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The Journal of Neuroscience, April 15, 2003, 23(8):3547
Cognitive Strategy-Specific Increases in Phosphorylated cAMP
Response Element-Binding Protein and c-Fos in the Hippocampus and
Dorsal Striatum
Paul J.
Colombo1, 2,
Jennifer J.
Brightwell1, and
Renee A.
Countryman2
1 Neuroscience Program and 2 Department of
Psychology, Tulane University, New Orleans, Louisiana 70118
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ABSTRACT |
Extensive research has shown that the hippocampus and striatum have
dissociable roles in memory and are necessary for "place" and
"response" learning, respectively. In the present study, rats were
trained on a cross maze task that could be solved by either a place or
a response strategy, and the strategy used was determined by a probe
trial. Phosphorylated cAMP response element-binding protein (pCREB) and
c-Fos immunoreactivity (IR) were measured in the hippocampus and
striatum either immediately or 1 hr after cross maze training.
Immediately after training, pCREB-IR and c-Fos-IR were significantly
higher in the hippocampus and striatum of trained rats than in control
rats matched for motor activity, but the increase was independent of
the strategy revealed at probe. One hour after training, however,
pCREB-IR and c-Fos-IR were sustained in the hippocampal pyramidal and
granule cell layers of place learners but returned to basal levels
among response learners. In addition, pCREB-IR was sustained in the
dorsomedial and dorsolateral striatum of response learners but returned
to basal levels among place learners. There were no differences between
place and response learners in c-Fos-IR in the striatum at either time
point. The present results indicate that cross maze training causes an
initial activation of transcription factors in both the hippocampus and striatum. Formation of memory for a place strategy, however, is related
to sustained phosphorylation of CREB and expression of c-Fos for at
least 1 hr in the hippocampus, whereas formation of memory for a
response strategy is related to phosphorylation of CREB in the striatum.
Key words:
cAMP response element-binding protein; CREB; c-Fos; place learning; response learning; hippocampus; dorsal neostriatum; cross maze
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Introduction |
Distinct memory functions are
attributed to the hippocampal formation and the neostriatum in humans
(Knowlton et al., 1996 ; Maguire et al., 1998; Casey et al., 2002),
nonhuman primates (Teng et al., 2000; Fernandez-Ruiz et al., 2001), and
rats (Kesner and Beers, 1988; Kesner et al., 1993; McDonald and White,
1993; Packard et al., 1994; Compton, 2001). Lesions or pharmacological
manipulations that alter the function of the hippocampal formation or
the neostriatum provide the primary evidence that these two brain
systems are specialized for different types of memory. In rats, damage
to the hippocampal formation selectively impairs formation of memory for the relationships among stimuli (Eichenbaum et al., 1990; Eichenbaum, 2001), whereas damage to the neostriatum tends to impair
acquisition of associations between stimuli and motor responses (Colombo et al., 1989; Packard and White, 1990; Packard and McGaugh, 1992; McDonald and White, 1994; Golf Racht-Delatour and El Massioui, 1999). Specialized mnemonic functions attributed to the hippocampus and
striatum, respectively, include memory for spatial and nonspatial information (Packard and McGaugh, 1992, 1996), memory for allocentric (place) and egocentric (response) information (Kesner and Beers, 1988;
Packard, 1999), and declarative and procedural memory (DeCoteau and
Kesner, 2000). Although there is compelling evidence that the
contributions of the hippocampus and striatum to memory formation can
be dissociated, the relationship between the systems during normal
operations is not understood. One recent report suggests that the two
systems may operate in temporal sequence (Packard, 1999).
Members of the cAMP response element-binding protein (CREB) family of
transcription factors have been implicated in the formation of
long-term memory (Lamprecht and Dudai, 1996; Lamprecht et al., 1997).
Suppression of CREB protein by administration of antisense oligodeoxynucleotides (Guzowski and McGaugh, 1997) or genetic knock-out
(Bourtchuladze et al., 1994) impairs spatial memory, whereas
overexpression of CREB can enhance the formation of long-term memory
(Josselyn et al., 2001). CREB phosphorylation is increased by exposure
to a novel environment (Vianna et al., 2000), contextual fear
conditioning (Stanciu et al., 2001), inhibitory avoidance (Bernabeu et
al., 1997; Cammarota et al., 2000; Taubenfeld et al., 2001), and radial
arm maze training (Mizuno et al., 2002). Stimuli that increase cAMP or
Ca2+-dependent protein kinase activity
phosphorylate CREB (Gonzalez and Montminy, 1989; Dash et al., 1991),
and phosphorylated CREB (pCREB) stimulates the expression of
immediate-early genes, including the transcription factor c-Fos (Sheng
and Greenberg, 1990). Learning-induced expression of c-Fos is
implicated in visual recognition memory (Wan et al., 1999), fear
conditioning (Milanovic et al., 1998; Radulovic et al., 1998), spatial
working (Vann et al., 2000) and reference memory (Qiang et al., 1999),
brightness discrimination (Tischmeyer et al., 1990), and avoidance
learning (Qiang et al., 1999; Cammarota et al., 2000).
In the present study, rats were trained on a cross maze task that could
be solved by either a hippocampus-dependent place strategy or a dorsal
striatum-dependent response strategy, and the strategy used was
determined during a probe trial. Levels of pCREB and c-Fos
immunoreactivity (IR) were measured in the hippocampus and striatum
either immediately or 1 hr after cross maze training.
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Materials and Methods |
Eighty-two naive male Long-Evans hooded rats (weight, 250-275
gm) were housed individually in a temperature-controlled environment with a 12 hr light/dark cycle (lights on at 7:00 A.M.) and
ad libitum access to food and water. All behavioral testing
was conducted during the light phase of the cycle.
The behavioral apparatus was an eight arm radial maze (Lafayette
Instruments, Lafayette, IN) with black metal floors and clear Plexiglas walls. The arms of the cross maze (10 cm wide × 70 cm long × 20 cm high) had recessed food wells at the end and were separated from an octagonal center compartment (33 cm). The maze was located in a testing room that contained several extramaze cues and
was sanitized between rats and before all probe trials to inhibit
intramaze olfactory cues.
Animals were handled extensively (5 min each per day) for 2 weeks from
the time of arrival to the first day of habituation. One week before
maze testing, animals were reduced to 85% of their free-feeding
weights over 7 d and maintained at this weight throughout the
experiment. One day before habituation, animals received 4 gm of Froot
Loops cereal (Kellogg, Battle Creek, MI) in addition to sufficient chow
to maintain the 85% target weight and reduce neophobic reactions to
the Froot Loops during training trials.
Animals were habituated for 3 d with one 5 min trial per day. On
day 1, the rats were placed into the south arm of the maze with two
additional arms open at right angles (west and east) and with
Froot Loops broken into thirds and scattered throughout all three arms. On day 2, the Froot Loops were placed only in the east
and west arms of the maze, and on day 3, the Froot Loops were placed
only in the recessed food wells at the ends of the east and west arms.
Training and testing were completed on the fourth day. Rats were
released from the end of the south arm and allowed to enter one arm
(neither of which was baited), and the arm opposite the one chosen was
baited for all subsequent trials. On training trials, rats were allowed
2 min to obtain the food reward of one-third of a Froot Loop. Entries
into the unbaited arm of the maze were scored as incorrect responses,
and entries into the baited arm of the maze were scored as correct
responses. An entry was defined as all four feet crossing into an arm,
and rats were allowed to enter one arm only per trial, after which they
were placed back into their holding cage for a 30 sec intertrial interval. All rats were trained to a criterion of 9 of 10 correct choices (range, 11-44 trials), after which they were released from the
arm opposite the original start location (north) for a single probe
trial. Rats that reentered the arm rewarded during training were
categorized as place learners, whereas rats that made the same turning
response as that rewarded during training and thus entered the arm
opposite the one rewarded during training were categorized as response
learners. Previous research (Restle, 1957; Packard, 1999) and pilot
studies conducted in this laboratory (data not shown) indicate that
factors such as the amount of training, salience of extramaze cues, and
amount of illumination influence the numbers of rats characterized as
place and response learners based on performance during the probe
trial. In the present study, probe trials revealed that approximately
one-half of the trained rats used a place strategy (n = 27) and one-half used a response strategy (n = 23).
Rats in control conditions were matched to the numbers and durations of
trials of both place (n = 16) and response
(n = 16) learners. This group was included to test
whether differences in pCREB or c-Fos between place and response
learners were attributable to differences in cognitive factors
or to differences in locomotor or other performance factors. Control
rats were released from the south arm on all trials and could access
the north arm only, whereas experimental rats were released from the
south arm on all trials except the probe trial. Thus, control rats were matched to experimental rats in all aspects of the task except that
they had only one arm available for food reward, whereas experimental
rats had to choose between two.
Either immediately or 1 hr after the probe trial, animals were injected
with a ketamine-xylazine solution (1.65 mg/kg) and perfused
transcardially with ice-cold 0.1 M PBS, pH 7.4, and
NaNO3 followed by ice-cold 4% paraformaldehyde
in 0.1 M PBS. Brains were removed and postfixed in 4%
paraformaldehyde for 3 hr and then transferred to a 20% sucrose and
0.1 M phosphate buffer cryoprotectant overnight at 4°C.
Forty micrometer coronal sections were taken beginning at the posterior
end of the anterior olfactory nucleus and extending throughout the
hippocampus. Sections were collected in cryopreservative and frozen at
 70°C. For each subject, four sections were selected at
approximately bregma 0.2 mm for striatum and four sections at bregma
3.8 mm for the hippocampus (Fig. 1) and
immunostained as described below. Net wells (24 mm;
Corning, Corning, NY) were used to wash tissue
sections several times in 0.05 M PBS and then once in 1%
normal goat serum (NGS), 0.02% Triton X-100 (TX), and 1%
H2O2 in PBS for 10 min to
inhibit endogenous peroxidase. Sections were blocked for 15 min in a
2% NGS and 0.4% TX solution in PBS followed by incubation in 1% NGS
and 0.4% TX in PBS containing either c-Fos rabbit polyclonal antibody
(1:10,000; Santa Cruz Biotechnology, Santa Cruz, CA) or
pCREB rabbit polyclonal antibody (1:1000; Upstate
Biotechnology, Lake Placid, NY) for 48 hr at 4°C. Sections
were washed four times with 0.05 M PBS for 15 min each
before a 1 hr incubation in biotinylated goat anti-rabbit secondary
antibody (1:400 in 1% NGS and 0.2% TX PBS; Santa Cruz Biotechnology).
Sections were washed in 0.05 M PBS three times for 5 min
each and then processed with avidin-biotinylated horseradish peroxidase
complex in PBS (Elite Kit; Vector Laboratories, Burlingame, CA) for 45 min at room temperature. Sections were washed
four times for 15 min each in PBS, and the reaction was visualized with
diaminobenzidine (DAB substrate kit; Vector Laboratories). The reaction was stopped by washing three times for 10 min each in cold
0.01 M PBS. Sections were mounted on slides, allowed to dry
overnight, and plated under coverslips. Nuclear immunoreactivity was
quantified by the two focal plane method of Brown et al. (1998). Sampling templates of consistent area were established, and
immunoreactive cells were counted in CA1, CA3, and the dentate gyrus of
the dorsal hippocampus, as well as the dorsomedial and dorsolateral
striatum (Fig. 1).
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Figure 1.
A, Immunoreactive cells were
counted within sampled areas of the dorsal hippocampus. These included
the pyramidal cell layers CA1 and CA3 (medium circles) and the granule
cell layers of the dentate gyrus (small circles). B,
Sampled areas of the dorsomedial and dorsolateral striatum (large
circles).
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Figure 2.
Latency to complete the last 10 criterion trials
for place learners (n = 27) and response learners
(n = 23).
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Results |
ANOVA revealed no difference in the number of trials to criterion
between place and response learners
(F(1,48) = 0.01; p = 0.92). The mean number of trials to criterion was 18.9 ± 1.1 SEM for place learners and 18.7 ± 1.7 SEM for response learners. In contrast, the total time in the maze and the average trial duration over the last 10 criterion trials were greater among place learners than among response learners
(F(1,48) = 6.86, p = 0.01 and F(1,48) = 7.83, p = 0.007, respectively) (Fig. 2).
Relationships between learning and levels of pCREB-IR and c-Fos-IR were
analyzed independently for the hippocampus and striatum. Multivariate
ANOVAs (MANOVAs) were conducted with levels of pCREB-IR and c-Fos-IR in
CA1, CA3, and the dentate gyrus of the hippocampus and dorsomedial and
dorsolateral striatum as dependent variables. Independent variables
were training condition (trained or control), type of strategy revealed
at probe test (place or response), and interval between test and
killing of the animal (immediate or 1 hr).
Overall MANOVA of pCREB in the hippocampus revealed significant main
effects for training condition
(F(3,71) = 20.4; p < 0.001), test-to-killing interval
(F(3,71) = 2.96; p = 0.04), and a training condition by test-to-killing interval interaction
(F(3,71) = 3.92; p = 0.01) (Figs. 3A,B, 4). Overall
ANOVA of pCREB in the striatum revealed significant main effects
for training condition (F(2,71) = 37.6; p < 0.001), test-to-killing interval
(F(2,71) = 60.2; p < 0.001), and a training condition by test-to-killing interval interaction (F(2,71) = 28.7;
p < 0.001) (Figs. 3C,D,
5). Thus, trained rats had significantly
more hippocampal and striatal pCREB-IR than motor controls immediately
after training, and that effect was independent of whether rats showed
place or response strategies. One hour after training, however, levels
of pCREB remained significantly greater in the hippocampus of place
learners than in that of motor controls
(F(1,20) = 13.6; p = 0.001), whereas there was no difference between levels of pCREB in the
hippocampus of response learners compared with motor controls
(F(1,18) = 0.35; p = 0.56) (Fig. 3B). Of particular importance, place learners
had higher levels of hippocampal pCREB than response learners 1 hr
after training. These differences were found throughout the principal
cell layers of the hippocampus and included the dentate gyrus
(F(1,24) = 7.8; p = 0.01), CA1 (F(1,24) = 17.9;
p < 0.001), and CA3
(F(1,24) = 18.4; p < 0.001). The converse pattern was found in the striatum 1 hr after
training. That is, levels of pCREB remained significantly greater in
the striatum of response learners than in that of motor controls
(F(1,18) = 4.8; p = 0.04), but there was no difference between levels of pCREB in the
striatum of place learners and that of motor controls
(F(1,20) = 0.78; p = 0.39) (Fig. 3D). Response learners had significantly greater
levels of pCREB than place learners in the dorsolateral striatum
immediately (F(1,21) = 6.1; p = 0.02) and 1 hr after training
(F(1,24) = 4.3; p = 0.049) and in the dorsomedial striatum
(F(1,24) = 8.48; p = 0.008) 1 hr after training (Fig. 3C,D).
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Figure 3.
Numbers of pCREB-positive cells in the hippocampus
(A, B) and striatum (C, D) of place
learners, response learners, and controls matched to the number and
duration of trials of place and response learners either
immediately (A, C) or 1 hr (B, D) after
completion of training. DG, Dentate gyrus; DL, dorsolateral striatum;
DM, dorsomedial striatum. *p < 0.05.
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Figure 4.
A, pCREB-IR in the hippocampus of a
representative place learner immediately after training.
B, pCREB-IR in the hippocampus of a representative motor
control immediately after training. pCREB-IR in the hippocampus of a
representative response learner immediately (C)
and 1 hr (D) after training.
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Figure 5.
Representative pCREB-IR immediately after training
in the dorsolateral striatum of a response learner
(A), place learner (B), and
motor control (C). Representative pCREB-IR 1 hr
after training in the dorsolateral striatum of a response learner
(D), place learner (E), and
motor control (F). Representative pCREB-IR 1 hr
after training in the dorsomedial striatum of a response learner
(G), place learner
(H), and motor control
(I).
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Overall MANOVA of c-Fos in the hippocampus revealed a significant main
effect of training condition (F(3,63) = 73.8; p < 0.001). Thus, there was significantly more
hippocampal c-Fos-IR in trained rats than in control rats immediately
and 1 hr after training (Figs.
6A,B, 7). In the
striatum, overall ANOVA of c-Fos revealed a significant main effect of test-to-killing interval
(F(2,71) = 24.5; p < 0.001) and a training condition by test-to-killing interval interaction
(F(2,71) = 6.67; p = 0.002). Thus, there was greater c-Fos-IR immediately after training
than 1 hr after training. The training condition by test-to-killing
interaction was attributable to greater c-Fos-IR among trained rats
than among motor controls immediately after training
(F(2,37) = 5.88; p = 0.006) but not 1 hr after training (Fig. 6C,D). Place
learners and response learners had equivalent levels of c-Fos-IR in the hippocampus immediately after training. At 1 hr after training, however, place learners had significantly higher levels of c-Fos-IR in the dentate gyrus and CA1 than response learners
(F(1,24) = 4.3, p = 0.04 and F(1,24) = 4.9, p = 0.01, respectively) (Fig. 6B).
There were no differences in striatal c-Fos-IR between place and
response learners either immediately or 1 hr after training (Figs.
6C,D, 8). Representative
images of pCREB and c-Fos immunoreactivity in the hippocampus and
striatum of place learners, response learners, and controls are shown
in Figures 4, 5, 7, and 8.
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Figure 6.
Numbers of c-Fos-positive cells in the hippocampus
(A, B) and striatum (C, D) of place
learners, response learners, and controls matched to the numbers and
durations of trials of place and response learners either immediately
(A, C) or 1 hr (B, D) after completion of
training. DG, Dentate gyrus; DL, dorsolateral striatum; DM, dorsomedial
striatum. *p < 0.05.
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Figure 7.
Representative c-Fos-IR immediately after training
in the hippocampus of experimental (A) and motor
control (B) rats. Representative c-Fos-IR 1 hr
after training in the hippocampus of place learners
(C) and response learners
(D).
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Figure 8.
Representative c-Fos-IR in the dorsolateral
striatum of experimental (A) and motor control
(B) rats immediately after training and
experimental rats (C) 1 hr after training.
Representative c-Fos-IR in the dorsomedial striatum of experimental
(D) and motor control (E)
rats immediately after training and experimental rats
(F) 1 hr after training.
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Discussion |
The main findings of this study are twofold. First, rats trained
to make a spatial discrimination in the cross maze have significantly more phosphorylation of CREB and expression of c-Fos in the hippocampus and striatum than control rats matched for motor activity and time in
the maze. The activity of these transcription factors occurs initially
in both the hippocampus and the striatum independently of whether rats
use place or response strategies to solve the task. Second, regional
activity of CREB, and to a lesser extent c-Fos, distinguishes place and
response learners 1 hr after training. Specifically, pCREB-IR is
greater in the dentate gyrus, CA1, and CA3 of place learners than in
that of response learners. In contrast, pCREB-IR is greater in the
dorsolateral and dorsomedial striatum of response learners than in that
of place learners. Elevated c-Fos is observed in the dentate gyrus and
CA1 of place learners compared with response learners 1 hr after training.
It is most likely that regional differences in pCREB and c-Fos between
place and response learners are related to differences in cognitive
factors rather than to differences in locomotor or other performance
factors. This conclusion is based on our finding that levels of pCREB
and c-Fos do not differ in either the hippocampus or the striatum of
control rats matched to the numbers and durations of trials of place
learners in comparisons with controls matched to response learners.
Thus, differences in the numbers and durations of trials in the range
observed between place and response learners are not sufficient to
cause the differences in pCREB and c-Fos that we report here.
The current findings extend previous dissociations of the hippocampus
and striatum resulting from localized lesions (Packard and McGaugh,
1992; Kesner et al., 1993; McDonald and White, 1993) or pharmacological
manipulations (Packard and White, 1990; Packard and Teather,
1997, 1998; Packard, 1999). Specifically, functional measures of
transcription factors involved in memory formation reveal localized
activity in the hippocampus of place learners and in the striatum of
response learners.
White and McDonald (2002) theorized that multiple parallel memory
systems including the hippocampus and dorsal striatum access much of
the same information, but that each system has a unique "processing
style." The present results are consistent with this theory in that
activation of the transcription factors CREB and c-Fos was observed
initially in both the hippocampus and striatum immediately after
training. One hour after training, however, sustained activation of the
transcription factors was observed only in the brain region implicated
in a particular type of memory storage. Sustained pCREB and c-Fos were
observed in the hippocampus of place learners but not response
learners, whereas sustained pCREB occurs in the dorsal striatum of
response learners but not place learners.
It has been proposed that the dorsomedial and dorsolateral striatum are
involved primarily in stimulus-stimulus and stimulus-response associations, respectively (Devan and White, 1999; Devan et al., 1999;
White and McDonald, 2002). Rats that adopted a response strategy had
elevated pCREB in the dorsolateral striatum both immediately and 1 hr
after learning compared with place learners, which is consistent with
the hypothesis that the dorsolateral striatum has a prominent role in
coding stimulus-response associations. In contrast, there was no
difference in pCREB between place and response learners in the
dorsomedial striatum immediately after training. By 1 hr after
training, levels of pCREB in the dorsomedial striatum were
significantly higher in response learners than in place learners. Thus,
although the present findings indicate neuronal plasticity in the
dorsolateral striatum during response learning, they do not support a
prominent role for the dorsomedial striatum during place learning.
Studies in which rats are trained to use a place strategy rather than
to choose between at least two different strategies may result in a
stronger test of the hypothesis that activity in the dorsomedial
striatum is related to place learning.
It is well established that formation of long-term memory is dependent
on protein synthesis (Davis and Squire, 1984), and current theories of
the cellular mechanisms of memory formation indicate that expression of
c-Fos and the transcription of late-effector genes may stabilize
synapses and increase synaptic efficacy to subsequent stimuli (Morgan
and Curran, 1991). Transient synapse formation, for example, is related
to CREB phosphorylation after avoidance learning (O'Connell et al.,
2000). Reports of learning-induced CREB phosphorylation indicate that
the time courses of peak phosphorylation may vary. For single-trial
aversively motivated learning, CREB phosphorylation may be biphasic,
with peaks immediately and 3-6 hr after training, but there is
disagreement as to whether the immediate increase is caused by the
aversive foot shock alone or the learned association (Bernabeu et al.,
1997; Stanciu et al., 2002). In contrast to the biphasic peaks,
Taubenfeld et al. (2001) reported that inhibitory avoidance training
caused CREB phosphorylation that began immediately and was sustained
for up to 20 hr after training. Moreover, increased pCREB was reported 2 hr after inhibitory avoidance training (Cammarota et al., 2000) and
1-2 hr after exposure to a novel environment (Vianna et al., 2000).
For incremental learning in the radial arm maze, CREB phosphorylation reportedly is elevated after the last training trial on days 4 and 8 (Mizuno et al., 2002), which indicates that activity is either
sustained or occurs in relation to each bout of learning. Learning-related expression of c-Fos is generally reported to occur
1-2 hr after training (Curran and Morgan, 1995; Stanciu et al., 2002).
A recent study shows that c-Fos is expressed in the hippocampus during
radial arm maze training, and that inhibition of c-Fos by antisense
oligonucleotide treatment impairs spatial memory formation (He et al.,
2002). Sustained strategy- and region-specific activity of c-Fos and
CREB 1 hr after training, therefore, is in the range of previous
reports of the time courses of learning-related activity of
transcription factors. The present results indicate that pCREB is
increased throughout the dorsal hippocampus of place learners 1 hr
after training, whereas c-Fos is expressed in CA1 and the dentate gyrus
but not in CA3. There is evidence that CA3 may be active during pattern
completion rather than spatial learning because of recurrent
connectivity (Kazu et al., 2002). It remains to be determined, however,
whether the differences between c-Fos expression and CREB
phosphorylation after cross maze training are attributable to
differences in their time courses of maximal activity or to other factors.
As evidence for multiple memory systems increases, theorists are
beginning to form hypotheses about how these systems interact in the
intact brain. Multiple memory systems may act independently, cooperatively, competitively, or in temporal sequence (Packard and
Knowlton, 2002; White and McDonald, 2002). The present findings support
the view that the hippocampus and striatum can act in parallel during
acquisition of a task that can be solved by either hippocampus- or
striatum-dependent strategies. Additional studies of incremental
learning may be necessary to reveal conditions under which the
hippocampus and striatum may act competitively or in temporal sequence.
The present results suggest further that localized, functional
measurements of transcription factors and other signaling proteins
during memory formation are useful for describing relationships among
multiple memory systems during normal cognitive processes in the intact brain.
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FOOTNOTES |
Received Oct. 9, 2002; revised Feb. 4, 2003; accepted Feb. 7, 2003.
This work was supported by National Science Foundation Grant
IBN-0133734.
Correspondence should be addressed to Paul J. Colombo, Tulane
University, Department of Psychology, New Orleans, LA 70118. E-mail:
pcolomb{at}tulane.edu.
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References |
-
Bernabeu R,
Bevilaqua L,
Ardenghi P,
Bromberg E,
Schmitz P,
Bianchin M,
Izquierdo I,
Medina JH
(1997)
Involvement of hippocampal cAMP/cAMP-dependent protein kinase signaling pathways in a late memory consolidation phase of aversively motivated learning in rats.
Proc Natl Acad Sci USA
94:7041-7046[Abstract/Free Full Text].
-
Bourtchuladze R,
Frenguelli B,
Blendy J,
Cioffi D,
Schutz G,
Silva AJ
(1994)
Deficient long-term memory in mice with a targeted mutation of the cAMP-responsive element-binding protein.
Cell
79:59-68[ISI][Medline].
-
Brown HE,
Garcia MM,
Harlan RE
(1998)
A two focal plane method for digital quantification of nuclear immunoreactivity in large brain areas using NIH-image software.
Brain Res Brain Res Protoc
2:264-272[Medline].
-
Cammarota M,
Bevilaqua LR,
Ardenghi P,
Paratcha G,
Levi DS,
Izquierdo I,
Medina JH
(2000)
Learning-associated activation of nuclear MAPK, CREB and Elk-1, along with Fos production, in the rat hippocampus after a one-trial avoidance learning: abolition by NMDA receptor blockade.
Brain Res Mol Brain Res
76:36-46[Medline].
-
Casey BJ,
Thomas KM,
Davidson MC,
Kunz K,
Franzen PL
(2002)
Dissociating striatal and hippocampal function developmentally with a stimulus-response compatibility task.
J Neurosci
22:8647-8652[Abstract/Free Full Text].
-
Colombo PJ,
Davis HP,
Volpe BT
(1989)
Allocentric spatial and tactile memory impairments in rats with dorsal caudate lesions are affected by preoperative behavioral training.
Behav Neurosci
103:1242-1250[Medline].
-
Compton DM
(2001)
Are memories for stimulus-stimulus associations or stimulus-response associations responsible for serial-pattern learning in rats?
Physiol Behav
72:643-652[Medline].
-
Curran T,
Morgan JI
(1995)
Fos: an immediate-early transcription factor in neurons.
J Neurobiol
26:403-412[ISI][Medline].
-
Dash PK,
Karl KA,
Colicos MA,
Prywes R,
Kandel ER
(1991)
cAMP response element-binding protein is activated by Ca2+/calmodulin- as well as cAMP-dependent protein kinase.
Proc Natl Acad Sci USA
88:5061-5065[Abstract/Free Full Text].
-
Davis HP,
Squire LR
(1984)
Protein synthesis and memory: a review.
Psychol Bull
96:518-559[ISI][Medline].
-
DeCoteau WE,
Kesner RP
(2000)
A double dissociation between the rat hippocampus and medial caudoputamen in processing two forms of knowledge.
Behav Neurosci
114:1096-1108[ISI][Medline].
-
Devan BD,
White NM
(1999)
Parallel information processing in the dorsal striatum: relation to hippocampal function.
J Neurosci
19:2789-2798[Abstract/Free Full Text].
-
Devan BD,
McDonald RJ,
White NM
(1999)
Effects of medial and lateral caudate-putamen lesions on place- and cue-guided behaviors in the water maze: relation to thigmotaxis.
Behav Brain Res
100:5-14[ISI][Medline].
-
Eichenbaum H
(2001)
The hippocampus and declarative memory: cognitive mechanisms and neural codes.
Behav Brain Res
127:199-207[ISI][Medline].
-
Eichenbaum H,
Stewart C,
Morris RG
(1990)
Hippocampal representation in place learning.
J Neurosci
10:3531-3542[Abstract].
-
Fernandez-Ruiz J,
Wang J,
Aigner TG,
Mishkin M
(2001)
Visual habit formation in monkeys with neurotoxic lesions of the ventrocaudal neostriatum.
Proc Natl Acad Sci USA
98:4196-4201[Abstract/Free Full Text].
-
Golf Racht-Delatour B,
El Massioui N
(1999)
Rule-based learning impairment in rats with lesions to the dorsal striatum.
Neurobiol Learn Mem
72:47-61[Medline].
-
Gonzalez GA,
Montminy MR
(1989)
Cyclic AMP stimulates somatostatin gene transcription by phosphorylation of CREB at serine 133.
Cell
59:675-680[ISI][Medline].
-
Guzowski JF,
McGaugh JL
(1997)
Antisense oligodeoxynucleotide-mediated disruption of hippocampal cAMP response element binding protein levels impairs consolidation of memory for water maze training.
Proc Natl Acad Sci USA
94:2693-2698[Abstract/Free Full Text].
-
He J,
Yamada K,
Nabeshima T
(2002)
A role of Fos expression in the CA3 region of the hippocampus in spatial memory formation in rats.
Neuropsychopharmacology
26:259-268[ISI][Medline].
-
Josselyn SA,
Shi C,
Carlezon Jr WA,
Neve RL,
Nestler EJ,
Davis M
(2001)
Long-term memory is facilitated by cAMP response element-binding protein overexpression in the amygdala.
J Neurosci
21:2404-2412[Abstract/Free Full Text].
-
Kazu N,
Quirk MC,
Chitwood RA,
Watanabe M,
Yeckel MF,
Sun LD,
Kato A,
Carr CA,
Johnston D,
Wilson MA,
Tonegawa S
(2002)
Requirement for hippocampal CA3 NMDA receptors in associative memory recall.
Science
297:211-218[Abstract/Free Full Text].
-
Kesner RP,
Beers DR
(1988)
Dissociation of data-based and expectancy-based memory following hippocampal lesions in rats.
Behav Neural Biol
50:46-60[Medline].
-
Kesner RP,
Bolland BL,
Dakis M
(1993)
Memory for spatial locations, motor responses, and objects: triple dissociation among the hippocampus, caudate nucleus, and extrastriate visual cortex.
Exp Brain Res
93:462-470[ISI][Medline].
-
Knowlton BJ,
Mangels JA,
Squire LR
(1996)
A neostriatal habit learning system in humans.
Science
273:1399-1402[Abstract].
-
Lamprecht R,
Dudai Y
(1996)
Transient expression of c-Fos in rat amygdala during training is required for encoding conditioned taste aversion memory.
Learn Mem
3:31-41[Abstract/Free Full Text].
-
Lamprecht R,
Hazvi S,
Dudai Y
(1997)
cAMP response element-binding protein in the amygdala is required for long- but not short-term conditioned taste aversion memory.
J Neurosci
17:8443-8450[Abstract/Free Full Text].
-
Maguire EA,
Burgess N,
Donnett JG,
Frackowiak RS,
Frith CD,
O'Keefe J
(1998)
Knowing where and getting there: a human navigation network.
Science
280:921-924[Abstract/Free Full Text].
-
McDonald RJ,
White NM
(1993)
A triple dissociation of memory systems: hippocampus, amygdala, and dorsal striatum.
Behav Neurosci
107:3-22[ISI][Medline].
-
McDonald RJ,
White NM
(1994)
Parallel information processing in the water maze: evidence for independent memory systems involving dorsal striatum and hippocampus.
Behav Neural Biol
61:260-270[ISI][Medline].
-
Milanovic S,
Radulovic J,
Laban O,
Stiedl O,
Henn F,
Spiess J
(1998)
Production of the Fos protein after contextual fear conditioning of C57BL/6N mice.
Brain Res
784:37-47[Medline].
-
Mizuno M,
Yamada K,
Maekawa N,
Saito K,
Seishima M,
Nabeshima T
(2002)
CREB phosphorylation as a molecular marker of memory processing in the hippocampus for spatial learning.
Behav Brain Res
133:135-141[Medline].
-
Morgan JI,
Curran T
(1991)
Stimulus-transcription coupling in the nervous system: involvement of the inducible proto-oncogenes fos and jun.
Annu Rev Neurosci
14:421-451[ISI][Medline].
-
O'Connell C,
Gallagher HC,
O'Malley A,
Bourke M,
Regan CM
(2000)
CREB phosphorylation coincides with transient synapse formation in the rat hippocampal dentate gyrus following avoidance learning.
Neural Plast
7:279-289[Medline].
-
Packard MG
(1999)
Glutamate infused posttraining into the hippocampus or caudate-putamen differentially strengthens place and response learning.
Proc Natl Acad Sci USA
96:12881-12886[Abstract/Free Full Text].
-
Packard MG,
Knowlton BJ
(2002)
Learning and memory functions of the basal ganglia.
Annu Rev Neurosci
25:563-593[ISI][Medline].
-
Packard MG,
McGaugh JL
(1992)
Double dissociation of fornix and caudate nucleus lesions on acquisition of two water maze tasks: further evidence for multiple memory systems.
Behav Neurosci
106:439-446[ISI][Medline].
-
Packard MG,
McGaugh JL
(1996)
Inactivation of hippocampus or caudate nucleus with lidocaine differentially affects expression of place and response learning.
Neurobiol Learn Mem
65:65-72[ISI][Medline].
-
Packard MG,
Teather LA
(1997)
Posttraining injections of MK-801 produce a time-dependent impairment of memory in two water maze tasks.
Neurobiol Learn Mem
68:42-50[Medline].
-
Packard MG,
Teather LA
(1998)
Amygdala modulation of multiple memory systems: hippocampus and caudate-putamen.
Neurobiol Learn Mem
69:163-203[ISI][Medline].
-
Packard MG,
White NM
(1990)
Lesions of the caudate nucleus selectively impair "reference memory" acquisition in the radial maze.
Behav Neural Biol
53:39-50[ISI][Medline].
-
Packard MG,
Cahill L,
McGaugh JL
(1994)
Amygdala modulation of hippocampal-dependent and caudate nucleus-dependent memory processes.
Proc Natl Acad Sci USA
91:8477-8481[Abstract/Free Full Text].
-
Qiang M,
Xie J,
Wang H,
Qiao J
(1999)
Effect of nitric oxide synthesis inhibition on c-Fos expression in hippocampus and cerebral cortex following two forms of learning in rats: an immunohistochemistry study.
Behav Pharmacol
10:215-222[Medline].
-
Radulovic J,
Kammermeier J,
Spiess J
(1998)
Relationship between fos production and classical fear conditioning: effects of novelty, latent inhibition, and unconditioned stimulus preexposure.
J Neurosci
18:7452-7461[Abstract/Free Full Text].
-
Restle F
(1957)
Discrimination of cues in mazes: a resolution of the "place-vs. response" question.
Psychol Rev
64:217-227[ISI][Medline].
-
Sheng M,
Greenberg ME
(1990)
The regulation and function of c-fos and other immediate early genes in the nervous system.
Neuron
4:477-485[ISI][Medline].
-
Stanciu M,
Radulovic J,
Spiess J
(2001)
Phosphorylated cAMP response element binding protein in the mouse brain after fear conditioning: relationship to Fos production.
Brain Res Mol Brain Res
94:15-24[Medline].
-
Taubenfeld SM,
Wiig KA,
Monti B,
Dolan B,
Pollonini G,
Alberini CM
(2001)
Fornix-dependent induction of hippocampal CCAAT enhancer-binding protein
 and  colocalizes with phosphorylated cAMP response element-binding protein and accompanies long-term memory consolidation.
J Neurosci
21:84-91[Abstract/Free Full Text]. -
Teng E,
Stefanacci L,
Squire LR,
Zola SM
(2000)
Contrasting effects on discrimination learning after hippocampal lesions and conjoint hippocampal-caudate lesions in monkeys.
J Neurosci
20:3853-3863[Abstract/Free Full Text].
-
Tischmeyer W,
Kaczmarek L,
Strauss M,
Jork R,
Matthies H
(1990)
Accumulation of c-fos mRNA in rat hippocampus during acquisition of a brightness discrimination.
Behav Neural Biol
54:165-171[ISI][Medline].
-
Vann SD,
Brown MW,
Erichsen JT,
Aggleton JP
(2000)
Fos imaging reveals differential patterns of hippocampal and parahippocampal subfield activation in rats in response to different spatial memory tests.
J Neurosci
20:2711-2718[Abstract/Free Full Text].
-
Vianna MR,
Barros DM,
Silva T,
Choi H,
Madche C,
Rodrigues C,
Medina JH,
Izquierdo I
(2000)
Pharmacological demonstration of the differential involvement of protein kinase C isoforms in short- and long-term memory formation and retrieval of one-trial avoidance in rats.
Psychopharmacology (Berl)
150:77-84[Medline].
-
Wan H,
Aggleton JP,
Brown MW
(1999)
Different contributions of the hippocampus and perirhinal cortex to recognition memory.
J Neurosci
19:1142-1148[Abstract/Free Full Text].
-
White NM,
McDonald RJ
(2002)
Multiple parallel memory systems in the brain of the rat.
Neurobiol Learn Mem
77:125-184[ISI][Medline].
Copyright © 2003 Society for Neuroscience 0270-6474/03/2383547-08$05.00/0
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TOP
ABSTRACT
Introduction
