Activity-dependent K+ accumulation in the developing rat optic nerve.

Potassium-sensitive microelectrodes were used to study activity-dependent changes of extracellular potassium ion concentration ([K+]o) in rat optic nerves of different postnatal ages (1 day to adulthood). The maximum level to which [K+]o rose with optimal frequencies of stimulation depended on age: mean maximum evoked [K+]o was 17.2 microM in 1- to 3-day-old optic nerves and 9.8 microM in adult nerves. The ceiling [K+]o seen in immature optic nerves, which is uniquely large for a mammalian central nervous system structure, may result from a relatively enhanced rate of evoked K+ release.

Modulation of parallel fiber excitability by postsynaptically mediated changes in extracellular potassium.

Field potentials and extracellular potassium concentration ([K+]o) were simultaneously monitored in the molecular layer of the rat cerebellar cortex during stimulation of the parallel fibers. The synaptic field potential elicited by stimulation was reduced by several methods. Reduction of synaptic field potentials was accompanied by a marked increase in the excitability of the parallel fibers. This change in excitability was related to the degree of extracellular K+ accumulation associated with parallel fiber stimulation. These findings support the proposal that increases in [K+]o associated with activity in postsynaptic elements can modulate the excitability of presynaptic afferent fibers.

Glial-neuronal interactions in non-synaptic areas of the brain: studies in the optic nerve.

Optic nerves, like other CNS tracts, consist of axons closely apposed across narrow extracellular clefts to the cell bodies and processes of glial cells. Despite the anatomical simplicity of these pathways and the absence of synapses, a surprising range of interactions occurs between axons and glial cells mediated by changes in the chemical composition of the extracellular fluid produced by glial or neuronal stimulation. Some of the interactions are relatively brief, resulting from alterations in extracellular ions such as K+ or H+, or alterations of small molecules like glutamate or ATP. Other interactions involve much longer time periods and presumably larger signaling molecules, like peptides or proteins. These play a role not only in the development of axonal pathways but also in the processes of degeneration and regeneration that follow brain injury or disease.

Non-synaptic mechanisms of Ca(2+)-mediated injury in CNS white matter.

Clinical deficits after injury to the CNS are due, in large part, to dysfunction of white matter (myelinated fiber tracts), including descending and ascending tracts in the spinal cord. A crucial set of questions, in the search for strategies that will preserve or restore function after CNS injury, centers on the pathophysiology of, and mechanisms underlying recovery of conduction in, CNS white matter. These questions are relevant both to spinal cord injury, and to brain infarction, which frequently affects white matter.

Ionic mechanisms of aglycemic axon injury in mammalian central white matter.

The authors investigated ionic mechanisms underlying aglycemic axon injury in adult rat optic nerve, a central white matter tract. Axon function was assessed using evoked compound action potentials (CAPs). Glucose withdrawal led to delayed CAP failure, an alkaline extracellular pH shift, and an increase in extracellular [K(+)]. Sixty minutes of glucose withdrawal led to irreversible axon injury. Aglycemic axon injury required extracellular calcium; the extent of injury progressively declined as bath [Ca(2+)] was decreased. To evaluate Ca(2+) movements during aglycemia, the authors recorded extracellular [Ca(2+)] ([Ca(2+)](o)) using Ca(2+)-sensitive microelectrodes. Under control conditions, [Ca(2+)](o) fell with a similar time course to CAP failure, indicating extracellular Ca(2+) moved to an intracellular position during aglycemia. The authors quantified the magnitude of [Ca(2+)]o decrease as the area below baseline [Ca(2+)]o during aglycemia and used this as a qualitative measure of Ca(2+) influx. The authors studied the mechanisms of Ca(2+) influx. Blockade of Na(+) influx reduced Ca(2+) influx and improved CAP recovery, suggesting Na(+)-Ca(2+) exchanger involvement. Consistent with this hypothesis, bepridil reduced axon injury. In addition, diltiazem or nifedipine decreased Ca(2+) influx and increased CAP recovery. The authors conclude aglycemic central white matter injury is caused by Ca(2+) influx into intracellular compartments through reverse Na(+)-Ca(2+) exchange and L-type Ca(2+) channels.

Effects of temperature on evoked electrical activity and anoxic injury in CNS white matter.

Temperature is known to influence the extent of anoxic/ischemic injury in gray matter of the brain. We tested the hypothesis that small changes in temperature during anoxic exposure could affect the degree of functional injury seen in white matter, using the isolated rat optic nerve, a typical CNS white matter tract (Foster et al., 1982). Functional recovery after anoxia was monitored by quantitative assessment of the compound action potential (CAP) area. Small changes in ambient temperature, within a range of 32 to 42 degrees C, mildly affected the CAP of the optic nerve under normoxic conditions. Reducing the temperature to < 37 degrees C caused a reversible increase in the CAP area and in the latencies of all three CAP peaks; increasing the temperature to > 37 degrees C had opposite effects. Functional recovery of white matter following 60 min of anoxia was strongly influenced by temperature during the period of anoxia. The average recovery of the CAP, relative to control, after 60 min of anoxia administered at 37 degrees C was 35.4 +/- 7%; when the temperature was lowered by 2.5 degrees C (i.e., to 34.5 degrees C) for the period of anoxic exposure, the extent of functional recovery improved to 64.6 +/- 15% (p < 0.00001). Lowering the temperature to 32 degrees C during anoxic exposure for 60 min resulted in even greater functional recovery (100.5 +/- 14% of the control CAP area). Conversely, if temperature was increased to > 37 degrees C during anoxia, the functional outcome worsened, e.g., CAP recovery at 42 degrees C was 8.5 +/- 7% (p < 0.00001). Hypothermia (i.e., 32 degrees C) for 30 min immediately following anoxia at 37 degrees C did not improve the functional outcome. Many processes within the brain are temperature sensitive, including O2 consumption, and it is not clear which of these is most relevant to the observed effects of temperature on recovery of white matter from anoxic injury. Unlike the situation in gray matter, the temperature dependency of anoxic injury cannot be related to reduced release of excitotoxins like glutamate, because neurotransmitters play no role in the pathophysiology of anoxic damage in white matter (Ransom et al., 1990a). It is more likely that temperature affects the rate of ion transport by the Na(+)-Ca2+ exchanger, the transporter responsible for intracellular Ca2+ loading during anoxia in white matter, and/or the rate of some destructive intracellular enzymatic mechanism(s) activated by pathological increases in intracellular Ca2+.

Anoxia-induced changes in extracellular K+ and pH in mammalian central white matter.

In gray matter (GM), anoxia induces prominent extracellular ionic changes that are important in understanding the pathophysiology of this insult. White matter (WM) is also injured by anoxia but the accompanying changes in extracellular ions have not been studied. To provide such information, the time course and magnitude of anoxia-induced changes in extracellular K+ concentration ([K+]o) and extracellular pH (pHo) were measured in the isolated rat optic nerve, a representative central WM tract, using ion-selective microelectrodes. Anoxia produced less extreme changes in [K+]o and pHo in WM than are known to occur in GM; in WM during anoxia, the average maximum [K+]o was 14 +/- 2.9 mM (bath [K+]o = 3 mM) and the average maximum acid shift was 0.31 +/- 0.07 pH unit. The extracellular space volume rapidly decreased by approximately 20% during anoxia. Excitability of the rat optic nerve, monitored as the amplitude of the supramaximal compound action potential, was lost in close temporal association with the increase in [K+]o. Increasing the bath glucose concentration from 10 to 20 mM resulted in a much larger acid shift during anoxia (0.58 +/- 0.08 pH unit) and a smaller average increase in [K]o (9.2 +/- 2.6 mM). The increased extracellular glucose concentration presumably provided more substrate for anaerobic metabolism, resulting in more extracellular lactate accumulation (although not directly measured) and a greater acid shift. Enhanced anaerobic metabolism during anoxia would provide energy for operation of ion pumps, including the sodium pump, that would result in smaller changes in [K+]o. These effects were probably responsible for the observation that the optic nerve showed significantly less damage after 60 min of anoxia in the presence of 20 mM glucose compared to 10 mM glucose. Under normoxic conditions, increasing bath K+ concentration to 30 mM (i.e., well beyond the level shown to occur with anoxia) for 60 min caused abrupt loss of excitability during the period of application but minimal change in the amplitude of the compound action potential following the period of exposure. The anoxia-induced increase in [K+]o, therefore, was not itself directly responsible for irreversible loss of optic nerve function. These observations indicate that major qualitative differences exist between mammalian GM and WM with regard to anoxia-induced extracellular ionic changes.

Morphology of astrocytes and oligodendrocytes during development in the intact rat optic nerve.

The detailed three-dimensional morphology of macroglial cells was determined throughout postnatal development in the intact rat optic nerve, a central nervous system white matter tract. Over 750 cells were analyzed by intracellular injection of horseradish peroxidase or Lucifer Yellow to provide a new perspective of glial differentiation in situ. Retrograde analysis of changes in glial morphology allowed us to identify developmental timetables for three morphological subclasses of astrocytes and oligodendrocytes, and to estimate their time of emergence from undifferentiated glial progenitors. Glial progenitors were recognised throughout postnatal development and persisted in 35-day-old nerves, where we suggest they represent adult progenitor cells. Astrocytes were present at birth, but the majority of these cells developed over the first week as three morphological classes emerged having either transverse, random, or longitudinal process orientation. Several lines of evidence led us to believe that the majority of astrocytes in the rat optic nerve were morphological variations of a single cell type. Young oligodendrocytes were first observed 2 days after birth, indicating that they diverged from progenitors at or near this time. During early development these cells extended a large number of fine processes, which then bifurcated and extended along axons. Later, as myelination proceeded, oligodendrocytes exhibited fewer processes which grew symmetrically and uniformly along the axons, resulting in a highly stereotypic mature oligodendrocyte form. Our analysis of oligodendrocyte growth suggests that these cells did not myelinate axons in a random manner and that axons may influence the myelinating processes of nearby oligodendrocytes.

Levodopa-responsive parkinsonism following central herniation due to bilateral subdural hematomas.

A 66-year-old man suffered bilateral subdural hematomas progressing to central herniation, despite repeated surgical evacuations. This eventually resolved, leaving him with a severe parkinsonian syndrome that was responsive to levodopa. MRI and CT showed midbrain compression from central herniation, and a follow-up MRI revealed thinning of the pars compacta. The clinical and radiologic evidence suggested that midbrain compression from central herniation was the probable cause of parkinsonism in this patient.

Anoxic injury of CNS white matter: protective effect of ketamine.

Gray and white matter of the mammalian CNS are both damaged by anoxia. Anoxic injury in gray matter is mediated in part by excessive accumulation of excitotoxins like glutamate. Drugs such as ketamine, a dissociative anesthetic known to block glutamate (NMDA) receptors, reduce hypoxic neuronal injury in gray matter. In this study we used the isolated rat optic nerve preparation to determine if ketamine influences recovery after anoxia in a nonsynaptic system, ie, CNS white matter. Optic nerves from adult rats were exposed to a standard 60-minute period of anoxia. Ketamine (1 mM) improved recovery of the compound action potential (CAP) after anoxia. Since glutamate and aspartate (up to 10 mM) had no effect on CAP amplitude in the optic nerve, the effect of ketamine is probably not mediated by NMDA receptor blockade. These observations indicate that ketamine is able to protect CNS white matter, as well as gray matter, from anoxic injury.

K(+)-induced reversal of astrocyte glutamate uptake is limited by compensatory changes in intracellular Na+.

Glutamate uptake is coupled to counter-transport of K+, and high external K+ concentrations can induce reversal of glutamate uptake in whole-cell patch-clamp and isolated membrane preparations. However, high external K+ causes little or no reversal of glutamate uptake in intact astrocytes, suggesting a regulatory mechanism not evident in membrane preparations. One mechanism by which intact cells could limit the effects of altered extracellular ion concentrations on glutamate transport is by compensatory changes in intracellular Na+ concentrations. This possibility was examined using astrocyte cultures treated in two ways to reduce the driving force for glutamate uptake: incubation in high K+ (with reciprocal reduction in Na+), and incubation with metabolic inhibitors to induce ATP depletion. ATP depletion produced a rise in intracellular Na+, a collapse of the membrane sodium gradient and a massive reversal of glutamate uptake. By contrast, incubation in high K+/low Na+ medium did not significantly alter the sodium gradient and did not induce glutamate uptake reversal. The sodium gradient was shown to be maintained under these conditions by compensatory reductions in intracellular Na+ that approximately matched the reductions in extracellular Na+. These findings suggest a mechanism by which astrocytes may limit reversal of glutamate uptake under high K+/low Na+ conditions, and further suggest a general mechanism by which Na(+)-dependent transport processes could be shielded from fluctuating extracellular ion concentrations.

Sodium channel mRNAs I, II and III in the CNS: cell-specific expression.

The cellular localization of rat brain sodium channel alpha-subunit mRNAs I, II and III in the central nervous system (CNS) was examined by non-isotope in situ hybridization cytochemistry utilizing two independent sets of isoform-specific RNA probes, one set recognizing sodium channel isoforms in the coding region and the other in the non-coding region of the sodium channel messages. The independent sets of probes demonstrated qualitatively similar patterns of sodium channel mRNA expression. In the hippocampus, sodium channel mRNA I was very weakly expressed in the pyramidal layer and in the granular layer of the dentate gyrus; in contrast, sodium channel mRNA II was strongly expressed by neurons in these regions. Sodium channel mRNA III exhibited low-to-moderate expression in some neurons of the pyramidal layer of the hippocampus and granular layer of the dentate gyrus, and was not detectable in others. In the cerebellum, sodium channel mRNA I was moderately expressed in some Purkinje cells, weakly expressed in scattered cells in the molecular layer and negligibly expressed in the granular layer. Sodium channel mRNA II was strongly expressed in Purkinje and granule cells, and was moderately expressed in some cells in the molecular layer. Sodium channel mRNA III was generally not detectable in the cerebellum. In the spinal cord, motor neurons and scattered neurons throughout the gray matter exhibited moderate-to-strong expression of both sodium channel mRNA I and II. A population of cells in the spinal zone of Lissauer showed heavy expression of mRNA II, but not mRNA I. Sodium channel mRNA III was not detectable in spinal cord neurons. These observations are consistent with a general regional distribution of sodium channel message isoforms, with mRNA II being preferentially expressed in rostral regions of the CNS and mRNA I in caudal regions. However, the results also indicate that different cell types, within a given region, display different patterns of sodium channel mRNA expression. Moreover, these data suggest that individual neurons may express multiple forms of sodium channel mRNA.

Sodium channel mRNAs in cultured spinal cord astrocytes: in situ hybridization in identified cell types.

The expression of rat brain sodium channel alpha-subunit mRNAs I, II and III and a putative glial cell-specific sodium channel (NaG) mRNA was examined in cultured astrocytes from P-0 rat spinal cord by RNA blot hybridization and by non-isotope in situ hybridization cytochemistry utilizing two independent sets of isoform-specific RNA probes. Sodium channel mRNA I was not detectable in the cultured astrocytes by RNA blot or in situ hybridization. Sodium channel mRNA II showed negligible-to-low levels of expression in flat, fibroblast-like and 'pancake' astrocytes at 4 days in vitro (div), while stellate, process-bearing astrocytes exhibited low-to-moderate levels of mRNA II expression. At 7 div, mRNA II expression ranged from low-to-moderate in flat astrocytes and was moderately high in most process-bearing astrocytes. In RNA blots, a weak band was observed at 9.5 kb. Sodium channel mRNA III expression was negligible in flat astrocytes and was detectable in low-to moderate levels in stellate astrocytes beginning at 4 div; by 7 div, mRNA III was detectable in low levels in flat astrocytes and low-to-moderate levels in stellate astrocytes. RNA blots showed two bands of nearly equal intensity, one at 9.0 kb and one at 7.2 kb. NaG mRNA showed increased expression with time in culture, being detectable in flat and stellate astrocytes at 4 div and becoming very prominent in flat astrocytes at extended times in culture. In RNA blots of cultured astrocytes at 7 div, a strong hybridizing signal with the NaG probe was observed. These observations demonstrate that flat and stellate astrocytes cultured from rat spinal cord express rat brain sodium channel mRNA II and III, and NaG, and suggest that astrocytes in vitro may co-express multiple forms of sodium channel mRNA.

Brain extracellular space: developmental studies in rat optic nerve.

Analysis of neural activity-dependent fluctuations in K+, H+, and ECS dimensions in the developing RON has revealed major changes during the first two to three postnatal weeks. The emergence of the adult ceiling level for evoked extracellular K+ (10 to 12 mM) and significant ECS shrinkage are roughly correlated in time with the proliferation and maturation of glial cells in this structure. This observation and others have led to the hypothesis that ECS shrinkage depends upon electrolyte and water transport into glial cells with subsequent swelling. Development of the adult K+ ceiling level may also depend upon glial cells, but it is likely that other factors contribute to this homeostatic mechanism. Marked alterations in activity-dependent pHo shifts were seen with development and may be related to changes in the activity of carbonic anhydrase in this structure. The technological means are at hand to pursue these questions vigorously in an effort to provide further insight into the mechanisms of ionic and fluid homeostasis of brain ECS, and the developing RON appears to be a useful model system in this regard.

Lysophosphatidic acid-induced calcium signals in cultured rat oligodendrocytes.

Oligodendrocytes are the myelin forming glial cells of the CNS and are known to express receptors linked to ion channels and intracellular second messenger cascades. In this paper, we describe the intracellular calcium responses of cells from the oligodendrocyte lineage to application of lysophosphatidic acid (LPA), a naturally occurring, growth factor-like phospholipid. Oligodendrocyte precursors did not respond to application of LPA (1 microM). In mature oligodendrocytes, however, LPA (1 microM) induced an increase in the intracellular calcium concentration ([Ca2+]i). In the majority of cells this increase was followed by a persistent plateau phase. The LPA-induced [Ca2+]i signal vanished in Ca2+-free medium, implying that it arose due to a Ca2+ influx across the plasma membrane. Preincubation of the cells with Pertussis-toxin prevented the generation of LPA-induced [Ca2+]i signals. We conclude that cultured rat oligodendrocytes express functional LPA receptors, which mediate a transmembrane Ca2+ influx via a Pertussis-toxin-sensitive G-protein.

Changes in [Ca2+]0 during anoxia in CNS white matter.

Irreversible anoxic injury of axons in the rat optic nerve requires the presence of extracellular Ca2+. To test the hypothesis that Ca2+ enters an intracellular compartment during anoxia we monitored [Ca2+]0 in this CNS white matter tract using ion-sensitive microelectrodes. Periods of anoxia lasting 15 min resulted in a rapid, reversible increase in [Ca2+]0 accompanied by transient loss of nerve conduction. This increase in [Ca2+]0 was apparently the result of extracellular space shrinkage. Anoxic periods lasting 60 min resulted in an initial rise followed by a sustained fall in [Ca2+]0, indicative of net influx of Ca2+ into an intracellular compartment. Following reoxygenation after 60 min of anoxia, [Ca2+]0 slowly returned toward control levels but nerve conduction recovered incompletely, indicating irreversible loss of function. Removal of bath Ca2+ lowered [Ca2+]0 to about 100 microM, prevented the anoxia-induced fall in [Ca2+]0, and protected against irreversible loss of the compound action potential.

A simple method for making ion-selective microelectrodes suitable for intracellular recording in vertebrate cells.

A simple procedure for manufacturing Cl-, K+, and pH liquid membrane ion-sensitive microelectrodes is presented in detail. Electrodes suitable for recording from the specimen of interest are back-filled with a small amount of silane solution and heated for 5 min on a hot plate at a temperature between 400 and 500 degrees C, after which they are injected with the ion-sensitive resin. The procedure is adaptable to many different glass stocks, e.g., single-barreled, double-barreled, or theta glass, and can be used to produce electrodes having a wide range of tip sizes for recording either extracellular or intracellular ion activities. Another advantage of the method is speed; up to 10 electrodes can be prepared simultaneously, permitting over 40 functional electrodes to be made per hour.

Effects of altered gliogenesis on activity-dependent K+ accumulation in the developing rat optic nerve.

Gliogenesis in the rat optic nerve is disrupted by neonatal treatment with the mitotic inhibitor 5-azacytidine (5-AZ). The rate of myelination and number of glial cells are markedly reduced in treated animals. We analyzed the physiological consequences of these chemically induced morphological alterations in terms of activity-dependent K+ accumulation in brain extracellular space and characteristics of the compound action potential (CAP). Nerves from 5-AZ-treated animals older than 5 days of age showed significantly higher activity-dependent 'ceiling levels' of extracellular K+ concentration ( [K+]o) than controls. This result is consistent with the hypothesis that glial cells are involved in K+ homeostasis at a cellular level and play a role in helping to set the ceiling level of activity-dependent K+ accumulation. The CAPs of 5-AZ-treated nerves older than 5 days of age were larger and generally of simpler configuration than those observed in control animals, perhaps due, among other factors, to the retained uniformity of axonal conduction velocity caused by inhibition of myelination.

Ionic determinants of excitability in cultured mouse dorsal root ganglion and spinal cord cells.

The ionic components of the action potentials of mouse spinal cord (SC) cells and dorsal root ganglion (DRG) cells were studied in dissociated cell cultures. It was found that the action potentials of SC cells required Na+ in the medium and were blocked by tetrodotoxin (TTX) (1 micron). Action potentials of DRG cells, on the other hand, were not blocked by TTX (up to 10 micron) and were observed in Na-free media in the presence of 8 mM Ca2+. In low Na (31 mM), low Ca2+ (0.1 mM) medium, action potentials were not observed but could be obtained if the Ca2+ concentration was increased. Action potentials of DRG cells investigated in low Na concentration in the presence of 1 mM or 8 mM Ca2+ became larger in amplitude and shorter in duration when the sodium concentration was increased. Na+ has this effect even in the presence of TTX. It is concluded that the action potentials of SC cells result mainly from a TTX-sensitive Na component. The action potentials of DRG cells on the other hand have both a TTX-insensitive Na component and a Ca2+ component.

Different Na+ currents in P0- and P7-derived hippocampal astrocytes in vitro: evidence for a switch in Na+ channel expression in vivo.

Hippocampal astrocytes, derived from postnatal day zero (P0) rats, appear to be pluripotential with respect to sodium current expression in vitro, and display Na+ currents with h infinity midpoints close to -65 up to 5 days in vitro (DIV), and Na+ currents with midpoints close to -85 mV at 6 DIV and thereafter. These astrocytes also exhibit a biphasic pattern of Na+ current density, which is expressed at moderate levels at early times in vitro and decreases throughout the first 5 DIV, prior to expressing a second peak for the duration of time in culture. These observations have been interpreted as suggesting that astrocytes in these cultures display a 'switch' in Na+ channel biosynthesis, so that they express different types of Na+ current (with different h infinity curves) at early and later times in culture. To test the hypothesis that a similar switch in Na+ channel expression occurs in vivo, we have used patch-clamp methods to study Na+ current expression in astrocytes derived from rat hippocampus at various stages of postnatal development, P0, P4, P5 and P7. We observed a biphasic distribution of Na+ current density, which was highest in P0- and P7-derived astrocytes (18 pA/pF and 10.3 pA/pF, respectively); astrocytes derived at P4 and P5 did not express sodium currents. While P0-derived astrocytes show depolarized h infinity curves (midpoints close to -65 mV) at early times in culture, P7-derived astrocytes, studied at comparable times in vitro, display hyperpolarized h infinity curves (midpoints close to -85 mV).(ABSTRACT TRUNCATED AT 250 WORDS)