Abstract
The weaver mutation results in the extensive death of midline cerebellar granule cells. The mutation consists of a single base pair substitution of the gene encoding the G-protein-activated inwardly rectifying potassium channel protein, GIRK2. The functional consequences of this mutation are still in dispute. In this study we demonstrate the in vivo and in vitrorescue of weaver granule cells when NR1 NMDA subunits are eliminated in weaverNR1 double mutants. This rescue of weaver granule cells provides evidence that wvGIRK2 alone is not sufficient to cause granule cell death.
- weaver
- GIRK2
- granule cell development
- cerebellum
- NMDA receptor
- cell death
The external granular layer (EGL) of the cerebellum is the site of genesis of the most abundant neuron in the adult CNS, the granule cell. During the first 3 weeks of postnatal development in the mouse, the cells of the EGL undergo a well characterized temporospatial pattern of granule cell proliferation, migration, and differentiation that is dependent on both the appropriate expression and function of intrinsic and extrinsic factors (Hatten and Heintz, 1995). Genetic mutations that disrupt this orderly developmental progression result in aberrant cerebellar histogenesis (Goldowitz and Hamre, 1998).
This is nowhere more apparent than in the weaver neurological mutant. In this mutation, cerebellar cytoarchitectonics are disrupted severely, attributable primarily to the vast depletion of cerebellar granule cells. In homozygous weaver(wv/wv) mice, granule cell precursors proliferate normally in the EGL, exit the cell cycle, and die just before their migration from the EGL (Smeyne and Goldowitz, 1989).
Recently, the weaver mutation was identified as a single base pair substitution in the gene encoding a G-protein-activated inwardly rectifying potassium channel protein, GIRK2 (Patil et al., 1995). GIRKs are believed to play a role in controlling cell membrane excitability by opposing deviations from the K+ equilibrium potential (Wickman and Clapham, 1995; Slesinger et al., 1996; Ehrengruber et al., 1997). The functional consequences of this mutation are in dispute. Results from whole-cell recordings of wv/wv and wild-type cerebellar granule cells have differed, suggesting that the weavermutant phenotype is attributable either to a gain-of-channel function (wvGIRK2 channels lose their selectivity for K+ and become constitutively active) (Kofuji et al., 1996) or to a loss of GIRK2-mediated currents (Surmeier et al., 1996; Lauritzen et al., 1997). In either case, theweaver mutation must be reconciled with the selective cell death that occurs in the weaver mutant cerebellum. GIRK2 has been shown to be expressed in all cells of the EGL (Kofuji et al., 1996; Slesinger et al., 1996; Chen et al., 1997; Wei et al., 1997), but only the wv/wv midline premigratory EGL cells experience massive degeneration (Herrup and Trenkner, 1987; Smeyne and Goldowitz, 1990). These findings mandate the involvement of another factor in addition to the mutated GIRK2 protein in causing granule cell death.
It is known that the activation of NMDA receptors coupled to an increase in Ca2+ influx through N-type Ca2+ channels triggers granule cell migration from the premigratory zone of the cerebellar EGL (Komuro and Rakic, 1993). We hypothesized that cerebellar granule cell death inwv/wv is attributable to the loss of GIRK2 currents that normally would moderate the NMDA-based depolarizing currents (Surmeier et al., 1996). To test this hypothesis, we generated wv/wvmice carrying the NMDA receptor 1 subunit (NR1) null mutation to see whether granule cell precursors could be rescued from death. The NR1 subunit is required for NMDA receptor function, and targeted disruption of the NR1 gene has been shown to abolish NMDA responses (Forrest et al., 1994). In this study we provide evidence that wvGIRK2 alone is not enough to cause granule cell death in wv/wv, by demonstrating that death is prevented when NMDA receptor function is blocked in wv/wv NR1 double-mutant granule cells.
MATERIALS AND METHODS
Animals. The weaver NR1 colony was established from matings between heterozygous weaver female mice from our on-site, inbred weaver colony (derived from the original stock of weaver mice that was maintained on a C57BL/6 background at Children’s Hospital, Boston, MA) (Sidman et al., 1965) and NR1−/+ mutant males obtained from the laboratory of Tom Curran (St. Jude Children’s Research Hospital, Memphis, TN). TheseNR1−/+ mutants were produced from 129/Sv embryonic stem cells injected into C57BL/6 blastocysts. Founder mice were mated to C57BL/6 mice, and the NR1 colony was maintained by brother × sister matings (Forrest et al., 1994). All animals used in this study were generated from matings between female wv/+ NR1−/+ or wv/wv NR1−/+ mice and male wv/+ NR1−/+ mice.
Determination of genotype. DNA was isolated from the ends of tails, and wv and NR1 genotypes were determined by two separate PCR reactions. NR1 genotypes were identified by a protocol, developed by Douglas Forrest at the former Institute of Molecular Biology at Roche (Nutley, NJ), which uses a common antisense primer (5′-CCA GCC TGC ACA CTT TAG GTC ACA TTG-3′), a sense primer for the wild-type NR1 allele (5′-CCA ACG CCA TAC AGA TGG CCC TGT-3′), and a sense primer for the null allele (5′-GTG CCA GCG GGG CTG CTA AAG-3′). The reaction was performed in a total vol of 50 μl and included an initial denaturation at 94°C/4 min plus 35 cycles consisting of denaturation at 94°C/30 sec, annealing at 59°C/30 sec, and extension at 72°C/90 sec. The wild-type allele yielded a 950 bp band, and the null allele yielded a 500 bp band.
weaver genotypes were determined by a restriction site-generating PCR protocol developed by Patricia Ehrhard (Roche, Nutley, NJ). This protocol used a 3′ wild-type primer (5′-CAT GAA GGC GTT GAC AAT GGA-3′) and a 5′ mismatched primer (5′-CCA TAG AGA CAG AAA CCA CGA TC-3′), which creates a PvuI restriction site in the wild-type allele. PCR reactions were performed in a total vol of 20 μl and included an initial denaturation at 94°C/3 min plus 30 cycles each consisting of denaturation at 94°C/30 sec, annealing at 55°C/45 sec, and extension at 72°C/60 sec. The PCR product was digested with PvuI restriction enzyme, and 8 μl samples of the digested PCR product were subjected to electrophoresis; the bands were visualized with ethidium bromide. The wild-type allele yielded a 101 bp band, and the wv allele yielded a 119 bp band.
Histology and morphometric analysis. Postnatal day 0 (P0) and adult mice were anesthetized with Avertin and perfused with PBS, pH 7.35, followed by a 3:1 95% ethanol/acetic acid fixative. Brains were removed and post-fixed for 24 hr. After post-fixation, the brains were bisected sagittally, dehydrated, and embedded in paraffin. A series of 50 sagittal sections, cut at 6 μm, were mounted on slides; every third slide was stained with cresyl violet.
For each P0 animal of the wv/wv NR1+/+ (n = 5),wv/wv NR1−/+(n = 6), wv/wv NR1−/− (n = 9),+/+ NR1+/+ (n = 3),+/+ NR1−/+ (n = 3), and +/+ NR1−/− (n= 3) genotypes, three nonconsecutive sections of the midline cerebellum were analyzed and averaged. The most posterior 300 μm of the external granule cell layer was measured along the pial surface, and three features within this area were quantified by (1) total number of cells, (2) total number of mitotic figures, and (3) total number of pyknotic cells. Pyknotic cells were defined as densely heterochromatic figures in which cellular details were no longer visible. Mitotic figures were differentiated from pyknotic cells on the basis of the appearance of defined heterochromatic structure and phase of cell division. For each animal the percentage of total cells that were either pyknotic or mitotic was calculated. To determine if there were significant differences among the genotypes, we performed an ANOVA. TUNEL staining was performed as another indicant of cell death, according to the manufacturer’s instructions (Apoptag kit, Oncor, Gaithersburg, MD).
For each adult animal of wv/wv NR1−/+ (n = 3) andwv/wv NR1+/+ (n = 3) genotypes, three nonconsecutive sections of the midline cerebellum were analyzed and averaged. The total number of granule cells in lobules 2/3, 8 and 10 was counted. Granule cells were identified easily by their size, shape, and characteristic heterochromatin structure. To determine if there were significant differences between the genotypes, we performed an unpaired Student’s t test.
GIRK2 immunohistochemistry. Tissue sections were prepared as described above. Slides were rinsed in PBS containing 0.3% Triton X-100 (PBS/T), blocked with 1% hydrogen peroxide in PBS/T, washed with PBS/T, and then blocked in 2% dry milk in PBS/T. Slides were rinsed in PBS/T and overlaid with rabbit polyclonal GIRK2 antibody (1:250) directed against the N terminus (Liao et al., 1996) in PBS/T with 5% normal goat serum (NGS). On control slides the primary antibody was omitted. Slides were rinsed with PBS/T and then overlaid with biotinylated goat anti-rabbit IgG (1:200) (Vector Laboratories, Burlingame, CA) in PBS/T with 5% NGS. Slides were rinsed with PBS/T, and the sections were developed with Vectastain ABC kit (Vector Laboratories) and 3,3′-diaminobenzidine (DAB), yielding a brown precipitate. After being rinsed, the slides were dehydrated and coverslipped.
Cell culture. Cerebellar granule cell cultures were prepared from P0 cerebella. Mice were decapitated, and cerebella were removed and carefully cut into four pieces in calcium- and magnesium-free buffer solution (CMF) containing HBSS and HEPES, pH 7.35 (Sigma, St. Louis, MO). After being rinsed with CMF, cerebellar pieces were placed in CMF containing 0.25% trypsin for 10 min at room temperature with slight rotary agitation. The tissue was rinsed three times in CMF to remove the trypsin and then placed in trituration medium [Neurobasal medium supplemented with B27, 0.5 mml-glutamine (NBM; Life Technologies, Gaithersburg, MD), and 0.05% deoxyribonuclease and 0.25% glucose]. Trituration of tissue was done on ice by using successively smaller bore, fire-polished sterile Pasteur pipettes (ten times each with pipettes of 1, 0.5, and 0.1 mm internal diameter). Then the entire cell suspension was sedimented by centrifugation (600 rpm) for 8 min at 4°C. The pellet was resuspended in culture medium (NBM supplemented with B27, 0.5 mml-glutamine, 10 pg/ml GDNF, and 100 μg/ml of penicillin and streptomycin). Cell viability was assessed by using the trypan blue dye exclusion method. Cells were plated on round sheets of Aclar (Pro Plastics) coated with poly-l-lysine at a density of 2 × 105 cells/well. After 8 d in vitro, some cultures were fixed with 4% paraformaldehyde/0.3% glutaraldehye, and immunohistochemical analysis was performed with rabbit polyclonal antibody against glutamate, according to the manufacturer’s instructions (Incstar, Stillwater, MN).
RESULTS
Generation and behavior of double-mutant mice
To determine the effects of the NR1 null mutation onweaver granule cell survival, we crossed weavermice with NR1−/+ mice to generatewv/+ NR1−/+ male and female mice. These mice were intercrossed to produce homozygous mutant offspring.wv/wv NR1−/+ were viable and survived until adulthood, whereas wv/wv NR1−/− offspring died within the first 24 hr after birth. This neonatal lethality is the same as that reported by Forrest et al. (1994) in NR1−/−mice that were wild-type at the weaver locus. Adult and neonatal mice were genotyped by a PCR-based method that allowed for the determination of both weaver and NR1 null alleles (see Materials and Methods).
By the second postnatal week, when the first signs of ataxia are evident in wv/wv mice, nonataxic littermates were culled to ensure the maximum viability of wv/wv young. It was immediately apparent that among the ataxic mice there were two phenotypically distinct groups. One group paralleled the well characterized wv/wv behavioral phenotype, including gait instability, outward splaying of hindlimbs, tremor, curled posture, and severe ataxia (Sidman et al., 1965). The behavioral phenotype of the second group was markedly different. These mice had a more normal posture and leg stance and attenuated tremor and ataxia. Furthermore, these mice had an overall increased viability and better reproductive success and were better at caring for their young. On genotyping, the healthier animals were invariably wv/wv NR1−/+, whereas the more ataxic animals were wv/wv NR1+/+.
Analysis of the adult wv NR1 cerebellum
Histological analysis of the adult wv/wv NR1 cerebellum was performed to determine whether the improved behavioral phenotype reflected an improved cerebellar phenotype. Overall, wv/wv NR1+/+ cerebella appeared similar to those of the inbred wv/wv cerebella. In these cerebella there is a near-total loss of midline granule cells and a diminutive cerebellum (Fig. 1A,C). In contrast, the cerebella of wv/wv NR1−/+ mice appeared larger, and there was an increased survival of granule cells (Fig.1B,D). To quantitate this, we made counts of the total number of granule cells in regions of the midline cerebellum (lobules 2/3, 8, and 10) between wv/wv NR1−/+ and wv/wv NR1+/+ mice. There was a significant difference in the total number of granule cells between the two groups (unpaired t test, p < 0.05), with more than twice as many granule cells found in wv/wv NR1−/+ cerebella (Fig.1E).
Analysis of the P0 wv NR1 cerebellum
It was expected, given the partial survival of granule cells in the adult wv/wv NR1−/+cerebellum, that an even more profound effect on granule cell survival should be seen in the wv/wv NR1−/−cerebellum. In wv/wv cerebella the first evidence of granule cell death is at P0 (Smeyne and Goldowitz, 1989). At this time cell death is restricted to the deep aspect of the EGL in the most posterior lobules of the cerebellum. Because the NR1 null mutants survive birth (but die during the first 24 hr postnatal), we were able to determine the effects of the NR1 homozygous deletion onweaver granule cell death at the P0 time point. Qualitative comparisons of the midline cerebellar EGL were made among wv/wv NR1+/+, wv/wv NR1−/+, and wv/wv NR1−/− mice. There were no noticeable differences in the overall size and shape of the cerebellum among mice of the three genotypes (Fig.2A–C). Additionally, there were no obvious genotypic differences in the total numbers of cells or mitotic figures within the EGL. However, there were marked differences in the presence of pyknotic cells in the deep aspect of the EGL among cerebella of the three genotypes (Fig.2D–F). Prominent cell death was evident in the posterior lobules of the wv/wv NR1+/+ EGL (Fig. 2D), mimicking the phenotype of the inbred P0 weaver cerebellum (Smeyne and Goldowitz, 1989). In the wv/wv NR1−/− cerebellum there was notably less cell death in this region (Fig. 2E). Many of the pyknotic cells in the EGL of all genotypes were also TUNEL-positive (data not shown), as previously demonstrated for the weavercerebellum (Wullner et al., 1995; Migheli et al., 1997; Harrison and Roffler-Tarlov, 1998).
The total number of cells in the most posterior lobules of the EGL was counted, and the percentages of mitotic figures and pyknotic cells were calculated for each of the three genotypes. There were no significant differences in the percentage of mitotic figures (Table1). However, there were highly significant differences (ANOVA, p < 0.01) in the percentage of pyknotic cells among the three genotypes, with the highest percentage of pyknotic cells found in wv/wv NR1+/+ mice and a dramatic decrease in the percentage of pyknotic cells in wv/wv NR1−/− mice (Table 1). Interestingly, there was an intermediate amount of pyknotic cells in wv/wv NR1−/+ mice, indicating a gene dosage effect. What made these differences even more compelling is that in all but one of the wv/wv NR1−/− pups that were included in the cerebellar analysis there were varying degrees of neural cell death in other regions of the brain, especially the colliculi and cortex. This is most likely attributable to the declining state of the NR1−/−animals. Despite this fact, wv/wv NR1−/− cerebella exhibited less cell death in the EGL.
In the postnatal developing cerebellum the granule cells undergo the process of naturally occurring cell death (Wood et al., 1993). It is possible that the NR1 null mutation somehow delays or inhibits this process, resulting in the apparent dearth of cell death in the wv/wv NR1−/− EGL. To control for this possibility, we examined the effects of theNR1 null mutation on the non-weaver cerebellum. We quantitatively analyzed cell death and proliferation in the EGL of+/+ NR1+/+, +/+ NR1−/+, and +/+ NR1−/− mice. There were no significant differences in either the percentage of pyknotic or percentage of mitotic figures among mice of the three genotypes (Table 1). However, it is notable that there was a significant difference (unpairedt test, p < 0.05) in the percentage of pyknotic cells between +/+ NR1−/−and wv/wv NR1−/− cerebella. This indicates that, although NMDA receptor activation is the principal means of effecting cell death in wv/wv, there are other as yet to be identified mechanisms that likely are responsible for a component of cell death in wv/wv granule cells.
To rule out the possibility that the NR1 null mutation interferes with the expression of GIRK2, we assessed GIRK2 immunostaining in P0 cerebella. We compared the expression of GIRK2 in+/+ NR1+/+, +/+ NR1−/−, wv/wv NR1+/+, and wv/wv NR1−/− brains. GIRK2 immunoreactivity was present throughout the EGL and in some Purkinje cells and nerve fibers in the future cerebellar white matter. The location of immunoreactivity was the same in all of the genotypes (Fig.3A–H). GIRK2 immunoreactivity was observed throughout the EGL, both anterior to posterior and medial to lateral, which is consistent with previous reports (Kofuji et al., 1996; Slesinger et al., 1996). GIRK2 immunoreactivity was found to be more intense in non-weavercerebella, as was demonstrated from studies of the adultweaver brain (Liao et al., 1996). However, there were no detectable differences in GIRK2 immunoreactivity attributable to theNR1 null mutation in any of the genotypes that were examined.
In vitro analysis of wv NR1granule cells
It is conceivable the NR1 null mutation affectswv/wv granule cell development to delay the onset ofweaver-induced cell death. We addressed this issue by establishing cerebellar cultures to examine the effects ofNR1−/− on wv/wv granule cell survival beyond P0. The morphological and physiological maturation of NR1−/− granule cells in vitro has been shown to be normal (Forrest et al., 1994). Dissociated wv/wv NR1+/+ andwv/wv NR1−/− granule cells were cultured and assessed every 24 hr for features as previously characterized for wild-type granule cells in culture (Trenkner and Sidman, 1977). These features include reaggregation within the first 24 hr of plating, neurite extension, the formation of cables between the reaggregates, and cell migration along the cables. The behavior ofwv/wv NR1+/+ granule cells in culture was comparable to that of wv/wv granule cells derived from the original stock of weaver mice (Trenkner et al., 1978; Willinger et al., 1981). wv/wv NR1+/+ granule cells reaggregrated within the first day of culture; however, the reaggregates were much smaller than what are seen in wild-type cultures, and there was also considerable neuronal degeneration. Compared with wild-type cultures, there was very little cable formation and no migrating neurons inwv/wv NR1+/+ cultures. After 8 d in vitro all wv/wv NR1+/+ granule cells were dead or degenerating (Fig. 4A).
After the first 24 hr in culture wv/wv NR1−/− granule cells also reaggregated; however, there were few degenerating neurons. The reaggregates were also much larger, with increased cable formation and numerous migrating granule cells as compared with wv/wv NR1+/+ cultures. After 8 d in vitro, wv/wv NR1−/− cultures had numerous clusters of small round cells (Fig. 4B), identified as granule cells by their glutamate immunoreactivity (data not shown). In all measures wv/wv NR1−/− cultures were not readily distinguishable from wild-type cultures.
DISCUSSION
The present study demonstrates for the first time the in vivo rescue of granule cells in the wv/wv cerebellum. Analysis of wv/wv NR1 double mutants shows thatwv/wv granule cells are rescued from cell death when NMDA receptor function is blocked and also shows that there is a gene dosage effect. This rescue is not likely attributable to genetic background introduced via the matings necessitated to produce the double mutants, because wv/wv NR1+/+mice exhibit the same level of cell death as the inbredwv/wv strain. However, this does not address the remote possibility that a locus tightly linked to the insertional event that created the NR1 knock-out is responsible for the effects we see. It is also very unlikely that the NR1 null mutation alters wv/wv granule cell development before the onset of death, because adult wv/wv NR1−/+mice show enhanced granule cell survival. Furthermore, unlike P0wv/wv NR1+/+ granule cells in culture, wv/wv NR1−/− granule cells differentiate and survive in a manner analogous to wild-type granule cells.
One important implication of our results is that wvGIRK2 alone is not sufficient to cause granule cell death. Our findings indicate that it is critical to pair the wvGIRK2 mutation with a depolarizing influence to effect cell death. In the absence of such an influence inwv/wv NR1 double-mutant granule cells, cell death is prevented. These conclusions are in line with a host of in vitro studies that demonstrate that wv/wv granule cells can be rescued by altering culture conditions to reduce cell membrane depolarization. Altered conditions that saved weaver granule cells include the NMDA channel blockers APV (Trenkner, 1990) and MK-801 (Kofuji et al., 1996), the voltage-gated Na+ channel blocker QX-314 (Kofuji et al., 1996), the Ca2+ channel blocker verapamil (Liesi and Wright, 1996), the intracytoplasmic Ca2+ chelator BAPTA-AM (Liesi et al., 1997), and ethanol (Liesi et al., 1997), which causes a reduction in Ca2+ signaling in response to NMDA in cerebellar granule cells (Gruol and Parsons, 1996; Gruol et al., 1998). Our current results, along with these studies, indicate a critical role for epistatic factors that influence cellular depolarization in effecting wv/wv granule cell death.
It is axiomatic that the presence of a mutated wvGIRK2 channel is also requisite for cell death in the weaver mutant mouse. In granule cells GIRK channels are heteromeric tetramers (Liao et al., 1996). In the absence of GIRK2 the other GIRKs should form functional channels. The analysis of GIRK2 null mutant mice supports such a conclusion. In girk2 knock-out mice there is no apparent cerebellar granule cell death (Signorini et al., 1997). Therefore, the GIRK2 null mutant may not adequately portray the normal contributions of this protein to granule cell development because of compensatory mechanisms that may be activated when the gene is missing. Obversely, the loss of a gene (as in the GIRK2 knock-out) is not necessarily equivalent to an altered gene product (as in the weavermutation).
An additional point of discussion is that the gain-of-function hypothesis put forward by Kofuji and coworkers (1996) is difficult to sustain. In their gain-of-function hypothesis, the cause of cell death in wv/wv is attributable solely to new functions of the wvGIRK channel. These new functions are a loss of ionic selectivity and constitutive activity allowing for the passage of sodium and calcium ions and the resulting lethal depolarization of the cell. The ability to block cell death with various pharmacological agents (QX314, MK-801, and verapamil) was interpreted as a direct effect on the mutant GIRK channel. However, this may not have been the case. In the present paper we show that the abolition of the NMDA receptors in wv/wvgranule cells, a perturbation that has no known effect on GIRK function, mainly blocks cell death. Although this does not rule out that the mutation in wvGIRK2 results in a gain-of-channel function or a loss of GIRK2 currents, it does indicate that wvGIRK2 alone is not sufficient to cause granule cell death.
A further problem with the gain-of-function hypothesis is its failure to address adequately the selective cell death seen in thewv/wv brain. One of the continuing puzzles of theweaver story is the selective vulnerability of certain neurons (e.g., cerebellar granule cells, dopaminergic cells of the substantia nigra), whereas other wvGIRK2-positive neuronal populations, such as the hippocampal granule cells and thalamic neurons, apparently are unscathed. This selective vulnerability also is seen within a single population of neurons. GIRK2 has been shown to be expressed in all cells of the EGL (Kofuji et al., 1996; Slesinger et al., 1996; Chen et al., 1997; Wei et al., 1997), but only the wv/wv midline premigratory EGL cells experience massive degeneration (Herrup and Trenkner, 1987; Smeyne and Goldowitz, 1990). For the gain-of-function hypothesis to be valid, all unaffected wvGIRK2-expressing cells would require a compensatory mechanism to be in place to oppose the constitutive Na+ influx. In the loss-of-function hypothesis, cell death would occur only in cells in which the normal functioning GIRK2 currents are critical to oppose depolarizing influences.
The activation of GIRKs in other neurons of the CNS has been shown to function in controlling cell excitability by hyperpolarizing the cell membrane (Ehrengruber et al., 1997; Svoboda and Lupica, 1998). To understand fully how GIRK2 functions in regulating cell excitability in the premigratory granule cells, it will be necessary to identify the mechanism of GIRK2 activation. It is clear from recordings of cerebellar slice preparations that the activation of GIRK channels is regulated developmentally (Rossi et al., 1998). Premigratory granule cells of the EGL exhibit G-protein-dependent inward rectifier currents. In wv/wv premigratory granule cells, Rossi and coworkers (1998) observed no inwardly rectifying currents. However, in bothwv/wv and wild-type granule cells in deeper positions, presumed postmigratory granule cells expressed a constitutively active inward rectifier current (Rossi et al., 1998). The molecular identity of the channels underlying this current is unknown at present. These developmental differences in electroresponsiveness of the granule cells may account for the conflicting results obtained from single-cell recordings of wv/wv granule cells.
In the developing cerebellum it appears that the activation of NMDA receptors on premigratory granule cells makes this population of neurons more vulnerable to the effects of the weavermutation. During this period, premigratory granule cells transiently express functional NMDA receptors believed to be composed of NR2B and NR1 subunits, which are known to make this cell population more susceptible to excitotoxicity (Garthwaite and Garthwaite, 1986). NMDA receptors composed of both NR2B and NR1 subunits form high conductance channels (Hollmann and Heinemann, 1994). Ca2+ entry through these channels could be the trigger for wv/wv cell death. The spatiotemporal activation of NMDA receptors appears to coincide with wv/wvgranule cell death. Although functional NMDA receptors are present on premigratory cells, their activation is tightly regulated by both the density of NMDA receptors and by glutamate uptake (Rossi and Slater, 1993; Farrant et al., 1994). Premigratory neurons display spontaneous NMDA receptor–channel activity that increases with postnatal age. When the uptake of glutamate by glutamate transporters is blocked with the application of l-α-aminoadipate, the level of tonic channel activity is greatly enhanced (Rossi and Slater, 1993). Glutamate transporters have been localized to the Bergmann glial fibers (Rothstein et al., 1994). In fact, when these glial cells are ablated, there is massive granule cell death (Delaney et al., 1996). This death is linked to a loss of glutamate uptake and excitotoxicity that is specific to NMDA-type glutamate receptors, because granule cells are saved when these transgenic mice are injected with the NMDA receptor antagonist MK-801, whereas the non-NMDA receptor antagonist CNQX has no effect (Delaney et al., 1996). From these studies it is apparent that the activation of NMDA receptors in premigratory granule cells is important to the development of these cells. This well orchestrated activation of NMDA receptors on neurons at the EGL–molecular layer interface may account for the vulnerability of these neurons to cell death in the weaver cerebellum.
We propose that, in premigratory granule cells, NMDA receptors are activated in parallel with GIRK2-containing channels. Under normal conditions the activation of K+-selective GIRK2-containing channels counterbalances ionotropic glutamate receptor-mediated depolarization, preventing excessive glutamate-mediated depolarization (Fig.5). Although cerebellar granule cells express several receptors that could couple to GIRK channels, metabotropic glutamate receptors are the most likely to play an important role in this context (Kinney and Slater, 1993). These receptors, by rapidly activating GIRK2-containing channels, may effectively regulate membrane potential and the Mg2+ block of NMDA receptors (Hollmann and Heinemann, 1994). In the absence of hyperpolarizing GIRK currents—as in the weaver mutant—ambient glutamate may depolarize more effectively the granule cells, leading to relief of the Mg2+ block of NMDA channels and activation of voltage-dependent Ca2+ channels, providing a fatal Ca2+ load. Prolonged Ca2+ influx via NMDA receptors has been shown to be a key event in neuronal excitotoxity (Choi, 1992) and the death of weaver granule cells (Tucker et al., 1996) (Fig.5). This proposal is consistent with either a loss-of-function hypothesis (see Surmeier et al., 1996) or a weaker version of the gain-of-function hypothesis in which the mutation in wvGIRK2 is not sufficient to cause cell death but requires an additional element, such as NMDA receptor activation.
Footnotes
- Received February 2, 1999.
- Revision received June 14, 1999.
- Accepted June 30, 1999.
This research was supported by a UT-Memphis Center for Neuroscience Fellowship (P.J.) and the Department of Anatomy and Neurobiology and the University of Tennessee College of Medicine (D.G.). This work also was supported by National Institute of Neurological Diseases and Stroke Grant NS 36496 (D.J.S.). We thank Dr. Tom Curran for providing us with the NR1 null mouse, Dr. Paul Mermelstein for designing Figure 5, Dr. Lily Jan for the GIRK2N antibody, Dr. Michisuke Yuzaki for help in establishing P0 cerebellar cultures, and Richard Carl Cushing for technical assistance.
Correspondence should be addressed to Dr. Dan Goldowitz, Department of Anatomy and Neurobiology, Center for Neuroscience, 855 Monroe Avenue, University of Tennessee Memphis, Memphis, TN 38163.
- Copyright © 1999 Society for Neuroscience