Paradoxical sleep deprivation increases glutamine synthetase in rat brain.

The modifications of glutamine synthetase (GS) level, an enzyme mainly located in astrocytes, were investigated in rat after paradoxical sleep deprivation and during recovery. An immunotitration method was used to evaluate the relative level of GS in brain tissue. At the end of a 24 hrs. paradoxical sleep deprivation, a significant increase in GS level was observed both in the frontoparietal cortex and the locus coeruleus area. 4 hrs. later, during recovery, the GS level returned to control level in the cortex but was lower in the locus coeruleus area.     

A radiochemical assay for glutamine synthetase, and activity of the enzyme in rat tissues

1. A radiochemical assay for glutamine synthetase has been developed in which an ATP-regenerating system is incorporated to prevent accumulation of inhibitory amounts of ADP. It is particularly suitable for assay of the enzyme in crude tissue extracts containing high adenosine triphosphatase activity. 2. A survey of the distribution of the enzyme in tissues from normal male rats showed that activity is present in liver, brain cortex, kidney cortex, spleen, testis and retina. 3. The K(m) of the enzyme for l-glutamate is approx. 1.5x10(-2)m.     

Distribution of glutamine synthetase in the rat central nervous system.

The results of a light microscopic immunohistochemical study of glutamine synthetase in rat nervous system are presented. In all sites studied the enzyme was confined to astrocytes. Except for trace amounts in ependymal cells, the enzyme was not observed in other cells of the nervous system including neurons, choroid plexus, third ventricular tanycytes, subependymal cells and mesodermally-derived elements. The intensity of astrocyte staining varied in different regions with the greatest degree noted in the hippocampus and cerebellar cortex while the least was noted in brain stem, deep cerebellar nuclei and spinal cord. The glutamine synthetase content correlated well with sites of suspected glutamergic activity in keeping with the view of a critical role of astrocytes in the regulation of the putative neurotransmitter glutamic acid.     

Possible growth hormone regulation of rat liver glutamine synthetase activity.

Hypophysectomy results in a marked decrease in glutamine synthetase activity of rat liver homogenates. The enzyme is affected to a lesser extent in the kidneys and is not influenced in the brain. Bovine growth hormone treatment of hypophysectomized rats elevates the diminished glutamine synthetase activity in liver and kidneys but has no effect on the brain enzyme. Adrenalectomy also results in decreased liver glutamine synthetase activity although less than the decline seen with hypophysectomy. Cortisol treatment has no effect on glutamine synthetase activity in hypophysectomized animals. Our results suggest that growth hormone is involved in the regulation of liver glutamine synthetase activity. This regulation may be important in the utilization of α-amino nitrogen from glucogenic amino acids associated with growth hormone enhanced glucose production.     

Regulation of glutamine synthetase. VI. Interactions of inhibitors for Bacillus licheniformis glutamine synthetase

The relationships of five feedback inhibitors for the Bacillus licheniformis glutamine synthetase were investigated. The inhibitors were distinguishable by differences in their competitive relationship for the substrates of the enzyme. Mixtures of l-glutamine and adenosine-5'-monophosphate (AMP) or histidine and AMP caused synergistic inhibition of glutamine synthesis. Histidine, alanine, and glycine acted antagonistically toward the l-glutamine inhibition. Alanine acted antagonistically toward the glycine and histidine inhibitions. Independence of inhibitory action was observed with the other pairs of effectors. Possible mechanisms by which the inhibitors may interact to control glutamine synthesis are discussed. The low rate of catalysis of the glutamyl transfer reaction by the B. licheniformis glutamine synthetase can be attributed to the fact that l-glutamine serves both as a substrate and an inhibitor for the enzyme. Effectors which act antagonistically toward the l-glutamine inhibition stimulated glutamotransferase activity. The stimulation was not observed when d-glutamine was used as substrate for the glutamyl transfer reaction.     

Selection of a rat glutamine synthetase cDNA clone

We have selected a glutamine synthetase clone (pGSRK-1) from a rat kidney cDNA library. A partial restriction map has been constructed for the 1.65 kilobase pair (kbp) glutamine synthetase cDNA. Northern hybridization analysis indicates that 1) GS-specific RNA increases many-fold during adipocyte differentiation and 2) dexamethasone increases and insulin decreases GS-specific RNA in 3T3-L1 adipocytes.     

Expression of glutamine synthetase in macrophages.

We studied the expression of glutamine synthetase in liver macrophages (Kupffer cells, KCs) in situ and in culture. Glutamine synthetase was detectable at the mRNA and protein level in freshly isolated and short-term-cultured rat liver macrophages. Enzyme activity and protein content were about 9% of that in liver parenchymal cells. In contrast, glutamine synthetase mRNA levels in liver macrophages apparently exceeded those in parenchymal liver cells (PCs). By use of confocal laser scanning microscopy and specific macrophage markers, immunoreactive glutamine synthetase was localized to macrophages in normal rat liver and normal human liver in situ. All liver macrophages stained positive for glutamine synthetase. In addition, macrophages in rat pancreas contained immunoreactive glutamine synthetase, whereas glutamine synthetase was not detectable at the mRNA and protein level in blood monocytes and RAW 264.7 mouse macrophages. No significant amounts of glutamine synthetase were found in isolated rat liver sinusoidal endothelial cells (SECs). The data suggest a constitutive expression of glutamine synthetase not only, as previously believed, in perivenous liver parenchymal cells but also in resident liver macrophages.     

The location of glutamine synthetase within the rat and rabbit nephron.

Glutamine synthetase (EC 6.3.1.2) was measured in seven different parts of the nephron in the rat and five in the rabbit, dissected from freeze-dried microtome slices. In the rat the enzyme is essentially confined to the proximal straight tubule. Acidosis did not change the activity; methionine sulfoximine abolished it. In the rabbit the enzyme is high in both proximal convoluted and straight tubules. Assays were made with a new method which measures glutamine formation $\text{per se}$. One of the products, NADH, is amplified by enzymatic cycling to provide sufficient sensitivity (2–10 pmol of glutamine).     

Heterogeneous distribution of glutamine synthetase during rat liver development

Two days before birth, immunohistochemical detection of glutamine synthetase already reveals a heterogeneous distribution pattern related to the vascular architecture of the liver. Only a small number of hepatocytes in the vicinity of the efferent venules show relatively high staining intensity. Before that age, only megakaryocytes show intense staining, while liver parenchyma is only faintly stained. The developmental profile of glutamine synthetase activity shows two periods of increasing enzyme activity: one in the perinatal period and one in the second and third postnatal week. Both periods are correlated with high levels of circulating corticosteroid hormones. Although the relative number of intensely stained hepatocytes increases during the first rise in enzyme activity, the second rise is correlated with a decreasing number of glutamine synthetase-positive hepatocytes which, however, show a considerable increase in staining intensity. Carbamoylphosphate synthetase shows a homogeneous distribution pattern in the perinatal period. Conditions that lead during development to a relatively high level of glutamine synthetase expression in the pericentral compartment apparently originate before the appearance of conditions that lead to a relatively high level of carbamoylphosphate synthetase gene expression in the periportal compartment. Our results indicate that downstream localization of glutamine synthetase in liver acinus is essential from the perinatal period onwards, whereas reciprocal distribution of glutamine synthetase and carbamoylphosphate synthetase gene expression (that is found in adult rat liver) is not.