Astrocytes promote neurogenesis from oligodendrocyte precursor cells.

The oligodendrocyte precursor cell (OPC) has until recently been regarded as a lineage-restricted precursor cell. Considerable interest has been generated by reports suggesting that OPCs may possess a wider differentiation potential than previously assumed and thus be considered a multipotential stem cell. This study examined the neuronal differentiation potential of rat, postnatal cortical OPCs in response to extracellular cues in vitro and in vivo. OPCs did not exhibit intrinsic neuronal potential and were restricted to oligodendrocyte lineage potential following treatment with the neural precursor mitogen fibroblast growth factor 2. In contrast, a postnatal hippocampal astrocyte-derived signal(s) is sufficient to induce functional neuronal differentiation of cortical OPCs in vitro in population and single cell studies. Co-treatment with Noggin, a bone morphogenetic protein antagonist, did not attenuate neuronal differentiation. Following transplantation to the adult rat hippocampus, cortical OPCs expressed doublecortin, a neuroblast-associated marker. The present findings show that hippocampal, astrocyte-derived signals can induce the neuronal differentiation of OPCs through a Noggin-independent mechanism.

The effect of neuronal morphology and membrane-permeant weak acid and base on the dissipation of depolarization-induced pH gradients in snail neurons.

Neuronal depolarization causes larger intracellular pH (pH(i)) shifts in axonal and dendritic regions than in the cell body. In this paper, we present evidence relating the time for collapse of these gradients to neuronal morphology. We have used ratiometric pH(i) measurements using 8-hydroxypyrene-1,3,6-trisulfonic acid (HPTS) in whole-cell patch-clamped snail neurons to study the collapse of longitudinal pH gradients. Using depolarization to open voltage-gated proton channels, we produced alkaline pH(i) microdomains. In the absence of added mobile buffers, facilitated H(+) diffusion down the length of the axon plays a critical role in determining pH(i) microdomain lifetime, with axons of approximately 100 microm allowing pH differences to be maintained for >60 s. An application of mobile, membrane-permeant pH buffers accelerated the collapse of the alkaline-pH gradients but, even at 30 mM, was unable to abolish them. Modeling of the pH(i) dynamics showed that both the relatively weak effect of the weak acid/base on the peak size of the pH gradient and the accelerated collapse of the pH gradient could be due to the time taken for equilibration of the weak acid and base across the cell. We propose that appropriate weak acid/base mixes may provide a simple method for studying the role of local pH(i) signals without perturbing steady-state pH(i). Furthermore, an extrapolation of our in vitro data to longer and thinner neuronal structures found in the mammalian nervous system suggests that dendritic and axonal pH(i) are likely to be dominated by local pH(i)-regulating mechanisms rather than simply following the soma pH(i).

A role for Na+/H+ exchange in pH regulation in Helix neurones.

We have used the pH-sensitive fluorescent dye 8-hydroxypyrene-1,3,6-trisulphonic acid (HPTS) to reexamine the mechanisms that extrude acid from voltage-clamped Helix aspersa neurones. Intracellular acid loads were imposed by three different methods: application of weak acid, depolarization and removal of extracellular sodium. In nominally CO2/HCO3-free Ringer the rate of recovery from acid loads was significantly slowed by the potent Na+/H+ exchange inhibitor 5-[N-ethyl-N-isopropyl]-amiloride (EIPA, 50 microM). Following depolarization-induced acidifications the rate of intracellular pH (pHi) recovery was significantly reduced from 0.41 +/- 0.13 pH units.h-1 in controls to 0.12 +/- 0.09 pH units.h-1 after treatment with EIPA at pHi approximately equal to 7.3 (n = 7). The amiloride analogue also reduced the rate of acid loading seen during extracellular sodium removal both in the presence and absence of the Na(+)-dependent Cl-/HCO3- exchange inhibitor 4-acetamido-4'-isothiocyanato-stilbene-2,2'-disulphonic acid (SITS, 50 microM). This is consistent with EIPA inhibiting reverse-mode Na+/H+ exchange. In 2.5% CO2/20 mM HCO3-buffered Ringer pHi recovery was significantly inhibited by SITS, but unaffected by EIPA. Our results indicate that there are two separate Na(+)-dependent mechanisms involved in the maintenance of pHi in Helix neurones: Na(+)-dependent Cl-/HCO3- exchange and Na+/H+ exchange. Acid extrusion from Helix neurones is predominantly dependent upon the activity of Na(+)-dependent Cl-/HCO3- exchange with a lesser role for Na+/H+ exchange. This adds further weight to the belief that the Na+/H+ exchanger is ubiquitous.

Comparison of simultaneous pH measurements made with 8-hydroxypyrene-1,3,6-trisulphonic acid (HPTS) and pH-sensitive microelectrodes in snail neurones.

We have evaluated the pyrene-based ratiometric fluorescent dye, 8-hydroxypyrene-1,3,6-trisulphonic acid (HPTS), by using it in conjunction with glass pH-sensitive microelectrodes to measure intracellular pH (pHi) in voltage-clamped snail neurones. Intracellular acidification with propionic acid, and alkalinization following the activation of H+ channels allowed the calibration of the dye to be compared with that of the pH microelectrode over the pH range 6.50-7.50. HPTS calibrated in vitro and glass pH-sensitive microelectrodes produced similar absolute resting pHi values, 7. 16+/-0.05 (n=10) and 7.17+/-0.06 (n=9) respectively in nominally CO2/HCO3--free saline. At both extremes of the pH range there were small discrepancies. At acidic pHi, 6.87+/-0.09 (n=5), the intracellular HPTS measurement differed by -0.08+/-0.03 pH units from the pH-sensitive microelectrode measurement. At alkaline pHi, 7. 32+/-0.10 (n=5), HPTS measurements produced pH values that differed by +0.07+/-0.04 pH units from those of the pH-sensitive microelectrode. Some of the discrepancy could be accounted for by the slow response of the recessed-tip pH-sensitive microelectrode (time constant 77+/-15 s, n=3). Further experiments showed that HPTS, used at an intracellular concentration of 200 microM to 2 mM, did not block activity-dependent pHi changes. The intracellular HPTS concentration was calculated by measurement of intracellular chloride during a series of HPTS-KCl injections. Comparison of HPTS with 2',7'-bis(2-carboxyethyl)-5,6-carboxyfluorescein (BCECF), at the same concentration, showed that HPTS produces a larger change in ratio over the pH range 6.00-8.00.

Relationship between intracellular calcium and its muffling measured by calcium iontophoresis in snail neurones.

1. We have measured intracellular free calcium ion concentration ([Ca2+]i) with fura-2, and intracellular chloride with chloride-sensitive microelectrodes, in voltage-clamped snail neurones. By making iontophoretic injections of CaCl2 we have investigated calcium muffling, the sum of the processes which minimize the calcium transient, at different values of [Ca2+]i. 2. By injection of calcium into cell-sized droplets of buffer we measured the calcium transport index. It was stable over the range pCa 6-7.4 (0.48 +/- 0.06 measured at pCa 6.70 +/- 0.12, n = 5). 3. Measurement of intracellular chloride activity during a series of fura-2-KCl pressure injections revealed a nearly linear relationship between fura-2 Ca(2+)-insensitive fluorescence and the sum of the increments in intracellular chloride. This allowed us to calculate the intracellular fura-2 concentration ([fura-2]i). 4. The rate of recovery of [Ca2+]i following a depolarization-induced load was increased by low [fura-2]i (10-20 microM) but decreased by higher [fura-2]i (40-80 microM). These effects are consistent with the addition of a mobile buffer to the cytoplasm. 5. Iontophoresis of Ca2+ at various membrane potentials allowed us to calculate the intracellular calcium muffling power (the amount of calcium required to cause a transient tenfold increase in [Ca2+]i per unit volume) and calcium muffling ratio (number of Ca2+ ions injected divided by the maximum increase in [Ca2+]i per unit volume) at different values of [Ca2+]i. 6. Calcium muffling power at resting [Ca2+]i was approximately 40 microM Ca2+ (pCa unit)-1, (about 250 times less than for hydrogen ions). It increased linearly about fivefold with [Ca2+]i over the range 20-120 nM (10 cells, 153 measurements) and therefore exponentially with decreasing pCa. 7. The calcium muffling ratio appeared to be constant (361 +/- 14, n = 10 cells, 130 measurements) over the range 20-120 nM Ca2+. 8. In three experiments we modelled the additional calcium buffering power produced by multiple pressure injections of fura-2 into voltage-clamped snail neurones. Back-extrapolation of the increases in calcium buffering power allowed us to calculate the calcium muffling power of the neurones. 9. Small increases in [fura-2]i (approximately 10 microM) significantly increased intracellular calcium muffling power in individual experiments. However, the variability among neurones in intracellular calcium muffling power was large enough to obscure the additional buffering produced by fura-2 in pooled experiments.

Use of BCECF and propidium iodide to assess membrane integrity of acutely isolated CA1 neurons from rat hippocampus.

We used 2 fluorescent dyes, 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) and propidium iodide (PI), to assess the membrane integrity of neurons acutely isolated from the CA1 region of the rat hippocampus. Exciting BCECF at a relatively pH-insensitive wavelength (440 nm), or exciting PI at 490 nm, we quantitatively recorded, in real time and in single cells, the rate constants for BCECF loss (-k440) and PI uptake (k490). We found that approximately 98% of intracellular BCECF is rapidly released by applying 0.01% saponin. In neurons not treated with saponin, rate constants for BCECF loss and PI uptake typically were 1% min-1 or less under control conditions, in the presence of NH3/NH4+ and in the absence of Na+. However, in a small number of neurons, the rate constant for BCECF loss increased markedly (-k440 > 5% min-1), while pHi approached pHo, suggesting that the plasma membrane spontaneously became leaky. When neurons were progressively swollen in hypotonic solutions, rates constants for BCECF loss and PI uptake generally were affected minimally unless osmolality was decreased to approximately 75 mOsmol/kg. Treating neurons with 0.001% saponin caused an increase in PI uptake rate only in a minority of neurons, whereas in most experiments a similar treatment caused -k440 for BCECF to exceed 5% min-1, and led to a rapid deterioration of the pH gradient across the cell membrane. At even lower saponin levels (0.0005-0.0007%), we observed a much slower deterioration of pHi, which occurred at low rates of BCECF loss (-k440 = approximately 3% min-1). We conclude that computing rate constants for BCECF loss and PI uptake may be useful for assessing neuronal health, and that BCECF loss may be more sensitive to cell damage than PI uptake.

Effects of CGRP, forskolin, PMA, and ionomycin on pHi dependence of Na-H exchange in UMR-106 cells.

We examined the effects of calcitonin gene-related peptide (CGRP), forskolin, phorbol 12-myristate 13-acetate (PMA), and ionomycin on the intracellular pH (pHi) dependence of Na-H exchange in UMR-106 cells. In the nominal absence of CO2-HCO3-, each agent increased pHi, measured with 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF). From the rate of pHi recovery (dpHi/dt) from an acid load, and intracellular buffering power, we computed the pHi dependence of the total acid-extruding flux (JTotal). All four agents increased JTotal. From dpHi/dt data obtained in the presence of ethylisopropyl amiloride (EIPA, a blocker of Na-H exchange), we determined the EIPA-resistant component of JTotal (JEIPA/R). We estimated the Na-H exchange flux (JNa-H) as the difference JTotal-JEIPA/R-CGRP, forskolin, and PMA produced similar increases in the slope of the JNa-H vs. pHi-relationship. The net effect of these agents, as well as ionomycin, was to increase JNa-H over a broad pHi range. Ionomycin alkaline shifted the JEIPA/R vs. pHi relationship; the other agents had no effect. Our results indicate that CGRP increased JTotal by stimulating Na-H exchange, with little effect on EIPA-resistant processes. A signaling pathway involving only adenosine 3',5'-cyclic monophosphate, only protein kinase C, or only Ca2+ cannot account for the effects of CGRP on both pHi and pHi dependence of JNa-H. Thus, CGRP probably affects UMR-106 pHi physiology via more than one pathway.

Regulation of intracellular pH in pyramidal neurones from the rat hippocampus by Na(+)-dependent Cl(-)-HCO3- exchange.

1. We have measured intracellular pH (pHi) in freshly isolated pyramidal neurones from the CA1 region of the rat hippocampus using the fluorescent indicator 2',7'-bis(carboxy-ethyl)-5-(and-6)-carboxyfluorescein (BCECF). 2. The neurones selected by our isolation procedure, when studied in the nominal absence of CO2-HCO3-, had a mean steady-state pHi of 6.81 +/- 0.02 (n = 163). The recovery of pHi from acid loads was very slow. The rate of recovery from acid loads was reduced by Na+ removal, but only very slightly inhibited by 1 mM amiloride. 3. The addition of 5% CO2-25 mM HCO3- caused steady-state pHi to increase from 6.74 +/- 0.05 to 7.03 +/- 0.03 (n = 28). In the presence of 5% CO2-25 mM HCO3-, the rate of pHi recovery from acid loads was much faster than in its absence. 4. The HCO(3-)-induced alkalinization was reversible, and did not occur in the absence of extracellular Na+ or in the presence of DIDS (4,4'-diisothiocyanatostilbene- 2,2'-disulphonic acid). 5. In the absence of external Cl-, successive exposures to CO2-HCO3- elicited alkalinizations that were progressively reduced in rate and amplitude. This effect, presumably due to gradual depletion of internal Cl-, was rapidly reversed by returning Cl- to the external medium. 6. We conclude that the major acid-extrusion mechanism in pyramidal CA1 neurones is the Na(+)-dependent Cl(-)-HCO3- exchanger. The Na(+)-dependent mechanism that operates in the nominal absence of HCO3- is far less active.

Calcium-hydrogen exchange by the plasma membrane Ca-ATPase of voltage-clamped snail neurons.

The submicromolar levels of free Ca(2+) ions in animal cells are believed to be maintained in the long term by two different plasma membrane transport mechanisms. These are Na-Ca exchange, driven by the sodium gradient, and a Na-independent Ca pump, driven by ATP. There is good evidence from red blood cells, and indirect evidence from other non-neuronal preparations, that the Ca-ATPase exchanges internal Ca(2+) for external H(+). Although Ca extrusion from nerve cells is inhibited by high external pH, there as yet is no evidence for the counter-transport of H(+). We have used both pH- and calcium-sensitive microelectrodes on the cell surface, and the Ca indicator fura-2 intracellularily, to investigate how snail neurons regulate cytoplasmic free Ca(2+). We now report that in snail neurons the recovery of intracellular Ca(2+) after an increase coincides with both the expected increase in surface Ca(2+) and a decrease in surface H+. Recovery of intracellular Ca and the changes in surface pH and Ca are all blocked by intracellular vanadate. We conclude that snail neurons regulate intracellular Ca mainly by a Ca-H ATPase, and suggest that this Ca-H exchange may account for many of the reported extracellular pH changes seen with neuronal excitation.

Mechanism of pHi regulation by locust neurones in isolated ganglia: a microelectrode study.

1. We have measured membrane potential (Em) and intracellular pH (pHi), and sodium and chloride activities (aNai and aCli) in exposed dorsal unpaired median neurones in isolated metathoracic ganglia from the desert locust, Schistocerca gregaria using eccentric double-barrelled ion-sensitive microelectrodes. 2. In the absence of added HCO3- the steady-state pHi was 7.21 +/- 0.13 (mean +/- S.D.) at a mean membrane potential of -37 +/- 7.0 mV (S.D.) (n = 44 cells). The pHi was always more alkaline than predicted for passive H+ distribution. 3. The pHi recovery from acid loads, induced by weak acid application or weak base removal, was pHi dependent and associated, in both the presence and absence of added CO2-HCO3-, with a transient increase in aNai. 4. In the absence of added HCO3-, application of the Na(+)-H+ exchange blocker amiloride or external Na+ removal caused intracellular acidification. Also in the absence of added HCO3- the inhibitor SITS (4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonic acid) caused an acidification of about 0.2 pH units which was not additive to the effects of the removal of external Na+. 5. We found that the application of a CO2-HCO3(-)-containing solution increased the rate of pHi recovery from acidification. 6. Intracellular chloride was decreased by intracellular acidification in the presence of added CO2-HCO3-. In the presence of amiloride, intracellular Cl- depletion inhibited pHi regulation. 7. Simultaneous application of SITS (160 microM) and removal of CO2-HCO3- revealed a continuous underlying acid load of 0.03-0.05 pH unit min-1. 8. We conclude that locust neurones possess at least two pHi-regulating mechanisms which operate against a continuous acid load. One is a Na(+)-H+ exchanger which can be blocked by amiloride, while the second is a Na(+)-dependent Cl(-)-HCO3- exchanger. The latter mechanism appears to be able to operate in the absence of added HCO3- and can recover pHi to around pH 7.4; it is probably the main pHi regulating mechanism. The Na(+)-H+ exchanger appears to activate at more acid pHi and being less energy efficient may serve a protective role.