Effects of arginine vasopressin and atriopeptin on chloride uptake in cultured astroglia.

Ion and water homeostasis in the CNS is subjected to a neuroendocrine control exerted by neuropeptides formed within the brain. In order to gain information on this neuroendocrine control of Cl- homeostasis, 36Cl- uptake was measured in cultured Type-I astrocytes exposed to the neuropeptides [Arg8]Vasopressin (AVP), and atriopeptin (AP) and to various Cl- transport modifiers. AVP increased while AP decreased 36Cl- uptake of cultured astrocytes in a dose-dependent manner. Both effects became statistically significant at greater than 10(-9) M concentration of the peptides. For the appearance of the effects at least 30-min exposure was necessary. AVP and AP extinguished each other's effect by almost stochiometric manner. When administered together with AVP, the VIA vasopressin receptor antagonist "Manning compound" inhibited, while V2 vasopressin receptor agonist did not influence the 36Cl- uptake-increasing effect of AVP. However, bumetanide, a specific inhibitor of Na+-K+-2Cl- cotransport, inhibited the effect of vasopressin and also inhibited the 36Cl- uptake of AVP non-treated, control cells. Our findings suggest that brain Cl- homeostasis is controlled by neuroendocrine system in the CNS.

A putative tetrapeptide antagonist prevents beta-amyloid-induced long-term elevation of [Ca2+]i in rat astrocytes.

Comparative fluorimetric studies on the long-term (8-hour) action of beta[1-42]amyloid and its shorter fragments beta[1-40], beta[25-35] and beta[31-35] on the steady-state intracellular Ca2+ concentration in primary cultures of rat astroglial cells using the Ca2+-sensitive fluorescent probe Fura-2 AM revealed higher 340/380 fluorescence excitation ratios in the treated cells as compared to the untreated controls. All the peptides were found to induce similar cellular effects, suggesting the [31-35] region as the putative active centre of the molecule. No significant alteration was detectable in Fura-2 fluorescence using the Ca2+-insensitive excitation wavelength of 367 nm, indicating that the observed changes reflect a real alteration in the Ca2+ concentration of the cells. Moreover, no considerable difference was observed in the total protein content of treated and untreated cells. Co-treatment of the cells with Pr-Ile-Ile-Gly-Leu-NH2 (Pr-IIGL) peptide, an analogue of the [31-34] region of beta[1-42]-amyloid, was found to effectively antagonize the beta[1-42]-amyloid-induced elevation of the fluorescence excitation ratio, leaving the 367-nm fluorescence unaffected. To the best of the authors' knowledge, this is the first report on an analogue of beta-amyloid peptide capable of blocking one of its physiological effects, thereby raising the possibility that this sequence could prove to be a lead compound for designing effective beta-amyloid antagonists.

Intracellular free Ca2+ elevations in cultured astroglia induced by neuroligands playing a role in cerebral ischemia.

For better understanding of glial participation in cerebral ischemia, spectrofluorimetric analysis using the calcium indicator Fura-2AM was applied to examine the role of intracellular free Ca2+ ([Ca2+])i elevation induced by different neuroactive substances in cultured rat brain astrocytes. The activation by the general receptor agonist glutamate resulted in a biphasic cell response in [Ca2+]i. We couldn't observe N-methyl-D-aspartate-evoked [Ca2+]i response at all. Quisqualate triggered a complex [Ca2+]i response in astrocytes consisting of mobilization of Ca2+ from the intracellular stores and also Ca2+ influx from the extracellular space. Kainate elicited a markedly different Ca2+ signal an external Ca(2+)-dependent sustained [Ca2+]i rise resulting from the activation of the ionotropic glutamate receptor. According to our results two types of glutamate receptors, the quisqualate-specific metabotropic and kainate-specific ionotropic receptor, are involved in [Ca2+]i elevation in these cultures. We could monitor agonist-specific cell response to noradrenaline, serotonin, vasopressin and ATP as well in these cultured rat astrocytes.

Effects of arginine vasopressin and atriopeptin on glial cell volume measured as 3-MG space.

This study evaluates the hypothesis that arginine vasopressin (AVP) and atriopeptin, peptide hormones synthesized and released within the brain, are regulators of brain cell volume using cultured astroglial cells derived from newborn rats. Cell water content, regarded as volume, was measured in defined, serum-free medium as the 3-O-methylglucose (3-MG) space. Initial experiments established conditions such that glucose, which competes with 3-MG for the glucose carrier, would not interfere with the measurement of the 3-MG space. AVP increased the 3-MG space of glial cells by an average of 25% between 30 and 120 min of exposure, whereas atriopeptin decreased it by 32%. The 3-MG space remained close to normal after coadministration of both peptides. The AVP-dependent increase in 3-MG space was blocked both by the V1 antagonist d(CH2)5Tyr(Me)AVP (Manning compound) and by the cotransport inhibitor, bumetanide. Results are consistent with a role for AVP and atriopeptin in the homeostasis of atroglial cell volume.

Sodium and potassium uptake in primary cultures of rat astroglial cells induced by long-term exposure to the basic astroglial growth factor (AGF2).

Astroglial cell cultures were derived from newborn rat forebrain and cultured for 5 days in serum containing-, and for an additional 4 days in a serum-free, defined medium. At the end of this 9-day-long period, basic astroglial growth factor (AGF2) was administered to the culture medium (10 ng per ml). Cells were subsequently cultured in AGF2 containing serum-free, defined medium for further two weeks. At definite intervals of culturing, unidirectional influx of both Na+ and K+ (INa and IK, respectively) was determined by applying 22Na and 42K. The AGF2-treated cultures showed highly increased, amiloride-sensitive INa at the early exposure period (2-8 hours), similar to that we have reported about cultured astroglia exposed to AGF2 for minutes. They also exhibited significant furosemide-sensitive-, while relatively poor ouabain-sensitive component of INa. However, at later periods of exposure to AGF2, INa was significantly reduced, particularly due to the decrease of its amiloride-sensitive component, while its furosemide-sensitive component further increased with the time of AGF2 treatment. In contrast to INa, the IK in the cultures exposed to AGF2 increased significantly in the course of the long-term exposure period, particularly the ouabain-, and furosemide-sensitive-components, while its amiloride-sensitive component, similarly to that of INa, decreased.(ABSTRACT TRUNCATED AT 250 WORDS)

Sodium and potassium uptake in primary cultures of proliferating rat astroglial cells induced by short-term exposure to an astroglial growth factor.

Primary cultures of rat astroglial cells were maintained in a serum-free medium. After 8-10 days of cultivation the cells were exposed to an astroglial growth factor (AGF2) for short periods (1-120 min). Subsequently, uptake of 22Na+ and 42K+ into control and AGF2-pretreated cells was studied. Assay of the Na+ and K+ values in the cells was also performed by atomic absorption spectrometry. Treatment of rat astroglial cells with AGF2 resulted in a significant increase of the uptake of both Na+ and K+ depending on the duration of the exposure period. To reach the maximum increase of cation uptake, 6-10 min and 30 min of AGF2 pretreatment were needed for Na+ and K+, respectively. Amiloride blocked this increase of Na+ and K+ uptake elicited by AGF2 pretreatment, but the control cells were amiloride resistant. Treatment with AGF2 increased the ouabain sensitivity of the K+ uptake as that: 10(-4) M ouabain inhibited K+ uptake of the AGF2-treated cells to the same degree as 5 X 10(-3) M ouabain with the control cells. The Na+ uptake of AGF2-treated cells, however, exhibited no relevant changes in the presence of ouabain. A significant part of the AGF2-induced K+ uptake could be inhibited by both ouabain and amiloride, but a ouabain-resistant and amiloride-sensitive component also was revealed. The furosemide sensitivity of both Na+ and K+ uptake into cultured astroglial cells was also significantly increased by AGF2. Our findings suggest that short-term exposure of cultured glial cells to AGF2 induces these very early ionic events: 1) The appearance of a relevant amiloride-sensitive Na+/H+ exchange, and as a consequence of increased Na+ entry into the cells, secondary activation of the ouabain-sensitive K+ uptake via the Na+,K+-pump. 2) A direct effect of AGF2 on the Na+,K+-pump assembly in the membrane, resulting in increased Na+ sensitivity of the inner pump sites and enhanced ouabain sensitivity of the external K+-binding sites. 3) An increase of ouabain-resistant but amiloride- or furosemide-sensitive Na+ and K+ uptake.

Changes in medium radioactivity and composition accompany high-affinity uptake of glutamate and aspartate by mouse brain slices.

In measurements of high affinity transport in tissue slices, the incubation medium is often treated as an "infinitely large pool". External substrate concentrations, even at the micromolar level, are assumed to be constant and metabolic interactions between tissue and medium are neglected. In the present report we describe experiments in which glutamic and aspartic acid uptake by mouse brain slices were studied using techniques that could test these assumptions. Cerebral hemispheres were cut into 0.1 mm sections and about 90 mg of tissue incubated in 10 ml of oxygenated medium. After 45 minutes of equilibration, radioactive substrates were added and the concentrations and specific activities of the amino acids and their metabolites in the medium were determined. During the first 10 min following substrate addition, rapid decreases in glutamic and aspartic acid concentrations in the medium were accompanied by large decreases in specific activity caused by the continuous release of these amino acids from the tissue. In addition, extensive conversion of both substrates to glutamine and the preferential accumulation of this metabolite, in the medium, was found. These results demonstrate that metabolism and release occur simultaneously with uptake during transport experiments in vitro and that these processes can take place in specific tissue compartments. It is therefore necessary to measure the tissue and medium concentration levels of amino acids along with their radioactivity in such experiments, since all three processes (transport, metabolism, and compartmentation) are interrelated in the clearance of amino acids from the incubation medium and probably from the extracellular spaces in vivo as well.

Manifestation of K+ transport alterations in cultured tumour cells of mice.

Sarcoma was induced by injection of human adenovirus type 12 into newborn, isogeneic CBA mice and maintained in adult female CBA mice by serial passages. Cells obtained from the tumours were cultivated by 3-4 passages in vitro. Normal fibroblastic cell cultures were gained by the same manner from isogeneic CBA mouse embryos. Characteristics of potassium transport in cultures of malignant cells and of normal fibroblastic cells were analysed. As a chemical tracer of K+ movements, 86Rb+ was applied. No significant difference could be detected either in the potassium concentration, or in the 86Rb+ uptake of the two types of cultured cells. However, when the cells were exposed to ouabain, the malignant cells showed a significantly reduced response, thus, the malignant cells accomplished a much less decrease in either cellular potassium concentration or in that of 86Rb+ uptake rate than the normal cells. These findings well fit the hypothesis advanced by several authors that malignant cells have a reduced density of ouabain receptor on the membrane.

Control of cation transport in cultured glial cells by external Ca++: a possible signal in glial-neuronal interaction.

In cultured glial cells from chick embryonic brain, both influx and efflux of 42K+ and 22Na+ are dependent on the external Ca++ and concentration ([Ca++]0) between 2 and 0.1 mM although intracellular concentrations of K+ ([K+]i) and Na+ ([Na+]i) do not change. Only a reduction of [Ca++]0 below 0.1 mM results in both a decrease of [K+]i and an increase of [Na+]i. Ouabain significantly decreases the [Ca++]0 sensitivity of uphill cation movements (K+ influx and Na+ efflux), while the [Ca++]0 sensitivity of downhill cation movements (K+ efflux and Na+ influx) is almost not affected by the presence of ouabain. Additionally, a decrease in [Ca++]0 triggers an increase in intracellular concentration of adenosine 3':5'-cyclic monophosphoric acid (cAMP). These findings suggest that changes of [Ca++]0, which take place in vivo in the microenvironment of the glia after neuronal firing, represent a signal in the glial-neuronal interaction controlling cation transport and that this control is achieved by a co-operation between the cAMP-generating and the cation transport system.

Na-dependent Li-transport in primary nerve cell cultures.

Primary cultures from chick embryonic brain were used to study the steady state distribution of lithium. The intra/extracellular Li+ ratio decreased by enhancing the external Na+ concentration. Ouabain did not influence this unequality. A phloretin-sensitive component was revealed in the Li uptake at low Na+ concentration. The findings might suggest the existence of a Na+-dependent Li+ countertransport system in these brain cell cultures.

Cell-to-cell contacts in primary cultures of dissociated chicken embryonic brain.

The fine structure of intercellular contacts was studied in primary cultures prepared from chicken embryonic brain. Desmosomes were frequently seen between the glial cells. Synaptic contacts were observed among neuronal cell bodies and neural processes after 8 days in vitro. Gap junctions were revealed between glial elements suggesting a functional role in direct cell communication and providing a morphological basis for previous observations on potassium transport in cultures of dissociated brain cells.

Neuronal cells from chick embryo cerebral hemispheres cultivated on polylysine-coated surfaces.

Dissociated cells from 5- to 12-day-old chick embryo cerebral hemispheres were cultivated in polylysine-coated plastic Petri dishes. The polylysine substrate was observed to be favorable for the growth of neuronal cells, whereas glioblast proliferation was inhibited. The optimal conditions for the production of a predominantly neuronal culture were to use cerebral hemispheres from 7-day-old chick embryos, to dissociate the brain tissue mechanically and to seed the cells at a concentration range between 1.5 and 5 X 10(6) cells/ml. The cultures were observed by phase contrast microscopy. Most cells grew fibers and differentiated into bipolar and multipolar neurons. These neurons were stained by thionine, which demonstrated the presence of Nissl bodies. The silver impregnation revealed the presence of neurofibrils within the nerve fibers. Acetylcholinesterase was found to be present in the neuronal cells, but absent in the glioblasts. Under our culture conditions the neurons survived for 10-12 days. This system should allow further studies on the effects of growth factors on the differentiation of isolated neurons as well as investigations on neuron-glial interrelationship.

Comparison of turnover rates of proteins of the brain, liver and kidney in mouse in vivo following long term labeling.

Intraperitoneal injection of [14C]tyrosine suspension followed by subcutaneous implantation of a [14C]tyrosine pellet in mice produced a fairly constant specific activity of plasma free tyrosine for 5 days, and for 3-5 days in the tissue free amino acid pool. The specific activity of tyrosine in the tissue (brain, liver, and kidney) free amino acid pool was 75-90% of that in plasma. Incorporation of tyrosine into tissue proteins was followed for 5 days in brain; during this time 33% of tissue proteins were labeled. Incorporation for 68 h in liver and kidney showed labeling of over 70% of the protein of these tissues. These percentages assume a homogeneous tissue free tyrosine pool as the precursor. The rate of incorporation initially was 0.6, 2.8, and 2.0% per h in brain, liver, and kidney protein, respectively. These rates decreased in longer term experiments. The best fit to the incorporation curves was obtained by assuming the following average half-lives for tissue proteins: brain, two compartments, 5.7% with a half-life of 15 h, 94.3% with a half-life of 10 days; liver, a single compartment with a 26-h half-life; kidney, two compartments, 41% with an 18-h half-life, and 59% with a 63-h half-life.