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The Journal of Neuroscience, April 15, 1998, 18(8):2822-2833
Mouse Cerebellar Granule Cell Differentiation: Electrical
Activity Regulates the GABAA Receptor  6 Subunit Gene
J. R.
Mellor,
D.
Merlo,
A.
Jones,
W.
Wisden, and
A. D.
Randall
Medical Research Council Laboratory of Molecular Biology,
Cambridge, CB2 2QH, United Kingdom
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ABSTRACT |
GABAA receptor  6 subunit gene expression marks
cerebellar granule cell maturation. To study this process, we used the
 6lacZ mouse line, which has a lacZ reporter inserted into the
6 gene. At early stages of postnatal cerebellar development,
6-lacZ expression is mosaic; expression starts at postnatal day 5 in
lobules 9 and 10, and 6-lacZ is switched on inside-out, appearing
first in the deepest postmigratory granule cells. We looked for factors regulating this expression in cell culture. Membrane depolarization correlates inversely with 6-lacZ expression: granule cells grown in
25 mM [K+]o for 11-15 d
do not express the 6 gene, whereas cultures grown for the same
period in 5 mM [K+]o do.
This is influenced by a critical early period: culturing for  3 d in
25 mM [K+]o curtails the
ability to induce the 6 gene on transfer to 5 mM
[K+]o. If the cells start in 5 mM [K+]o, however,
they still express the 6-lacZ gene in 25 mM
[K+]o. In contrast to granule cells
grown in 5 mM
[K+]o, cells cultured in 25 mM [K+]o exhibit no action
potentials, mEPSCs, or mIPSCs. In chronic 5 mM
[K+]o, factors may therefore be
released that induce 6. Blockade of ionotropic and metabotropic GABA
and glutamate receptors or L-, N-, and P/Q-type Ca2+
channels did not prevent 6-lacZ expression, but inhibition of action
potentials with tetrodotoxin blocked expression in a subpopulation of
cells.
Key words:
GABAA receptor subunit; cerebellum; granule
cell;  -galactosidase reporter genes; internal ribosome entry site; differentiation; cell culture; electrophysiology; transgenic mice; membrane depolarization; action potentials; tetrodotoxin; neuron-specific gene expression
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INTRODUCTION |
At birth, rodent cerebellar granule
cell precursors are found in germinative zones on the exterior surface
of the cerebellum. During the first postnatal weeks, they divide,
become postmitotic, and migrate across the molecular layer, finally
settling in the internal granule cell layer (Altman and Bayer, 1996 ;
Hatten et al., 1997). This maturation has distinct phases of
neurotransmitter receptor expression (Farrant et al., 1994, 1995;
Monyer et al., 1994; Mosbacher et al., 1994; Watanabe et al., 1994;
Brickley et al., 1996; Takahashi et al., 1996; Tia et al., 1996; Wisden et al., 1996). For example, dividing precursor cells and premigratory postmitotic cells express transcripts encoding the GABAA
receptor 2, 3, 3,  1, and 2 subunits (Laurie et al.,
1992b). Later, 2, 3, and 1 are downregulated and replaced by
the adult complement (predominantly 1, 6, 2, 3, 2, and
 ) (Laurie et al., 1992a,b; Thompson and Stephenson, 1994; Caruncho
et al., 1995; Gao and Fritschy, 1995; Nadler et al., 1996; Wisden et
al., 1996). The 1, 6, and genes are expressed only when
granule cells arrive in the internal granule cell layer (Zdilar et al.,
1991; Laurie et al., 1992b; Korpi et al., 1993; Kuhar et al., 1993;
Zheng et al., 1993; Varecka et al., 1994).
What factors determine the final stages of granule cell
differentiation, e.g., GABAA receptor subunit gene
induction? Granule cell entry into the internal granule cell layer
coincides with their innervation by glutamatergic mossy fibers and
GABAergic Golgi cell axons (Altman and Bayer, 1996). Synaptic activity, therefore, may modulate differentiation, especially because membrane potential influences neurotransmitter receptor regulation in culture (Vallano et al., 1996; Wisden et al., 1996; Gault and Siegel, 1997).
Membrane potentials depend on the extracellular K+
concentration ([K+]o). The
physiological [K+]o is ~5
mM, but rat granule cell survival in vitro is
enhanced by depolarizing [K+]o,
e.g., 25 mM (Gallo et al., 1987), so cerebellar cultures
are often maintained under these conditions. The use of chronic 25 mM [K+]o to model neuronal
development, however, has been questioned. For example, in 25 mM [K+]o, rat
granule cells do not correctly develop their AMPA or NMDA receptor
subunit gene expression programs (Hack et al., 1995; Vallano et al.,
1996), whereas they do so in lower
[K+]o (Condorelli et al., 1993;
Vallano et al., 1996).
To study 6 gene regulation, we placed an Escherichia coli
enzyme -galactosidase (lacZ) reporter cassette into exon 8 of the
mouse 6 subunit gene by homologous recombination (Jones et al.,
1997). LacZ histochemistry allowed us to directly visualize the
expression heterogeneity of the gene in cultured granule cells. We
found that 6-lacZ gene expression fails to develop when dissociated mouse granule cells are cultured in chronic 25 mM
[K+]o. By contrast, in 5 mM [K+]o, cells
strongly induce the 6 gene. Induction is enhanced by action
potentials but not by synaptic transmission.
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MATERIALS AND METHODS |
Cell culture
Homozygous 6lacZ mice (strain C57BL/6x129S/v) (Jones et
al., 1997) or C57BL/6x129S/v wild-type mice were killed at postnatal day (P) 5. The cerebellum was dissociated with trypsin, and the cells
were maintained in culture (37°C, 5% CO2) on
Matrigel (Collaborative Research, Bedford, MA)-coated glass coverslips
(Randall and Tsien, 1995). The culture medium consisted of a minimal
essential medium (Life Technologies, Paisley, UK) supplemented with
10% fetal calf serum (Hyclone, Logan, UT), 5 mg/ml glucose, 0.3 mg/ml
glutamine, 100 µg/l transferrin (Calbiochem, Nottingham, UK), and 50 mg/l insulin (Sigma, Poole, UK). As appropriate, the media was further supplemented with 4, 10, or 20 mM KCl to give a final media
[K+]o of 9, 15, or 25 mM,
respectively. After 2 d in culture, all cells were fed with medium
supplemented with 4 µM cytosine arabinoside (ARA-C)
(Sigma) to reduce glial cell proliferation. Subsequently, cultures were
fed every 5 d by a 50% replacement of ARA-C-containing medium.
Drugs and growth factors
Where appropriate, drugs and growth factors were included in the
culture media from the time of cell plating: 200 ng/ml brain-derived neurotrophic factor (BDNF) (TCS Biologicals, Botolph Clayton, UK), 100 ng/ml neurotrophin-3 NT-3 (TCS Biologicals), 100 ng/ml nerve growth
factor (NGF) (gift of D. Mercanti, Consiglio Nazionale delle Ricerche,
Rome, Italy), and 10 ng/ml thyroid hormone (T3) (gift of P. Tirassa,
Consiglio Nazionale delle Ricerche) were replenished every day; 1 µM tetrodotoxin (TTX) (RBI, Natick, MA), 10 µM CNQX (Tocris-Cookson, Bristol, UK), 10 µM (carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP)
(Tocris-Cookson), 50 µM picrotoxin (Sigma), 500 µM -methyl-4-carboxyphenylglycine (-MCPG)
(Tocris-Cookson), 10 µM CGP 55 845A (gift of Ciba, Basel,
Switzerland) (Davies et al., 1993), 300 nM  -Aga-IVA
(Peptides International, Louisville, KY), 1 µM
-CTx-GVIA (Peninsula Laboratories, Belmont, CA), 10 µM
nifedipine (RBI), and 50 nM K252a (TCS Biologicals) were
replenished by the regular cell-feeding process.
-galactosidase (lacZ) staining
Brain slices. Timed matings of homozygous 6lacZ
mice were set up. Four pups were used at each time point. Anesthetized
animals were transcardially perfused with 4% paraformaldehyde (PFA) in PBS. Brains were removed, post-fixed for 15 min in 4% PFA on ice, and
then equilibrated overnight at 4°C in PBS/30% sucrose. Sections (40 µM) were cut on a sliding microtome and incubated
free-floating in 5-bromo-4-chloro-3-indolyl--galactoside (X-Gal) at
37°C (Bonnerot and Nicolas, 1993). After X-Gal staining, sections
were post-fixed in ice-cold 4% PFA for 15 min, rinsed in 100 mM phosphate buffer (PB), pH 7.4, mounted on slides,
counterstained with neutral red (Sigma), coverslipped with DePeX
(BDH), and photographed with a Leica Orthomat E microscope. Cerebellar
anatomy was confirmed from Marani and Voogd (1979) and Altman and Bayer
(1996).
Cell cultures. Coverslips were washed in PBS and fixed for 5 min in ice-cold 2% PFA/0.2% glutaraldehyde and then rinsed in PBS and
incubated in X-Gal solution at 37°C overnight, although granule cells
usually turned blue within 2 hr. After lacZ staining, coverslips were
washed in PBS, post-fixed for 10 min in 2% PFA, rinsed in PB,
counterstained with neutral red, and mounted in DePeX. Granule cells
were identified by their small size and round or ovoid shape.
Controls for lacZ background staining. To check for the
presence of endogenous -galactosidase-like activity (Rosenberg et al., 1992), cultured wild-type C57BL/6x129S/v granule cells from both 5 and 25 mM [K+]o conditions
were incubated, after 14 d in culture, with X-gal. No blue
staining was found in either cell culture condition or in wild-type
mouse brain slices of any age (data not shown).
Immunoblotting
Membranes were prepared from cultured cerebellar cells and whole
cerebella as described (Thompson and Stephenson, 1994; Jones et al.,
1997). Ten micrograms of protein/lane were run in an SDS-PAGE (12%
polyacrylamide) gel and immunoblotted. Immunodetection was by
chemiluminescence, using a Western-Lite protein detection kit (Tropix).
The 6 subunit-specific antibody 6-N (Thompson et al., 1992) was
used at 2 µg/ml.
Electrophysiology
Before recording, the culture medium was exchanged for a
standard Tyrode solution (in mM): NaCl 130, KCl 5 or 25, CaCl2 2, MgCl2 1, Glucose 30, HEPES-NaOH 25, pH
7.3. Coverslips were broken into pieces, and single shards were
transferred to a recording chamber mounted on an inverted microscope
stage (Nikon, Kingston-upon-Thames, UK). The chamber was constantly
perfused with Tyrode solution at room temperature. Individual
cerebellar granule cells were approached with 2-6 M resistance
glass pipettes, and whole-cell patch-clamp recordings were made in
voltage- or current-clamp mode.
Recordings of spontaneous GABAergic miniature IPSCs (mIPSCs) were made
at  70 mV in the presence of the AMPA/kainate receptor antagonist CNQX
(5 µM) and the Na+ channel blocker TTX
(1 µM). The intracellular solution consisted of (in
mM): CsCl 110, NaCl 10, MgCl2 5, EGTA 5, ATP 2, GTP 0.2, HEPES 35, pH 7.3. Data were filtered at 50 kHz (four-pole
analog Bessel filter), recorded to digital audiotape, refiltered at 5 kHz (Brownlee Precision digital eight-pole Bessel characteristic filter; San Jose, CA), and sampled at 10 kHz to a continuous computer file. Recordings of miniature EPSCs (mEPSCs) were made at a holding potential of 70 mV in the presence of the GABAA receptor
antagonist bicuculline methochloride (50 µM) and TTX (1 µM).
For analysis of membrane potentials and action potentials, the
intracellular solution was (in mM): KMeSO4 110, NaCl 10, MgCl2 5, EGTA 0.6, ATP 2, GTP 0.2, HEPES 40, pH
7.3. Recordings were filtered at 2 kHz and sampled at 5-20 kHz under
control of pClamp6 software (Axon Instruments, Foster City, CA).
Membrane potentials were measured in the current-clamp mode within 30 sec of reaching the whole-cell configuration and corrected for liquid
junction potentials (10.4 mV in 25 mM
K+, 8.8 mV in 5 mM
K+). Na+ currents were elicited
with step depolarizations to 0 mV from a holding potential of 70 mV.
At this holding potential there is <0.1% Na+
channel inactivation (data not shown). Data files were analyzed with
either Axobasic- or pClamp6-based programs (Axon Instruments).
Statistical analysis
Results are presented as mean ± 1 SEM. Statistical
analysis was performed using a standard two-tailed unpaired
t test; significance was set at a confidence level of 95%.
For each experimental manipulation in each individual culture, the
percentage of blue granule cells was determined by manual counting of
two or three randomly selected fields on two separate coverslips. The
effect of each culture condition was assayed in cultures derived from
at least three different litters.
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RESULTS |
6-lacZ gene expression has a complex sequence of regional
development correlating with cell birthday
In the 6lacZ mouse line, an internal ribosome entry site
(IRES) lacZ cassette has been inserted into exon 8 of the
GABAA receptor 6 subunit gene by homologous
recombination (Fig. 1) (Jones et al.,
1997). This allows cap-independent translation of -galactosidase
(-gal) from within the 6 mRNA, and the production of -gal in
the same pattern as native 6 gene expression (Kato, 1990;
Lüddens et al., 1990; Laurie et al., 1992a; Wisden et al., 1992;
Varecka et al., 1994).
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Figure 1.
Structure of the 6lacZ mouse
GABAA receptor 6 subunit gene (Jones et al., 1997). The
IRES-lacZ cassette is inserted into exon 8. The arrow
marks the transcriptional start sites; shaded boxes are
exons; IRES, Internal ribosome entry site.
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The developing 6 subunit-lacZ gene expression pattern in
vivo was traced in sagittal sections along the rostrocaudal
midline of the vermis. Expression started in the most posterior part, lobule X, in agreement with the in situ hybridization study
of Varecka et al. (1994). At P5, a few blue cells were found in the deepest part of the internal granule cell layer of lobule X (Fig. 2A). At this time
point, other lobules were not detectably expressing -gal. One day
later (P6), more cells were expressing in the deep layers of lobule X,
and scattered lacZ-positive cells were found in the dorsal aspect of
lobule IX (Fig. 2B). By P7, expression in lobules X
and IX had increased but was still confined to the deeper layers (Fig.
2C). At this stage, expression began to appear in the sulci
(stems) of the anterior lobules I-V (Fig. 2C). As with
lobules IX and X, these 6 gene-expressing cells in lobules I-V were
in the deeper part of the internal layer closest to the white matter
tracts. Kuhar et al. (1993) obtained a similar result by in
situ hybridization.
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Figure 2.
Sagittal sections of developing 6lacZ mouse
cerebella taken through the rostrocaudal midline, and stained for lacZ
activity (blue). The rostral direction is on the
left-hand side. A, Lobule X, postnatal day 5 (P5). B-D, Sections from postnatal day 6 (P6) to P9. E, P9 sagittal slice
with neighboring cerebellar granule cell layers, loops of lobules VIII
(right) and IX (left), at differing
stages of 6-lacZ gene expression; nonexpressing cells are
red. EGr, External granule cell layer;
IGr, internal granule cell layer; Mol,
molecular layer; WM, white matter. Roman
numerals identify the vermis lobules; arrowhead
marks -gal enzyme transported into granule cell axons, the parallel
fibers, in the molecular layer. Asterisk marks
postmigratory granule cells in the upper internal granule cell layer
not yet expressing the 6-lacZ gene. Scale bars: A,
80 µm; D, 0.3 mm; E, 40 µm.
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By P9, 6 expression was established in all lobules except the gyri
(outer folds) of VI and VII (Fig. 2D). In lobules X
and IX, I-V, where expression first started to appear (Fig.
2B), -gal activity became increasingly apparent in
the internal part of the molecular layer. This presumably corresponded
to transport of -gal into the granule cell axons, the parallel
fibers (Fig. 2D,E, arrowhead). By P10-11, the entire
internal granule cell layer in all lobules was lacZ-positive (data not
shown); over the following week, as more granule cells migrated into
the internal layer and switched on the gene, the intensity of
expression continued to increase (data not shown).
The contrast in 6 subunit gene expression between developing
vermis lobules is shown in detail in Figure 2E. At
P9, nearly all the granule cells in the internal layer of lobule IX
were lacZ positive; in the internal layer of VIII, however, expression was mosaic, with many cells still not expressing lacZ (Fig.
2E). At this age, the heterogeneity of
6-expressing cells compares well with the results of a single-cell
PCR study on juvenile rat cerebellar slices, in which 1
positive/6 negative, 1 negative/6 positive, and 1
positive/6 positive cells were found (Santi et al., 1994b).
Expression of the 6 subunit gene in culture depends on
[K+]o
After migration, granule cells extend dendrites that become
innervated by glutamatergic mossy fibers (arriving from outside the
cerebellum) and GABAergic axons of the Golgi cells (for review, see
Brickley et al., 1996; Wall and Usowicz, 1997); 6 gene expression could depend on these inputs. In the following sections, we examine 6 gene expression in primary cultures of dissociated cerebellum, where the extracellular environment can be precisely controlled. Previous studies have shown that the K+
concentration in the extracellular media influences neurotransmitter receptor expression of rat cerebellar granule cells (Cox et al., 1990;
Bessho et al., 1994; Harris et al., 1994; Santi et al., 1994a; Vallano
et al., 1996; Gault and Siegel, 1997); we therefore decided to look
first at the effects of [K+]o on 6
gene expression in cultured mouse granule cells.
Before we describe our experiments, it is first helpful to review the
effects of extracellular K+ concentrations in a
broader context, because there seem to be species-specific differences
in granule cell physiology. It is well known that elevated
extracellular K+ concentrations (e.g., 25 mM [K+]o) promote
long-term survival of rat cerebellar granule cells in dissociated
cultures (Gallo et al., 1987), but although chronic depolarization
gives maximal survival, it is not essential for experiments
that require long-term culture. If rodent granule cells cultured in
physiological K+ (i.e., 5 mM
[K+]o) are supplemented with
insulin (as in this study) or IGF-1, they also survive well (D'Mello
et al., 1993; Randall and Tsien, 1995; Lin and Bulleit, 1997). Growth
factors and serum also prevent apoptosis when rat cells that have been
grown in 25 mM [K+]o are
switched to 5 mM [K+]o
medium (D'Mello et al., 1993). However, there could be species differences: in some conditions, mouse cells survive just as well in 5 mM [K+]o as in 25 mM [K+]o (Peng et al.,
1991; Mogensen et al., 1994; Mogensen and Jorgensen, 1996).
We compared 6-lacZ gene expression in cultures of P5 6lacZ
cerebellar granule cells grown for 15 d in vitro (DIV)
in 5, 9, 15, and 25 mM
[K+]o. In 2-week-old 25 mM
[K+]o granule cell cultures, few cells
stained positive for lacZ expression (Fig.
3D). The absence of lacZ
product in 25 mM [K+]o
cultures of granule cells was independent of serum batch or type (not
shown); the situation was not altered by increasing the culture period.
In contrast, substantial increases in the number of lacZ-positive cells
were seen if the cells were cultured in lower
[K+]o (Figs. 3A-D,
4A). Heavy blue
staining was present in granule cells cultured in 5 mM
[K+]o (an average of 79 ± 3%
lacZ-positive granule cells) (Figs. 3A,
4A) or 9 mM
[K+]o (82 ± 2% lacZ-positive
granule cells) (Figs. 3B, 4A). The blue fibers between cell clusters indicate -gal protein transported into
the granule cell axons (Fig. 3A,B; compare Fig.
2E, arrowhead). Of the granule cells grown
in 15 mM [K+]o (Figs.
3C, 4A), 44 ± 5% stained positive
for lacZ, a situation intermediate to that in 5 or 9 mM
[K+]o cultures and that in 25 mM [K+]o cultures in which
<1% of cells were lacZ positive (Figs. 3D, 4A). When a logistic function was fitted to the data
in Figure 4A, the IC50 for
[K+]o-induced suppression of 6 gene
expression was 15.3 mM. This suggests that membrane
potential strongly influences 6 subunit gene regulation. The
[K+]o probably influences many other
aspects of gene expression in the cultured granule cells, as can be
seen by the differences in clustering of the cells shown in Figure
3A-D (also see Peng et al., 1991).
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Figure 3.
Development of 6-lacZ gene expression in
cultured cerebellar granule cells: effects of
[K+]o. A-D, Granule
cell cultures stained after 15 d in vitro, showing
the effects of increasing [K+]o (5, 9, 15, and 25 mM) on lacZ expression. E-H,
Development of lacZ expression in granule cells cultured in 5 mM [K+]o; cells
were stained after 3, 7, 11, and 15 d in vitro
(DIV). In all panels, blue marks
lacZ-positive cells; lacZ-negative cells are red. In
A-C and G, H, the blue
bundles linking the granule cell clusters mark the presence of
-galactosidase transported into the granule cell axons. Scale bars:
D, 70 µm; H, 500 µm.
(E-H are taken at a sevenfold lower magnification than
A-D and show a large coverslip area; each blue
dot in E-H is one of the clusters of cells
shown in A-D). I, Immunoblot confirming
the fidelity of the 6-lacZ expression data. Membranes were prepared
from P5 mouse wild-type cerebellar granule cells that had been cultured
for 10 d in 5 or 25 mM
[K+]o. Membrane extracts were also
prepared from adult wild-type (+/+) and 6lacZ whole cerebella as
positive and negative controls for antibody reactivity. The 6-N
antiserum detects 6 immunoreactivity in 5 mM
[K+]o-derived membranes, but not in
those from 25 mM [K+]o
cultures. The panel below shows the Coomassie-stained gel to
demonstrate equal protein loading.
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Figure 4.
6-lacZ gene expression: a summary of the
effects of [K+]o and time in culture.
Red (negative) and blue (positive) cells
were counted in randomly selected fields on each coverslip.
A, The percentage of lacZ-positive cells when cultures
were maintained for 15 d in media containing 5, 9, 15, or 25 mM [K+]o. Two coverslips
in each of three separate cultures were analyzed. Each point
corresponds to the percentage of blue cells on a single coverslip. The
data are fitted with a standard logistic function
(IC50, 15.3 mM). B,
Development of lacZ expression in cells cultured in 5 mM
[K+]o for up to 15 DIV. Each point
represents a single coverslip. Two coverslips were examined in three
separate cultures. C, The decline in the number of
lacZ-positive cells seen as the time of switch from 25 to 5 mM [K+]o medium was
increasingly delayed (open squares). In all cases the
number of lacZ-positive cells was assessed after 15 DIV. Each point
represents the average of two coverslips from each of three cultures.
Alternatively, when cells were switched from increasingly long
incubations in 5 mM [K+]o
to 25 mM [K+]o and
cultured for a total of 15 DIV (filled circles),
more lacZ-positive cells appeared the longer the initial culture period
in 5 mM [K+]o.
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The fidelity of 6-lacZ expression as a measure of genuine 6
expression was confirmed by immunoblotting. P5 wild-type
cerebellar granule cells (i.e., cells with an 6 gene producing
intact 6 protein) were cultured in 5 and 25 mM
[K+]o for 10 d. Cell membranes
were then harvested, run in an SDS-PAGE gel, blotted, and probed with
an 6-specific antibody (6-N) (Thompson et al., 1992) (Fig.
3I). Only cells cultured in 5 mM
[K+]o contained detectable 6-like
immunoreactivity; a doublet was present in membranes from cell cultures
in contrast to the single band (57 kDa) obtained from a whole
cerebellar extract (positive control) (Fig. 3I). The
doublet could be attributable to either differential glycosylation or
degradation.
The time course of 6-lacZ gene expression in a typical
culture maintained in 5 mM
[K+]o is shown in Figure
3E-H. Data from a number of similar experiments are plotted
in Figure 4B. In these experiments, cells prepared from P5 6lacZ cerebella were plated in 5 mM
[K+]o and stained for lacZ at 4 d
intervals, starting at 3 DIV. After 3 DIV there were no lacZ-positive
cells (Fig. 3E); after 7 DIV there was significant blue
staining (an average of 37 ± 3% lacZ-positive cells) (Figs.
3F, 4B). An additional increase in the
culture period to 11 and 15 d produced a steady increase in the
number of lacZ-positive cells (61 ± 4% and 75 ± 2%,
respectively) (Figs. 3G,H, 4B). Cultures that were maintained for longer periods in 5 mM
[K+]o exhibited no significant
increase in the fraction of lacZ-positive cells (data not shown). A
uniform development of lacZ expression in all cells would not be
expected. During preparation of cerebellar cultures, cells from all of
the different regions of the cerebellum are intermixed, and these cells
are not homogeneous with respect to their development of 6 gene
expression (Fig. 2).
Culture in 5 mM [K+]o
fails to induce 6 gene expression after a critical period in 25 mM [K+]o
Cultures of granule cells from P5 mouse cerebella were initiated
and maintained in 25 mM
[K+]o medium for 3, 5, 7, 9, or
11 d and then switched to 5 mM
[K+]o medium until a total time in
culture of 15 d had passed (i.e., 3 d in 25 mM
[K+]o, then 12 d in 5 mM [K+]o; 5 d
in 25 mM [K+]o,
then 10 d in 5 mM
[K+]o, etc.). The control
culture was plated and grown in 5 mM
[K+]o for 15 DIV. Cultures were then
stained for lacZ (Fig. 4C, closed circles). After
3 d in 25 mM
[K+]o, a culture period that
produces no lacZ-positive cells after initial plating in 5 mM [K+]o (Fig.
4B), reversion to 5 mM
[K+]o media resulted in only 41 ± 4% lacZ-positive cells being present after 15 DIV (compared with
74 ± 2% in side-by-side 5 mM
[K+]o controls) (Fig.
4B,C). Greater depressions in the final fraction of
lacZ-positive cells were seen when the cultures were switched to 5 mM [K+]o after 5, 7, 9, or
11 d in 25 mM [K+]o
(Fig. 4C). Thus, the longer the cells are maintained in 25 mM [K+]o, the
greater the loss in the capacity to induce the 6 gene on subsequent
transfer to 5 mM
[K+]o.
In reciprocal experiments, cells from P5 cerebella were
maintained in 5 mM [K+]o
for the initial 3, 5, 7, 9, or 11 d before switching to 25 mM [K+]o, until a
total of 15 d had passed (i.e., 3 d in 5 mM
[K+]o, then 12 d in 25 mM [K+]o; 5 d
in 5 mM [K+]o,
then 10 d in 25 mM
[K+]o, etc.). Cultures were
then stained for lacZ (Fig. 4C, open squares). In
three separate experiments, the longer the cells were initially
cultured in 5 mM
[K+]o, the greater the final
number of cells that expressed lacZ after culture in 25 mM
[K+]o. The time course mirrors the
switching of experiments from 25 to 5 mM
[K+]o: when switched after 3 d,
the number of lacZ-positive cells is 30 ± 3%, after 5 d
50 ± 7%, after 7 d 70 ± 3%, after 9 d 72 ± 2%; a switch after 11 d of initial culture in 5 mM
[K+]o had no effect on the final
percentage, which was 75 ± 2% (the same as cultures grown in 5 mM [K+]o for 15 DIV) (Fig.
4B).
A critical early period in culture therefore determines the ability of
the cell to subsequently express the 6 subunit gene: periods of
culture 3 d in 25 mM
[K+]o curtail the ability of cells to
induce the 6 gene on transfer to 5 mM
[K+]o. If the cells spend their
initial culture time in 5 mM
[K+]o, however, they can still
express the 6-lacZ gene in 25 mM [K+]o.
Granule cells maintained in 25 mM
[K+]o are electrically silent
An increase in the [K+]o
produces a depression in 6 gene expression. Does this correlate with
neural activity? We compared the electrophysiological properties of
granule cells grown in 5 and 25 mM
[K+]o. We analyzed (1) the resting
membrane potential and the ability to fire action potentials in
response to a depolarizing stimulus and (2) the presence of spontaneous
glutamatergic and GABAergic synaptic transmission.
Resting potentials and excitability
The resting membrane potentials of 6lacZ cells cultured in 5 and 25 mM [K+]o were
compared (see Materials and Methods). The membrane potential of cells
cultured and recorded in 25 mM
[K+]o was significantly more positive
(36 ± 1 mV; n = 11) than that in granule cells
cultured and recorded in 5 mM
[K+]o (50 ± 2 mV;
n = 7). In contrast to 25 mM
[K+]o cells, a proportion of cells
from 5 mM [K+]o cultures
showed spontaneous action potential firing at their resting potential
(data not shown). Depolarizing stimuli (see Materials and Methods)
applied to cells from 5 mM
[K+]o cultures (recorded in 5 mM [K+]o)
consistently produced action potentials (Fig.
5A, left, arrow) within
milliseconds of the start of the stimulus (n = 7). In
contrast, current injection into cells from 25 mM
[K+]o cultures, at their resting
potential in 25 mM
[K+]o, produced no action
potentials in any cell tested (n = 8) (Fig. 5A, center).
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Figure 5.
Effects of [K+]o
on membrane potential, action potential generation, and activity of
synaptic inputs of cerebellar granule cells. A, Examples
of granule cells recorded in current-clamp mode. The cell on the
left, cultured in 5 mM
[K+]o, is at its resting
potential in an extracellular solution containing 5 mM
[K+]o; the cell in the
center, cultured in 25 mM
[K+]o, is at its resting
potential in a 25 mM [K+]o
extracellular solution; the cell on the right is similar
to that in the center, but it has been hyperpolarized by current
injection. The traces show the responses to a range of
current injections (5 to 35 pA); arrows mark the
action potentials produced close to the start of the current injection
pulse. B, Comparison of excitatory synaptic transmission
(mEPSCs) between 6lacZ cultures maintained in 5 and 25 mM [K+]o. Example of
current traces recorded in the whole-cell voltage-clamp at 70 mV.
6lacZ cells grown in 25 mM
[K+]o exhibited no spontaneous
excitatory transmission. mEPSCs were isolated in TTX (1 µM) and bicuculline methochloride (50 µM).
C, Comparison of inhibitory synaptic transmission
(mIPSCs) between 6lacZ cultures maintained in 5 and 25 mM [K+]o. Example of
current traces recorded in the whole-cell voltage-clamp at 70 mV.
6lacZ cells grown in 25 mM
[K+]o had no spontaneous miniature
synaptic transmission in the presence of 10 µM CNQX and 1 µM TTX. In contrast, those cultured in 5 mM
[K+]o had frequent spontaneous
synaptic events. These results were obtained with >10 separate culture
preparations.
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|
The mean amplitude of Na+ currents recorded (under
voltage-clamp) from granule cells cultured in 5 and 25 mM
[K+]o is not significantly different
(250 ± 62 pA, 5 mM K+ vs 257 ± 37 pA, 25 mM K+), so downregulation
of Na+ channel expression is not responsible for the
absence of spontaneous or stimulus-induced action potentials in cells
chronically cultured in 25 mM
[K+]o. In fact, action potential
generation can be restored in 25 mM
[K+]o cultured cells simply by
hyperpolarizing the resting membrane potential with a steady injection
of negative current (Fig. 5A, right). Thus voltage-dependent
inactivation of the Na+ channel is responsible for
the lack of action-potential firing in cells maintained in 25 mM [K+]o.
Spontaneous synaptic inputs
Reflecting spontaneous vesicular release, mEPSCs and mIPSCs arise
independently of action potential firing. GABAergic interneurons are
typically present in granule cell cultures, and 10 of 10 6lacZ granule cells from 5 mM
[K+]o cultures had spontaneous mIPSCs
(average frequency 6.2 ± 1.3 Hz) (Fig. 5C) (also see
Martina et al., 1997). These events were reversibly blocked by either
10 µM bicuculline methochloride or 200 µM
picrotoxin (data not shown). In contrast, 10 of 10 cells from cultures
grown in 25 mM [K+]o had
no detectable mIPSCs (Fig. 5C). A similar lack of mIPSCs was
seen in wild-type cultures grown in 25 mM
[K+]o (data not shown) [note: in
6lacZ homozygous mice, the 6 and subunits are eliminated
and reduced, respectively (Jones et al., 1997), but the remaining 1,
2, 3, and 2 subunits are adequate for GABAA
receptor-mediated synaptic responses of granule cells].
In dissociated cerebellar cultures, rat granule cells innervate and
release glutamate onto each other (Gallo et al., 1982). In cells from
chronic 5 mM [K+]o
6lacZ mouse cultures, mEPSCs occurred at a frequency of ~0.1 Hz
(Fig. 5B). As for mIPSCs, no spontaneous excitatory synaptic activity was detected in cells from 25 mM
[K+]o cultures (Fig.
5B).
The absence of spontaneous GABA and glutamate release in cells
chronically cultured in strongly depolarizing media could be caused by
a failure to form synaptic connections or long-term vesicle depletion
from presynaptic terminals. Both mIPSCs and mEPSCs of 25 mM
[K+]o cultured cells could be
reestablished by overnight culture in 5 mM
[K+]o (data not shown). This suggests
that vesicle depletion is the most likely explanation for the absence
of synaptic transmission in long-term 25 mM
[K+]o cultures.
Expression of the 6 subunit is depressed by tetrodotoxin but not
by blockers of synaptic transmission
The electrophysiological experiments described above demonstrate
that in 5 mM [K+]o
cultures, granule cells receive active excitatory and inhibitory synaptic inputs and are competent to fire action potentials; in contrast, in chronic 25 mM
[K+]o, granule cells are
electrically silent. Therefore, either intrinsic firing, released
neurotransmitters (e.g., GABA or glutamate), or agents such as growth
factors could be responsible for 6 gene induction in the 5 mM [K+]o cultures.
To test the contribution of GABA and glutamate, 5 mM
[K+]o 6lacZ cultures were grown
in the presence of glutamate and GABA receptor antagonists for 11 d. Blockade of AMPA/kainate receptors with CNQX (10 µM),
NMDA receptors with CPP (10 µM)
(also see Thompson et al., 1996a), or
metabotropic mGluR receptors with -MCPG (500 µM) (Fig.
6A) had no influence on the number of lacZ-positive cells produced in 5 mM
[K+]o. Similarly, neither the
GABAA/GABAC receptor antagonist
picrotoxin (50 µM) nor the GABAB receptor
blocker CGP 55 845A (10 µM) (Davies et al., 1993)
inhibited 6-lacZ expression (Fig. 6A). For rat granule cells, the effects of elevated
[K+]o are mimicked by long-term
culture in the presence of 5 mM
[K+]o and NMDA (Balázs et al.,
1988). Chronically applied NMDA (10 µM), however, did not
mimic the inhibition of lacZ expression produced by chronic 25 mM [K+]o in our mouse cell
cultures (Fig. 6A).
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Figure 6.
The effects of ion channel activity on the
development of 6-lacZ granule cell expression in 5 mM
[K+]o. A, The effects
of 10 µM CPP, 500 µM MCPG, 50 µM picrotoxin (PTX), 10 µM CNQX, 10 µM CGP55845A (C55), and 10 µM NMDA on lacZ expression in cultures maintained in 5 mM [K+]o for 11 d
in vitro. Each bar represents data pooled from two
coverslips in each of three separate 6lacZ cultures.
B, The fraction of lacZ- positive cells present in 5 mM [K+]o 6lacZ
cultures grown under control conditions (Cntl) or
in 1 µM -CTx-GVIA (GVIA), 300 nM -Aga-IVA (AIVA), or 10 µM nifedipine (Nif). Each bar
represents the average of two coverslips in each of three
cultures.
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At 1 µM, the Na+ channel blocker TTX
eliminates sodium currents and action potentials in cerebellar granule
cells (data not shown). TTX (1 µM) applied for the
duration of the culture (15 DIV in 5 mM
[K+]o) produced a significant
inhibition in the number of lacZ-positive cells (Fig.
7), although many cells still expressed
the gene. Many cells also died during the TTX treatment; only 45% of
cells survived, compared with those grown in 5 mM
[K+]o alone (Fig. 7C).
However, within this surviving group, only 25 ± 4% of cells
express lacZ, compared with the 60 ± 8% in the parallel control
groups (Fig. 7D). Therefore, action potential firing
stimulates induction of the 6 subunit gene, either directly by
regulating the gene or indirectly by promoting the health of the
granule cell, because so many cells die in the presence of TTX, and the
remaining nonexpressing ones may be compromised.
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Figure 7.
Development of 6-lacZ gene expression in
cultured cerebellar granule cells: effects of TTX. A, B,
Cultures maintained in 5 mM
[K+]o for 15 DIV in the absence
(A) and presence (B) of 1 µM TTX. C, The percentage of surviving
cells in 5 mM [K+]o and 1 µM TTX compared with cells in the same media but with no
added TTX. D, The percentage of 6-lacZ-expressing
cells present in 1 µM TTX-containing and control media
for the experiments described in C. The cells were
counted at the cell-dense area of the coverslips; the average of four
separate experiments was calculated. In all panels, blue
staining indicates lacZ-positive cells; lacZ-negative cells are
red. Scale bar, 30 µm.
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|
One link between changes in membrane potential (e.g., action potential
firing) and gene expression is through activation of voltage-dependent
dihydropyridine-sensitive L-type Ca2+ channels
(Bading et al., 1993). Although these channels are present on rodent
granule cells grown in 5 mM
[K+]o (Randall and Tsien, 1995), their
chronic inhibition with the antagonist nifedipine (10 µM)
had no effect on the number of lacZ-positive cells in cultures grown in
5 mM [K+]o (Fig.
6B). Rat granule cells cultured in 5 mM
[K+]o also express considerable
current components that are sensitive to antagonists of N- and P/Q-type
Ca2+ channels (Randall and Tsien, 1995). Chronic
applications of the N-type channel antagonist -CTx-GVIA (1 µM) and the P/Q-type antagonist -Aga-IVA (300 nM), however, produced no change in the number of
lacZ-positive granule cells in 5 mM
[K+]o cultures (Fig.
6B). Therefore, in vitro expression of the
6 subunit gene is not specifically coupled to the opening of L-, N-,
P-, or Q-type Ca2+ channels.
Growth factors
Growth factors, such as brain-derived neurotrophic factor (BDNF)
or thyroid hormone (T3), promote granule cell function and differentiation (Leingärtner et al., 1994; Gao et al., 1995; Neveu and Arenas, 1996; Nonomura et al., 1996). We examined whether 6 gene expression in cultures grown in 25 mM
[K+]o could be rescued by these or
other growth factors. P5 granule cells were cultured in 25 mM [K+]o for 11 d,
and the following growth factors were included individually in the
media throughout the culture period: BDNF (200 ng/ml), NT-3 (100 ng/ml), NGF (100 ng/ml) or T3 (10 ng/ml). None of these factors were
able to induce lacZ expression in 25 mM
[K+]o media (data not shown). The trk
antagonist K252a (used at 50 nM) (Leingärtner et al.,
1994) produced no change in the number of lacZ-positive cells in a 5 mM [K+]o culture of
6lacZ cerebellum: 68% blue cells in K252a versus 71% blue cells
in control [also reported with mouse cells (Lin and Bulleit, 1997)].
Therefore, various growth factors implicated in cerebellar development
are not required for the induction of the mouse 6 subunit gene.
| |
DISCUSSION |
We have used a lacZ reporter inserted into the GABAA
receptor subunit 6 gene to follow 6 expression in developing
mouse cerebellum and to assay factors regulating this expression in differentiating mouse granule cells in culture. At early stages (the
first 3 postnatal weeks), 6 expression is strongly mosaic within and
between developing cerebellar lobules (Fig. 2). This may account for
differences in GABAA receptor subunit expression assayed by
single-cell PCR on juvenile slices, in which 50% of rat granule cells
are 6-negative (Santi et al., 1994b). In culture, cells express the
6-lacZ gene only in low (5-15 mM)
[K+]o, whereas under chronic
depolarizing conditions (25 mM
[K+]o) 6 is induced in few
cells. The use of lacZ as a reporter allowed the heterogeneity in the
cultures to be seen directly. In most previous studies of
GABAA receptor subunit development in culture, mRNA or
membranes have been pooled from populations of cells. In agreement with
the lacZ gene expression results, benzodiazepine enhancements of
GABAA receptor responses recorded from granule cells
cultured in 25 mM [K+]o
did not differ between 6lacZ +/+ and / cells (J. R. Mellor and A. D. Randall, unpublished observations), and no 6
immunoreactivity could be detected in membrane extracts prepared from
+/+ mouse cells cultured in 25 mM
[K+]o. (Fig. 3I). By
contrast, when cells were grown in 5 mM
[K+]o for 2 weeks, +/+ and /
granule cells differed in benzodiazepine sensitivities, as expected
from the loss of the 6 subunit in / cells (Jones et al., 1997),
and 6 immunoreactivity could be detected from +/+ membranes
(Fig. 3I).
Factors regulating GABAA receptor 6 subunit gene
expression: subtle species differences?
There are many descriptions of the development of
GABAA receptor 6 subunit expression in dissociated
cultures of rat cerebellum (for review, see Wisden et al., 1996), but
few using mice [only Lin and Bulleit (1996, 1997), Lin et al. (1998),
and this report]. The majority finding is that in rat cultures using
20-25 mM [K+]o,
6 subunit gene expression, as assayed by RNA and protein levels or
with electrophysiology and drug-binding profiles, either increases with
time in culture or is at least abundantly present (Malminiemi and
Korpi, 1989; Bovolin et al., 1992; Mathews et al., 1994; Thompson and
Stephenson, 1994; Zheng et al., 1994; Caruncho et al., 1995; Gao and
Fritschy, 1995; Thompson et al., 1996a,b; Zhu et al., 1996; Ghose et
al., 1997). There is no evidence for the effect of
[K+]o, and therefore membrane
depolarization, on rat 6 gene expression: the rate of 6 gene
transcription does not vary between rat cells cultured in 12.5 versus
25 mM [K+]o (Harris et
al., 1995). 6 mRNA steady-state levels are not significantly
different in rat granule cells (prepared from P8 cerebella) after 5 DIV
in either 12.5 or 25 mM
[K+]o cultures (Harris et al.,
1994).
It may be that mouse and rat 6 gene regulation differ subtly. For
example, mouse and rat granule cells have differing survival requirements, possibly reflecting physiological differences. It is well
known that elevated extracellular K+ concentrations
(e.g., 25 mM [K+]o)
promote long-term survival of rat cerebellar granule cells in
dissociated cultures (Gallo et al., 1987), but they are not essential
for experiments requiring long-term culture of mouse cells. In some
conditions, mouse cells survive as well in 5 as in 25 mM
[K+]o (Peng et al., 1991; Mogensen et
al., 1994; Mogensen and Jorgensen, 1996).
Our results for mouse cells are partially supported, however, by
observations that in some cases 6 expression in rat cells is not
necessarily constitutive. One group has reported that regardless of
culture conditions, 6 mRNA fails to increase from low basal levels
in 25 mM [K+]o,
although the RNA levels of some other subunits increase over time in
the same cultures (Behringer et al., 1996; Gault and Siegel, 1997).
In vivo, the 6 and subunit genes have similar
developmental profiles: both genes switch on as the cells reach the
internal granule cell layer (Laurie et al., 1992b), and the two
proteins specifically associate in a GABAA receptor subtype
(Jones et al., 1997; for review, see Wisden and Moss, 1997).
Interestingly, they are not regulated in the same way: subunit mRNA
increases in rat granule cells cultured in chronic 25 mM
[K+]o, but not in 5 mM [K+]o, and is
also regulated by cell density (Behringer et al., 1996; Gault and
Siegel, 1997). Chronically depolarized cells have higher calcium loads
than those maintained in 5 mM
[K+]o, and
Ca2+/calmodulin-dependent protein kinases are
implicated in gene regulation (Gault and Siegel, 1997). We have
found that cells maintained in chronic 25 mM
[K+]o are electrically silent (see
below), suggesting that subunit gene expression is inversely
related to the amount of synaptic transmission and action potential
firing.
Action potential firing, but not synaptic transmission,
stimulates 6 gene induction
There is a correlation between neuronal activity and 6 gene
induction. In 5 mM
[K+]o, a proportion of granule
cells fire spontaneous action potentials and have spontaneous
excitatory and inhibitory synaptic transmission. In chronic
depolarizing conditions (25 mM
[K+]o), voltage-gated
Na+ channels are inactivated (no action potentials),
and transmitter vesicle pools are probably depleted (no mIPSCs or
mEPSCs). Despite the correlation with activity, GABA receptor,
glutamate receptor [see also Thompson et al. (1996a) for ionotropic
glutamate antagonists on rat cells in 25 mM
[K+]o], and voltage-gated
Ca2+ channel activation are not necessary for 6
gene induction in cultures grown in 5 mM
[K+]o (Fig. 6).
Nevertheless, elimination of Na+ channel function
with chronic TTX treatment blocks 6-lacZ induction in some cells,
as well as killing many of them, although a proportion of surviving
cells remain intensely stained for lacZ (Fig. 7). This mixed result could be because dissociated granule cell cultures are made by pooling
granule cells at different stages of their development (i.e., at P5,
vermis lobule IX and X are already beginning to express the 6 gene,
whereas other lobules and the hemispheres are several days behind)
(Fig. 2). At the time of plating, some cells may already be committed
to expressing 6 and may be unresponsive to the inhibition of
Na+ channels; other cells could still be at an
earlier and more malleable stage.
There could be factors (other than GABA or glutamate) endogenously
released in 5 mM [K+]o
that promote 6 expression. For instance, in the granule cell layer
of the mutant mouse stargazer, BDNF mRNA levels are
attenuated (Qiao et al., 1996), and 6 protein levels are reduced to
20% of wild-type (Barnes et al., 1997). However, K252a, a selective blocker for trk tyrosine kinases (receptors for BDNF, NT-3, and NGF)
(Leingärtner et al., 1994), did not stop an increase of 6 mRNA
in cultured mouse cells over a 4 d period (Lin and Bulleit, 1997;
and our results). Although BDNF is not essential for 6 expression,
it does enhance the rate of appearance of 6 mRNA in cultured mouse
granule cells, possibly by promoting the general maturation of the cell
(Lin et al., 1998).
| |
Conclusions |
The best predictor of 6 gene expression is simply cell age:
6 expression may be "hard-wired" into the terminal
differentiation program of granule cells (Lin and Bulleit, 1996), with
the commitment to express 6 starting at an earlier point in granule
cell development, as suggested for other GABAA receptor
subunit genes (Beattie and Siegel, 1993). For example, this could be
regulated by a cellular clock initiating from the last mitotic division
in the external granule cell layer. The development of 6 expression
is resistant to most experimental modulations. During the first days in
culture, however, depolarizing [K+]o
blocks subsequent 6 gene expression, whereas normal
[K+]o permits future induction. As the
period of initial plating and growing in 25 mM
[K+]o is increased, fewer cells are
capable of switching on the 6-lacZ gene after they are transferred
to 5 mM [K+]o. Conversely,
prolongation of the initial culture period in 5 mM
[K+]o enables more cells to express
the 6-lacZ gene after transfer to 25 mM
[K+]o. Although the effect of an
initial plating in 25 mM
[K+]o for 11 DIV is absolute (no
expression), voltage-gated Na+ channel activity acts
on subpopulations of developing cells; cAMP elevation also reduces 6
levels (Thompson et al., 1996b; rat cells, Ghose et al., 1997). Stimuli
that pattern action potential firing may therefore influence the timing
of 6 induction. Identification of the proteins that bind to the
regulatory regions of the 6 gene will explain how the final stages
of granule cell maturation take place (Jones et al., 1996; Bahn et al.,
1997).
| |
FOOTNOTES |
Received Sept. 12, 1997; revised Jan. 26, 1998; accepted Feb. 3, 1998.
D.M. holds a European Community Training and Mobility of Researchers
Fellowship (category 30), and J.R.M. holds a Medical Research Council
(MRC) Research Studentship. We thank H. Bading [Laboratory of
Molecular Biology (LMB), MRC] and A. J. Morton (Department of
Pharmacology, University of Cambridge) for discussion; G. Percipalle
(LMB, MRC) for advice on immunoblotting; F. A. Stephenson (School
of Pharmacy, University of London) for the gift of 6-N serum; and A. Lenton and J. Westmorland (MRC Visual Aids) for help with figure
preparation.
Correspondence should be addressed to A. D. Randall or W. Wisden,
Medical Research Council Laboratory of Molecular Biology, Medical
Research Council Centre, Hills Road, Cambridge, CB2 2QH, UK.
| |
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Copyright © 1998 Society for Neuroscience 0270-6474/98/1882822-12$05.00/0
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Top
Abstract
Introduction
Gene
