pH regulation after acid load in primary cultures of mouse astrocytes

Intracellular pH (pHi) recovery in primary cultures of mouse astrocytes after acid-loading was studied with the ion transport inhibitors (amiloride, SITS, acetazolamide, ouabain and bumetanide), and by reducing the concentration of Na+ or Cl- in HCO3- -free HEPES-buffered (HEPES) and in HCO3-/CO2 Hanks' balanced salt solution (HBSS). The pHi of astrocytes exposed to 15 mM NH4Cl decreased abruptly and began to recover slowly after 5 min. Exposure of the cells to NH4Cl for 2 min and reincubation in HEPES HBSS decreased pHi further within 1-2 min after removal of NH4Cl; pHi then recovered toward the control value. Cultures exposed to HCO3-/CO2 HBSS (10 mM/2%) showed changes in pHi in the opposite direction. These responses are unique to astrocytes and differ from those occurring in most other cells. Recovery of pHi after NH4Cl prepulse was markedly inhibited in low-Na+ and in amiloride-containing HEPES HBSS. Ouabain also reduced pHi recovery rate; however, SITS, acetazolamide and bumetanide did not. Therefore, Na(+)-H+ exchange is the major process for pHi recovery from acidification in HCO3- -free solution. In HCO3-/CO2 HBSS pHi recovery was markedly inhibited by SITS and acetazolamide, but not by amiloride, ouabain, or bumetanide. The inhibitory effect of SITS on pHi recovery was enhanced in low-Na+ HBSS. These results indicate that both Na+ and HCO3- are directly related to pHi recovery in HCO3-/CO2 solution after acid-load. Low-Cl HEPES HBSS and low-Cl HCO3-/CO2 HBSS media did not alter pH recovery rate. Thus, pHi recovery after acid-load is not Cl- -dependent, and therefore, does not involve a Na(+)-dependent Cl- -HCO3- exchange process. It appears that mouse astrocytes possess 3 acid-regulating systems: Na(+)-H+ exchange, Na(+)-HCO3- co-transport and Na(+)-independent Cl- -HCO3- exchange.     

Astrocytes fail to regulate intracellular pH at moderately reduced extracellular pH.

Microspectrofluorometry was used to study the regulation of intracellular pH (pHi) in 2'-7'-bis (carboxyethyl-)-5,6-carboxyfluorescein (BCECF)-loaded astrocytes. They rapidly regulated an acid transient induced by an NH4+ prepulse. This back regulation was blocked by removal of Na+, or by addition of amiloride, but was also inhibited when extracellular pH (pHe) was lowered. Furthermore, when cells were exposed to HEPES buffer with reduced or increased pHe, pHi changed in parallel. Thus, although the cells possess an efficient H+ extrusion mechanism they fail to regulate pHi to a normal value unless pHe is held constant. The results challenge the concept of a H+ regulatory site at the internal side of the exchanger regulating pHi to a constant value.     

Studies on pH Regulatory Mechanisms in Cultured Astrocytes of DBA and C57 Mice

pH regulatory mechanisms in primary cultures of astrocytes from the cerebral cortex of neonatal audiogenic-seizure-susceptible DBA/2J (DBA) and genetically controlled C57BL/6J (C57) mice were studied with [14C]dimethyloxazolidine-2-4-dione (DMO) and [3H]-methyl-D-glucose (MDG). Effects of changing the concentration of Na+, K+, HCO3- or Cl- in medium, and/or of different transport blockers and metabolite inhibitor on intracellular pH (pHi) of cultured astrocytes were also studied. In nominal HCO3(-)-free HEPES-buffered Hanks' balanced salt solution (HEPES HBSS), when the pH of medium (pHo) was maintained at 7.4, the steady-state pHi of cultured astrocytes from DBA mice was 6.98 +/- 0.03, and that from C57 mice was 7.01 +/- 0.03. When the cells were incubated in HBSS containing 25 mM HCO3- and equilibrated with 5% CO2 (HCO3- HBSS, pHo = 7.4), pHi of both DBA and C57 astrocytes was approximately 0.1-0.15 pH units higher than that in HEPES HBSS. Reducing the pH or the Na+ concentration in media (pHo, [Na+]o) of either HEPES HBSS or HCO3- HBSS, pHi of both DBA and C57 astrocytes decreased markedly (0.25-0.45 pH units lower than the controls). The decrease in pHi was greater in HEPES HBSS than in HCO3- HBSS. Reducing the Cl- concentration ([Cl-]o) in either HEPES or HCO3- HBSS, pHi of astrocytes increased by 0.05-0.1 pH units. Increasing the K+ concentration ([K+]o) of or adding Ba2+ to the media increased the pHi of both DBA and C57 astrocytes accordingly. SITS, an anion transport inhibitor, decreased the pHi of both DBA and C57 astrocytes in HCO3- HBSS but not in HEPES HBSS. It enhanced the response of pHi to reduction in pHo. Amiloride, a Na(+)-H+ exchange inhibitor, decreased the pHi of both DBA and C57 astrocytes more in HEPES HBSS than in HCO3- HBSS. It enhanced the response of pHi to reduction in pHo and [Na+]o. Ouabain, an Na+,K(+)-ATPase inhibitor, decreased the pHi of cultured astrocytes in HEPES HBSS, but not in HCO3- HBSS. It also enhanced the response of pHi to changing pHo and [Na+]o in HEPES HBSS. Acetazolamide, a carbonic anhydrase inhibitor, decreased the pHi of astrocytes in both HEPES and HCO3- HBSS. Both bumetanide, an Na+,K+/Cl- cotransport blocker, and KCN, a metabolic inhibitor, produced no significant effect on the steady-state pHi or the response of pHi to changing ionic concentration in media in both DBA and C57 astrocytes.     

Mechanisms of pH recovery from intracellular acid loads in the leech connective glial cell.

We used double-barrelled, neutral carrier, pH-sensitive microelectrodes to study the mechanisms by which the intracellular pH (pHi) is regulated in the connective glial cells of the medicinal leech. In HEPES-buffered, nominally CO2/HCO3(-)-free solutions the recovery of pHi from intracellular acidosis is Na(+)-dependent and reduced by at least half in the presence of amiloride, suggesting the action of Na+:H+ exchange. The rate of pHi recovery by this mechanism can be increased by raising the extracellular buffering power or by increasing extracellular pH. The presence of CO2/HCO3(-)-greatly increases the rate of pHi recovery from intracellular acidosis. This CO2/HCO3(-)-stimulated recovery is also dependent on external Na+, largely Cl(-)-independent, inhibited by DIDS, and accompanied by membrane hyperpolarization. This is consistent with it being mediated by the electrogenic cotransport of Na+ and HCO3- into the cells. A Cl(-)-dependent component to Na(+)- and HCO3(-)-dependent regulation is most easily explained by the added presence of a Na(+)-dependent exchange of HCO3- and Cl-.     

Sodium-bicarbonate cotransport in retinal Müller (glial) cells of the salamander.

An electrogenic Na+/HCO3- cotransport system was studied in freshly dissociated Müller cells of the salamander retina. Cotransporter currents were recorded from isolated cells using the whole-cell, voltage-clamp technique following the block of K+ conductance with external Ba2+ and internal Cs+. At constant pHo, an outward current was evoked when extracellular HCO3- concentration was raised by pressure ejecting a HCO3(-)-buffered solution onto the surface of cells bathed in nominally HCO3(-)-free solution. The HCO3(-)-evoked outward current was reduced to 4.4% of control by 0.5 mM DIDS (4,4'-diisothiocyanatostilbene-2,2'-disulfonate), to 28.8% of control by 2 mM DNDS (4,4'-dinitrostilbene-2,2'-disulfonate), and to 28.4% of control by 2 mM harmaline. Substitution of choline for Na+ in bath and ejection solutions reduced the response to 1.3% of control. Bicarbonate-evoked currents of normal magnitude were recorded when methane sulfonate was substituted for Cl- in bath, ejection, and intracellular solutions. Similarly, an outward current was evoked when extracellular Na+ concentration was raised in the presence of HCO3-. The Na(+)-evoked response was reduced to 16.2% of control by 2 mM DNDS and was abolished by removal of HCO3- from bath and ejection solutions. Taken together, these results (block by stilbenes and harmaline, HCO3- and Na+ dependence, Cl- independence) indicate that salamander Müller cells possess an electrogenic Na+/HCO3- cotransport system. Na+/HCO3- cotransporter sites were localized primarily at the endfoot region of Müller cells. Ejection of HCO3- onto the endfoot evoked outward currents 10 times larger than currents evoked by ejections onto the opposite (distal) end of the cell. The reversal potential of the cotransporter was determined by DNDS block of cotransport current. In the absence of a transmembrane HCO3- gradient, the reversal potential varied systematically as a function of the transmembrane Na+ gradient. The reversal potential was -0.1 mV for a [Na+]o:[Na+]i ratio of 1:1 and -25.2 mV for a Na+ gradient ratio of 7.4:1. Based on these values, the estimated stoichiometry of the cotransporter was 2.80 +/- 0.13:1 (HCO3-:Na+). Possible functions of the glial cell Na+/HCO3- cotransporter, including the regulation of CO2 in the retina and the regulation of cerebral blood flow, are discussed.     

Intracellular Na+ activity in cultured mouse oligodendrocytes

Na(+)-selective double-barrelled microelectrodes were used to measure the intracellular Na+ activity (aiNa) and membrane potential (Em) in oligodendrocytes from cultures of embryonic mouse spinal cord. In Na(+)-free solutions aiNa rapidly fell from its baseline of about 15 mM to values below 1 mM. Elevation of the K+ concentration in the bath ([K+]o) from 5.4 to 15 or 50 mM elicited an aiNa decrease of 4.7 or 9.0 mM, respectively. Ouabain blocked the aiNa decrease in response to 50 mM K+ by 37%. Bath application of 1 mM glutamate resulted in a membrane depolarization of 4.5 mV and a concomitant rise of aiNa by 8.6 mM. aiNa increased by approximately 11 mM after washout of a solution containing 20 mM NH4+. This aiNa increase was not blocked by amiloride, excluding a major contribution of a Na+/H+ antiporter. We conclude that, in cultured oligodendrocytes, transmembraneous Na+ movements are involved in pH regulation, glutamate causes an influx of Na+, and that the Na+/K+ pump and passive KCl uptake contribute to K+ accumulation.     

Thrombin stimulation of Cl-/HCO3- exchange in human platelets

The presence of one acidifying Cl-/HCO3- exchange mechanism in human platelets has not been previously reported. This paper demonstrates that this mechanism does function and that it increases its activity after stimulation with thrombin. On resuspension of BCECF-loaded platelets in a chloride-free medium (gluconate replaced) that contains bicarbonate, cytosolic pH (pHi) increased and stabilized after 10 min at an alkaline value. After addition of 50 mM NaCl, pHi fell rapidly reaching steady state in the succeeding 5 min. The stilbene derivative 4-acetamido-4'-isothiocyanato stilbene-2,2' disulfonic acid (SITS) inhibited both, the alkalization in chloride-poor solution and the recovery from the alkaline load after chloride enrichment. The decline in pHi was observed whether chloride was delivered to the solution in the form of LiCl or NaCl, or when the later was applied after blockage of the Na+/H+ exchanger. The recovery in chloride-containing solution was in contrast to the effect of a similar change in osmolarity by addition of 50 mM sodium gluconate that did not produced a significant variation of pHi. Posterior addition of NaCl after 5 min in high gluconate reproduced the pHi fall of the control experiment. Alkali loads produced by 25 mM trimethylamine hydrochloride (TMA) were also counteracted by HCO(3-)-equivalent efflux via Cl-/HCO3- exchange. One of the major observations of the present study is that HCO3- equivalent efflux was twice as high when the platelets were previously stimulated with 0.1 IU of thrombin, but thrombin did not produce significant changes of the pHi recovery rate in a bicarbonate-free solution. The increase of the decline in pHi elicited by preexposure to thrombin was still observed in the presence of an inhibitor of the Na+/H+ exchange or in sodium-free solutions. It is concluded that a Na-independent Cl-/HCO3- exchange mechanism mediates the recovery of pHi from alkalosis in platelets and that thrombin activates this exchanger by a direct regulatory pathway.     

Localization and stoichiometry of electrogenic sodium bicarbonate cotransport in retinal glial cells.

An electrogenic Na+/HCO3- cotransport system was identified and characterized in freshly dissociated salamander Müller (glial) cells. Under voltage-clamp, these cells generated an outward current when external HCO3- concentration [( HCO3-]o) was raised. This current was Na(+)-dependent, Cl(-)-independent, and was blocked by the stilbenes 4,4'-diisothiocyanato-stilbene-2,2'-disulfonate (DIDS) and 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS), and by harmaline, demonstrating that the current was generated by a Na+/HCO3- cotransport system. Substantially larger currents were evoked when [HCO3-]o was raised at the Müller cell endfoot as compared to other cell regions, indicating that cotransporter sites are localized preferentially to the endfoot. The reversal potential of the current, which varied as a function of HCO3- and Na+ transmembrane gradients, indicated that the cotransporter has a HCO3-:Na+ stoichiometry of 3:1.     

Intracellular pH and some membrane characteristics of cultured carotid body glomus cells

Clusters of carotid body (glomus) cells cultured from a few days to 3 weeks, maintained their morphological characteristics during this period. The resting potential (Em) and input resistance (Ro) did not change for 2 weeks but both declined afterwards. The intracellular pH (pHi) of glomus cells, measured with glass microelectrodes filled with an H+ ion exchanger, was 6.34-6.96 at extracellular pH (pHo) of 7.32-7.53. Changes in pHo from normal to about 5.5 depolarized most cells but the fall in pHi was less marked than predicted by the Nernst equation. Conversely, shifting pHo to 8.5 hyperpolarized the cells with an increase in pHi which was more acid than predicted. EH (the calculated equilibrium potential for H+ (Nernst equation) was more positive than Em during acidity and more negative during normal or alkaline pHo. The kinetics of H+ ion distribution was assessed by brief exposures to NH4Cl. It is concluded that hydrogen ions are not passively distributed across the glomus cell membranes and that Em is dependent on H+ ions.     

Regulation of intracellular pH in vertebrate central neurons

The regulation of intracellular pH (pHi) was investigated in reticulospinal neurons of the lamprey using ion-selective microelectrodes. Steady-state pHi in 23 mM HCO-3-buffered Ringer was 7.44 +/- 0.03 with a membrane potential of 54 +/- 4 mV (mean +/- S.E.M., n = 6). In nominally HCO-3-free solutions, pHi recovery from acid loading was blocked by 10(-3)M amiloride. Recovery was stimulated by transition to HCO-3-containing solutions. Results suggest that pHi regulation in lamprey reticulospinal neurons is mediated by a Na+-H+ exchanger. The presence of a distinct, HCO-3-dependent pHi regulatory mechanism is postulated.     

Effects of pHi and pHe on membrane currents recorded with the perforated-patch method from cultured chemoreceptors of the rat carotid body

In this study we investigated the effects of intracellular pH (pHi) and extracellular pH (pHe) on whole-cell currents in cultured glomus cells of the rat carotid body and small, intensely fluorescent (SIF) cells of sympathetic ganglia. The use of the perforated-patch recording technique along with established methods of cytoplasmic acidification allowed us to carry out this study without greatly disturbing the cell's endogenous pH regulatory mechanisms. A reversible decrease in the outward K+ current (20-30%) was observed during acid loading of glomus (and SIF cells) using the K+/H+ ionophore nigericin (3 microM) and acetate (20 mM). A reversible decrease in the inward Na+ current was also observed in both cell types during nigericin application. Application of amiloride (0.1 mM) to the bathing solution inhibited recovery of the K+ current from an acid load implicating the Na+/H+ antiporter as a mechanism involved in pH homeostasis in glomus cells. A reversible decrease in K+ and Na+ currents was also observed during changes in pHe from 7.4 to 6.5. The effects of pHi on membrane currents, Ca2+ levels, and neurotransmitter release are discussed in the context of the role of glomus cells as primary transducers of chemosensory stimuli in arterial blood.     

Glial cells of the oligodendrocyte lineage express proton-activated Na+ channels

Neurons and oligodendrocytes, but not type I astrocytes and Schwann cells, generate large Na+ currents in response to a step increase of [H+]. Proton-activated Na+ channels are the first cationic channels expressed in neuronal precursor cells from the mammalian brain. Glial precursor cells cultured from mouse brain are also capable of generating Na+ currents in response to step acidification (INa(H]. With further development along the oligodendrocyte lineage, this property is retained, whereas voltage-activated Na+ and K+ currents disappear. Comparing INa(H) of oligodendrocytes with INa(H) of their precursor cells did not reveal a difference in current amplitude, suggesting a higher density of INa(H) channels on the (smaller) precursor cells. The properties of INa(H) in glial precursor cells and oligodendrocytes are similar to those of neurons, with respect to activation conditions, time course, and the effect of extracellular Ca2+ concentrations. The results are consistent with previous observations which showed that oligodendrocytes partially preserve their chemically activated, but completely lose their voltage-activated, ion channels.     

Sodium-bicarbonate cotransport in retinal astrocytes and Müller cells of the rat.

Sodium-bicarbonate cotransport in retinal glial cells was studied in the everted eyecup preparation of the rat. Intracellular pH was monitored with the indicator dye BCPCF and fluorescence confocal microscopy. Raising the K+ concentration from 3 to 12 mM in HCO3- -buffered perfusate evoked an intracellular alkalinization in both astrocytes and Müller cells. The alkalinization developed more rapidly and was larger in astrocytes. The K+ -induced alkalinization was HCO3- -dependent; it was reduced by 33% in astrocytes and 71% in Müller cells when HCO3- was removed from the perfusate. The alkalinization was effectively blocked by addition of 0.5 mM 4,4"-diisothiocyanato-stilbene-2,2'-disulfonic acid (DIDS). Removal of Na+ from the perfusate evoked a rapid acidification in both types of glial cells. The results indicate that astrocytes and Müller cells in situ in the rat retina possess an electrogenic Na+/HCO3- cotransporter.     

Electrogenic Na+/HCO3- cotransport in neuroglia

Membrane potential recording from glial cells in Necturus optic nerve in the presence of 2 mM Ba++, which was added to block the K+ conductance, gave the following results. 1) In HCO3- -free, low-Na+ solutions (11% of control; Na+ replaced with N-methyl-D-glucamine), the hyperpolarizing effect of adding 10 mM HCO3- was reduced by approximately 80%. 2) 4-acetamido-4'-isothiocyanato-stilbene-2,2'-disulfonic acid (SITS, 0.1 or 1 mM) reduced the effect of HCO3- by at least 50%. 3) In the presence of HCO3-, reduction of Na+ caused a depolarization which was much larger than that observed in nominally HCO3- -free solutions. These observations indicate the presence in the glial membrane of an electrogenic Na+/HCO3- cotransporter in which the stoichiometry of HCO3- to Na+ is greater than 1.     

Electrophysiological characterization of a nicotinic acetylcholine receptor on leech neuropile glial cells

Ion-selective double-barrelled microelectrodes were used to measure the activities of intracellular K+, Na+, Cl-, and H+ (aiK, aiNa, aiCl, pHi) and membrane potential (Em) in neuropile glial cells as well as extracellular K+ activity (aeK) in the neuropile of the leech, Hirudo medicinalis, during bath application of carbachol. As measured with conventional single-barrelled microelectrodes, acetylcholine (ACh), nicotine, carbachol, tetramethylammonium (TMA), and choline elicited concentration-dependent (10(-6)-5 X 10(-3) M) transient membrane depolarizations of up to 60 mV amplitude whereas muscarine (10(-6)-10(-3) M) did not affect Em. alpha-Bungarotoxin (10(-7) M), decamethonium (10(-5) M), d-tubocurarine (5 X 10(-5) M), and strychnine (5 X 10(-5) M) blocked the carbachol depolarization by about 90%. Atropine (5 X 10(-5) M) blocked the response by about 75%, whereas hexamethonium was only effective at millimolar concentrations. Average baseline levels of aeK in the neuropile and of aiK, aiNa, and aiCl in the neuropile glial cells were about 3, 70, 10, and 7 mM, respectively. During the carbachol depolarization aeK and aiNa transiently increased, whereas aiK decreased. In contrast, a rise of aiK and a fall of aiNa were observed during glial depolarizations in solutions with elevated K+ concentration. aiCl increased during both the carbachol- and the K+-induced depolarization. During carbachol, pHi transiently fell by about 0.2 units from its average baseline level of 6.9, whereas an alkalinization of small amplitude was observed in high-K+ solutions. Bath-applied choline, TMA, and decamethonium rapidly accumulated in the neuropile glial cells as intracellularly monitored with double-barrelled microelectrodes filled with Corning K+ exchanger resin, which is highly selective for these agents. The results suggest that leech neuropile glial cells have a nicotinic ACh receptor coupled to a cation channel. It is hypothesized that this channel might also be permeable to choline, TMA, and decamethonium.     

Water and Electrolyte Contents, Cell pH, and Membrane Potential of Primary Cultures of Astrocytes from DBA, C57, and SW Mice

Some basic properties of primary cultures of astrocytes derived from the cerebral cortex of an audiogenic seizure-sensitive strain of mice, DBA/2J (DBA), were studied with different approaches. The results were compared with those of audiogenic seizure-resistant strains, C57BL/6J (C57) and Swiss Webster (SW). Contents of intracellular water, protein, and DNA of DBA astrocytes were 0.673 +/- 0.019 ml/g cells, 0.082 +/- 0.006 g/g cells, and 0.0072 +/- 0.0005 g/g cells, respectively. These results are not different from those of either C57 or SW astrocytes. Intracellular concentration of K+, Na+, and Cl- ([K+]1, [Na+]1, and [Cl-]1) derived from the flame photometric and from the radioisotope uptake data of DBA astrocytes were 120.4 +/- 8.5, 25.9 +/- 3.2, and 26.8 +/- 1.8 mM/L cell H2O, respectively. [Na+]1 and [Cl-]1 in DBA astrocytes were lower than those in C57 and SW astrocytes. In DBA astrocytes, SITS decreased the cell/medium ratio (C/M) of 36Cl- and increased the C/M of 125I-; ouabain increased the C/M of 22Na+ and decreased the C/M of 125I-; bumetanide decreased the C/M of both 36Cl- and 22Na+; and NaClO4 decreased the C/M of 125I-. Similar results were observed in both C57 and SW astrocytes. Intracellular pH (pHi) as determined with 14C-DMO of astrocytes in HEPES-buffered saline solution averaged 7.04 +/- 0.03 for DBA, 7.01 +/- 0.02 for C57, and 6.97 +/- 0.02 for SW mice when pH of medium was maintained at 7.4. Modification of ion (HCO3-, Cl-, Na+, and K+) concentration and pH of culture medium all changed the pHi of astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electrical coupling, without dye coupling, between mammalian astrocytes and oligodendrocytes in cell culture

Evidence of electrical and dye coupling between oligodendrocytes and astrocytes was sought in cultures of mouse spinal cord. Cell identity was verified using cell specific antigenic markers. In most experiments current was injected into oligodendrocytes while recording voltage in nearby astrocytes. Nine of 17 oligodendrocyte-astrocyte cell pairs showed weak electrical coupling; the average estimated coupling ratio was 0.03 +/- 0.06 (cf. 0.11 for oligodendrocyte-oligodendrocyte and 0.44 for astrocyte-astrocyte pairs; Kettenmann and Ransom: Glia, 1: 64-73, 1988). Application of 0.5 mM BaCl2 or 44.6 mM CsCl depolarized astrocytes and oligodendrocytes and was estimated to increase the coupling ratio between these cells 3-5-fold; these effects were rapid in onset and completely reversible. In 5 of 7 cases, oligodendrocyte-astrocyte pairs that appeared uncoupled in normal solution exhibited coupling during Ba++ or Cs+ exposure. The actions of these cations are believed to be mediated by blockade of glial K+ channels. Depolarization, per se, as induced by increasing [K+]o, did not increase coupling ratio. The fluorescent dye lucifer yellow (LY) was injected into 10 oligodendrocytes, 8 of which were electrically coupled to nearby astrocytes, and never passed into astrocytes in detectable quantities. Likewise, astrocytes injected with LY stained other astrocytes, but never oligodendrocytes. These findings document the presence of weak electrical coupling between astrocytes and oligodendrocytes, in the absence of dye coupling. Weak coupling of this sort could subserve metabolic interactions between these cells mediated by the passage of small but important molecules such as cyclic AMP, but would not allow strong electrical interactions. If such coupling among glial cells is widespread, it would constitute a "metabolic syncytium" that could serve to coordinate glial behavior.     

Ionic conductances underlying the activity of interneurons that control heartbeat in the medicinal leech

Electrical properties of interneurons that control heartbeat in the leech (HN cells) were studied using intracellular recording and stimulation in isolated ganglia bathed by salines of various ionic compositions. Substitution of Na+ ions in the bath by Tris stopped the spontaneous firing of HN cells and led to their gradual hyperpolarization by 15-20 mV. In the absence of Na+, HN neurons produced long-lasting regenerative plateau potentials with thresholds near -55 mV and peaks near -30 mV that were accompanied by an increase in membrane conductance. Elevation of Ca2+ concentration enhanced plateaus, as did replacement of Ca2+ by Ba2+. Plateaus were formed when Sr2+ replaced Ca2+, but were blocked by addition of Mg2+ or Co2+ to the bath, Co2+ being effective at lower concentrations than Mg2+. Hyperpolarization of HN neurons with injected currents revealed a time-dependent change in membrane potential, whereby initial maximum hyperpolarization was followed by a "sag" in potential towards more depolarized values. The sag showed dual voltage dependence, being diminished when HN neurons were hyperpolarized or depolarized outside the normal range of oscillation. The sag was found to depend on the presence of Na+ ions and to be blocked by Cs+ but not by Ba2+. This time-dependent change in membrane potential counters hyperpolarizations of HN neuron membrane potential and may contribute to the escape of these neurons from synaptic inhibition.     

Cell swelling following recovery from acidification in C6 glioma cells: an in vitro model of postischemic brain edema

Two consequences of cerebral ischemia are cell acidification and cytotoxic edema. To test the possibility that Na+/H+ exchange mediates acid-induced edema, we measured cytoplasmic pH (pHi) and cell volume changes in C6 glioma cells that were artificially acid-loaded using weak electrolytes. pHi was monitored fluorimetrically with 2',7'-bis-(2-carboxyethyl)-5,6-carboxyfluorescein. Upon acidification with sodium propionate, pHi dropped to 6.74 +/- 0.05 (n = 25), and then recovered to levels near the physiological value of 7.23 +/- 0.02 (n = 13). Cell volume, measured by electronic sizing, increased concomitantly by approximately 50% in sodium propionate solution. Both pHi recovery and cell swelling were Na+-dependent, amiloride-sensitive, and inhibited at pHo less than 6.0. These results demonstrate that in vitro: (1) intracellular acidification can lead to cell swelling, and (2) pHi recovery and the concomitant cell swelling are likely mediated by Na+/H+ exchange. These mechanisms may be related to postischemic cytotoxic glial edema.     

Neuron-glial trafficking of NH4+ and K+: separate routes of uptake into glial cells of bee retina

Ammonium (NH4+ and/or NH3) and K+ are released from active neurons and taken up by glial cells, and can modify glial cell behaviour. Study of these fluxes is most advanced in the retina of the honeybee drone, which consists essentially of identical neurons (photoreceptors) and identical glial cells (outer pigment cells). In isolated bee retinal glial cells, ammonium crosses the membrane as NH4+ on a Cl- cotransporter. We have now investigated, in the more physiological conditions of a retinal slice, whether the NH4+-Cl- cotransporter can transport K+ and whether the major K+ conductance can transport NH4+. We increased [NH4+] or [K+] in the superfusate and monitored uptake by recording from the glial cell syncytium or from interstitial space with microelectrodes selective for H+ or K+. In normal superfusate solution, ammonium acidified the glial cells but, after 6 min superfusion in low [Cl-] solution, ammonium alkalinized them. In the same low [Cl-] conditions, the rise in intraglial [K+] induced by an increase in superfusate [K+] was unchanged, i.e. no K+ flux on the Cl- cotransporter was detected. Ba2+ (5 mm) abolished the glial depolarization induced by K+ released from photoreceptors but did not reduce NH4+uptake. We estimate that when extracellular [NH4+] is increased, 62-100% is taken up by the NH4+-Cl- cotransporter and that when K+ is increased, 77-100% is taken up by routes selective for K+. This separation makes it possible that the glial uptake of NH4+ and of K+, and hence their signalling roles, might be regulated separately.