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The Journal of Neuroscience, January 1, 2000, 20(1):8-21
Positive Modulation of AMPA Receptors Increases Neurotrophin
Expression by Hippocampal and Cortical Neurons
Julie C.
Lauterborn1,
Gary
Lynch2,
Peter
Vanderklish3,
Amy
Arai2, and
Christine M.
Gall1, 3
Departments of 1 Anatomy and Neurobiology,
2 Psychiatry and Human Behavior, and
3 Psychobiology, University of California, Irvine,
California 92697-4292
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ABSTRACT |
This study investigated whether positive modulators of AMPA-type
glutamate receptors influence neurotrophin expression by forebrain
neurons. Treatments with the ampakine CX614 markedly and reversibly
increased brain-derived neurotrophic factor (BDNF) mRNA and protein
levels in cultured rat entorhinal/hippocampal slices. Acute effects of
CX614 were dose dependent over the range in which the drug increased
synchronous neuronal discharges; threshold concentrations for acute
responses had large effects on mRNA content when applied for 3 d.
Comparable results were obtained with a second, structurally distinct
ampakine CX546. Ampakine-induced upregulation was broadly suppressed by
AMPA, but not NMDA, receptor antagonists and by reducing transmitter
release. Antagonism of L-type voltage-sensitive calcium channels
blocked induction in entorhinal cortex but not hippocampus. Prolonged
infusions of suprathreshold ampakine concentrations produced peak BDNF
mRNA levels at 12 hr and a return to baseline levels by 48 hr. In
contrast, BDNF protein remained elevated throughout a 48 hr incubation
with the drug. Nerve growth factor mRNA levels also were increased by
ampakines but with a much more rapid return to control levels during
chronic administration. Finally, intraperitoneal injections of CX546
increased hippocampal BDNF mRNA levels in aged rats and middle-aged
mice. The present results provide evidence of regional differences in
mechanisms via which activity regulates neurotrophin expression.
Moreover, these data establish that changes in synaptic potency produce
sufficient network level physiological effects for inducing
neurotrophin genes, indicate that the response becomes refractory
during prolonged ampakine exposure, and raise the possibility of using
positive AMPA modulators to regulate neurotrophin levels in aged brain.
Key words:
brain-derived neurotrophic factor; nerve growth factor; ampakine; hippocampus; gene regulation; trkB; aging
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INTRODUCTION |
Neurotrophins protect neurons from a
variety of pathogenic conditions (Lindvall et al., 1994 ; Mattson and
Scheff, 1994). Consequently, there is considerable therapeutic interest
in finding means to increase their availability in adult brain.
In vivo the neurotrophins brain-derived neurotrophic factor
(BDNF) and nerve growth factor (NGF) are positively regulated by
neuronal activity across a broad intensity range as demonstrated by the
effects of seizures (Gall and Isackson, 1989; Bengzon et al., 1993;
Lauterborn et al., 1995), afferent (Patterson et al., 1992;
Castrén et al., 1993) and sensory (Castrén et al., 1992;
Rocamora et al., 1996) stimulation, physical exercise (Neeper et al.,
1996), and behavior in complex environments (Torasdotter et al., 1996;
Gall et al., 1998; Kesslak et al., 1998). Although there is no direct
evidence that variations in patterns of activity associated with
everyday behaviors are sufficient to alter expression, the above
observations suggest that elevations in neurotrophin production might
be achieved by enhancing normally occurring physiological events.
Current evidence suggests that activity-dependent expression is
primarily mediated by non-NMDA glutamate receptors. Kainic acid is a
potent inducer of BDNF and NGF in hippocampal neurons, whereas NMDA is
not (Zafra et al., 1990; Ghosh et al., 1994; Wetmore et al., 1994). The
degree to which kainate's effects on expression are caused by
stimulation of kainate- as opposed to AMPA-type glutamate receptors has
not been established. The excitotoxin causes seizures, the concomitants
of which undoubtedly include AMPA receptor activation. AMPA receptors
bind kainate with moderate affinity (Hall et al., 1994) and do not
desensitize as rapidly as kainate receptors (Patneau and Mayer, 1991;
Lerma et al., 1993). Because the former receptors are orders of
magnitude more numerous than the latter (Simon et al., 1976; Olsen et
al., 1987), slowly desensitizing binding to them is likely to be a
significant contributor to the effects induced by kainate. If
AMPA-gated ion currents regulate neurotrophin gene regulation, then
compounds that specifically enhance these currents should promote
expression. The present studies tested this prediction using cultured
hippocampal slices.
Ampakines are a group of recently introduced, small compounds (Arai et
al., 1994; Staubli et al., 1994a) that slow deactivation of AMPA
receptors and thereby increase fast excitatory synaptic currents (Arai
et al., 1996). The drugs do not have agonistic or antagonistic
properties but instead modulate the receptor rate constants for
transmitter binding, channel opening, and desensitization (Arai et al.,
1996). Ampakines are of particular interest with regard to neurotrophin
regulation because they freely cross the blood-brain barrier (Staubli
et al., 1994b) and have subtle effects on behavior at dosages
sufficient to affect unit activity in the hippocampus (Hampson et al.,
1998b). They enhance the encoding of several variants of memory
in rats (Staubli et al., 1994a; Rogan et al., 1997) and possibly humans
(Ingvar et al., 1997) without detectably affecting performance or mood.
Moreover, repeated administration produces lasting improvements in
learned behaviors without causing evident side effects (Hampson et al.,
1998a). If positive modulation of AMPA receptors is an adequate
stimulus for upregulating neurotrophins, then ampakines could provide a means to exploit this for therapeutic purposes. Accordingly, the present studies included tests of whether systemic ampakine treatment increases neurotrophin gene expression in brain.
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MATERIALS AND METHODS |
In vitro experiments. Cultured hippocampal
slices were prepared from Sprague Dawley rat pups (9-10 d after birth;
Simonsen Labs, Gilroy, CA; n = 70) as described
previously (Stoppini et al., 1991; Rivera et al., 1993). In most cases,
the cultured slices contained the hippocampus, subiculum, and portions
of entorhinal cortex. Slices were explanted onto Millicel-CM
biomembrane inserts (Millipore, Bedford, MA) in a six-well
culture cluster plate (Corning, Cambridge, MA) containing sterile media
(1 ml/well) consisting of minimum essential media, 30 mM dextrose, 30 mM HEPES, 5 mM Na2HCO3, 3 mM glutamine, 0.5 mM
ascorbic acid, 2 mM CaCl2,
2.5 mM MgSO4, 1 mg/l
insulin, and 20% horse serum, pH 7.2 (all reagents from Sigma, St.
Louis, MO). For each rat, slices from both hippocampi were explanted
onto four biomembranes (four slices per membrane group). The tissue was
maintained for 12-18 d in a humidified incubator at 37°C in 5%
CO2; the medium was changed every other day.
Treatment was as follows. All experiments were begun on days 11-12 in
culture. Two AMPA receptor-modulating drugs (ampakines) were used:
CX614 (LiD37 or BDP-37) (Arai et al., 1997; Hennegriff et al.,
1997; Kessler et al., 1998) and CX546 (GR87 or BDP-17) (Rogers et al.,
1988; Holst et al., 1998), both gifts from Cortex Pharmaceuticals
(Irvine, CA). The ampakines were dissolved in 100% dimethylsulfoxide
(DMSO; Sigma) and stored at  20°C. Doses and treatment
schedules are presented in Results with each experiment. For controls,
cultures were either untreated or treated with equivalent concentrations of vehicle (i.e., DMSO at final dilutions of
1:2000-1:10,000). For experiments in which multiple drug doses were
used, the DMSO concentration used for the vehicle control was the same
as that used for the highest ampakine dose. Preliminary control
experiments demonstrated that treatment with DMSO vehicle alone had no
significant effect on BDNF mRNA content over the treatment intervals
used here. Specifically, explants were treated with the highest dose of
DMSO (1:2000) and fixed after exposure intervals of 12 hr
(n = 8), 24 hr (n = 7), 48 hr
(n = 15), and 96 hr (n = 7); mRNA
levels were compared with those in untreated explants
(n = 16). Evaluation of BDNF cRNA-labeling densities
within the principal cell layers of the hippocampus and in layers
II/III of the entorhinal cortex revealed no significant differences
between untreated and DMSO-treated explants at any time point
(p = 0.233 for stratum granulosum and p = 0.1 for entorhinal cortex, Kruskal-Wallis;
p = 0.294 for CA1 stratum pyramidale and
p = 0.164 for CA3 stratum pyramidale, ANOVA). Because
DMSO had no effect on mRNA expression, control tissue from each culture
plate was generally fixed to correspond to the longest time point
tested. However, to verify further that there were no effects of the
vehicle on mRNA content, in some sets DMSO-treated control tissue also
was fixed at additional time points as noted in the figure captions.
Because there were no significant differences in labeling densities
across control groups in time course experiments, the control data were
grouped for statistical comparisons with measures from experimental
tissue. For all experiments, the ampakines were maintained in the
culture media throughout the full treatment interval unless otherwise
indicated. For experiments using CNQX (20 µM;
Tocris Cookson, Ballwin, MO), APV (100 µM;
Tocris Cookson), nimodipine (20 µM; Alomone
Labs, Jerusalem, Israel), or CoCl2 (5 mM; Sigma), cultured slices were first pretreated
(1 hr for CNQX and APV, 30 min for nimodipine, and 10 min for
CoCl2) with either the blocker or vehicle in
media and then treated for 3 hr with either blocker alone, blocker + 50 µM CX614, 50 µM CX614 alone, or vehicle.
For in situ hybridization analyses, treatments were
terminated by fixation with 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.2 (PPB). After overnight
fixation the slices were cryoprotected with 20% sucrose in PPB for 1 hr and then sectioned (20 µm) parallel to the broad explant surface
using a freezing microtome. Sections were mounted onto Superfrost/Plus
slides (Fisher Scientific, Houston, TX) and processed for in
situ hybridization as described below. For BDNF protein assay,
tissue was collected as described below.
In vivo experiments. Aged Long-Evans rats (Charles
River Laboratories, Wilmington, MA) ranging in age from 18 to 21 months were used (n = 10). Because stress has been reported to
inhibit BDNF mRNA expression (Smith et al., 1995), rats were first
acclimated to procedures by handling (10 min/d) for 5 d followed
by handling with daily intraperitoneal injections of 0.9%
saline for 5 additional days. The rats were then injected once daily
for 5 d either with 30 mg/kg CX546 dissolved in 16.5%
cyclodextrin [2-hydroxypropyl- -cyclodextrin (CDX); Aldrich,
Milwaukee, WI] in 0.9% saline (n = 6) or with a
comparable volume of vehicle (16.5% CDX in 0.9% saline;
n = 3). One additional rat was injected daily with
0.9% saline. Animals were killed 24 hr after the last injection by
overdose with sodium pentobarbital and intracardial perfusion with PPB.
Middle-aged C57/blk mice (The Jackson Laboratory, Bar Harbor, ME) from
9 to 11 months of age were used (n = 9). Mice were injected intraperitoneally once with 40 mg/kg CX546 in 16.5% CDX in
0.9% saline (n = 3) or with vehicle (n = 3). Mice were killed 24 hr after injection, with paired untreated
controls (n = 3), by overdose with sodium pentobarbital
and perfusion with PPB.
Brains were post-fixed for 24 hr at 4°C in perfusate, cryoprotected
in 20% sucrose in PPB for 48-72 hr at 4°C, sectioned (25 µm,
coronal) through the hippocampus using a freezing microtome, and
collected into cold PPB.
cRNA probe preparation. All cRNA probes were transcribed in
the presence of 35S-labeled UTP (DuPont
NEN, Boston, MA). The cRNA to BDNF exon V was generated from
PvuII-digested recombinant plasmid pR1112-8 (Isackson et
al., 1991), yielding a 540 base length probe with 384 bases
complementary to BDNF exon V-containing mRNA (Timmusk et al., 1993).
The rat NGF cRNA transcribed from PvuII-digested genomic
clone pBSNGF (Stratagene, La Jolla, CA) was 970 bases long with a span
complementary to 750 bases of the coding region of rat NGF mRNA
(Whittemore et al., 1988). The trkB cRNA was transcribed from
EcoRI-digested pSKTrkBPCR; the insert includes 338 bp
specific for the kinase (+) form of the receptor (Dixon and McKinnon,
1994).
In situ hybridization. In situ hybridization
procedures for slide-mounted and free-floating tissue were as described
in detail elsewhere (Lauterborn et al., 1994) with hybridization
incubation times of 16-20 hr for slide-mounted tissue or 30-36 hr for
free-floating tissue at 60°C and the
35S-labeled cRNA probe at a concentration
of 1 × 107 cpm/ml. After a final
posthybridization wash in 0.1× SSC buffer (1× SSC = 0.15 M NaCl and 0.015 M Na
citrate, pH 7.0) at 60°C, the free-floating tissue was mounted onto
gelatin-coated slides. All tissue was processed for both film (-max;
Amersham, Arlington Heights, IL) and emulsion (NTB2; Kodak
Eastman, Rochester, NY) autoradiography with exposure times of 2-4 d
and 3-5 weeks, respectively. After emulsion development, the tissue
was stained with cresyl violet or hematoxylin and coverslipped with
Permount (Fisher Scientific).
Quantification of in situ hybridization.
Hybridization densities were measured from film autoradiograms, with
labeling densities calibrated relative to film images of
14C-labeled standards (American
Radiolabeled Chemicals, St. Louis, MO), using the Microcomputer Imaging
Device (Imaging Research, St. Catherines, Ontario, Canada). The
standards were rated by micro-Curies per gram; therefore these same
units of measure were applied to tissue hybridization densities
reported herein. For in vitro experiments, measurements were
taken from the internal leaf of the dentate gyrus stratum granulosum,
CA3b stratum pyramidale, and CA1b stratum pyramidale. Where possible,
hybridization densities also were measured in layers II/III of the
entorhinal cortex. Measurements from the dentate gyrus molecular layer
were collected to estimate tissue background levels. For all
experiments, multiple measurements were taken from three to four tissue
sections per explant using a square sample-field template that spanned
the depth of the target cell layer. Ten adjacent samples were collected from each cell layer per section and averaged. The section averages were then totaled and averaged to generate an explant mean for each
field. For NGF cRNA hybridization, density measures were analyzed for
the stratum granulosum alone because this neurotrophin is not expressed
by the principal neurons within CA3-CA1 stratum pyramidale (Lauterborn
et al., 1993). For most in vitro experiments, the
significance of effect of treatment was determined by the one-way
ANOVA followed by the Student-Newman-Keuls (SNK) post hoc test or Student's t test for individual
comparisons. In circumstances in which the SDs were
significantly different between treatment groups (as determined by
Bartlett's test for homogeneity of variances), significance was
determined using the Kruskal-Wallis nonparametric ANOVA followed by
Mann-Whitney U or Student's t tests for
individual comparisons. For experiments in which blocking agents and
ampakines were used together, a two-way ANOVA was performed followed by either Student-Newman-Keuls, Student's t, or Mann-Whitney
U tests for planned comparisons. For in vivo
experiments, measurements were taken from the midseptotemporal
hippocampus within the internal leaf of the stratum granulosum, CA3b
stratum pyramidale, and CA1b stratum pyramidale; 10-15 measurements
per section were made for each field as described above. For each
animal, measurements were taken from three to four sections; section
means were averaged to generate a mean value for each field. The
significance of differences between drug-treated and control groups was
determined using Student's t test. In all instances
statistical analyses were conducted using the Instat 2.03 program
(Graph Pad, San Diego, CA) with reference to Motulsky (1995), and the
95% confidence level was considered significant. Unless otherwise
stated, statistical results presented in the text are for comparison
with control values.
BDNF immunoassay. Cultures were collected into 100 µl of
cold lysis buffer (137 mM NaCl, 20 mM Tris,
10% glycerol, 1 mM PMSF, 10 µg/ml aprotinin, 1 µg/ml
leupeptin, 0.5 mM Na vanadate, and 1% NP-40). Four
hippocampal slices from one insert were pooled for each "sample"
assayed; each time point included three to four separate samples.
Tissue was manually homogenized in lysis buffer, acidified to pH 2.5 with 1N HCl, and incubated for 15 min on ice. The pH was neutralized to
pH 8.0 with 1N NaOH, and samples were frozen (70°C) until assayed.
Total BDNF protein content for each sample was measured using the BDNF
Emax Immunassay System (Promega, Madison, WI) according to kit
instructions, with the absorbance at 450 nm determined using a plate
reader. Data from two separate immunoassay experiments were pooled for
statistical analyses using ANOVA followed by the Student-Newman-Keuls
test for individual comparisons.
Electrophysiology. Culture inserts containing three to four
hippocampal slices were transferred to a recording chamber 10-20 min
before recording. Slices were maintained at the interface between a
moist atmosphere containing 5% CO2 (flow rate, 1 l/min) and serum-free culture media at 33°C. Extracellular recordings from the stratum radiatum of field CA1 and the granule cell layer were
made using a glass pipette filled with 2 M NaCl. Explants exhibiting high basal activity, i.e., massive spike events followed by
spreading depression, were discarded. For acute effects of drug, basal
activity was monitored for 30 min, in normal serum-free medium, and
then culture medium containing CX614 was infused into the chamber; a
stock solution of CX614 (50 mM) was prepared in DMSO and
diluted 1:1000-1:5000 for experimental use. Preliminary experiments
demonstrated that DMSO at concentrations up to 0.2% (i.e., double the
highest concentration used in the present experiments) had no effect on
synaptic responses. Spontaneous field potentials were recorded during
sweeps of 1 sec duration; recording blocks consisted of 200 consecutive
sweeps separated by a 1 sec interval and thus extended over a period of
6-7 min. Recording blocks were collected during baseline monitoring
and 10 min after switching the media to one containing CX614. Field
potentials were acquired and digitized at 10 kHz using the Neuronal
Activity Acquisition Program (Eclectek Enterprise, Irvine, CA).
Statistical significance was determined using the one-way ANOVA
followed by Student's t or Mann-Whitney U tests for
planned comparisons.
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RESULTS |
In vitro studies
Ampakines increase BDNF expression in a dose-dependent manner
Cultured hippocampal slices were incubated with the ampakine CX614
at various concentrations and for different durations, and effects on
BDNF mRNA content were assessed by
35S-cRNA in situ hybridization
and quantification of autoradiographic labeling. As shown in Figure
1B, treatment with 50 µM for 3 hr caused a striking increase in BDNF
cRNA labeling in all subdivisions of the hippocampus. This effect was
fully reversed after switching to drug-free media for 15 or 21 hr (Fig.
1C). Group results for the dentate gyrus stratum granulosum
are summarized in Figure 1D. BDNF cRNA labeling at
the 3 hr time point was elevated above control values
(p < 0.01, SNK) and had declined to control
levels in the 18 and 24 hr washout groups.
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Figure 1.
The ampakine CX614 increases BDNF mRNA expression
in hippocampal explant cultures. A-C, Bright-field
photomicrographs of film autoradiograms showing the in
situ hybridization localization of BDNF cRNA labeling in
sections from a vehicle-control explant (A), an
explant treated for 3 hr with 50 µM CX614
(B), and an explant treated for 3 hr with CX614
(50 µM) and then maintained in drug-free media for an
additional 15 hr (C). Shown in B,
the 3 hr CX614 treatment increased BDNF cRNA labeling in the stratum
granulosum (sg) and stratum pyramidale
(sp) (regions CA3-CA1). This effect was reversed by 18 hr after drug washout (C). Scale bar, 300 µm.
D, Bar graph showing group mean-labeling density values
(± SEM; n > 4/group) within the stratum
(str.) granulosum of control explants treated for 3 hr
with DMSO (con), explants treated for 3 hr with CX614
(50 µM) alone, and explants treated for 3 hr with CX614
(50 µM), followed by drug washout for an additional 15 or
21 hr (for 18 and 24 hr time points, respectively). As shown, CX614
significantly increased BDNF cRNA labeling in the granule cells by 3 hr
(p < 0.01 vs control, SNK; overall effect
of treatment, p < 0.0005, ANOVA). This increase
was eliminated by subsequent 15-21 hr drug washout.
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Dose-response data for 3 hr incubations with CX614 are summarized in
Figure 2. The threshold dose for the
granule cells appeared to be ~10 µM, with 20 µM causing a robust and reliable increase relative to
that in control slices (p < 0.04). BDNF
mRNA levels in CA3 stratum pyramidale tended to be greater than control
values with CX614 treatment at 10 and 20 µM but
not significantly so, whereas the effects at 50 µM were robust. Measures from CA1 stratum pyramidale gave no evidence of a response to 10 or 20 µM; as shown in Figure 2, median scores
(horizontal lines) were virtually identical for
the 0, 10, and 20 µM ampakine treatment groups
(n = 4 each). However, as in the other hippocampal
subfields, 50 µM CX614 produced a significant
(p < 0.001) elevation. Densitometric
values for CA3 and CA1 were highly correlated (r = 0.986 for controls), making it possible to use within-slice comparisons
to test for effects at low drug concentrations. As shown in Figure 2
(right), the within-slice CA3/CA1 ratio increased
significantly from 0.70 in controls to 1.04 at 10 µM and to 1.51 at 20 µM, thereby demonstrating that there was indeed
a significant response to the lower dose. These latter observations
indicate that 3 hr exposures to threshold concentrations of ampakine
are sufficient to modify the balance of neurotrophin expression across
pyramidal cell subfields.
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Figure 2.
Ampakine-induced increases in BDNF mRNA content
are dose-dependent. Bar graphs show the effect of a 3 hr treatment with
various concentrations of CX614 on BDNF cRNA labeling in the dentate
gyrus stratum granulosum (SG), CA3 stratum pyramidale,
and CA1 stratum pyramidale. Left, Graphs show mean
density values for each subfield (± SEM; n = 4/group; left y-axis applies to the
stratum granulosum; right y-axis applies
to CA3 and CA1). In all fields there was a significant effect of
treatment (p = 0.0336 for SG;
p = 0.003 for CA3; p < 0.0001 for CA1). For the granule cells, a modest increase in labeling was seen
with 10 µM, and more dramatic increases were apparent
with the higher doses (p < 0.05 vs control,
SNK). For the pyramidal cells, only 50 µM elicited
significant increases (p < 0.001 for CA3;
p < 0.001 for CA1 vs control, SNK).
Right, The graph shows the within-slice values for the
CA3/CA1-labeling ratio (± SEM). As shown, there were significant
increases in the CA3/CA1 ratio at both 10 and 20 µM
(p < 0.05 and 0.03, respectively,
Student's t test for comparison with controls).
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The possibility that ampakine concentrations that were near threshold
at 3 hr would increase BDNF expression with prolonged application was
tested using 10 µM CX614. The drug was reapplied every 24 hr for 2, 3, or 4 d. ANOVA indicated that the treatment significantly increased BDNF mRNA content in each of the three hippocampal subdivisions. As shown in Figure
3, dramatic increases were evident after
72 hr and, in marked contrast to the results obtained with acute
administration of this dose, were of approximately the same magnitude
(~10-fold) in pyramidal and granule neurons. Thus, when applied at a
relatively low dose the ampakine progressively increases BDNF
expression over time and can sustain BDNF mRNA content at elevated
levels for days.
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Figure 3.
Chronic treatment with near-threshold doses of
CX614 increases BDNF expression with time in vitro. The
bar graph shows the effect of maintaining cultured hippocampal explants
in 10 µM CX614 for 48, 72, or 96 hr; control cultures
(C) were treated with DMSO vehicle (1:10,000) for
96 hr. Group mean densitometric measures (± SEM; n = 8/group) of BDNF cRNA labeling in the stratum granulosum
(SG), CA3 stratum pyramidale, and CA1 stratum pyramidale
are presented. For all three regions, there was a significant effect of
treatment (p < 0.0152 for
SG, 0.0012 for CA3, and 0.0003 for CA1, ANOVA), with the
greatest increase in labeling density occurring at 72 hr as compared
with controls (p < 0.05, 0.01, and 0.001 for SG, CA3, and CA1, respectively, SNK).
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The time course of ampakine-induced increases in BDNF mRNA content was
further evaluated using 50 µM CX614, shown above to influence mRNA content in all subfields after a 3 hr exposure. Results
obtained with treatments of 12, 24, and 48 hr are illustrated in Figure
4. As shown, a 12 hr exposure (Fig.
4B) increased labeling above that in control slices
(Fig. 4A) in all subdivisions of the hippocampus and
retrohippocampal cortex. With a 24 hr treatment (Fig. 4C),
BDNF mRNA levels were also increased but not to the degree seen after
12 hr. The falloff in labeling was still more evident in slices
continuously exposed to the ampakine for 48 hr (Fig.
4D), at which time expression approached control
levels. Figure 5 summarizes time course
results with CX614 at 50 µM for seven
experiments involving 85 explants. Differences in labeling densities
across time points were highly significant for each region sampled
(stratum granulosum, CA3 and CA1 stratum pyramidale, and entorhinal
cortex layer II; p < 0.0001, ANOVA). Peak values for
the hippocampus were attained by 12 hr; increases in the entorhinal cortex may have reached their maximum previously, but variance between
experiments precludes a strong conclusion. The size of the increase
differed across regions, ranging from 5-fold for the pyramidal cell
layers to 30-fold for the superficial entorhinal cortex. The
quantitative results in Figure 5 also confirm that the elevation in
BDNF mRNA declines between 12 and 24 hr (p < 0.05 for CA1; p < 0.01 for the entorhinal cortex;
p > 0.05 for the stratum granulosum and CA3, SNK) and
is gone by 48 hr despite continuous exposure to the ampakine. Still
longer incubations at this dose (i.e., 72 hr) did not result in further
increases or decreases from control values.
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Figure 4.
Suprathreshold CX614 treatment induces a transient
increase in BDNF mRNA expression in hippocampal/entorhinal cortex
explant cultures. Dark-field photomicrographs of tissue autoradiograms
show BDNF cRNA labeling in tissue sections through a control explant
(A) and explants treated continuously with 50 µM CX614 for 12 hr (B), 24 hr
(C), or 48 hr (D). As shown
in B, a 12 hr treatment markedly increased BDNF mRNA
levels throughout the strata granulosum (sg) and
pyramidale (sp) of the hippocampus and in the entorhinal
cortex (EC). At 24 hr (C),
labeling had decreased in each of these fields, as compared with the 12 hr time point (layers II/III entorhinal cortex indicated). At 48 hr
(D), labeling densities had returned to
near-control levels. Scale bar, 300 µm.
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Figure 5.
Time course of changes in BDNF mRNA content in
hippocampal and entorhinal cortex explants treated continuously with 50 µM CX614. Bar graphs show group mean densitometric
measures of BDNF cRNA labeling (µCi/gm) within the stratum granulosum
(SG) and the superficial entorhinal cortex
(EC) (left) and the stratum pyramidale of
regions CA3 and CA1 (right). Graphs show the cumulative
data from seven experiments (n = 85 explants; group
mean values ± SEM) measured from film autoradiograms. Values from
vehicle-control slices are presented at the 0 time point; control
values represent combined measures from 3, 24, and 72 hr DMSO-treated
explants (n = 31). In all fields, there was a
significant effect of treatment (p < 0.0001, ANOVA). BDNF cRNA labeling was elevated by 3 hr, was maximal at
12 hr, and was still significantly elevated through 24 hr of treatment.
Hybridization densities were not significantly different from control
values in slices treated for 48 or 72 hr (*p < 0.001;  p < 0.05, for comparison with controls,
SNK).
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Among other possibilities, the inverted U curve for duration versus
BDNF expression observed with suprathreshold CX614 treatment could
indicate that the ampakine is in some way altered by exposure to the
tissue or that slices so treated generate diffusible materials that
interfere with the drug's actions. As a first test of these possibilities, media from slices that had been exposed to CX614 at 50 µM for 3 hr were collected and applied to a second set of previously untreated slices for 3 hr. The media from this group were
then collected and applied to a third set of previously untreated slices for 3 hr. Figure 6 shows that the
ampakine was as potent on second and third applications as it was on
the first in inducing BDNF mRNA levels across the hippocampal subfields
and entorhinal cortex.
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Figure 6.
CX614 retains the ability to induce BDNF mRNA
expression over time in vitro. Bar graphs show group
mean BDNF cRNA-labeling densities (µCi/gm; ± SEM) within the stratum
granulosum (SG) and the superficial entorhinal cortex
(EC) (left) and the stratum pyramidale of
regions CA3 and CA1 (right). Group #1 explants were
treated with fresh 50 µM CX614 for 3 hr. The media were
then transferred to group #2 for 3 hr and then collected and
transferred to group #3 for another 3 hr. Each group of slices was
fixed at the end of its 3 hr ampakine treatment interval. Values from
untreated control slices are presented as Con;
n = 4-5 explants per group. In all fields, there
was a significant overall effect of treatment (ANOVA,
p < 0.0001 for the stratum granulosum;
p = 0.0005 for CA3; p = 0.0084 for CA1; p = 0.0002 for EC). In comparison
with the control group, hybridization was significantly elevated in all
drug-treated groups (*p < 0.05;
**p < 0.01 for CA1 and the entorhinal cortex;
**p < 0.001 for the stratum granulosum and CA3,
SNK). Notably, as compared with group #1 values, hybridization
densities were not reduced in later-treated groups.
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A second and less potent ampakine, CX546, was also tested for its
ability to induce BDNF expression. In an acute study, explants were
treated for 3 hr with CX546 at a range of concentrations (50, 100, and
250 µM; n = 4-5 explants/drug group;
n = 7 for 3 hr DMSO controls). With the 3 hr treatment,
BDNF mRNA levels in the stratum granulosum were modestly increased
(190% of control values) by a 50 µM dose
(p < 0.001, ANOVA for overall effect of treatment; p < 0.006 for 50 µM
vs control, Student's t test), a concentration that is
close to the threshold for enhancing field EPSPs in hippocampal slices
(A. Arai and G. Lynch, unpublished observations). The highest
concentration tested (250 µM) generated a
5.5-fold increase in expression (p < 0.006 vs
control, Mann-Whitney U test) in this cell layer; this is
close to the approximate sixfold increase elicited over 3 hr by a
functionally equivalent concentration (50 µM)
of CX614. Expression in the CA3 stratum pyramidale was unaffected by
the threshold CX546 concentration, tended to be elevated at 100 µM, and was robustly increased 3.8-fold above control values at 250 µM
(p < 0.001, ANOVA; p = 0.0031, Mann-Whitney U test for 250 µM vs
control). Labeling within CA1 was only elevated after treatment with
250 µM (1.6-fold above control values;
p < 0.001, ANOVA; p = 0.0154, Student's t test, for 250 µM vs
control). In all, acute treatment with CX546 produced the same
quantitative results as CX614 and with a similar regional distribution
of sensitivities (dentate > CA3 > CA1).
Treatment with CX546 for 24 hr (n = 6-10 explants for
drug-treated and 24 hr DMSO-control groups) increased BDNF mRNA content over a far lower dose range (25, 50, and 100 µM). There was a significant effect of
treatment with the drug for all three hippocampal subfields
(p < 0.02, Kruskal-Wallis nonparametric ANOVA
for all fields). Labeling was elevated 2.2- and 1.9-fold in the CA1
stratum pyramidale of slices treated with CX546 at 50 and 100 µM, respectively, as compared with DMSO-treated
controls (p < 0.02, Mann-Whitney U
test); these concentrations had no clear effect on BDNF mRNA by 3 hr
(above). All three doses significantly increased mRNA content in the
granule cell layer [2.4-fold for 25 µM
(p < 0.05, Student's t test);
5.9-fold for 50 µM and 4.6-fold for 100 µM (p < 0.011, Mann-Whitney U test)] and the CA3 stratum pyramidale [1.3-fold for 25 µM (p < 0.027, Student's t test); 5.3-fold for 50 µM and 3.8-fold for 100 µM (p < 0.027, Mann-Whitney U test)], with the 50 and 100 µM concentrations having much larger effects with longer incubations.
Ampakine treatment increases BDNF protein content
To determine whether induced increases in BDNF mRNA content were
associated with increases in BDNF protein, immunoassays were performed
on slices treated with CX614 at 50 µM for 6, 24, and 48 hr. Six hours were chosen as the earliest time point because previous
work demonstrated a 3-4 hr delay between activity-induced increases in
BDNF mRNA and immunoreactivity (IR) in vivo (Nawa et
al., 1995). For analysis, the four hippocampal slices within a single
culture well were pooled to create an individual sample; three to four
samples were measured per group. CX614 induced a significant increase
in BDNF-IR in all treatment groups, and in contrast to mRNA measures
(Fig. 5), protein levels were comparably elevated above control values
after 6, 24, and 48 hr exposures [control, 3.92 ± 1.63 ng/µg
(± SEM); 6 hr, 9.76 ± 1.07 ng/µg; 24 hr, 11.82 ± 1.21 ng/µg; 48 hr, 11.99 ± 2.00 ng/µg; p < 0.05, for all control vs experimental comparisons]. Values between
ampakine-treated groups were not significantly different.
Receptor and ion channel dependencies
Cultured slices were treated with CX614 in combination with
receptor or ion channel blockers. Figure
7, A and B, shows a
control slice and one treated with 50 µM CX614
for 3 hr, respectively; drug-induced increases in BDNF cRNA
hybridization in the dentate gyrus granule cells, hippocampal pyramidal
cells, and retrohippocampal cortex are evident. As shown in Figure
7C, this effect was essentially eliminated in paired slices
cotreated with the ampakine and the selective AMPA receptor antagonist
CNQX at 20 µM, a dose shown in other work to
block fast excitatory transmission in slices. In contrast, the NMDA
receptor antagonist APV (100 µM) had no obvious
effect on CX614-induced increases in BDNF mRNA content at the 3 hr time
point (Fig. 7D). This impression was reinforced by
densitometric analyses that revealed no measurable difference between
slices treated for 3 or 6 hr with 50 µM CX614 + 100 µM APV and those treated with 50 µM CX614 alone (data not shown).
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Figure 7.
Effects of various glutamate receptor and
voltage-sensitive calcium channel blockers on CX614-induced increases
in BDNF mRNA expression. Light-field photomicrographs of film
autoradiograms show BDNF cRNA labeling in sections from a control
(Con) culture (A) and cultures
treated for 3 hr with CX614 (50 µM) alone
(B) or in combination with CNQX (20 µM; C), APV (100 µM;
D), nimodipine (Nim; 20 µM;
E), or CoCl2 (5 mM;
F). In comparison with cultures treated with
CX614 alone, cultures treated with CX614 + CNQX
(C) have BDNF cRNA labeling that was not elevated
in the hippocampus or entorhinal cortex (EC). By
contrast, in cultures treated with CX614 + APV
(D), labeling was elevated in all fields. In
cultures treated with CX614 + nimodipine (E),
BDNF cRNA labeling was elevated in the strata granulosum
(sg; arrowhead) and pyramidale
(sp; black arrow) of the
hippocampus but not in the entorhinal cortex (white
arrow). Cotreatment with CX614 + CoCl2
(F) resulted in complete blockade of
ampakine-induced increases in BDNF mRNA in all fields. Scale bar, 500 µm.
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Further evidence that the ampakine-induced increase in BDNF expression
is dependent on transmission was obtained with 5 mM CoCl2, a treatment that blocks calcium fluxes and
thus glutamate release. Figure 7F shows that the effects
of CX614 are altogether absent in a
CoCl2-cotreated slice. In contrast to this broad
effect, cotreatment with the L-type voltage-sensitive calcium channel blocker nimodipine (20 µM) reduced
CX614-induced increases in BDNF mRNA in layers II and III of the
entorhinal cortex (Fig. 7E, white
arrow) but did not block effects of the ampakine in the
hippocampus proper or the dentate gyrus.
Figure 8 summarizes group results for
nimodipine and CNQX applied alone or with CX614 for 3 hr. Note that
there was no overlap in labeling densities in the dentate gyrus (Fig.
8A) and field CA3 (Fig. 8B) for
slices given CX614 alone versus those cotreated with CNQX
(p < 0.001) and that the latter group values
were not detectably different from control. Similar results were
obtained in field CA1 stratum pyramidale and superficial entorhinal
cortex (data not shown). The regionally differentiated effects of
nimodipine were confirmed by quantitative analyses; within the same
slice the channel blocker significantly attenuated the ampakine effect on BDNF expression in the entorhinal cortex but not in the stratum granulosum (Fig. 8C,D).
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Figure 8.
CNQX and nimodipine significantly attenuate
CX614-induced increases in BDNF mRNA content. Scatter graphs show BDNF
cRNA-labeling densities (µCi/gm) in the stratum granulosum (A,
C), the CA3 stratum pyramidale (B), and
the entorhinal cortex layers II and III (D)
within individual explants treated 3 hr with vehicle
(Con) or with CX614 (50 µM), CX614 (50 µM) + CNQX (20 µM), CNQX (20 µM) alone, CX614 (50 µM) + nimodipine
(Nim; 20 µM), or nimodipine (20 µM) alone. Solid symbols
indicate significant differences between experimental and control group
mean values (n  4/group for A, B;
n = 7/group for C, D).
A, B, CX614 alone increased BDNF cRNA
labeling over control values in both hippocampal fields
(p < 0.001 for both, SNK), whereas
cotreatment with CNQX markedly blocked this effect. C,
D, In measures from a separate set of slices, CX614 alone
increased BDNF cRNA labeling in the stratum (str.)
granulosum and the entorhinal cortex (p  0.0003, Mann-Whitney U test). Moreover, in explants
treated with CX614 + Nim, labeling was increased above both control and
nimodipine-alone values in both fields (CX614 + Nim vs Nim,
p = 0.0002 for the str. granulosum, Mann-Whitney
U test; p = 0.0307 for the
entorhinal cortex, Student's t test; CX614 + Nim vs
Con, p = 0.0002 for the str.
granulosum, Student's t test; p = 0.0014 for the entorhinal cortex, Student's t test).
However, cotreatment with nimodipine significantly attenuated the
effect of CX614 on BDNF expression in the entorhinal cortex
(*p < 0.0001 vs the CX614 group, Student's
t test) but not in the str. granulosum.
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Effects on NGF and trkB mRNA levels
Previous studies have demonstrated that, in addition to effects on
BDNF, seizures and/or intense glutamate receptor activation increase
the expression of NGF, specifically within the dentate gyrus
granule cells (Lauterborn et al., 1993), and of the BDNF receptor trkB
(Bengzon et al., 1993; Merlio et al., 1993). To test the generality of
ampakine effects on activity-regulated neurotrophin genes, we examined
the influence of CX614 on NGF and trkB mRNA levels in cultured
hippocampal slices. As the photomicrographs in Figure
9, A and B,
illustrate, a 6 hr incubation with CX614 at 50 µM caused a marked increase in NGF cRNA
labeling within the stratum granulosum but did not appear to affect
labeling densities or numbers of the NGF mRNA-positive interneurons.
The increase in granule cell labeling was maximal after 3 hr, the
earliest time point tested, and declined thereafter (3 vs 6 hr
incubation; p < 0.01, SNK). Labeling densities were
not different from control values in slices exposed to CX614 for 24 hr
(Fig. 9C).
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Figure 9.
CX614 increases NGF and trkB mRNA content
in vitro. Panels A,
B, Dark-field photomicrographs showing in
situ hybridization localization of NGF cRNA labeling in
cultured hippocampal slices treated with vehicle
(panel A) or with 50 µM CX614 (panel B)
for 6 hr. As shown in panel B, CX614
treatment increased NGF cRNA labeling of the stratum granulosum
(sg; arrowhead) but not of scattered NGF
cRNA-positive interneurons (arrows in
panels A, B). Scale bar, 300 µm.
Panel C, Scatter graph showing the effect
of different CX614 treatment intervals on NGF cRNA labeling in the
stratum (str.) granulosum. As shown, labeling was
significantly increased above control (C) values
in slices treated with 50 µM CX614 for 3 and 6 hr but not
for 24 hr (p < 0.0001, ANOVA;
solid symbols indicate significant
differences between experimental and control group mean values,
p < 0.01, SNK; the number of explants per group is
given in parentheses). Control values represent combined
measures from 3 and 24 hr DMSO-treated explants; there was no
difference in mean densities between the two groups.
Panel D, Bar graph showing the effect of
different CX614 treatment intervals on trkB cRNA labeling in the
stratum granulosum (SG), the CA3 stratum pyramidale, and
the CA1
stratum pyramidale (group mean values ± SEM;
C, values from 24 hr DMSO controls;
n = 6 per group). CX614 significantly increased
trkB mRNA levels in all fields (p < 0.008, Kruskal-Wallis nonparametric ANOVA). In the stratum granulosum,
labeling was elevated at both 6 and 24 hr (p = 0.0011 and 0.03, respectively; Mann-Whitney U test).
Labeling was increased in stratum pyramidale cells at 6 hr, but the
data only reached significance for region CA1
(p = 0.013, Mann-Whitney U
test). ns, Not significant.
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Treatment with CX614 at 50 µM had smaller effects on mRNA
levels for trkB than for the two neurotrophins (Fig. 9D).
Three hour incubations had no detectable influence on trkB cRNA
labeling within the strata granulosum or pyramidale. Treatment for 6 hr yielded modest but significant increases in labeling within the stratum
granulosum (172% elevation; p = 0.0001 for comparison with control values) and CA1 stratum pyramidale (51% elevation; p < 0.02) with no reliable change in region CA3. After
24 hr, labeling was still elevated in the stratum granulosum but had returned to control values in the pyramidal cell layer.
Ampakine effects on hippocampal slice electrical activity
Previous studies have demonstrated that the ampakines positively
modulate AMPA receptor function without direct agonist activity (Arai
et al., 1994). In particular, they enhance monosynaptic potentials,
cause much larger increases in polysynaptic responses (Arai et al.,
1994, 1996; Sirvio et al., 1996), and facilitate the induction of
long-term potentiation (Staubli et al., 1994b). However, the
influence of the ampakine CX614 on evoked and spontaneous activity in
cultured hippocampal slices has not been well characterized. To address
this, extracellular recordings were collected to identify synaptic
events associated with the changes in gene expression reported here.
Bouts of synchronized activity and spontaneous field potentials in the
absence of stimulation were uncommon in untreated hippocampal explants
(Fig. 10A,D).
Stimulation (1-3 µA; 0.1 msec) of Schaffer-commissural fibers in the
CA1 stratum radiatum evoked synaptic responses with a slightly
different time course than that typically obtained in acute hippocampal
slices; i.e., responses had onset latencies of ~4 msec (vs 2 msec in
acute slices) and durations of 40-50 msec (vs 15-20 msec) (Fig.
10C). Activation of Schaffer-commissural fibers in untreated
slices often triggered repetitive synaptic activity (five to eight
events at 5-10 Hz), presumably originating from CA3 recurrent
circuitry (Granger et al., 1996). As shown in Figure 10C,
this repetitive synaptic activity was characterized by a single or
complex population spike followed by a series of EPSPs (only the
initial 200 msec segment is shown).
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Figure 10.
Effects of acute and chronic application of CX614
on electrical activity within hippocampal explants.
A-D, Acute treatment. A, Representative
field recordings from the CA1 stratum radiatum of a single slice. Each
block shows 199 recordings of 1 sec duration collected over a 400 sec
period. The three blocks were recorded consecutively during an initial
30 min period of monitoring predrug baseline activity
(left), 10 min after adding 10 µM CX614
into the recording chamber (middle), and 10 min after
increasing the drug concentration to 50 µM
(right). As shown, there was a modest increase in the
incidence of spontaneous potentials with the 10 µM dose.
At 50 µM there was a striking increase in spontaneous
potentials that appeared in clusters of 4-7 sec duration. Prolonged
recording in the absence of CX614 did not lead to an increase in
activity (data not shown). B, A spontaneous event taken
from A (50 µM CX614) shown at a faster
sweep speed. The arrowhead indicates the population
spike. C, Representative traces from
another experiment. Evoked synaptic responses within the CA1 were
recorded in the presence of 50 µM CX614 (top
trace). The bottom trace shows a spontaneous
event recorded from the same explant before drug infusion.
Lowercase letters indicate the time point
of the stimulation artifact (a) and the onset of
the synaptic potential (b). D, Bar
graph showing a summary of the data for recordings from the CA1
(black bars) and the dentate gyrus granule cell layer
(DG; white bars) with the measure of
activity being the percentage of total trials that exhibited
spontaneous synaptic events. Values plotted are percentage means ± SEM from recordings of predrug (n = 5; 5 experiments for CA1; n = 3; 3 experiments
for DG), 10 µM-treated
(n = 3; 3 experiments), 20 µM-treated
(n = 3; 3 experiments for CA1;
n = 3; 3 experiments for DG), and 50 µM-treated (n = 9; 3 experiments)
hippocampal slices (*p = 0.0357;
**p = 0.001 vs predrug group, Mann-Whitney
U test; for CA1, there was no significant difference in
spontaneous activity between the 20 µM- and 50 µM-treated slices, p > 0.05, SNK).
E, F, Chronic treatment. E,
Representative recordings from three cultured slices exposed to 50 µM CX614 for 10 min, 24 hr, and 48 hr. Field recordings
were made in the presence of the drug. F, Bar graph
showing the summarized activity levels for the CA1 and the
DG in slices treated for 24 hr
(n = 13; 4 experiments for CA1;
n = 7; 3 experiments for DG) and 48 hr (n = 7; 3 experiments) with 50 µM
CX614. For the sake of comparison, the data for CA1 baseline activity
(indicated as 0) and the 10 min exposure to CX614 (50 µM)
from D are included here. For DG, only
predrug activity (indicated as 0; n = 10) and
spontaneous activity after the 24 hr drug exposure are presented.
Values plotted are percentage means ± SEM (*p = 0.0043 vs control; **p = 0.001 vs control for
CA1; **p = 0.0001 vs control for DG,
Mann-Whitney U test).
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Figure 10 illustrates the effects of CX614 on spontaneous synaptic
activity in the CA1 stratum radiatum and stratum granulosum in
vitro. As shown in Figure 10A, at 10 µM, a concentration near the threshold for
modifying field EPSPs in acute slices (Arai and Lynch,
unpublished observations), CX614 caused a small but detectable increase
in the activity level within CA1 of all slices tested, but the
magnitude of this effect was highly variable (1 sec recording epochs
with spontaneous synaptic events ranged from 4 to 39%; average,
16 ± 11 vs 1.5 ± 0.5% before drug application; p = 0.0357, Mann-Whitney U test, two-tail;
n = 3). At 20 µM, a dose that
increased BDNF mRNA in the granule cells but not the CA1, acute
application of CX614 resulted in a large and consistent increase in
activity within both fields. Spontaneous synaptic events in the granule
cells occurred in 70 ± 0.5% of the trials with CX614 as compared
with 13.8 ± 2.5% before drug (p < 0.0001, two-tail Student's t test; n = 3).
There was a corresponding increase in spontaneous activity within field
CA1 (Fig. 10D; average, 75 ± 5.7%;
p = 0.0357 vs control, Mann-Whitney U test,
two-tail; n = 3). With CX614 applied at 50 µM, a dramatic increase in spontaneous activity
was reliably seen in all slices (Fig. 10A,D;
n = 9 slices; 3 experiments). The field EPSPs in the
CA1 occurred in trains usually lasting for 4-7 sec and at a frequency
of 5-10 Hz. Examples of the repetitive potentials are shown at a
faster sweep speed in Figure 10, B and C.
Notably, the time course of the spontaneous activity was similar to
that of evoked responses. Although high- and low-activity phases
alternated approximately every 10-20 sec, they did not have the high
voltage, sharp spikes, or postevent refractoriness of evoked field
EPSPs that are associated with epileptiform discharges.
Recordings were also collected from cultured slices treated
continuously for 24 or 48 hr with 50 µM CX614. Activity
in CA1 after 24 hr (Fig. 10E) was nearly the same as
after 10 min infusions with 57 ± 5.4% of the trials showing
spontaneous synaptic events (Fig. 10F;
n = 13 slices; 4 experiments). As shown in Figure
10F, spontaneous activity also was elevated in the
granule cells after 24 hr treatments (average, 50 ± 7.8 vs 9 ± 1.9% before CX614; n = 8; p < 0.0001, Mann-Whitney U test, two-tail). The frequency of
spontaneous activity (25.9 ± 3.8%) in CA1 decreased by
approximately one-half between 24 and 48 hr (Fig. 10F;
p = 0.002, 48 vs 24 hr, U test); recordings were
not made for the granule cells at this time point. In all cases, short
episodes of repetitive field EPSPs punctuated by complex spikes were
frequent and unaccompanied by evident disturbances in the size or shape
of monosynaptic responses elicited by single-pulse stimulation of the
Schaffer-commissural fibers. Accordingly, the above described
reductions in ampakine-induced BDNF expression occurring after 12 hr
incubations with 50 µM CX614 cannot be ascribed
to drug desensitization or a gradually developing depression of
neuronal activity.
Neurocytology
Chronic effects of the ampakine were also evaluated using
conventional histological procedures. Sections from slices treated with
CX614 (50 µM) for 24 hr were Nissl-stained and evaluated with regard to neuronal morphology and numbers of pyknotic cell bodies.
Darkly stained cells were commonplace in the extreme lower portion of
the explants (adjacent to the interface with the supporting membrane).
These seemingly pyknotic bodies were present in all laminae within
deeper levels of both vehicle-control and ampakine-treated slices.
However, as shown in Figure 11, they
were primarily absent in sections taken from central and superficial
levels. Neuronal somata in vehicle-control and drug-treated slices
appeared to be of similar size, number, and distribution with little
evidence of pyknotic cells in the principal cell layers. These
qualitative data suggest that a 24 hr treatment with CX614 at 50 µM does not induce overt neuropathology.
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Figure 11.
Treatment with CX614 does not induce overt cell
death. Light-field photomicrographs showing Nissl-stained tissue
sections from a vehicle-treated control culture
(A) and a culture treated with 50 µM CX614 (B) for 24 hr. As shown in
B, after a 24 hr exposure to CX614 the granule
(sg) and pyramidal (sp) cell layers
appear normal with neuronal morphology and distribution comparable with
that in control tissue. h, Hilus. Scale bar, 300 µm.
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In vivo studies
Although BDNF mRNA levels are reduced in the hippocampus with
Alzheimer's disease (Phillips et al., 1991; Murray et al., 1994), decreases in BDNF gene expression have not been observed with aging in
the rat (Lapchak et al., 1993; Narisawa-Saito and Nawa, 1996; Croll et
al., 1998; Sugaya et al., 1998). Nevertheless, protective effects of
BDNF in vitro (Alderson et al., 1990; Spina et al., 1992;
Kokaia et al., 1994) and in vivo (Ferrer et al., 1998; Hagg,
1998) suggest that increases in BDNF gene expression and/or local
availability may have therapeutic value for counteracting degenerative
processes associated with age and age-related disease in brain. With an
interest in this possibility, effects of AMPA receptor modulators on
BDNF mRNA expression in vivo were tested in aged (18- to
21-month-old) rats and middle-aged (9- to 11-month-old) mice using
CX546. The ampakine CX546 was chosen for in vivo studies because, unlike CX614, effective in vivo doses have been
identified in behavioral studies (Hess et al., 1999). Figure
12A illustrates the
quantitative results obtained in rats with five daily intraperitoneal injections of CX546 and 24 hr survival after the last injection. As
shown, BDNF cRNA labeling was markedly increased in the granule cells
with this ampakine treatment regimen. Labeling was 49% greater in the
stratum granulosum of ampakine-treated aged rats as compared with
controls (p < 0.03; because there were no
meaningful differences between CDX and saline controls, their values
were combined in the control group). There were no group differences in
hybridization densities within the pyramidal cell
fields.
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Figure 12.
Systemic treatment with the ampakine CX546
increases BDNF mRNA content in rat and mouse hippocampus in
vivo. A, B, Bar graphs show the densitometric
quantification of BDNF cRNA labeling in hippocampal stratum granulosum
(SG), CA3 stratum pyramidale, and CA1 stratum pyramidale
of control (dark bars) and CX546-treated
(light bars) aged rats
(A) and middle-aged mice
(B). A, Data from one naive and
three vehicle-control rats were combined for analysis, and aged rats
were treated for 5 d with CX546 (30 mg/kg, i.p., once a day;
n = 6) and killed 24 hr after the last injection.
Error bars represent group mean values (± SD) for the
SG and stratum pyramidale of fields CA3 and CA1. As
shown, in vivo treatment with CX546 resulted in
increased cRNA labeling in the granule cells as compared with control
values (p < 0.03, Student's
t test). No change was seen in the pyramidal cells.
B, The bar graph shows BDNF cRNA hybridization levels in
sections from control (naive and cyclodextrin vehicle;
n = 6 total) middle-aged mice and middle-aged mice
treated with CX546 (40 mg/kg, i.p.; n = 3) and
killed 24 hr after injection. Error bars show group means (± SEM).
Treatment with CX546 resulted in significantly elevated levels of BDNF
cRNA labeling in the stratum granulosum (p = 0.036, Student's t test) and CA3 stratum pyramidale
(p = 0.0025, Student's t
test) as compared with controls. As seen for the aged rat, there was no
difference in hybridization within CA1 in the middle-aged mice.
C, D, Dark-field photomicrographs show examples of BDNF
cRNA hybridization in sections through the hippocampus from a control
(naive) middle-aged mouse (C) and a middle-aged
mouse killed 24 hr after a single injection of CX546 (40 mg/kg, i.p.;
D). As shown in D, CX546 resulted in
elevated BDNF cRNA labeling within the stratum granulosum
(sg) and the CA3 stratum pyramidale (sp)
that is restricted to the cell layers with no obvious change in
hybridization within CA1. Scale bar, 200 µm.
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To determine whether the ampakine effects on BDNF expression can be
generalized to other mammalian species, we tested for the influence of
CX546 in middle-aged (9- to 11-month-old) mice. As shown in the
photomicrographs of Figure 12, C and D, after a single injection of CX546 and 24 hr survival, BDNF cRNA labeling was
clearly increased in the granule cells and CA3 pyramidal cells relative
to densities in the same regions in yoked vehicle controls. In
contrast, labeling in field CA1 was not obviously different between the
two animals (Fig. 12C). Quantitative analyses confirmed these impressions (Fig. 12B). Labeling was 76% more
dense in the stratum granulosum of ampakine-treated as compared with
control mice (p < 0.04). Measures from the
stratum pyramidale demonstrated a 51% increase in CA3
(p < 0.003) but no effect in CA1 after ampakine treatment.
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DISCUSSION |
The present results demonstrate that positive modulation of AMPA
receptor function causes rapid and substantial increases in
neurotrophin expression in the hippocampus and allied cortex. Like
effects of elevated neuronal activity in vivo (Gall, 1992), in ampakine-treated explants BDNF mRNA levels were increased throughout granule and pyramidal cell layers, NGF mRNA was increased within the
stratum granulosum alone, and trkB mRNA levels were more modestly affected. Ampakine concentrations that were suprathreshold for enhancing synaptic responses increased BDNF mRNA by 5- to 10-fold within 3 hr, and this effect was reversed with drug washout.
Drug-induced activity patterns in the CA1 consisted of 5-10 sec
episodes of spontaneous field EPSPs with individual potentials
separated by 100-200 msec. The periods of activity were numerous and
sometimes accompanied by synchronized cell discharges (population
spikes). The relatively brief duration of the episodes, the short
intervals between them, and their lack of effect on evoked field EPSPs
distinguish these events from classic epileptiform discharges. It is of
interest that the frequency of potentials within an episode
approximated that found within the theta rhythm (Vanderwolf, 1969;
Vertes, 1986). Repetitive, endogenously generated activity with known relationships to complex behaviors thus appears to be sufficient to
trigger reasonably rapid and pronounced changes in neurotrophin expression. This AMPA receptor-mediated effect is clearly independent of recently described BDNF induction via AMPA receptor-linked tyrosine
kinase signaling that requires high-ligand concentrations and occurs in
the absence of transmembrane calcium and sodium currents (Hayashi et
al., 1999).
The dose dependency for ampakine effects on expression paralleled that
for physiology. Three hour treatments with CX614 at near-threshold
concentrations for enhancing monosynaptic responses increased BDNF mRNA
levels in the dentate gyrus but were without effect in field CA1.
Physiological recordings from the dentate gyrus and CA1 showed that
spontaneous synaptic events in both regions were significantly enhanced
at near-threshold concentrations. The close correspondence between dose
dependencies for induction and synaptic facilitation, as well as the
greater responsivity of the dentate gyrus for BDNF expression, was
confirmed with a second ampakine. Why neurotrophin expression should be
more responsive in the granule cells than in the pyramidal neurons is
not apparent. The two classes of cells are distinct with regard to the
genes they express and the responsivity of gene expression to
peripheral stimuli (Gall et al., 1991a,b; Hess et al., 1995; Lauterborn
et al., 1995; Link et al., 1995). Firing rate is also notably different for pyramidal and granule neurons, with pyramidal cells typically firing in triplet bursts and granule cells occasionally firing in
extended high-frequency trains (Deadwyler et al., 1975; Rose et al.,
1983). Recent studies have demonstrated that temporal features of
neuronal firing determine the degree to which activity regulates
intracellular-signaling pathways and neuronal gene expression in
primary sensory neurons (Fields et al., 1997; Itoh et al., 1997).
Similar temporal specificities may account for regional differences in
the magnitude of activity-induced changes in gene expression within the hippocampus.
Although threshold ampakine concentrations did not produce sizeable
changes in pyramidal cell BDNF expression, they generated impressive
effects when applied for 24-72 hr. The fact that time can be
substituted for concentration is important with regard to the possible
use of ampakines for increasing neurotrophin levels in vivo.
The results obtained with prolonged treatment with low dosages also
provide clues about which aspects of physiological activity stimulate
neurotrophin genes. Threshold concentrations of CX614 increased
(1) the frequency of endogenous field EPSPs and complex spikes
as well as (2) the likelihood that these events would occur in
clusters. Both effects were relatively subtle (drug-induced changes
became apparent only after several minutes of recording) and indeed
constitute the minimal physiological conditions described to date for
upregulating neuronal gene expression. Although the amount of activity
over extended periods can reasonably be assumed to influence
expression, burst activity might more effectively link excitatory drive
with regulatory cascades. Long-term potentiation studies have shown
that two short bursts of afferent stimulation trigger postsynaptic
enzymes (Vanderklish et al., 1995) when applied in a pattern similar to
that initiated by ampakines in the present study. It remains to be
tested whether increasing synchronized activity (as opposed to overall
activity level) with manipulations other than ampakines will affect
hippocampal neurotrophin expression.
Blocking the release of transmitter or its binding to AMPA-type
glutamate receptors suppressed the effects of ampakines throughout the
hippocampus and retrohippocampal cortex. This is as expected for a
positive modulator of AMPA receptors. Increases in the strength of
excitatory input presumably affect gene expression by potentiating dendritic depolarization and/or cell spiking. Both processes promote the opening of voltage-sensitive calcium channels (VSCCs) and NMDA
receptors, events shown to stimulate BDNF gene expression in embryonic
cortical neurons, with VSCCs having the larger effect (Ghosh et al.,
1994). BDNF induction by ampakines was unaffected by an NMDA receptor
antagonist, leaving the VSCCs as likely mediators. This was confirmed
for the entorhinal cortex with the L-type calcium channel blocker
nimodipine. The absence of nimodipine effects on induction in the
hippocampus indicates regional specificity in mechanisms via which
activity regulates BDNF expression. This was suggested previously by
the finding that the calcium/calmodulin-dependent protein kinase (CamK)
II/IV inhibitor KN-62 attenuates BDNF induction by seizure in
the neocortex but not in the dentate gyrus (Murray et al., 1998).
Regional differences could arise at levels of calcium influx (e.g.,
nimodipine-sensitive vs -insensitive VSCCs), intracellular signaling,
and/or BDNF promoter use. There are four major BDNF transcript forms;
each contains a distinct promoter-associated 5' exon (I-IV) and a
common 3' exon (V) that encodes BDNF protein (Timmusk et al., 1993).
The BDNF cRNA used here recognizes BDNF exon V and, therefore, all
transcripts. Within cultured cortical neurons KCl depolarization
specifically induces BDNF exon III-containing mRNA via L-type VSCCs and
CamK IV/CRE-binding protein-dependent signaling (Ghosh et al., 1994;
Shieh et al., 1998; Tao et al., 1998). This specific mechanism, which
would be blocked by nimodipine as well as by KN-62, is likely to
account for ampakine effects on BDNF mRNA in entorhinal cortex. By
contrast, basal and activity-induced expression of transcripts
containing exons I and II is reportedly negatively regulated via a
neuron-restrictive silencer element in promoter II (Timmusk et
al., 1999). Major goals of future research will be to determine the
regional transcript profiles and signaling pathways that differentiate
ampakine-induced BDNF expression in the hippocampus and cortex.
Although BDNF mRNA levels initially increased over the time of ampakine
exposure, suprathreshold doses set in motion an effect that gradually
offset drug-induced upregulation. The ampakines did not lose potency
when incubated with cultured slices, as demonstrated with media
transfer experiments, and continued to exert electrophysiological effects, whereas BDNF mRNA content returned toward control levels. Recent in vivo studies indicate that NGF becomes refractory
to induction after transient upregulation (C. M. Gall and J. C. Lauterborn, unpublished observations); reduced BDNF mRNA levels with
continued ampakine exposure may represent a similar effect. BDNF
protein levels did not decrease when drug incubations were extended
beyond 12 hr. This raises the possibility that reduced gene expression with longer treatments may be caused by end-product inhibition; i.e.,
elevated levels of neurotrophin protein (or another gene product
upregulated by ampakine exposure) may depress gene expression and/or
block activating cascades. Refractoriness to chronic ampakine exposure
is likely to be a general phenomenon because induced NGF expression
reversed even more rapidly than did induced BDNF expression. In this
case, the fall off occurs in a sufficiently brief period that protein
synthesis inhibitors might be used to test the idea of end-product
inhibition. Whatever its mechanism, refractoriness will be a
consideration when devising pharmacological regimens for manipulating
neurotrophin expression and signaling.
The possibility of using ampakines to increase neurotrophin expression
in aged and middle-aged animals was tested using peripheral injections
of CX546 and a 24 hr delay. Doses were selected that generate a
characteristic ampakine effect on behavior, namely, suppression of
methamphetamine-induced hyperactivity (Hess et al., 1999). Five daily
injections in aged rats resulted in a marked increase in BDNF mRNA
levels in the dentate gyrus granule cells. Similarly, a single
treatment in middle-aged mice increased BDNF mRNA content in the
dentate gyrus and field CA3. For both species there was no change in
BDNF expression within field CA1. Because CA1 also was less responsive
in slices, these results suggest that the in vivo results
involve the same processes initiated by ampakines in vitro.
Optimal treatment regimens and effects on BDNF protein are not known,
but the present results strongly suggest that systemic treatment with
doses that do not perturb behavior can be used to upregulate at least
one aspect of neurotrophism in the middle-aged and aged brain.
Important goals for future research will be to determine whether
systemic ampakine treatment can sustain elevated brain neurotrophin
levels and to test the general idea that increasing endogenous
neurotrophin expression can be used to offset impairments in brain
functioning that arise with age.
| |
FOOTNOTES |
Received Aug. 4, 1999; revised Oct. 4, 1999; accepted Oct. 8, 1999.
This work was supported by Cortex Pharmaceuticals Grant CP22357 and the
National Institute of Neurological Disorders and Stroke Grant NS26748
to C.M.G. We wish to thank Yilu Xie and Fiesal Yamani for valuable
technical assistance and Dr. David McKinnon (State University of New
York, Stony Brook, NY) for generously providing the cDNA for trkB.
Correspondence should be addressed to Dr. Julie C. Lauterborn,
Gillespie Neuroscience Research Facility, Room 3226, University of
California, Irvine, CA 92697-4292. E-mail address: jclauter{at}uci.edu.
| |
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D. A. Simmons, C. S. Rex, L. Palmer, V. Pandyarajan, V. Fedulov, C. M. Gall, and G. Lynch
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TOP
ABSTRACT
INTRODUCTION
