cell membrane, the intermembranous space of the nuclear envelope, and the Golgi complex of these cells. The finding of BChE in canine brain pericytes and its absence in endothelium does not support the idea that this enzyme is important in blood-brain barrier function. The pericyte in dog brain may be a site of synthesis of this enzyme and is, in this respect, similar to the endothelial cell of rat 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.