Selective tonicity-induced expression of the neutral amino-acid transporter SNAT2 in oligodendrocytes in rat brain following systemic hypertonicity.

Sodium-coupled neutral amino-acid transporter member 2 (SNAT2) belongs to the family of neutral amino-acid transporters. SNAT2 is encoded by the gene Slc38a2, whose expression was reported to increase in vitro in fibroblasts, endothelial and renal cells exposed to a hypertonic medium. SNAT2 tonicity-induced expression brings about cellular accumulation of amino-acid, which contributes to osmoadaptation to hypertonicity. Since brain osmoadaptation is observed in relationship to neurological disorders resulting from pathological osmotic imbalances in blood plasma, we have investigated, through immunocytochemistry, SNAT2 expression in brain of rats subjected to systemic hypertonicity. Following prolonged systemic hypertonicity (24 h), small, strongly immunolabeled elements were observed that were not present in sham-treated animals. They were evenly distributed in the gray matter, with a lower density in the forebrain and a higher density in the brain stem. However the highest density by far was observed in white matter, where they were frequently aligned in chain-like rows. These observations suggested an oligodendrocyte location that was further established by double immunofluorescent labeling, using the oligodendrocyte phenotypic markers 2'-3'-cyclic nucleotide 3'phosphodiesterase and carbonic anhydrase II. SNAT2-positive elements were found associated with oligodendrocyte cell bodies, while oligodendrocyte processes were devoid of labeling. A quantitative analysis performed in the cerebral cortex indicated that virtually all SNAT2-positive elements were associated with oligodendrocyte cell bodies and conversely that the overwhelming majority of oligodendrocytes showed SNAT2 immunolabeling. The tonicity-induced expression of SNAT2 was not observed following acute systemic hypertonicity (6 h). Our results suggest that the osmoadaptation of brain oligodendrocytes to hypertonicity relies upon amino-acid accumulation through the tonicity-induced expression of SNAT2. The possible significance of these findings in relationship to the selective loss of oligodendrocytes observed in osmotic demyelination syndrome is discussed.

Antihyperglycemic activity of Arbutus unedo, Ammoides pusilla and Thymelaea hirsuta.

The effect of the water extract (WE) of three medicinal plants used as antidiabetic medication in Eastern Morocco (Arbutus unedo: Au, Ammoides pusilla: Ap and Thymelaea hirsuta: Th) was tested in rats with the Oral Glucose Tolerance Test (OGTT) and Intravenous Glucose Tolerance Test (IVGTT). In the OGTT the rats received water, glibenclamide (2 mg/kg) or WE (500 mg/kg for Au and 250 mg/kg for Th and Ap) 30 min before glucose loading (glucose: 1 g/kg). The WE of Au, Ap and Th produced a significant decrease in glycemia after glucose loading. In the IVGTT the WE of Ap and Th produced a significant decrease in glycemia 60 min after i.v. glucose loading (0.5 g/kg). The addition of the WE of Au (500 mg/kg), Ap or Th (250 mg/kg) induced a significant inhibition of jejunal glucose absorption, (31.6%, 28.5% and 40.5% respectively). This effect could explain in part the significant antihyperglycemic effect observed in the OGTT model but it does not exclude other effects on glucose homeostasis, particularly for Ap and Th. Toxicity tests (high LD50 value) suggest no adverse effect of the use of these plants.

Large discrepancies in cellular distribution of the tonicity-induced expression of osmoprotective genes and their regulatory transcription factor TonEBP in rat brain.

Osmoprotective genes are tonicity-activated genes involved in cellular osmoadaptation to hypertonicity and considered to be regulated by a specific transcription factor called tonicity-responsive enhancer-binding protein (TonEBP). In the brain we had previously established that TonEBP was expressed and tonicity-induced in neurons only. Here we have compared in various brain regions of rats subjected to systemic hypertonicity, the cellular expression of TonEBP through immunocytochemistry and the cellular expression of osmoprotective genes, namely aldose reductase (AR), sodium-dependent myo-inositol transporter (SMIT), betaine/GABA transporter (BGT1) and taurine transporter (TauT), by in situ hybridization using non-radioactive digoxigenin-labeled riboprobes. In neurons where TonEBP was strongly tonicity-induced, AR-mRNA labeling was strongly increased in some subsets (e.g. hippocampus pyramidal cells, cerebellar Purkinje cells and neurons of the hypothalamic magnocellular nuclei) but remained undetectable in some other subsets (e.g. neurons in cerebral cortex). Tonicity-induced AR-mRNA labeling was observed only several hours after the tonicity-induced expression of TonEBP. SMIT-mRNA labeling was tonicity-induced as densely and evenly distributed dots in neuron poor regions (e.g. cerebral cortex layer I and hippocampus stratum lacunosum-moleculare). The tonicity-induced expression of SMIT-mRNA may thus occur in non-neuronal cells, presumably astrocytes, where TonEBP is neither significantly expressed, nor tonicity-induced. In neurons showing a strong tonicity-induced expression of TonEBP, no SMIT-mRNA labeling was observed. BGT1-mRNA and TauT-mRNA labeling could not be detected, even after systemic hypertonicity. The present work reveals large discrepancies between the cellular distribution of the tonicity-induced expression of osmoprotective genes and that of their regulatory transactivator TonEBP. Depending on the cell subsets and the osmoprotective genes, TonEBP may appear insufficient or conversely unnecessary for the tonicity-induced activation of an osmoprotective gene. Altogether our results show that brain cells, even from the same class, activate distinct osmoprotective genes through distinct activation processes to adapt to hypertonicity.

Differential cellular distribution of tonicity-induced expression of transcription factor TonEBP in the rat brain following prolonged systemic hypertonicity.

In a previous work performed on cerebral cortex and hippocampus we reported that tonicity-responsive enhancer binding protein (TonEBP), originally identified as a transactivator of osmoprotective genes involved in osmoadaptation of renal cells, was induced in neurons only, but to varying levels, following acute systemic hypertonicity. Whether or not this cellular specificity reflected a unique ability of neurons or a differential time course among brain cells for tonicity-induction of TonEBP was investigated throughout the brain in this study by subjecting the animals to prolonged systemic hypertonicity. In normal rats, TonEBP immunolabeling and TonEBP-mRNA in situ hybridization labeling showed a widespread, uneven and parallel distribution. TonEBP was expressed primarily in the cell nuclei of neurons, where it was heterogeneously distributed in a nucleoplasmic and a granular pool. In rats subjected to prolonged systemic hypertonicity, TonEBP labeling increased in the cell nuclei of neurons only. The tonicity-induced expression of TonEBP for a given cell group of neurons was rather uniform but varied greatly among neuronal cell groups and was positively correlated with the average size of the cell nuclei, as determined by quantitative analysis of digitized images. The detailed distribution of tonicity-induced expression of TonEBP is reported throughout the brain. In normal rats, a very minor proportion of non-neuronal cells, identified as a subset of astrocytes and possibly oligodendrocytes, showed faint nuclear immunolabeling, which however did not increase in hypertonic animals. Ependymocytes, capillary endothelial cells, and microglial cells showed no TonEBP labeling, even in hypertonic animals. Altogether our data indicate that neurons, albeit possibly to a varying extent, are the only brain cells able to use TonEBP-mediated processes for adaptation to a systemic hyperosmotic unbalance.