Heinrich Wiesinger

Metabolic pathways for glucose in astrocytes

Cultured astroglial cells are able to utilize the monosaccharides glucose, mannose, or fructose as well as the sugar alcohol sorbitol as energy fuel. Astroglial uptake of the aldoses is carrier‐mediated, whereas a non‐saturable transport mechanism is operating for fructose and sorbitol. The first metabolic step for all sugars, including fructose being generated by enzymatic oxidation of sorbitol, is phosphorylation by hexokinase. Besides glucose only mannose may serve as substrate for build‐up of astroglial glycogen. Whereas glycogen synthase appears to be present in astrocytes as well as neurons, the exclusive localization of glycogen phosphorylase in astrocytes and ependymal cells of central nervous tissue correlates well with the occurrence of glycogen in these cells. The identification of lactic acid rather than glucose as degradation product of astroglial glycogen appears to render the presence of glucose‐6‐phosphatase in cultured astrocytes an enigma. The colocalization of pyruvate carboxylase, phosphenolpyruvate carboxykinase and fructose‐1,6‐bisphosphatase points to astrocytes as being the gluconeogenic cell type of the CNS. GLIA 21:22–34, 1997.

Uptake of l-lactate by cultured rat brain neurons

The uptake of L-lactate was investigated in neuronal primary cultures derived from embryonic rat brain with a radioactive tracer method. After preincubation of the cells in glucose-free buffer for 30 min, uptake increased with time for at least 10 min. A saturable component of uptake was found with half-maximal uptake at 10 mM lactate. This saturable component was abolished in the presence of 10 mM alpha-cyano-4-hydroxcinnamic acid. In addition, a non-saturable component dominated the uptake at high concentrations of lactate. Uptake was accelerated with decreasing pH, and was inhibited considerably by pyruvate. It is concluded that neurons are endowed with a lactate transport system which resembles in its properties the monocarboxylate carrier of peripheral tissues.

Anti-inflammatory antioxidants attenuate the expression of inducible nitric oxide synthase mediated by advanced glycation endproducts in murine microglia

Advanced glycation endproducts (AGEs) accumulate on long‐lived protein deposits including β‐amyloid plaques in Alzheimers disease (AD). AGE‐modified amyloid deposits contain oxidized and nitrated proteins as markers of a chronic neuroinflammatory condition and are surrounded by activated microglial and astroglial cells. We show in this study that AGEs increase nitric oxide production by induction of the inducible nitric oxide synthase (iNOS) on the mRNA and protein level in the murine microglial cell line N‐11. Membrane permeable antioxidants including oestrogen derivatives (e.g. 17β‐oestradiol) thiol antioxidants (e.g. (R+)‐α‐lipoic acid) and Gingko biloba extract EGb 761, but not phosphodiesterase inhibitors such as propentophylline, prevent the up‐regulation of AGE‐induced iNOS expression and NO production. These results indicate that oxygen free radicals serve as second messengers in AGE‐induced pro‐inflammatory signal transduction pathways. As this pharmacological mechanism is not only relevant for Alzheimers disease, but also for many chronic inflammatory conditions, such membrane‐permeable antioxidants could be regarded not only as antioxidant, but also as potent therapeutic anti‐inflammatory drugs.

Purification of Cytosolic Malic Enzyme from Bovine Brain, Generation of Monoclonal Antibodies, and Immunocytochemical Localization of the Enzyme in Glial Cells of Neural Primary Cultures

Abstract: Cytosolic malic enzyme (EC 1.1.1.40) was purified from bovine brain 5,600‐fold to a specific activity of 47 U/mg. The enzyme is a homotetramer with a subunit molecular mass of 60 kDa and an isoelectric point of 6.2. Mouse monoclonal antibodies raised against this enzyme were purified and shown to be monospecific, as indicated by immunoblotting. Immunocytochemical examination of rat astroglia‐rich primary cultures at the light microscopic level revealed colocalization of cytosolic malic enzyme with the astroglial marker glial fibrillary acidic protein. Also, a colocalization with the oligodendroglial marker myelin basic protein was found. Neurons in rat neuron‐rich primary cultures did not show positive staining. The data suggest that cytosolic malic enzyme is a glial enzyme and is lacking in neurons.

The regeneration of reduced glutathione in rat forebrain mitochondria identifies metabolic pathways providing the NADPH required.

Metabolic pathways underlying the regeneration of reduced glutathione were investigated in acutely isolated metabolically active mitochondria from rat forebrain. The application of hydrogen peroxide to the organelles was accompanied by a transient increase in glutathione disulfide. The recovery of reduced glutathione was significantly improved in the presence of alternatively succinate, malate, citrate, isocitrate, or beta-hydroxybutyrate. Inhibition of succinate dehydrogenase by malonate abolished the beneficial effect of succinate on the reduction of glutathione disulfide but did not influence the effect of isocitrate. Fluorocitrate, an inhibitor of aconitase, blocked the effect exerted by citrate but did not inhibit the effects of malate or beta-hydroxybutyrate. Uncoupling of the respiratory chain by carbonyl cyanide m-chlorophenylhydrazone prevented the beneficial effect of beta-hydroxybutyrate but did not abolish the improved reduction of mitochondrial glutathione disulfide in the presence of malate and isocitrate. These results suggest that NADP+-dependent isocitrate dehydrogenase as well as malic enzyme and nicotinamide nucleotide transhydrogenase contribute to the regeneration of NADPH required for the reduction of glutathione disulfide in brain mitochondria.

Expression of the Na+‐d‐Glucose Cotransporter SGLT1 in Neurons

Abstract: In brains of the rabbit, pig, and human, expression of the high‐affinity Na+‐d‐glucose cotransporter SGLT1 and of the protein RS1, which alters the activity of SGLT1, was demonstrated. In situ hybridization showed that SGLT1 and RS1 are transcribed in pyramidal cells of brain cortex and hippocampus and in Purkinje cells of cerebellum. In neurons of pig brain SGLT1 protein was demonstrated by western blotting with synaptosomal membranes and by immunohistochemistry, which showed SGLT1 in pyramidal and Purkinje cells. To test whether SGLT1 in neurons may be activated during increased d‐glucose consumption, an epileptic seizure was induced in rat brain, and the uptake of specific nonmetabolized substrates of SGLT1 {[14C]methyl‐α‐d‐glucopyranoside ([14C]AMG)} and of Na+‐independent transporters {2‐deoxy‐d‐[14C]glucose([14C]2‐DG)} was analyzed by autoradiography. During the seizure the uptake of AMG and 2‐DG was increased in the focus. Within two hours after the seizure 2‐DG uptake in the focus returned to normal. In contrast, the AMG uptake in the focus area was still increased 1 day later. The data show that the high‐affinity Na+‐d‐glucose cotransporter SGLT1 is expressed in neurons and can be up‐regulated.

Asymmetry of glutamine transporters in cultured neural cells

Transfer of glutamine between astrocytes and neurons is an essential part of the glutamate-glutamine cycle in the brain. Transport of glutamine was investigated in primary cultures of astrocytes and neurons and compared to glutamine transport in cell lines with glial and neuronal properties. Glutamine uptake in astrocytes was mainly mediated by general amino acid transporters with properties similar to ASCT2, LAT1, LAT2, SN1 and y(+)LAT2. In cultured neurons, transport activities were detected consistent with the presence of LAT1, LAT2 and y(+)LAT2, but the most prominent activity was a novel Na(+)-dependent glutamine transporter that could be inhibited by D-aspartate. The mRNA for system A isoforms ATA1 and ATA2 was detected in both neurons and astrocytes, but system A activity was only detected in neurons. ASCT2 on the other hand appeared to be astrocyte-specific. The cell lines F98 and 108CC-15, having astroglial and neuronal properties, respectively, expressed sets of glutamine transporters that were unrelated to those of the corresponding primary culture and are thus of limited use as models to study transfer of glutamine between astrocytes and neurons.

Lactate Transport in Cultured Glial Cells

Uptake of L-lactate was investigated with a radioactive tracer method in cultured rat glioma cells and in astroglia-rich primary cultures derived from rat brain. In the glioma cells, a saturable component of uptake was identified with half-maximal uptake occurring at 1.0 +/- 0.4 mM lactate. In addition, a non-saturable component dominated the uptake at high concentrations of lactate. In astroglia-rich primary cultures, no saturable component of uptake could be detected in the concentration range studied (0.1-15 mM). In conclusion, lactate uptake at physiological concentrations is predominantly mediated in the glioma cells by a carrier-dependent process, whereas in astroglial cells, simple diffusion appears to be the dominant way of lactate transport.

Mitochondrial Malic Enzyme: Purification from Bovine Brain, Generation of an Antiserum, and Immunocytochemical Localization in Neurons of Rat Brain

Abstract: To elucidate the cellular location of mitochondrial malic enzyme in brain, immunocytochemical studies were performed. For this purpose, mitochondrial malic enzyme was purified to apparent homogeneity from bovine brain and used for the immunization of rabbits. Subjecting the antiserum to affinity purification on immobilized antigen as an absorbent yielded a purified immunoreactive antibody preparation, which was characterized by probing cytosolic and mitochondrial fractions of bovine and rat brain in western blotting. As neither crossreactivity with cytosolic malic enzyme nor immunoreactivity against other proteins could be observed, the antibody preparation was found suitable for immunocytochemistry. By using sections of perfusion‐fixed rat brain, considerable resolution was achieved at the light‐microscopic level. Distinct and specific staining of neurons was observed; in contrast, no staining of astrocytes and possibly unspecific staining within the nuclei of oligodendrocytes were obtained. From these data, it is concluded that mitochondrial malic enzyme is located in neurons; however, in astrocytes, the enzyme appears to be either lacking or present at a much lower level. A protective role against oxidative stress in neurons is proposed for mitochondrial malic enzyme.

Stimulation of Arginine Transport and Nitric Oxide Production by Lipopolysaccharide Is Mediated by Different Signaling Pathways in Astrocytes

Abstract: Transport of l‐arginine and generation of nitrite in microglia‐free astroglial cultures derived from neonatal mouse brain were stimulated by bacterial lipopolysaccharide (LPS) in a time‐ and dose‐dependent manner. LPS stimulated arginine transport between 1.3‐ and 2.5‐fold; half‐maximal stimulation was obtained with 0.3 µg/ml LPS. Acceleration of transport was detectable within 6 h of incubation with LPS. Cycloheximide or actinomycin D neutralized the effect of LPS. Stimulation of generation of nitrite was reduced when the cells were incubated simultaneously with LPS and either genistein or diethyldithiocarbamate, inhibitors of protein tyrosine kinase and nuclear transcription factor κ, respectively. However, stimulation of arginine transport was not reduced in the presence of these compounds. Dexamethasone inhibited stimulation of nitric oxide (NO) production but not of arginine transport. Protein kinase C inhibitor staurosporine had no effect on either process. The results suggest that LPS‐stimulated acceleration of arginine transport in astrocytes requires protein as well as RNA synthesis. Induction of synthesis of an astroglial cationic amino acid transport system appears to be mechanistically independent from stimulation of intracellular NO production.