Abstract
Ischemic injury of immature oligodendrocytes is a major component of the brain injury associated with cerebral palsy, the most common human birth disorder. We now report that cultured immature oligodendrocytes [O4+/galactoceramide (GC)−] are exquisitely sensitive to ischemic injury (80% of cells were dead after 25.5 min of oxygen and glucose withdrawal). This rapid ischemic cell death was mediated by Ca2+ influx via non-NMDA glutamate receptors. The receptors were gated by the release of glutamate from the immature oligodendrocytes themselves via reverse glutamate transport and included a significant element of autologous feedback of glutamate from cells onto their own receptors. High (≥100 μm) extracellular glutamate was protective against ischemic injury as a result of non-NMDA glutamate receptor desensitization. Other potential pathways of Ca2+ influx, such as voltage-gated Ca2+ channels, NMDA receptors, or the Na+–Ca2+ exchanger, did not significantly contribute to ischemic Ca2+ influx or cell injury. Release of Ca2+ from intracellular stores was also not an important factor. In agreement with previous studies, more mature oligodendrocytes (O4−/GC+) were found to be less sensitive to ischemic injury than were the immature cells studied here.
- Ca2+
- cell death
- cerebral palsy
- ischemia
- glia
- glutamate transport
- neonatal brain injury
- necrotic cell death
- non-NMDA glutamate receptor
- oligodendrocyte
- white matter
Cerebral palsy is the most common human birth disorder, affecting between 1 and 2.5 per 1000 live births in the United States (Kuban and Leviton, 1994). The major pathology associated with cerebral palsy is an ischemic lesion most frequently located in the periventricular white matter and arising from a transient hypoxic-ischemic event in utero (Banker and Larroche, 1962; Paneth et al., 1994; Volpe, 1995). This lesion is termed “periventricular leukomalacia” and is characterized as an initial coagulating necrosis involving damage to axons and glia. Oligodendrocyte cell death is particularly marked, leading to hypomyelination (Flodmark et al., 1989; van de Bor et al., 1989; Rorke, 1992; Paneth et al., 1994; Volpe, 1995). It is the loss of axonal connections and myelination in these white matter structures that underlie the catastrophic motor deficits that characterize cerebral palsy (Volpe, 1995).
Typically, the fetal white matter structures that are subject to periventricular leukomalacia are undergoing myelinogenesis (Rice et al., 1981; Leviton and Paneth, 1990; Kinney and Back, 1999). The oligodendrocytes involved in the injury are primarily at an immature developmental stage characterized by the presence of surface markers such as A2B5 and O4 and the absence of galactoceramide (GC) and myelin basic protein (MBP) (Hardy and Reynolds, 1991; Rivkin et al., 1995; Miller, 1996; Back et al., 1998; Kinney and Back, 1999). Although immature oligodendrocytes (O4+/MBP−) are more vulnerable than mature oligodendrocytes (O4−/MBP+) to oxidative stress (Back et al., 1998), their sensitivity to ischemic injury is not known. Mature oligodendrocytes (GC+) exposed to 60–120 min of ischemia exhibit cell death determined 24 hr later via a mechanism involving Ca2+-permeable non-NMDA glutamate receptors (McDonald et al., 1998). This pathway can also be activated in immature and mature oligodendrocytes by exposure to non-NMDA glutamate receptor agonists, where cell death has been reported over a 1–24 hr time course (Yoshioka et al., 1996; Matute et al., 1997;Matute, 1998; McDonald et al., 1998). The acute affects (<60 min) of ischemia or non-NMDA glutamate receptor agonists on cell viability were not studied in these previous investigations.
In the present study we examine the effects of ischemia (oxygen and glucose withdrawal) on intracellular Ca2+([Ca2+]i) and cell viability in immature oligodendrocytes (O4+/GC−). Ischemic cell death was found to be extremely rapid (mean latency to cell death was 20.4 min) and occurred after Ca2+ influx mediated by non-NMDA glutamate receptors. Activation of glutamate receptors followed glutamate release from oligodendrocytes, including an element of autologous feedback in which glutamate released from a cell acted on that cell's own receptors. More mature oligodendroyctes (A2B5−/GC+) were more tolerant of ischemia, suggesting that this mechanism of oligodendrocyte injury is particularly relevant to the fetal brain. These findings show immature oligodendrocytes to be more sensitive to ischemia than thought previously. Indeed these cells are more sensitive to ischemic injury than any CNS cell type examined previously, including neurons (Petito and Pulsinelli, 1984; Goldberg and Choi, 1993; Johnson et al., 1994; Pantoni et al., 1996; Kusumoto et al., 1997; Lyons and Kettenmann, 1998; Petito et al., 1998).
MATERIALS AND METHODS
Cell culture. Oligodendrocytes were obtained according to the method of McCarthy and de Vellis (1980). In brief, newborn Long–Evans rat pups [postnatal day 0 (P0)–P2] were anesthetized by CO2 inhalation and decapitated, the cerebral cortexes were dissected out, and the meninges were removed. The cortexes were cut into 1 mm3 pieces and placed in DMEM/F12 (1:1; which contains 4500 mg/l l-glutamine) without FBS and enzymatically treated for 30 min with papain (20 U/ml) before trituration and plating in poly-l-lysine-coated cell culture flasks. The medium was changed <24 hr after plating to eliminate debris and bacteria. Cells were maintained in DMEM/F12 medium supplemented with 10% FBS and kept at 37°C in an atmosphere of 5% CO2 and 95% humid air. The medium was changed every 3–4 d.
For plating on coverslips, immature oligodendrocytes were collected as follows between 10 and 15 d of primary culture. Coculture flasks were shaken with mild-to-moderate force to remove any adherent microglia, and the cultures were washed twice with media. The flask was then shaken with moderate force to remove oligodendrocytes from the astrocyte layer, and the supernatant was collected and centrifuged at 900 rpm for 10 min. The pellet was resuspended in DMEM/F12 with 10% FBS, and the cells were plated on 22 × 44 mm poly-l-lysine-coated glass coverslips. After 20–30 min, the coverslips were washed with PBS and kept in a cell culture incubator in Sato medium with 5% horse serum overnight for use the next day. For experiments on more mature cells, primary cultures were maintained for 30–60 d as described above, and cells were plated onto poly-l-lysine- and laminin-coated 22 × 44 mm glass coverslips.
Immunocytochemistry. Cell cultures were washed in PBS containing 1% normal sheep serum (NSS). Cells were then fixed with 4% paraformaldehyde (PFA) for 10 min before washing three times in PBS with 1% NSS for 5 min each before a 60 min incubation in 4% NSS in PBS and primary antibody (anti-A2B5, -O4, -GC, or -GFAP; Boehringer Mannheim, Indianapolis, IN). In the case of anti-GFAP, a 30 min permeabilization step with 0.5% Triton X-100 was conducted before incubation with primary antibody, and 0.5% Triton X-100 was included in antibody incubation steps. Cells were then washed three times in PBS with 1% NSS for 5 min each before a 60 min incubation in PBS with 1% NSS containing indocarbocyanine (Cy3)-conjugated secondary antibody (Fab fragment; Sigma, St. Louis, MO). Cells were again washed three times in PBS, and the coverslips were mounted in Mowiol medium. Coverslips were visualized with phase-contrast optics, and Cy3 staining was detected by illumination at 550 nm and a rhodamine filter set. Phase-contrast images were collected with a stills camera, and fluorescent images were collected with the digital camera attached to the imaging setup.
Imaging. Coverslips were placed in artificial CSF (aCSF) comprised of (in mm): Na+, 153; K+, 3; Mg2+, 2; Ca2+, 2; Cl−, 131; HCO3−, 26; H2PO4−, 2; and glucose, 10. A stock solution containing 1 mm fura-2 AM (Molecular Probes, Eugene, OR) was made in dry DMSO and 10% pluronic acid. A final concentration of 5 μm fura-2 AM was used for all incubations. Coverslips were incubated in aCSF gassed with hydrated 95% O2 and 5% CO2 for 30–40 min at room temperature before being washed in aCSF and mounted in the perfusion chamber.
Coverslips were sealed onto a Plexiglas perfusion chamber (atmosphere chamber; Warner Instruments, Hamden, CT) with silicone grease. aCSF was run through the chamber at a rate of 2–3 ml/min with a fluid level of ∼1 mm. The top of the chamber was sealed with a second coverslip, and 95% O2 and 5% CO2 were blown over the aCSF at a rate of 1.5 l/min. The chamber is described in greater detail in Fern (1998). aCSF was bubbled with 95% O2 and 5% CO2, kept in a water bath at ∼40°C, and run through Tygon plastic tubing (Norton, OH) that was copper clad to minimize gas exchange. A star valve with a purge system was used to achieve a bath dye washout of ∼1 min (Fern, 1998).
The chamber was mounted on the stage of a Nikon diaphot-TMD-inverted epifluorescence microscope (Tokyo, Japan) equipped with a 20× air objective (Olympus Optical, Tokyo, Japan). Chamber temperature was closely maintained at 37°C using a flow-through feedback tubing heater (Warner Instruments) positioned immediately before the aCSF entered the chamber and a feedback stage heater (Warner Instruments), which heated the metal surround holding the chamber. This combination of heaters regulated the temperature of the bath and coverslip to 37°C as established periodically with a temperature probe.
Cells were visualized with a Hamamatsu C2400 ICCD video camera and image intensifier system (Hamamatsu, Bridgewater, NJ). Data were collected and stored with an image acquisition program from Photon Technology International (East Brunswick, NJ) running on a Dell 486-Omniplex personal computer (Austin, TX). Data were converted to TIF format after the experiment and transferred to a Macintosh Power personal computer for off-line analysis using NIH IMAGE (National Institutes of Health, Bethesda, MD).
Experimental protocol. After being mounted in the microscope, cells were allowed to equilibrate for 20 min. A 5 min period of baseline was then taken before switching to ischemic conditions. Ischemia was induced by changing from aCSF to perfusion with zero-glucose aCSF that had been bubbled with 95% N2 and 5% CO2 for a least an hour. The atmosphere in the recording chamber was simultaneously switched to 95% N2 and 5% CO2. Ischemia was maintained for 55 min. Cells were initially brought into focus during illumination at 360 nm. A field of 15–100 cells was typical and was randomly selected from the central area of the coverslip. One field was used per coverslip, and a minimum of three coverslips was tested for each experimental protocol. Cells were then illuminated at 340, 360, and 380 nm, and images were collected at 520 nm. This series was collected every minute, with 8–16 frames averaged per excitation wavelength. Changes in the 340/380 ratio were taken to indicate changes in [Ca2+]i(Grynkiewicz et al., 1985). Because the majority of cells died during ischemia, it was not possible to calibrate the ratio signal to give accurate values of [Ca2+]i.
Cell death. The 360 signal was monitored to assess the capacity of cells to retain dye. The isosbestic (Ca2+-insensitive) wavelength was used to eliminate the possibility that signal changes were caused by alterations in [Ca2+]i. Sudden and irreversible loss of the 360 signal from a cell such that the fluorescence fell to the background level correlated with the breakdown of cell membrane integrity and release of dye into the extracellular space (Lemasters et al., 1987; Geeraerts et al., 1991; Fern, 1998). Loss of cell membrane integrity was taken to indicate cell death. The use of intracellular fluorescent dye for quantitating cell death has been described in detail (Bevensee et al., 1995), and fura-2 has been used in this way in previous studies (Johnson et al., 1994;Fern, 1998).
Statistics. Results are reported as means ± SEM. Means represent values of all cells studied under a particular condition (cells from all coverslips pooled). Statistical significance was determined by ANOVA with Tukey post-test.
RESULTS
Under phase contrast, cells had either a spherical or bipolar morphology or exhibited a spherical cell body that extended several short processes (Fig.1A,C). Immunostaining for the surface marker O4 (Fig. 1A,B) revealed that almost all cells were positive for this indicator of immature oligodendrocytes (Sommer and Schachner, 1981), a marker widely expressed by immature oligodendrocytes in the midgestation human fetus, the period most commonly subject to periventricular leukomalacia (Kinney and Back, 1999). A large majority of cells also stained positive for the marker of oligodendrocyte precursors A2B5 (Fig.1C,D). This coexpression of O4 and A2B5 is similar to that reported previously in immature oligodendrocytes (Kinney and Back, 1999). A very small number of GC+ cells were observed, and no GFAP+ astrocytes were found (data not shown).
Ischemic Ca2+ influx and cell death
[Ca2+]i(340/380 ratio) (Grynkiewicz et al., 1985) increased rapidly after the initiation of ischemia (Fig. 1E). [Ca2+]i started to rise within the first minute of ischemia and typically continued to increase for the first 5–10 min. [Ca2+]i was relatively stable in cells perfused for 60 min with aCSF, and the 360 intensity of these cells drifted monotonically (Fig. 1G). During ischemia, the 360 intensity of cells collapsed at some point, indicating the lose of cell membrane integrity (Fig. 1E, arrow, cell death). Cells started to lose membrane integrity within the first few minutes of ischemia, with a mean time to cell death of 20.4 min (Fig. 1H, shaded histogram, left y-axis). In cells that survived ischemia for >10–15 min, [Ca2+]i tended to plateau at that point (data not shown). In the absence of extracellular Ca2+ (perfusion with zero Ca2+ and 50 μmEGTA), ischemia typically produced only an initial transient rise in [Ca2+]i that was not associated with cell death (Fig. 1F). The cumulative rate of cell death during ischemia (n = 396) and during ischemia in the absence if extracellular Ca2+ (n = 211) is shown in Figure 1H (solid lines, right y-axis).
Route of Ca2+ influx
Perfusion with 30 μm CNQX (a non-NMDA glutamate receptor antagonist) abolished the rises in [Ca2+]i produced by ischemia in most cells (Fig.2A), although small rises were sometimes observed (data not shown). If the application of 30 μm CNQX was delayed until 10 min after the onset of ischemia, [Ca2+]i typically started to decline at that point toward baseline (Fig.2B). The extent of cell death during ischemia was much reduced by 30 μm CNQX, including the 10 min-delayed application protocol (Fig. 2C). The NMDA receptor antagonist MK-801 had no similar effect on the extent of ischemic cell death (Fig. 2C) or on the changes in [Ca2+]i typically seen during ischemia (Fig. 2D). Perfusion with the broad-spectrum voltage-gated Ca2+ blocker La3+ (100 μm) or the Na+–Ca2+exchange inhibitor bepridil (100 μm) was also without effect (Fig. 2E,F). The effects of perfusion with various solutions on the extent of cell death and the mean time to cell death are shown in Figure3, confirming that only removing extracellular Ca2+ or blocking non-NMDA receptors had a significant impact on these parameters.
Glutamate excitotoxicity in neurons is mediated both by Ca2+ influx and by cell swelling (Goldberg and Choi, 1993). Cytotoxic cell swelling can be prevented in neurons by replacing extracellular Na+ with an impermeant ion such as choline (Goldberg and Choi, 1993). Perfusion with aCSF containing 5 mm Na+(compared with 128 mm Na+ in normal aCSF, the difference replaced with choline) did not affect either Ca2+ influx or the extent of cell death during ischemia (Fig.4A), suggesting that Na+-dependent cell swelling is not an important factor in ischemic injury of neonatal oligodendrocytes. Similar data were found with 28 mmNa+ aCSF (data not shown). Zero Na+ solutions were found to lead to cell detachment and were not used. Block of voltage-gated Na+ channels on the cells with 200 nm TTX also had no effect on Ca2+ influx or cell death during ischemia (Fig. 4B).
Extracellular glutamate: role of receptor desensitization
The effects of exposure to glutamate were investigated under normoxic–normoglycemic conditions. Perfusion with 1 mmglutamate either produced no effect on [Ca2+]i or evoked a partly transient increase (Fig.5A, bottom, top data points, respectively). In a small number of cells, 1 mm glutamate evoked [Ca2+]ioscillations (data not shown). Application of 1 mm glutamate for 55 min resulted in no significant increase in the occurrence of cell death compared with perfusion with aCSF [Fig. 5D, 2.3 ± 0.2% (n = 210) compared with 1.4 ± 0.5% (n = 211), respectively; p > 0.5]. Perfusion with the non-NMDA glutamate receptor desensitization blocker cyclothiazide (100 μm) resulted in large and sustained increases in [Ca2+]i during perfusion with 1 mm glutamate (Fig.5B), which could be associated with cell death (Fig.5C). The extent of cell death during perfusion with 1 mm glutamate in the presence of 100 μm cyclothiazide was significantly greater than that during perfusion with aCSF [Fig. 5D, 15.5 ± 3.4% (n = 172) compared with 1.4 ± 0.5% (n = 211), respectively; ***p < 0.001].
In the presence of 1 mm glutamate, ischemia resulted in either a small rise in [Ca2+]i or no detectable rise (Fig.6A, bottom data points). Glutamate (1 mm) was highly protective against ischemic cell death, reducing the extent of cell death to 24.5 ± 0.4% (Fig. 6B; n = 163), significantly lower than that in control ischemia (Fig. 6B, ***p < 0.001). In the presence of cyclothiazide (100 μm) the protective effect of 1 mm glutamate was significantly reduced, with 35.9 ± 1.2% of cells dying during ischemia (Fig.6B; n = 145; ***p < 0.001 compared with ischemic cell death in 1 mm glutamate alone). Large increases in [Ca2+]i were observed during ischemia in the combined presence of 100 μm cyclothiazide and 1 mmglutamate (Fig. 6A, top data points). As would be predicted if the protective action of glutamate were caused by receptor desensitization, the effect was concentration dependent. Glutamate concentrations between 100 nm and 25 μm did not influence either the mean time to ischemic cell death or the proportion of cells that died during ischemia compared with control ischemia (Fig. 6C,D).
Glutamate release from oligodendrocytes
In an effort to reduce extracellular glutamate concentration, we perfused the cells with a pyruvate and glutamic–pyruvic transaminase (GPT) glutamate-scavanging system. In the presence of pyruvate, GPT will catalyze the conversion of glutamate to alanine and a-ketoglutarate, reducing the glutamate concentration (O'Brien and Fischbach, 1986; Min et al., 1998). Increases in [Ca2+]i during ischemia in the presence of 20 U/ml GPT and 2 mm pyruvate were generally smaller than those seen in the presence of pyruvate alone (Fig. 7A,B). The glutamate-scavenging system reduced the extent of cell death during 55 min of ischemia to 65.5 ± 9.9% (n = 246), significantly lower than that found during ischemia in the presence of pyruvate alone (Fig. 7C, 86.6 ± 5.3%;n = 255; ***p < 0.001). Large increases in [Ca2+]i were found in immature oligodendrocytes during ischemia in the presence of 2 mm pyruvate alone (Fig. 7B), and the extent of cell death during ischemia was not significantly different from that found during control ischemia (Fig. 7C, 86.7 ± 5.3%; n = 255; p > 0.5).
The glutamate transport inhibitor dihydrokainic acid (DKA) is membrane permeant and has been identified as an inhibitor of glutamate release via reverse transport (Seki et al., 1999). Perfusion with 100 μm DKA significantly extended the mean time to ischemic cell death compared with control (Fig. 7E, 39.4 ± 0.5 min; n = 327; p < 0.001). The ischemic cell death found in the presence of DKA was associated with significant increases in [Ca2+]i (Fig.7D).
To test the hypothesis that glutamate released from a cell may act on glutamate receptors on the same cell, oligodendrocyte cultures of very low cell density were produced. The cell culture protocol was similar to that used for normal density cultures, with the exception that only a small number of cells from primary culture were plated onto the coverslips. Coverslips were used between 4 and 24 hr after plating. After the coverslips were mounted in the microscope, the number of cells on the coverslip was counted by eye (there were 4–20 cells/coverslip), and a cell distant from other cells was chosen for study. Typically, the cell closest to the chamber inflow was selected, and in all cases only one cell was present within the visual field of the microscope (a 100 μm2 area). Typical effects of ischemia on these very low-density immature oligodendrocytes are shown in Figure 8. Cell death occurred in 6 out of 12 of the cells (Fig. 8A,arrow), and ischemia was followed by an increase in [Ca2+]i in all 12 cells including cells that survived (Fig. 8B). The mean time to cell death was 40.1 ± 1.0 min, significantly longer than in normal cultures (p < 0.001).
Mature oligodendrocytes
The O4+/GC−immature oligodendrocytes that are used in this study and that populate fetal white matter have a number of physiological differences from the more mature oligodendrocytes used in some previous studies (Matute, 1998; McDonald et al., 1998). To test the sensitivity to ischemic injury in more mature oligodendrocytes, cells remained in primary culture for 30–60 d before plating onto coverslips. These cells had more extensive processes than the immature cells and were A2B5−/GC+(Fig. 9C, inset). Fifty-five minutes of ischemia produced either no change in [Ca2+]i in these cells or a gradual increase (Fig. 9A,B). Only 43.4 ± 5.3% of the mature cells died during this length of ischemia (n = 138), with a mean time to death of 42.8 ± 0.8 min. Both the mean time to death and the percentage of cells dying were significantly different from that found in immature oligodendroyctes (p < 0.001 in both cases). A comparison of the distribution of cell death with that of immature cells is shown in Figure 9C.
DISCUSSION
The current study focused on acute ischemic injury in cultured immature oligodendrocytes (almost all O4+/GC− and a large proportion also A2B5+/GC−). These cells correspond closely to the immature oligodendrocytes that populate CNS white matter at the start of the process of myelination, a developmental period highly vulnerable to periventricular leukomalacia (Back et al., 1998) (see introductory remarks). The onset of ischemia was followed in these cells by an increase in [Ca2+]i that resulted primarily from Ca2+ influx through non-NMDA glutamate receptors. The [Ca2+]i increase was apparent within 1 min of the onset of ischemia in most cells and continued to increase for 5–10 min before reaching a plateau. Cell death became evident within 5 min of the onset of ischemia, and the mean time to cell death was 20.4 min with 80% of the cells dead after 31 min; this represents the highest sensitivity to ischemic injury in any CNS cell type yet studied (Petito and Pulsinelli, 1984; Goldberg and Choi, 1993; Johnson et al., 1994; Pantoni et al., 1996; Kusumoto et al., 1997; Lyons and Kettenmann, 1998; Petito et al., 1998).
The rapid onset of cell death was a product of Ca2+ influx because no significant cell death occurred in the absence of extracellular Ca2+ or when non-NMDA glutamate receptors were blocked with CNQX. Block of other potential sources of Ca2+ influx such as the Na+–Ca2+exchanger or voltage-gated Ca2+ channels did not reduce the extent of cell death during ischemia or increase significantly the time to death. The mechanism of Ca2+ influx and cell death in immature oligodendrocytes is therefore distinct from that found in astrocytes (Fern, 1998, 2000), neurons (Goldberg and Choi, 1993), or axons (Stys, 1998) and was similar, although far more rapid, than that reported in mature oligodendrocytes (Yoshioka et al., 1996; Matute, 1998; McDonald et al., 1998). The mechanism of cell death of immature oligodendroyctes is summarized in Figure 10.
Although cell swelling has been observed in mature oligodendrocytes during ischemia (Pantoni et al., 1996; McDonald et al., 1998), there was no systematic change in the 360 intensity (the isosbestic point of fura-2) recorded from cells during ischemia in the current experiments. Any net increase in the water content of the cells associated with swelling would lead to dye dilution and reduction in the 360 intensity (see Fern, 1998). Lowering the extracellular Na+ concentration, which will reduce Na+-dependent cell swelling (Goldberg and Choi, 1993), did not affect the extent or time course of cell death during ischemia. These data indicate that cell swelling is not an important factor in the rapid ischemic cell death of immature oligodendrocytes reported here.
Glutamate release
The protective action of glutamate receptor block and of a glutamate-scavenging system confirmed the role of extracellular glutamate in ischemic cell death of immature oligodendrocytes. Contaminating cell types were extremely rare in the cell cultures, and the source of glutamate in the bath during ischemia is therefore the oligodendrocytes themselves. Oligodendrocytes express functional glutamate transporters including GLAST and GLT-1 (Reynolds and Herschkowitz, 1986; Kondo et al., 1995; Domercq and Matute, 1999), which will operate in glutamate release mode under ischemic conditions (Nicholls and Attwell, 1991; Levi and Raiteri, 1993). The protective action of the reverse glutamate transport inhibitor DKA (Seki et al., 1999) confirmed that reverse glutamate transport was the mechanism of glutamate release during ischemia. Perfusion with Na+-depleted aCSF or with the voltage-gated Na+ channel blocker TTX was not protective against ischemic injury, indicating that Na+ influx is not an important element in reverse glutamate transport in these cells.
Glutamate receptor desensitization
Rapid desensitization is a feature of non-NMDA glutamate receptors that can limit toxic influx of Ca2+ via this route (David et al., 1996). In immature oligodendrocytes, application of 1 mm glutamate did not typically result in a sustained increase in [Ca2+]i or in significant cell death over a 55 min period. Coperfusion with cyclothiazide, which will reduce non-NMDA glutamate receptor desensitization (Patneau et al., 1993; Yamada and Tang, 1993), sensitized the cells to the presence of 1 mm glutamate such that large sustained increases in [Ca2+]i were produced and a significant degree of cell death occurred. Desensitization of non-NMDA receptors by perfusion with high concentrations of glutamate (100–1000 μm) was highly protective against ischemic Ca2+ influx and cell death. This protective effect was reduced by cyclothiazide. These findings correlate with previous results showing toxicity of 1 mm glutamate over a 6–24 hr time course in oligodendrocytes via a nonglutamate receptor-mediated mechanism (Oka et al., 1993). Presumably in these previous studies glutamate receptors were desensitized by the high glutamate concentration, and glutamate toxicity was mediated by a separate, more slowly operating, pathway. The current findings suggest that very high extracellular glutamate concentrations would be protective of immature oligodendrocytes during the initial period of an ischemic event in vivo and that the precise extracellular glutamate concentration present during the development of periventricular leukomalacia will be a critical variable for oligodendrocyte survival.
Fatal autologous glutamate feedback?
The observation that glutamate release from immature oligodendrocytes is fatal to these cells raises the possibility of autologous feedback, i.e., glutamate released from a cell acting on receptors on the same cell. When cells were plated on coverslips at very low density, ischemia was followed by an increase in [Ca2+]i in all cells, resulting in cell death within 55 min in 50% of cells. Because only one cell was visible in the microscope field (100 μm2) the minimum distance over which glutamate would have to diffuse from a neighboring cell under these conditions is 50 μm. In some coverslips as few as four cells were counted on the entire coverslip, representing a much larger cell-free zone around the cell under study. In all cases, a cell at the chamber inlet edge of the coverslip was selected, so that contaminating glutamate from neighboring cells would have to diffuse against the fluid flow to reach the cell being studied. These considerations strongly indicate that glutamate released during ischemia acted on glutamate receptors on the homologous cell to evoke potentially fatal Ca2+ influx. In vivo, where the extracellular space around cells is limited (Nicholson and Sykova, 1998), conditions will strongly favor the operation of a similar autologous feedback loop mediated by the glutamate transport proteins known to be present on these cells in situ (Domercq and Matute, 1999).
Extremely rapid ischemic injury
The time course of immature oligodendrocyte death during ischemia reported here is rapid. Previous studies have shown that early injury to oligodendrocytes is a feature of ischemic adult brain in vivo (Pantoni et al., 1996; Petito et al., 1998). In the current study, ischemic injury of mature (GC+) oligodendrocytes occurred more slowly than that of immature oligodendrocytes, at a rate similar to that reported previously for non-NMDA receptor-mediated injury of GC+oligodendrocytes (McDonald et al., 1998) and mature oligodendrocytes during ischemia in vivo (Pantoni et al., 1996; Petito et al., 1998). The time course of oligodendrocyte injury in ischemic CNS white matter during the development of periventricular leukomalacia is not known, but the current results indicate a critical sensitivity to ischemia in cultured cells at the same developmental point. This suggests that pharmacological intervention to protect immature oligodendrocytes in the fetus at risk of cerebral palsy is an area worthy of future investigation because injury to these cells may be the earliest cellular manifestation of coagulating necrosis.
Footnotes
This work was supported by the National Institute of Neurological Disorders and Stroke Grant NS36790 to R.F. Thanks to Bruce R. Ransom for use of facilities and Mark Moksycki for technical assistance.
Correspondence should be addressed to Dr. Robert Fern, Department of Neurology, University of Washington, Box 356465, Seattle, WA 98195. E-mail address: bobfern{at}u.washington.edu.