The blockade of endothelin A receptor protects astrocytes against hypoxic injury: common effects of BQ-123 anderythropoietin on the rejuvenation of the astrocyte population

In the present study the role of endothelin (ET) and its receptors (ETA-R and ETB-R) in cellular mechanisms underlying the resistance of astroglial cells to low oxygen level and development of hypoxia has been investigated. To define the influences of ET and its receptors on survival and on antigenic as well as morphologic differentiation of rat astroglial cells in normoxic (NC) and hypoxic culture (HC) the selective antagonists of ETA-R (BQ-123) and ETB-R (BQ-788) were used. Treatment of HC with BQ-123 caused an increase in cell number and inhibited the hypoxia-induced apoptosis by 37%. BQ-123 decreased the hypoxia-induced cytotoxicity in HC. These effects of BQ-123 were abolished in cultures simultaneously treated with BQ-123 and BQ-788. Administration of BQ-788 alone decreased the number of living cells in NC, but not in HC. The activity of caspase-3/-7 was not changed by exposure of NC and HC to BQ-788. The protection provided by BQ-123 to astroglial cells against cytotoxicity in NC and HC was similar to that of erythropoietin (EPO), a cytokine with established neuroprotective effects. The functional improvement of astroglial cells and slowing down of their differentiation under exposure to BQ-123, or EPO, or BQ-123 + EPO has been evidenced by an increased number of nestin+/glial fibrillary acidic protein-positive (GFAP+) astrocytes accompanied by decrease of nestin-/GFAP+ cells. The simultaneous treatment with BQ-123 and EPO additionally decreased the activities of caspase-3/-7 (64%) and release of LDH into the medium (94%). The benefits in the functional states of astrocytes obtained by combined treatment of HC with BQ-123 and EPO suggest a new therapeutic strategy in treatment of hypoxic brain injury.     

POTENTIATION OF AMP-AMINOHYDROLASE ACTIVITY OF BRAIN MITOCHONDRIA BY HEXOKINASE

Abstract— The addition of hexokinase (yeast and brain) to mitochondrial fractions of brain (rat) resulted in a considerable increase of formation of ammonia from AMP. The mechanisms underlying the activation of AMP-aminohydrolase of brain mitochondria by ATP and hexokinase are quite different. In the activation of AMP-aminohydrolase by hexokinase the SH-groups of both enzymes particularly of the latter are of importance. Brain mitochondria contain low-molecular dialysable substances of unknown nature which are necessary for the interaction of both enzymes.     

Further similarities between astrocytes and perisinusoidal stellate cells of liver (Ito cells): Colocalization of desmin and glial fibrillary acidic protein in astroglial primary cultures

The colocalization of desmin and glial fibrillary acidic protein (GFAP) in astrocytes was inferred from previous studies demonstrating a unique antigenic composition comprising GFAP, desmin and vimentin in perisinusoidal stellate cells (PSC) of liver which share several features with astrocytes. In the present study the colocalization of GFAP and desmin was investigated by double-immunolabeling experiments in 12-day-old rat astroglial primary cultures with antiserum against GFAP and two commercial monoclonal antibodies against desmin, antibodies of clone DEU-10 and clone DEB-5. These antibodies selectively decorated the perisinusoidal stellate cells (PSC) of liver for which desmin is known to be a marker. The results obtained with astroglial cells demonstrate that both GFAP and desmin are coexpressed in morphologically different types, process-bearing and process-lacking astrocytes. The expression of desmin was apparently more pronounced in process-lacking astrocytes and was considerably lower in process-bearing ones. In process-lacking astrocytes, in contrast to filamentous cytoplasmic staining for GFAP, the immunoreactivity for desmin was non-filamentous and was irregularly spread in the perinuclear cytoplasm of the cells, while in process-bearing astrocytes the pattern of staining for desmin was similar to that of GFAP. The variability in the intensity and pattern of staining for desmin in astrocytes might be due to transitional stages of differentiation for part of the cells. This interpretation was supported by the presence of GFAP in the cells weakly expressing smooth muscle alpha-actin and the absence of GFAP in the cells enriched with microfilaments.     

ON THE MECHANISM OF STIMULATION OF AMP-AMINOHYDROLASE ACTIVITY BY HEXOKINASE IN BRAIN TISSUE

—A hexokinase has been isolated from brain tissue on Sephadex G-100 and DEAE cellulose which is similar to yeast enzyme in stimulating the AMP-aminohydrolase activity of rat brain soluble fractions. This effect of hexokinase is influenced neither by N-acetyl-glucosamine nor noradrenaline. An isoenzyme of hexokinase isolated from brain tissue on DEAE cellulose, having properties similar to that of the muscle enzyme, has no effect on AMP-aminohydrolase activity. The activating effect of yeast hexokinase is not due to its oligomeric structure. Enzyme subunits obtained by the treatment of native yeast enzyme by urea also activate AMP-aminohydrolase of rat brain soluble fractions.     

ON THE INVOLVEMENT OF INORGANIC IONS IN THE EFFECT OF γ-AMINOBUTYRIC ACID ON BRAIN SEROTONIN AND NOREPINEPHRINE

Abstract— The loss of GABA, norepinephrine and serotonin and the uptake of GABA (in the presence of 1 mM-GABA) and the effect of GABA on the loss of norepinephrine and serotonin were investigated in rat midbrain slices incubated in media of various compositions. In a medium of low Na⁺ concentration the loss of serotonin from incubated slices was markedly inhibited while that of norepinephrine and GABA was significantly increased. Conversely the most pronounced loss of serotonin from slices was observed on the addition of ouabain to a medium of a balanced ionic composition. Whereas the loss of serotonin from slices increased in a medium of high K⁺ content, it was significantly reduced after 45 min incubation in a high K⁺-low Na⁺ medium. In all the modified media used, a significant loss of norepinephrine was observed while that of GABA was not affected by the omission of Ca2⁺ and was slightly reduced in the absence of K⁺. GABA enhanced the loss of norepinephrine and inhibited that of serotonin in a high-K⁺ medium and in one with a balanced ionic composition. A deficiency of Na⁺ in the medium had a differential effect on the loss of norepinephrine and serotonin similar to that observed with 1 mM-GABA. These results suggest that Na⁺ may be of crucial importance in the release of serotonin from midbrain slices and that an enhancement of the Na+ extrusion mechanism at the synaptosomal level may be involved in the effect of GABA on brain monoamines.     

Dynamics of glial fibrillary acidic protein distribution in cultured glomerular podocytes and mesangial cells of the rat kidney

Glial fibrillary acidic protein (GFAP) has recently been shown to be expressed in the glomerular podocytes and mesangial cells (MC) of kidney (Buniatian et al (1998) Biol Cell 90, 53-61). The different localization of GFAP in podocytes and MC has raised the question whether this might reflect specific cellular functions. To address this question, in the present study podocytes and MC in early (2, 3 day-old), prolonged (5, 7 day-old) and late (14, 21 day-old) primary cultures from out-growths of glomerular explants were used. Double-immunolabeling studies demonstrated that podocytes transiently acquire myofibroblastic features, characterized by the expression of smooth muscle alpha-actin (SMAA) and increased perinuclear reaction of GFAP in prolonged cultures. The morphological differentiation of cobblestone-like podocytes into process-bearing cells was followed by loss of the myofibroblastic marker, SMAA, de novo expression of desmin, and distribution of GFAP, vimentin and desmin into the processes. In late culture, GFAP and SMAA were nearly absent from the podocytes which maintained the cobblestone-like morphology. By contrast, the myofibroblastic features gained by MC during prolonged culturing increased with time. A myofibroblast-like cytoskeleton of podocytes and MC similar to that of healthy astrocytes suggest an increased spectrum of functional activities of these cells during the acquisition of myofibroblastic features. In addition, the present study provides a new combination of biochemical and biological features by which podocytes and MC can be distinguished in culture.     

Similar protective effects of BQ-123 and erythropoietin on survival of neural cells and generation of neurons upon hypoxic injury

Our recent study [Danielyan et al., 2005. Eur. J. Cell Biol. 84, 567-579] showed an additive protective effect of endothelin (ET) receptor A (ETA-R) blockade and erythropoietin (EPO) on the survival and rejuvenation of rat astroglial cells exposed to hypoxia. Whether the effects observed with rodent astroglial cells can be reproduced in human astrocytes and whether these effects of ETA-R blockade and EPO on astrocytes are associated with neuronal survival remained open. Therefore, in the present study, the effects of the ETA-R antagonist BQ-123 and EPO on the maintenance of the neuronal population and survival of the human fetal astroglial cell line (SV-FHAS) under normoxic and hypoxic conditions (NC and HC, respectively) were investigated. Rat brain primary cultures exposed to BQ-123 and/or EPO revealed an increase in the number of beta-III tubulin-positive neurons under NC. The hypoxia-caused loss of neurons was abolished by administration of BQ-123 or EPO. Simultaneous application of EPO and BQ-123 led to an additive protective effect on the generation of neurons under NC only. By contrast, BQ-788, the selective ETB-R antagonist, diminished the neuronal population both in NC and HC. Both under NC and HC the number of non-differentiated nestin+/GFAP- neural cells increased upon application of EPO or BQ-123. SV-FHAS responded to BQ-123 or EPO by a decrease in LDH activity in the culture medium under NC (35%) and HC (26% LDH decrease). Concomitant effects of EPO and BQ-123 were illustrated in an additional increase in the survival of human astrocytes (33% under NC and 17% under HC). These data hint at a neuroprotective therapeutic potency of ETA-R blockade, which either alone or in combination with EPO may improve the survival of astroglial and neuronal cells upon hypoxic injury.     

Stages of activation of hepatic stellate cells: effects of ellagic acid, an inhibiter of liver fibrosis, on their differentiation in culture

To further explore that hepatic stellate cell (HSC) activation results in physiological protection against environmental insult, the profile of differentiation of HSC has been examined upon treatment with ellagic acid (EA), a plant-derived antioxidant that shows multiple protective effects during liver disease. Sparse rat liver cell cultures were grown in media containing EA (3, 6, 30 and 100 microg/ml) and, as controls, without EA, and inspected until day 7 in culture. The cells were double-labelled with antibodies against glial fibrillary acidic protein (GFAP) and smooth muscle alpha-actin (SMAA), marker proteins of quiescent and activated HSC, respectively. In EA-free culture conditions, the quiescent (SMAA-/GFAP+) HSC transiently acquired a semi-activated (SMAA+/GFAP+), phenotype and were further transformed into activated (SMAA+/GFAP-), pleomorphic HSC. Up to a concentration of 30 microg/ml, EA induced an early synthesis of SMAA in all HSC and inhibited their morphologic differentiation and individual growth throughout the culture period. At a concentration of 6 microg/ml, EA supported the semi-activated (SMAA+/GFAP+) phenotype of HSC throughout the culture period, whereas treatment with high EA concentrations (30 microg/ml) resulted in an early loss of GFAP expression. In conclusion: (i) the uniform response of HSC to EA by mild activation adds functional significance to cellular features preceding the transformation of HSC to myofibroblasts; (ii) the high sensitivity of HSC to EA treatment suggests their involvement in any mechanisms of protection by this antioxidant; (iii) the maintenance of HSC morphology might be one of the factors playing a role in the prevention or slowing down of liver fibrosis; (iv) because the effects of EA are concentration- and time-dependent, an arbitrary usage of this antioxidant is a matter of potential concern; (v) the various patterns of HSC activation observed might correspond to distinct activities of these cells, which, in turn, might lead to different outcomes of liver fibrosis.     

EFFECT OF γ-AMINOBUTYRIC ACID ON BRAIN SEROTONIN AND CATECHOLAMINES

—Intraperitoneal injections of GABA (5 mg/kg) to rats lowered the level of norepinephrine in brain, heart and spleen but not suprarenals and raised that of serotonin in brain. Changes of these monoamines were most pronounced in the hypothalamic region after 20min. A reduction of hypothalamic norepinephrine was also observed 15min following the intracarotid administration of 0·5 mg/kg of GABA. In these experiments there was a concomitant increase in the level of free GABA in the anterior portion of the ventral hypothalamus. Brain dopamine level and 5-hydroxytryptophan decarboxylase, dihydroxyphenylalanine decarboxylase and monoamine oxidase activities were not affected. The 20 per cent increase of endogenous GABA observed in the midbrain 30 min following the administration of amino-oxyacetic acid was accompanied by a sharp fall in norepinephrine level (39 per cent) and an increase in serotonin (20 per cent). In in vitro studies 10–300 μg/ml of GABA were shown to release norepinephrine from cortical and hypothalamic slices, and to inhibit serotonin release without affecting 5-hydroxytryptophan uptake and to have no effect on the release of dopamine from slices of the region of the corpus striatum nor on the activity of the enzymes mentioned. Subcellular studies showed that the particulate:supernatant ratio for norepinephrine was reduced from a control value of 2·04 to 1·75 and that of serotonin was raised from 2·8 to 3·5. Following pretreatment with iproniazid, GABA reduced the raised level of brain norepinephrine to a greater extent than reserpine but not as intensively as amphetamine. The results obtained suggest that these monoamines may be involved in the mechanisms underlying the action of GABA in brain and that the effect of GABA on brain monoamines may be of certain significance in synaptic events.