Induction of Hippocampal Long-Term Potentiation during Waking Leads to Increased Extrahippocampal zif-268 Expression during Ensuing Rapid-Eye-Movement Sleep

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (50)

Citing Articles via Google Scholar

Google Scholar

Articles by Ribeiro, S.

Articles by Pavlides, C.

Search for Related Content

PubMed

PubMed Citation

Articles by Ribeiro, S.

Articles by Pavlides, C.

Previous Article  |  Next Article

The Journal of Neuroscience, December 15, 2002, 22(24):10914-10923

Induction of Hippocampal Long-Term Potentiation during Waking Leads to Increased Extrahippocampal zif-268 Expression during Ensuing Rapid-Eye-Movement Sleep
Sidarta Ribeiro¹, Claudio V. Mello², Tarciso Velho², Timothy J. Gardner³, Erich D. Jarvis¹, and Constantine Pavlides⁴
¹ Department of Neurobiology, Duke University Medical Center, Durham, North Carolina 27710, ² Neurological Sciences Institute, Oregon Health and Science University, Beaverton, Oregon 97006, and ³ Center for Physics and Biology, and ⁴ Laboratory of Neuroendocrinology, The Rockefeller University, New York, New York 10021

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Rapid-eye-movement (REM) sleep plays a key role in the consolidation of memories acquired during waking (WK). The search formechanisms underlying that role has revealed significant correlationsin the patterns of neuronal firing, regional blood flow, and expressionof the activity-dependent gene zif-268 between WK and subsequentREM sleep. Zif-268 integrates a major calcium signal transductionpathway and is implicated by several lines of evidence in activity-dependentsynaptic plasticity. Here we report that the induction of hippocampallong-term potentiation (LTP) during WK in rats leads to an upregulationof zif-268 gene expression in extrahippocampal regions duringsubsequent REM sleep episodes. This upregulation occurs predominantlyin the amygdala, entorhinal, and auditory cerebral cortices duringthe first REM sleep episodes after LTP induction and reaches somatosensoryand motor cerebral cortices as REM sleep recurs. We also showthat hippocampal inactivation during REM sleep blocks extrahippocampalzif-268 upregulation, indicating that cortical and amygdalar zif-268expression during REM sleep is under hippocampal control. Thus,expression of an activity-dependent gene involved in synapticplasticity propagates gradually from the hippocampus to extrahippocampalregions as REM sleep recurs. These findings suggest that a progressivedisengagement of the hippocampus and engagement of the cerebralcortex and amygdala occurs during REM sleep. They are also consistentwith the view that REM sleep constitutes a privileged window forhippocampus-driven cortical activation, which may play an instructiverole in the communication of memory traces from the hippocampusto the cerebralcortex.

Key words: REM sleep; zif-268; LTP; learning and memory; immediate-early gene; hippocampus; cerebral cortex; amygdala; plasticity; late sleep; early sleep

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mammalian sleep consists of the cyclic alternation of two behaviorally and physiologically distinct states: slow-wave sleep(SWS) and rapid-eye-movement (REM) sleep (Timo-Iaria et al., 1970;Hobson, 1995). Several lines of research indicate that sleep isimportant for learning (Idzikowski, 1984; Stickgold et al., 2000a,2001; Maquet, 2001; but see Siegel, 2001). Moderate sleep deprivationimpairs plasticity in the visual cortex (Frank et al., 2001) aswell as the induction of hippocampal long-term potentiation (LTP)(Campbell et al., 2002), a standard model of synaptic plasticityand memory formation (Bliss and Lomo, 1973; Bliss and Collingridge,1993). REM sleep, in particular, plays an important role in theconsolidation of memories (Winson, 1985; Hennevin et al., 1995;Smith, 1996; Stickgold et al., 2000b). It has been shown thatexposure to learning situations during waking (WK) enhances subsequentREM sleep in rats (Smith and Rose, 1996). Conversely, REM sleepdeprivation impairs short-term memory in rats (Pearlman and Becker,1974; Fishbein and Gutwein, 1977; Smith and Butler, 1982; Smithand Kelly, 1988) and perceptual learning in humans (Karni et al.,1994).

Relevant WK experience results in increased hippocampal neuronal firing in rats (Pavlides and Winson, 1989; Poe et al., 2000a;Louie and Wilson, 2001) and cerebral activation in humans (Maquetet al., 2000) during subsequent REM sleep, indicating that experience-dependentbrain reactivation occurs during this sleep state. In line withthis notion, we have shown that brain expression of the activity-dependentgene zif-268 (same as Egr-1, NGFI-A, Krox-24, and ZENK) (Milbrandt,1987; Sukhatme et al., 1988) is reinduced during REM sleep inrats exposed previously to an enriched environment during WK butnot in unexposed controls (Ribeiro et al., 1999). Neuronal zif-268expression is rapidly and transiently induced in response to synapticactivation via calcium signal transduction pathways (Cole et al.,1989; Wisden et al., 1990; Cullinan et al., 1995; Mello and Clayton,1995). Therefore, the finding that zif-268 is reactivated in severalbrain areas during REM sleep that follows a significant WK experience(Ribeiro et al., 1999) indicates that these areas are synapticallyactive during REMsleep.

Here we characterize the spatiotemporal dynamics of zif-268 expression during wake and sleep episodes that follow the inductionof LTP in medial perforant path (mPP)-dentate gyrus (DG) synapses.We used a well established LTP-inducing, high-frequency stimulation(HFS) protocol (Winson and Dahl, 1986) shown previously to inducemarked zif-268 upregulation in ipsilateral DG granule neurons~30 min after stimulation (Cole et al., 1989; Wisden et al., 1990;Worley et al., 1993). Brain zif-268 expression was assessed ingroups of rats representing "early" and "late" post-LTP episodesof WK, SWS, and REM sleep. We also investigated the effect ofhippocampal inactivation during post-LTP REM sleep on extrahippocampalexpression of zif-268. The results demonstrate that zif-268 isreinduced in a hippocampus-dependent manner in extrahippocampalregions during REM sleep that follows hippocampal LTP induction.Zif-268 reinduction during REM sleep may provide a window of increasedextrahippocampal synaptic plasticity, possibly contributing tomemoryconsolidation.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animal care. Experiments were approved by the Rockefeller University Institutional Animal Use and Care Committee, in accordancewith National Institutes of Health Guidelines for the Care andUse of Laboratory Animals. Adult male Sprague Dawley rats (weight,250-300 gm; n = 4 per group; total, n = 52) were housed in individualhome cages, kept on a 12 hr light/dark schedule (lights on at7:00 A.M.), and provided with food and water ad libitum. Animalswere handled daily (10-15 min) for 2 weeks before surgery, soas to effectively minimize handling and stress-related zif-268expression (Cullinan et al., 1995; Jarvis et al., 1995; Ribeiroet al., 1999).

Electrode implant. Recording and stimulating electrodes were prepared from 125 µm formvar-insulated stainless-steel wire (CaliforniaFine Wire, Grover Beach, CA) with resistances of 0.5-1.2 M $Omega$ . Onthe day of surgery, animals were injected with 0.1 mg/kg atropinesulfate (Baxter, Irvine, CA) to prevent excessive secretions andwere deeply anesthetized 10 min later with 50 mg/kg sodium pentobarbital(Nembutal; Abbott Laboratories, North Chicago, IL). Animals werethen placed in a rat stereotaxic device (David Kopf Instruments,Tujunga, CA). The skull was aseptically exposed, burr holes weredrilled, and four stainless-steel anchor screws were insertedinto the holes, two of which had plastic-coated silver wire presolderedto them (California Fine Wire), so as to provide ground and referencefor stimulation and recording. Animals were implanted bilaterallywith recording and stimulation electrodes in the DG [+3.8 anteroposterior(AP), ±2.1 mediolateral (ML), and $-$ 3.3 dorsoventral (DV) mm frombregma] and in the mPP (+7.9 AP, ±4.1 ML, and $-$ 3 DV from bregma),respectively (Paxinos and Watson, 1997). Electrode placement wasguided by the depth profile of evoked field potentials, and thefinal positions of the stimulating and recording electrodes wereadjusted to produce maximum responses. The electrodes and skullscrew ground/reference were then connected to an 11 pin plasticplug, and the entire implant was permanently secured in placewith dental acrylic cement. Animals were allowed 1 week of postsurgeryrecovery.

Electrophysiological recordings. Electrophysiological recordings were made using a field-effect transistor head-stage connectedto the electrode plugs, and an AC/DC differential amplifier (model3000; A-M Systems, Sequim, WA) was set at 100× gain. Evoked fieldpotentials were band-pass filtered between 1 Hz and 10 kHz, digitizedat 10 kHz (MIO-16X acquisition board; National Instruments, Austin,TX), and averaged on-line using custom-built LabView software.EEG signals were band-pass filtered between 1 and 100 Hz and digitizedat 400 Hz with a PowerLab recording unit (AD Instruments, GrandJunction,CO).

LTP induction. After recovery from surgery, baseline recordings of field potentials and EEG, along with handling of the animals,were performed for an additional week. Initially, an input-outputfunction was constructed by varying the current intensity betweenthat required to produce minimum and maximum responses (usually20-300 µA). A "test" intensity was then chosen that was ~30% ofmaximum stimulation intensity. Test stimuli were delivered fourtimes, once every 15 sec, to obtain each averaged field potentialdata point. Both the EPSP slope (from the initial positive rise)and the population spike amplitude of each averaged field potentialwere measured. Baseline recordings were taken for 1 week to ensurethat the recordings were stable. On the day of the experiment,which always began within the first 2 hr of the light cycle, animalswere taken to the recording chamber, and baseline potentials wereacquired for both hemispheres. After baseline field potentialrecording, one hemisphere (randomized) was subjected to HFS toproduce unilateral LTP, whereas the contralateral hemisphere receivedno stimulation. Two HFSs per animal were applied within 5 minof each other and consisted of 10 50 msec trains of 0.25 msecpulses at 400 Hz, with one train every 10 sec (Winson and Dahl,1986). Induction of unilateral LTP was verified after the secondHFS (see Fig. 1b); animals that failed to show LTP (n = 5) werediscarded from the study and later substituted with other animalsto complete all groups. An additional group of animals receivedHFS in one hemisphere and, as a control, low-frequency stimulation(LFS) (10 1 sec trains of 0.25 msec pulses at 10 Hz, one trainevery 10 sec, same total number of pulses as in HFS) in the otherhemisphere, and was assigned to the early REM sleep condition.Three control groups not subjected to HFS stimulation were alsostudied.

Quantitative identification of wake-sleep states. Animals were continuously observed from time of baseline recording to kill.Hippocampal EEG and evoked field potentials were also continuouslyrecorded, and behaviors were annotated in real time on the EEGrecord (see Fig. 2a) according to the following categories: alertWK (active exploration of the environment with whisking and hippocampaltheta rhythm), quiet WK (stillness or grooming with eyes openand non-theta low-amplitude hippocampal EEG), drowsy WK (stillnesswith eyes semiclosed and non-theta variable hippocampal EEG),SWS (stillness with eyes closed, plus large-amplitude slow EEGhippocampal waves), pre-REM sleep (short periods of <10 sec ofoverall stillness with brief whisking, eyes closed, and hippocampaltheta rhythm), and REM sleep (overall stillness with prolongedwhisking, eyes closed, and hippocampal theta rhythm). Group assignmentwas confirmed after an offline comparison of the behavior recordand the spectrogram (see Fig. 2b), which was generated by applyinga multitaper fast Fourier transform to the EEG record (Thomson,1982). The total time spent in WK (alert plus quiet plus drowsy),SWS, and REM (pre-REM plus REM) states was calculated for eachanimal and averaged by group. Very mild sleep deprivation wasused during selected times to standardize the kill times acrossgroups. Specifically, all animals were kept awake in the initial2 hr after LTP induction, by gently tapping the recording boxwhen animals showed drowsiness; in addition, animals in the lategroups were similarly prevented from going back to sleep for 1hr after the first sleep cycle was completed. The criteria forassigning animals to the different wake and sleep groups wereestablished previously (Ribeiro et al., 1999), as follows: WKanimals were kept awake for $>=$ 1 hr before kill without any sleep,SWS animals had $>=$ 3 min of SWS but were woken up at the first signsof REM sleep, and REM animals were allowed to transit spontaneouslyfrom SWS into REM sleep and had $>=$ 90 sec of total REM. Figure 2cdepicts the mean sleep-wake structure of control and experimentalgroups.

Survival times and group assignment. On reaching behavioral and physiological criteria for WK, SWS, or REM sleep (see Fig.2a,b), all animals were kept awake to prevent subsequent uncontrolledwake and/or sleep states and, thus, to normalize postcriterionexperience. Zif-268 mRNA levels peak ~30 min after a given referencestimulus or behavior (Cullinan et al., 1995; Mello and Clayton,1995; Ribeiro et al., 1999). Therefore, animals were killed bydecapitation 30 min after reaching criteria (see Fig. 1a, asterisks),and any zif-268 expression caused by postcriteria WK was assumedto be the same across all groups. Figure 2d summarizes the meansurvival times relative to the time of LTP induction. Animalswere assigned to one of seven groups, based on post-LTP survivaltimes and cumulative wake-sleep states reached (see Fig. 1a).The first stimulated group (HFS/30') consisted of animals keptawake for 30 min after unilateral HFS and then killed; this groupserved as a positive control for the unilateral DG induction ofzif-268 under our stimulation protocol. The six remaining stimulatedgroups were studied according to the cumulative wake-sleep statesreached: HFS/early WK, HFS/early SWS, HFS/early REM, HFS/lateWK, HFS/late SWS, and HFS/late REM. Animals in the late groupshad one full sleep cycle followed by 1 hr of WK before being randomlysorted according to wake-sleepstates.

Histology and in situ hybridization. The brains were quickly removed, frozen in dry ice, and stored at $-$ 70°C. Serial frontalsections (10 µm) were taken between approximately $-$ 1.4 and $-$ 4.4mm from bregma (Paxinos and Watson, 1997) and thaw mounted onRNase-free glass slides (Superfrost Plus; VWR Scientific, WestChester, PA) as adjacent triplicates. Thicker sections (20 µm)collected every 300 µm were stained with cresyl violet and usedto identify the brain regions of interest. Sections were hybridizedwith ³⁵S-labeled zif-268 riboprobes, as described previously (Mello etal., 1992). Absence of sense-strand hybridization was used asa control for signal specificity. Several hybridizations wereperformed to optimize stringency conditions and assess consistencyof results across different batches. Hybridized sets were exposedto a high-resolution ³⁵S phosphor screen and scanned on a Storm phosphorimager system(Amersham Biosciences, Sunnyvale, CA). Selected sets were latersubjected to emulsion autoradiography for cell resolution imagingof zif-268 expression. The phosphorimager autoradiograms shownin this study (see Figs. 3, 5) were obtained from an optimizedhybridization batch that showed consistent expression levels acrossbrain section triplicates. The middle section of each triplicatewas chosen for blind phosphorimager densitometric quantificationswith ImageQuant 5.0 software (Amersham Biosciences). Seven regionswere selected for quantification based on the rat stereotaxicatlas (Paxinos and Watson, 1997): the DG, Ammon's horn (CA), entorhinalcortex (EC), dorsolateral nucleus of the amygdala (LaD), and theauditory (Au), primary somatosensory (S1), and primary motor (M1)cortices (see Fig. 3c).

Hippocampal inactivation. Hippocampal infusion of the anesthetic tetracaine was used to investigate the effects of hippocampalinactivation (Poe et al., 2000b) on extrahippocampal zif-268 expression.Different groups of animals were implanted with chronic bilateralstimulating electrodes in the mPP and recording electrodes inthe DG, as described above. In addition, bilateral guide cannulas(26 gauge; Plastics One, Roanoke, VA) attached to the recordingelectrodes were implanted 1.5 mm above the DG (+3.8 AP, ±2.1 ML,and $-$ 1.8 DV mm from bregma). On the day of the experiment, tetracaine(Sigma, St. Louis, MO) was dissolved in PBS to make a 2% solution.Two microliter precision syringes (Hamilton, Reno, NV) filledwith tetracaine solution and vehicle (PBS) were connected withpolyethylene tubing to the infusion cannulas (33 gauge; PlasticsOne). Immediately before baseline recordings, the infusion cannulaswere inserted into the guides with tips placed 0.5 mm above therecording electrodes in the DG. After baseline recordings of EEGand evoked potentials, experimental animals (n = 4) received bilateralHFS and were kept awake for 2 hr before being allowed to sleep(see Fig. 5a). Ten seconds after the onset of REM sleep and withoutwaking the animals, tetracaine (2 µl) was slowly infused over2-3 min into the left DG, while the same volume of vehicle wasinjected into the right DG. Tetracaine strongly reduces the EEGpower recorded in the infusion site (see Fig. 5b); animals thatfailed to show such reduction (n = 2) were discarded from thestudy and later substituted with other animals to complete thegroups. Animals were killed 30 min after REM sleep offset, andtheir brains were processed for zif-268 expression. To controlfor nonspecific diffusion effects, animals (n = 4) not subjectedto HFS were injected during WK with tetracaine and saline (leftand right hemispheres, respectively) and killed after 30 min (seeFig. 5a).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All of the animal groups included in this study (with the exception of those subjected to LFS or hippocampus inactivation)are represented in Figure 1a, comprising three unstimulated controlgroups (Fig. 1a, three top bars) and seven experimental groups,the latter consisting of rats that experienced unilateral LTPinduction during WK (Fig. 1a, seven bottom bars). HFS producedsignificant LTP that was long lasting and unilateral to the ipsilateral(stimulated) hemisphere; at 60 min after HFS (30 min for the HFS/30'group), the average EPSP slope change over baseline levels acrossall groups was 21.9 ± 2.8% for ipsilateral and $-$ 12.5 ± 5.3% (mean± SEM) for contralateral (unstimulated) hemispheres. Correspondingly,the average population spike amplitude changes were 276.4 ± 27.4%for ipsilateral and 60.1 ± 15.6% for contralateral hemispheres.Post-HFS slope and spike amplitudes in ipsilateral hemisphereswere significantly higher than both baseline and contralateralvalues (Student's t test; p < 0.01). No significant differencesoccurred in the amount of potentiation among groups (one-way ANOVAof slope values; F_(6,21) = 1.17; p = 0.36). Animals subjectedto HFS did not display noticeable behavioral differences fromunstimulated animals, having similar wake-sleep structures (Fig.2c). Likewise, the mean survival times relative to the momentof LTP induction (Fig. 2d) did not differ across WK/SWS/REM groups(one-way ANOVA) (for early groups, F_(2,9) = 0.38, p = 0.69; forlate groups, F_(2,9) = 0.89, p = 0.44).

View larger version (26K):
[in this window]
[in a new window]
Figure 1. Experimental design and LTP induction. a, Seven HFS and three unstimulated control groups were studied. Acquisition of baseline field potentials was followed by HFS of one hemisphere (vertical line) to produce unilateral LTP. Group criteria are indicated by asterisks. Notice that all animals were kept awake during the last 30 min of the experiment. b, HFS potentiated mPP-DG synapses. A representative experiment is shown. Plotted are EPSP slope and population spike amplitudes from evoked field potentials recorded in the DG after single-pulse stimulation of the mPP. HFS (arrows) was followed by sustained potentiation of evoked responses.

View larger version (50K):
[in this window]
[in a new window]
Figure 2. Assessment of wake and sleep in rats. a, Characteristic wake-sleep EEG traces recorded in the DG. Notice the presence of theta rhythm (~7 Hz) during both alert WK and REM sleep states. b, EEG spectral analysis used for quantification of wake-sleep states. Plotted is a spectrogram (frequency and power over time) of a representative 60-min-long EEG segment. Power is coded according to the color bar to the left, which runs linearly between $-$ 10 and +13 SDs of the logarithm of the power between 6 and 9 Hz. Frequencies are depicted in a linear scale according to the references on the top right. Arrows, Time points used to sample the EEG traces depicted in a. c, Wake-sleep state composition of experimental and control groups. Shown are the mean relative times spent in WK, SWS, and REM sleep, in percentage of the last 35 min before criterion. Histograms are colored according to the key on Figure 1a. d, Survival times after HFS. Plotted are the average elapsed times between HFS and kill (mean ± SEM). Histograms are colored according to the key on Figure 1a.

Unstimulated animals showed relatively high zif-268 expression in all brain areas studied during WK but decreased zif-268expression when entering SWS sleep, and for some brain areas anadditional decrease on entering REM sleep (see unstimulated controlsin Fig. 3b; for quantification, see unstimulated control panelsin Fig. 4a). These observations are consistent with previous findingsthat zif-268 expression is relatively high during WK but decreasesduring sleep (Pompeiano et al., 1994; Ribeiro et al., 1999). Alsoconsistent with previous findings (Cole et al., 1989; Wisden etal., 1990; Worley et al., 1993), the induction of unilateral LTPof mPP-DG synapses led to strong zif-268 upregulation in ipsilateralDG granule neurons 30 min later (Fig. 3a; see Fig. 3c for anatomy).Average zif-268 expression in the stimulated (ipsilateral) DGwas 4.8 ± 0.4 (mean ± SEM) times higher than the average in theunstimulated (contralateral) DG.

View larger version (46K):
[in this window]
[in a new window]
Figure 3. Post-LTP zif-268 expression profile across wake-sleep cycles. a, Phosphorimager autoradiogram of a representative zif-268-hybridized section. The ipsilateral (but not contralateral) DG showed marked zif-268 upregulation 30 min after unilateral HFS. b, Zif-268 expression levels in the brain during early and late WK, SWS, and REM sleep depend on previous WK stimulation. Both HFS-stimulated and unstimulated controls showed a generalized decrease in brain zif-268 expression in association with SWS, whereas HFS-stimulated hemispheres in both HFS early and late groups showed a selective increase in zif-268 expression in the cortex and amygdala in association with REM sleep. c, Brain regions in which zif-268 expression was quantified. d, Zif-268 cortical reinduction during REM sleep occurred predominantly in layers II, III, and V. Shown is a dark-field view of the auditory cortex in a representative section from the HFS/early REM group, hybridized to zif-268 and exposed to autoradiographic emulsion. White-silver grains denote gene expression; red marks on the right indicate cell layer boundaries, as determined by cresyl violet counterstaining. Scale bar, 250 µm.

View larger version (43K):
[in this window]
[in a new window]
Figure 4. Quantification of zif-268 expression across the wake-sleep cycle. a, Absolute levels of zif-268 expression. Both hemispheres of unstimulated controls showed decreased zif-268 expression levels during SWS and REM sleep compared with WK. The same general pattern was observed in the unstimulated (contralateral) hemispheres of HFS animals. In contrast, several brain structures in the HFS (ipsilateral) hemispheres of both HFS/early and HFS/late groups showed high zif-268 expression during WK and REM sleep and low zif-268 expression during SWS. Zif-268 reinduction occurred in proximal extrahippocampal regions (EC, Au, and LaD) during Early REM sleep and reached distal extrahippocampal areas (S1 and M1) during Late REM sleep (Bonferroni post hoc tests; *p < 0.05). OD, Optical density. b, Interhemispheric zif-268 expression ratios. Histograms are according to the key in a. Whereas unstimulated controls did not show differences between left and right hemispheres (two-way ANOVA; F_(12,63) = 0.33; p = 0.98), significant interactions were detected in HFS groups (two-way ANOVA; F_(30,126) = 3.72; p < 0.0001), because of higher zif-268 interhemispheric ratios (HFS/unstimulated) in the EC, LaD, Au, S1, and M1 during REM sleep than during preceding SWS (Bonferroni post hoc tests; *p < 0.05; **p < 0.01). Notice that the interhemispheric zif-268 expression ratio was also significantly higher for LaD in the HFS/late WK group than in the HFS/late SWS group.

Three hours after HFS application, zif-268 expression returned to low basal levels in the hippocampus (compare the hippocampusbetween Fig. 3a with the HFS/early WK group in Fig. 3b) but increasedbilaterally in extrahippocampal regions in all stimulated animalscompared with corresponding unstimulated controls (compare corticalsites between the HFS/early WK and unstimulated controls/WK groupsin Fig. 3b; for quantification, see Fig. 4a). When the animalsthat received HFS entered the first post-LTP sleep phase, theirunstimulated (contralateral) hemispheres showed a sleep-relateddecrease in zif-268 expression similar to the decrease found inunstimulated controls (compare unstimulated hemispheres in HFS/earlygroups across WK/SWS/REM sleep in Fig. 3b; for quantification,see the HFS/early unstimulated (contralateral) panel in Fig. 4a).

In contrast, zif-268 expression in the stimulated (ipsilateral) hemispheres of these same animals was reduced during SWS butmarkedly increased during REM sleep, approaching in various brainareas the same expression levels seen during WK [compare HFS hemispheresin HFS/early groups across WK/SWS/REM sleep in Fig. 3b; for quantification,see the HFS/early HFS (ipsilateral) panel in Fig. 4a]. Noticein Figure 4a that for many brain regions, REM bars (black) haveheights comparable with the WK bars (white) and higher than SWSbars (gray). Highly significant interactions were detected withinleft/HFS hemispheres (two-way ANOVA; F_(48,189) = 2.48; p < 0.000001).Although comparisons between SWS and REM groups for single brainstructures did not yield significant differences when correctedfor the number of comparisons, grouping the structures in threeputative anatomical divisions (hippocampus, DG plus CA; proximalextrahippocampal, EC plus Au plus LaD; distal extrahippocampal,S1 plus M1) revealed significantly higher zif-268 levels in REMsleep than in SWS (Bonferroni post hoc tests, *p < 0.05) in proximalextrahippocampal regions (Fig. 4a). This unilateral increase inzif-268 expression during REM sleep in HFS animals can be clearlyseen when expressed as an interhemispheric (HFS/unstimulated)ratio, as in Figure 4b. Although no appreciable interhemisphericdifferences in zif-268 expression were seen in unstimulated controls(left/right ratios of ~1), HFS/early animals showed significantlyhigher interhemispheric zif-268 expression ratios (HFS/unstimulatedratios significantly > 1) during REM sleep in the EC and Au. Thisextrahippocampal upregulation of zif-268 during REM sleep wasrestricted to a coronal band of ~500 µm around the hippocampalsite of LTP induction (DG) and was robust in all layers of thecortex, except for layer IV, which showed low levels of gene expression(Fig. 3d).

These data indicate that zif-268 expression is reinduced in the brain during the first REM sleep episode that follows HFSof the hippocampus during WK. Because the interval between theapplication of HFS and kill did not differ across WK/SWS/REM sleepgroups (Fig. 2d), the observed effect cannot be explained by differencesin the survival intervals after stimulation. Additional controls(n = 4; data not shown) that received HFS in one hemisphere andLFS in the other hemisphere showed no significant difference ingene expression profile from that of HFS/unstimulated animals(two-way ANOVA; F_(6,42) = 1.8; p = 0.12), indicating that specificpatterns of WK electrical stimulation, such as HFS, are requiredfor the reinduction of zif-268 during ensuing REM sleep. Notably,HFS of the mPP induces both zif-268 primary induction and LTPin the DG, whereas LFS fails to produce either effect (Cole etal., 1989).

Essentially the same effects as described above for early groups were observed in the late groups: animals showed a generalizedsleep-related decrease in brain zif-268 expression in unstimulated(contralateral) hemispheres but a selective second upregulationof zif-268 expression in extrahippocampal sites of stimulatedhemispheres during a second post-LTP REM sleep episode (see HFS/lategroups in Figs. 3b, 4a). Whereas reactivation of zif-268 expressionduring early REM sleep was most robust in proximal extrahippocampalregions (EC, LaD, and Au), during late REM sleep the effect alsoincluded distal extrahippocampal areas (S1 and M1) (Fig. 4a).This is particularly clear when interhemispheric zif-268 expressionratios are calculated (Fig. 4b, HFS/late panel).

The fact that most of the REM-associated reinduction of zif-268 expression occurs in extrahippocampal sites raised the questionof whether extrahippocampal zif-268 reinduction during REM sleepis dependent on concurrent hippocampal activity. To investigatethis issue, we assessed whether unilateral inactivation of thehippocampus during post-LTP early REM sleep disrupts zif-268 reinductionin proximal extrahippocampal regions. Rats (n = 4) were subjectedto bilateral HFS to induce comparable LTP in both hemispheres(average population spike change of 582.3 ± 70.9% and 422.2 ±167.1% for left and right hemispheres, respectively; mean ± SEM).The animals were kept awake for a minimum of 2 hr and then allowedto sleep (Fig. 5a). Shortly after the onset of REM sleep (durationof 2.4 ± 0.7 min; mean ± SEM), left hippocampi were inactivatedwith tetracaine, whereas right hippocampi received saline. Animalswere killed 30 min after REM sleep offset, and their brains wereprocessed for zif-268 expression. Unstimulated controls (n = 4)similarly injected during WK were also analyzed (Fig. 5a).

View larger version (49K):
[in this window]
[in a new window]
Figure 5. Effect on extrahippocampal zif-268 expression of hippocampal inactivation during REM sleep and WK. a, Experimental design of the hippocampal inactivation experiment (see Materials and Methods). b, Tetracaine infusion strongly reduced EEG power in the DG immediately after the beginning of injection. Amplitude is color coded as in Figure 2b. c, Tetracaine effects on evoked potentials. A representative experiment is shown; notice that potentials almost recovered to previous potentiated levels right before kill, at 14:15. d, Zif-268 brain expression levels during early REM sleep, after bilateral HFS and unilateral tetracaine infusion. Shown is a phosphorimager autoradiogram of a representative brain section hybridized for zif-268. There was a marked reduction of zif-268 expression in the left EC, Au, and LaD (tetracaine side) compared with the right hemisphere (saline side). Arrowheads, Auditory cortex (see Fig. 3c for anatomical localization). e, Zif-268 expression interhemispheric ratios (tetracaine/saline) in bilateral HFS and early REM animals (*p < 0.05 and **p < 0.01). f, Zif-268 brain expression levels during WK, after unilateral tetracaine infusion. Zif-268 expression levels were comparable between hemispheres. Arrowheads, Auditory cortex. g, Zif-268 expression interhemispheric ratios (tetracaine/saline) in WK control animals.

Tetracaine administration strongly reduced the EEG power in hemispheres ipsilateral to the anesthetic injection (Fig. 5b).An immediate and robust reduction of evoked potentials was alsoobserved in the tetracaine-infused (left) DG (Fig. 5c) (populationspike amplitude decreased by 73.1 ± 11.6%; mean ± SEM), whereasminor effects were observed in the vehicle-infused (right) DG(population spike amplitude decreased by 3.6 ± 2.6%; mean ± SEM).Tetracaine effects lasted for ~30 min, keeping the hippocampussilenced during the entire REM sleep episode and most of the ensuingWK. These results confirm the effectiveness of the tetracainetreatment to locally inactivate the hippocampus during a restrictedtime window (Poe et al., 2000b), with very interesting effectson zif-268 expression. Although the saline-injected (right) hemispheresshowed the expected REM-related high expression of zif-268 inthe cerebral cortex (EC and Au) and amygdala (LaD) (Fig. 5d, comparesaline-injected hemisphere with HFS hemisphere in REM/early group,Fig. 3b), the increase in zif-268 expression was blocked in thosesame regions in the tetracaine-injected (left) hemispheres (Fig.5d). This effect becomes very clear when expressed as the interhemisphericzif-268 expression ratio, indicating significantly lower zif-268expression in tetracaine-injected than in saline-injected hemispheres(ratio values are significantly <1 for the EC, Au, and LaD inFig. 5e) (one-way ANOVA; F_(6,21) = 13.72; p < 0.0001; followedby Bonferroni post hoc tests). No effect on zif-268 expressionin these same areas was seen when comparable hippocampal tetracaineinjections were applied during WK (Fig. 5f,g) (one-way ANOVA;F_(6,21) = 1.78; p = 0.15). Thus, extrahippocampal zif-268 expressionduring WK is primarily independent of hippocampal activity, presumablybecause of the intense thalamocortical processing that characterizesWK. This also indicates that the ipsilateral blockade of zif-268reinduction during REM sleep in the cortex and amygdala of tetracaine-injectedanimals cannot be explained by diffusion of tetracaine from theinjection site. Therefore, extrahippocampal zif-268 reinductionduring early REM sleep requires an activehippocampus.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experience-dependent zif-268 reinduction during REM sleep

We have shown for the first time that: (1) zif-268 is reinduced during REM sleep in extrahippocampal regions after the inductionof hippocampal LTP during WK; (2) zif-268 reinduction occurs predominantlyin the amygdala, entorhinal, and auditory cortices during thefirst REM sleep episodes after LTP induction and reaches somatosensoryand motor cortices as REM sleep recurs; and (3) extrahippocampalzif-268 reinduction during REM sleep requires concurrent hippocampalactivity. These results extend our previous report that zif-268is upregulated during REM sleep in the brains of animals exposedpreviously to a novel enriched environment but not in unstimulatedcontrols (Ribeiro et al., 1999). The LTP-inducing HFS protocolprovided a spatially more discrete and standardized stimulationparadigm, inducing gene expression in a more specific anatomicalpathway downstream of the stimulation site, compared with thewidespread brain activity associated with the enriched environmentparadigm. The stimulation was also more discrete temporally, allowinga better dissection of the kinetics of generegulation.

Our results are seemingly at odds with several studies showing that sleep downregulates the expression of immediate-earlygenes (IEG) (Pompeiano et al., 1992, 1994; O'Hara et al., 1993;Basheer et al., 1997; Cirelli and Tononi, 1998). Two factors mightexplain this discrepancy. First, these studies did not attemptto separate the specific contributions of SWS and REM sleep toIEG expression. We have found that indeed a marked decrease inzif-268 expression occurs during SWS, regardless of the precedingWK experience. Therefore, the postsleep zif-268 downregulationreported previously (O'Hara et al., 1993; Pompeiano et al., 1994;Cirelli and Tononi, 1998) likely reflects the natural predominanceof SWS over REM sleep in spontaneous sleep episodes (Timo-Iariaet al., 1970; Hobson, 1995). Second and perhaps more importantly,those studies did not examine the effect of exposing animals torelevant WK experience a few hours before the sleep episodes investigated.Thus, their results likely correspond to the zif-268 downregulationthat we find in association with SWS and REM sleep in unstimulatedcontrol groups (Figs. 3b, 4a).

Another important point regards the mechanisms underlying experience-dependent zif-268 upregulation during REM sleep. Cirelliet al. (1996) have shown that IEG expression in the brain is dependenton the integrity of the noradrenergic nucleus locus ceruleus,leading the authors to propose that a general decrease in neuronalexcitability attributable to the silencing of the locus ceruleusduring sleep (Aston-Jones and Bloom, 1981) causes a sleep-relateddecrease in IEG expression. This rationale accounts well for theSWS/REM sleep downregulation of zif-268 observed in unstimulatedanimals but not for the gene upregulation seen during REM sleepin exposed animals. At least three hypotheses can be formulatedto reconcile the lack of locus ceruleus activity during REM sleepwith concurrent zif-268 upregulation. The most parsimonious regardscholinergic transmission, which is very robust during REM sleep(Hobson, 1992; Williams et al., 1994) and could in principle compensatefor the lack of noradrenaline, setting in motion molecular cascadesthat would result in the upregulation of zif-268 (Greenberg etal., 1986; Shiromani et al., 1992). Another possibility is thatthe locus ceruleus actually releases noradrenaline during REMsleep that follows relevant WK experience, either via subthresholdactivity or through experience-dependent neuronal firing. Althoughless likely than the previous one, this specific hypothesis hasyet to be tested. Finally, it is possible that zif-268 reinductionduring REM sleep is triggered in an experience-dependent mannerduring the transition between REM sleep and subsequent WK, a briefmoment in which REM-associated neuronal activity and noradrenalinerelease might coexist in space andtime.

Hippocampal interactions with the cerebral cortex and amygdala during REM sleep

Considering the known neuroanatomical circuitry downstream of the DG (Lopes da Silva et al., 1990; Paxinos, 1995), our resultsreveal a sequence of three spatiotemporally distinct waves ofzif-268 upregulation after the induction of LTP (Fig. 6). Thefirst begins locally at the stimulation site (DG) ~30 min afterthe application of HFS, reaches proximal brain areas relativeto the stimulation site (CA, Au, and LaD) after 3 hr of sustainedwakefulness (early WK), and is terminated during early SWS. Asecond wave begins during early REM sleep predominantly in brainregions proximal to the stimulus site (EC, Au, and LaD), propagatesto distal brain regions (S1 and M1) during late WK, and is terminatedduring late SWS. Finally, a third wave of zif-268 upregulationbegins during late REM sleep in all proximal (EC, Au, and LaD)and distal (S1 and M1) extrahippocampal regions studied. Althoughlater time points were not investigated, our data suggest thatthis third wave extends through WK that follows late REM sleep,being terminated during ensuing SWS. Notice that hippocampal regions(DG and CA) show a gradual decrease in zif-268 expression fromthe first to the second and third waves. Conversely, the mostdistal extrahippocampal region studied (M1), several synapsesaway from the site of HFS application, shows an opposite geneexpression profile: a gradual increase in zif-268 expression fromthe first to the second and third waves. These results indicatethat hippocampal LTP induction during WK leads to a series ofzif-268 upregulation waves that propagate from the hippocampusto cortical areas during the course of WK and REM sleep but thatare terminated during SWS.

View larger version (18K):
[in this window]
[in a new window]
Figure 6. Hippocampal LTP is followed by a series of zif-268 induction waves that progressively disengage the hippocampus and engage the cerebral cortex and the amygdala as the wake-sleep cycle recurs. Shown is a diagram of zif-268 expression across states, organized according to the intrinsic and extrinsic connectivity of the hippocampus with brain areas showing zif-268 reinduction. The mean ratios of zif-268 expression across successive states (HFS/30' over control/WK; HFS/early WK over HFS/ 30'; HFS/early SWS over HFS/early WK, etc.) are plotted in color according to the key at the top. Panels are labeled with the name of the later state. Boxes, Brain regions; arrows, connections between them. Three distinct waves of experience-dependent zif-268 upregulation generated during REM sleep or WK and separated by periods of SWS-associated gene downregulation were observed.

To the extent that zif-268 expression reflects synaptic activation occurring during a restricted time window before kill,we provide evidence that a significant increase in synaptic activityoccurs in several extrahippocampal brain areas during REM sleepthat follows induction of hippocampal LTP. Furthermore, extrahippocampalactivation during REM sleep is dependent on concurrent hippocampalactivity, suggesting the existence of a hippocampofugal processof cortical and amygdalar activation during REM sleep. Althoughadditional experimentation is required to determine whether distalzif-268 upregulation during late REM sleep depends on proximalgene upregulation during early REM sleep, the spatiotemporal patternof zif-268 expression and the effects of hippocampal inactivationon proximal extrahippocampal zif-268 expression suggest that brainreactivation during REM sleep occurs sequentially, initially inbrain regions proximal to the hippocampus and later reaching moredistalsites.

Independent lines of evidence show that although several kinds of memory initially depend on the hippocampus, such memoriesgradually become hippocampus-independent and correspondingly morereliant on the cerebral cortex for long-term storage (Scovilleand Milner, 1957; Mishkin, 1978; Kesner and Novak, 1982; Squire,1992; Izquierdo and Medina, 1997; Bontempi et al., 1999). Basedon our findings, we suggest that REM sleep may constitute a privilegedwindow for hippocampus-driven cortical activation, free from wakinginterference, and, in principle, capable of playing an instructiverole in the communication of memory traces from the hippocampusto the cortex. The fact that zif-268 reinduction is anatomicallymore extensive in late than in early REM sleep is especially interestingconsidering that late but not early post-training REM episodesare crucial for learning (Smith and Rose, 1996; Stickgold et al.,2000b). It is also noteworthy that the LaD shows significantlyhigh levels of zif-268 expression during late WK and REM. Thisobservation adds to the evidence that the amygdala plays a sustainedrole in information processing after the initial phase of LTPor behavioral learning (Ben-Ari and Le Gal la Salle, 1972; Izquierdoand Medina, 1997; Rogan et al., 1997; McGaugh, 2000).

Although the exact relationship between brain activation and ensuing activity-dependent gene expression is still a matterof some debate, it is important to note that zif-268 encodes atranscriptional regulator (Milbrandt, 1987; Sukhatme et al., 1988)that controls the expression of several target genes, some ofwhich are involved in various aspects of neuronal function andplasticity. For example, zif-268 regulates the expression of synapsins(Thiel et al., 1994; Petersohn et al., 1995), the most abundantproteins of synapses, with a key function in neurotransmission(De Camilli, 1995). By coupling neuronal activation to the upregulationof cell components such as synapsins, zif-268 may play an importantrole in the regulation of activity-dependent synaptic plasticity.This notion is supported by the fact that zif-268 expression isincreased in brain regions that undergo dendritic changes afterexposure to an enriched environment (Wallace et al., 1995) andin association with novelty/learning behavioral paradigms (Melloet al., 1992; Nikolaev et al., 1992; Jarvis et al., 1995) andhippocampal LTP induction (Cole et al., 1989; Wisden et al., 1990).Most compellingly, zif-268 expression has been shown to be necessaryfor the long-term maintenance of hippocampal LTP and differenttypes of spatial and nonspatial memories (Jones et al., 2001).Because the consolidation of memories most likely requires modification,addition, and/or extinction of synapses (Bliss and Collingridge,1993), it is plausible that experience-dependent brain reactivationduring REM sleep (Pavlides and Winson, 1989; Maquet et al., 2000;Poe et al., 2000a; Louie and Wilson, 2001) contributes to theformation of long-lasting memories through the upregulation ofactivity-dependent genes associated with synaptic plasticity.More specifically, hippocampofugal zif-268 upregulation duringREM sleep may reflect the propagation of calcium-dependent postsynapticchanges from the hippocampus to cortical and amygdalar networks,seemingly a crucial step for the consolidation of long-term memories(Frankland et al., 2001).

  FOOTNOTES

Received July 19, 2002; revised Oct. 4, 2002; accepted Oct. 4, 2002.

This work was supported by a Pew Latin American Fellowship (S.R.), a Whitehall Foundation grant (E.D.J., C.P.), a NationalInstitute on Deafness and Other Communication Disorders grant(C.V.M.), and National Heart, Lung, and Blood Institute Grant1 R01 HL69699-01 (C.P.). We thank D. Chialvo, C. Braham, D. Gervasoni,R. Crist, R. Costa, I. Araújo, M. Frank, S. Oster, S. Neuenschwander,and W. Singer for insightful criticism of these results and/orthis manuscript; G. Oksman, J. Pantoja, M. Rivas, A. Warren-Gregory,and J. Gyrda for assistance with data collection; D. Katz forstatistical advice; and M. Nicolelis, F. Nottebohm, and J. Hudspethfor their support and encouragement. This study is dedicated toProfessors Gustavo de O. Castro (in memoriam) and JonathanWinson.

Correspondence should be addressed to Sidarta Ribeiro, Department of Neurobiology, Duke University Medical Center, Box 3209,Durham, NC 27710. E-mail: ribeiro{at}neuro.duke.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Aston-Jones G, Bloom FE (1981) Activity of norepinephrine-containing locus ceruleus neurons in behaving rats anticipates fluctuations in the sleep-waking cycle. J Neurosci 1:876-886[Abstract].
Basheer R, Sherin JE, Saper CB, Morgan JI, McCarley RW, Shiromani PJ (1997) Effects of sleep on wake-induced c-fos expression. J Neurosci 17:9746-9750[Abstract/Free Full Text].
Ben-Ari Y, Le Gal la Salle G (1972) Plasticity at unitary level. II. Modifications during sensory-sensory association procedures. Electroencephalogr Clin Neurophysiol 32:667-679[Medline].
Bliss TV, Collingridge GL (1993) A synaptic model of memory: long-term potentiation in the hippocampus. Nature 361:31-39[Medline].
Bliss TV, Lomo T (1973) Long-lasting potentiation of synaptic transmission in the dentate area of the anaesthetized rabbit following stimulation of the perforant path. J Physiol (Lond) 232:331-356[Abstract/Free Full Text].
Bontempi B, Laurent-Demir C, Destrade C, Jaffard R (1999) Time-dependent reorganization of brain circuitry underlying long-term memory storage. Nature 400:671-675[Medline].
Campbell IG, Guinan MJ, Horowitz JM (2002) Sleep deprivation impairs long-term potentiation in rat hippocampal slices. J Neurophysiol 88:1073-1076[Abstract/Free Full Text].
Cirelli C, Tononi G (1998) Differences in gene expression between sleep and waking as revealed by mRNA differential display. Brain Res Mol Brain Res 56:293-305[Medline].
Cirelli C, Pompeiano M, Tononi G (1996) Neuronal gene expression in the waking state: a role for the locus coeruleus. Science 274:1211-1215[Abstract/Free Full Text].
Cole AJ, Saffen DW, Baraban JM, Worley PF (1989) Rapid increase of an immediate early gene messenger RNA in hippocampal neurons by synaptic NMDA receptor activation. Nature 340:474-476[Medline].
Cullinan WE, Herman JP, Battaglia DF, Akil H, Watson SJ (1995) Pattern and time course of immediate early gene expression in rat brain following acute stress. Neuroscience 64:477-505[ISI][Medline].
De Camilli P (1995) Neurotransmission. Keeping synapses up to speed. Nature 375:450-451[Medline].
Fishbein W, Gutwein BM (1977) Paradoxical sleep and memory storage processes. Behav Biol 19:425-464[ISI][Medline].
Frank MG, Issa NP, Stryker MP (2001) Sleep enhances plasticity in the developing visual cortex. Neuron 30:275-287[ISI][Medline].
Frankland PW, O'Brien C, Ohno M, Kirkwood A, Silva AJ (2001) $alpha$ -CaMKII-dependent plasticity in the cortex is required for permanent memory. Nature 411:309-313[Medline].
Greenberg ME, Ziff EB, Greene LA (1986) Stimulation of neuronal acetylcholine receptors induces rapid gene transcription. Science 234:80-83[Abstract/Free Full Text].
Hennevin E, Hars B, Maho C, Bloch V (1995) Processing of learned information in paradoxical sleep: relevance for memory. Behav Brain Res 69:125-135[ISI][Medline].
Hobson JA (1992) Sleep and dreaming: induction and mediation of REM sleep by cholinergic mechanisms. Curr Opin Neurobiol 2:759-763[Medline].
Hobson JA (1995) In: Sleep. Scientific American Library. New York: Freeman.
Idzikowski C (1984) Sleep and memory. Br J Psychol 75:439-449.
Izquierdo I, Medina JH (1997) Memory formation: the sequence of biochemical events in the hippocampus and its connection to activity in other brain structures. Neurobiol Learn Mem 68:285-316[ISI][Medline].
Jarvis ED, Mello CV, Nottebohm F (1995) Associative learning and stimulus novelty influence the song-induced expression of an immediate early gene in the canary forebrain. Learn Mem 2:62-80[Abstract/Free Full Text].
Jones MW, Errington ML, French PJ, Fine A, Bliss TV, Garel S, Charnay P, Bozon B, Laroche S, Davis S (2001) A requirement for the immediate early gene Zif268 in the expression of late LTP and long-term memories. Nat Neurosci 4:289-296[ISI][Medline].
Karni A, Tanne D, Rubenstein BS, Askenasy JJ, Sagi D (1994) Dependence on REM sleep of overnight improvement of a perceptual skill. Science 265:679-682[Abstract/Free Full Text].
Kesner RP, Novak JM (1982) Serial position curve in rats: role of the dorsal hippocampus. Science 218:173-175[Abstract/Free Full Text].
Lopes da Silva FH, Witter MP, Boeijinga PH, Lohman AH (1990) Anatomic organization and physiology of the limbic cortex. Physiol Rev 70:453-511[Free Full Text].
Louie K, Wilson MA (2001) Temporally structured replay of awake hippocampal ensemble activity during rapid eye movement sleep. Neuron 29:145-156[ISI][Medline].
Maquet P (2001) The role of sleep in learning and memory. Science 294:1048-1052[Abstract/Free Full Text].
Maquet P, Laureys S, Peigneux P, Fuchs S, Petiau C, Phillips C, Aerts J, Del Fiore G, Degueldre C, Meulemans T, Luxen A, Franck G, Van Der Linden M, Smith C, Cleeremans A (2000) Experience-dependent changes in cerebral activation during human REM sleep. Nat Neurosci 3:831-836[ISI][Medline].
McGaugh JL (2000) Memory-a century of consolidation. Science 287:248-251[Abstract/Free Full Text].
Mello CV, Clayton DF (1995) Differential induction of the ZENK gene in the avian forebrain and song control circuit after metrazole-induced depolarization. J Neurobiol 26:145-161[ISI][Medline].
Mello CV, Vicario DS, Clayton DF (1992) Song presentation induces gene expression in the songbird forebrain. Proc Natl Acad Sci USA 89:6818-6822[Abstract/Free Full Text].
Milbrandt J (1987) A nerve growth factor-induced gene encodes a possible transcriptional regulatory factor. Science 238:797-799[Abstract/Free Full Text].
Mishkin M (1978) Memory in monkeys severely impaired by combined but not by separate removal of amygdala and hippocampus. Nature 273:297-298[Medline].
Nikolaev E, Kaminska B, Tischmeyer W, Matthies H, Kaczmarek L (1992) Induction of expression of genes encoding transcription factors in the rat brain elicited by behavioral training. Brain Res Bull 28:479-484[ISI][Medline].
O'Hara BF, Young KA, Watson FL, Heller HC, Kilduff TS (1993) Immediate early gene expression in brain during sleep deprivation: preliminary observations. Sleep 16:1-7[ISI][Medline].
Pavlides C, Winson J (1989) Influences of hippocampal place cell firing in the awake state on the activity of these cells during subsequent sleep episodes. J Neurosci 9:2907-2918[Abstract].
Paxinos G (1995) In: The rat nervous system, Ed 2. San Diego: Academic.
Paxinos G, Watson C (1997) In: The rat brain in stereotaxic coordinates, Ed 3. San Diego: Academic.
Pearlman C, Becker M (1974) REM sleep deprivation impairs bar-press acquisition in rats. Physiol Behav 13:813-817[Medline].
Petersohn D, Schoch S, Brinkmann DR, Thiel G (1995) The human synapsin II gene promoter. Possible role for the transcription factor zif268/egr-1, polyoma enhancer activator 3, and AP2. J Biol Chem 270:24361-24369[Abstract/Free Full Text].
Poe GR, Nitz DA, McNaughton BL, Barnes CA (2000a) Experience-dependent phase-reversal of hippocampal neuron firing during REM sleep. Brain Res 855:176-180[ISI][Medline].
Poe GR, Teed RG, Insel N, White R, McNaughton BL, Barnes CA (2000b) Partial hippocampal inactivation: effects on spatial memory performance in aged and young rats. Behav Neurosci 114:940-949[ISI][Medline].
Pompeiano M, Cirelli C, Tononi G (1992) Effects of sleep deprivation on fos-like immunoreactivity in the rat brain. Arch Ital Biol 130:325-335[ISI][Medline].
Pompeiano M, Cirelli C, Tononi G (1994) Immediate-early genes in spontaneous wakefulness and sleep: expression of c-fos and NGIF-A mRNA protein. J Sleep Res 3:80-96[ISI][Medline].
Ribeiro S, Goyal V, Mello CV, Pavlides C (1999) Brain gene expression during REM sleep depends on prior waking experience. Learn Mem 6:500-508[Abstract/Free Full Text].
Rogan MT, Staubli UV, LeDoux JE (1997) Fear conditioning induces associative long-term potentiation in the amygdala. Nature 390:604-607[Medline].
Scoville WB, Milner B (1957) Loss of recent memory after bilateral hippocampal lesions. J Neurol Neurosurg Psychiatry 20:11-21[ISI][Medline].
Shiromani PJ, Kilduff TS, Bloom FE, McCarley RW (1992) Cholinergically induced REM sleep triggers Fos-like immunoreactivity in dorsolateral pontine regions associated with REM sleep. Brain Res 580:351-357[ISI][Medline].
Siegel JM (2001) The REM sleep-memory consolidation hypothesis. Science 294:1058-1063[Abstract/Free Full Text].
Smith C (1996) Sleep states, memory processes, and synaptic plasticity. Behav Brain Res 78:49-56[ISI][Medline].
Smith C, Butler S (1982) Paradoxical sleep at selective times following training is necessary for learning. Physiol Behav 29:469-473[Medline].
Smith C, Kelly G (1988) Paradoxical sleep deprivation applied two days after end of training retards learning. Physiol Behav 43:213-216[Medline].
Smith C, Rose GM (1996) Evidence for a paradoxical sleep window for place learning in the Morris water maze. Physiol Behav 59:93-97[Medline].
Squire LR (1992) Memory and the hippocampus: a synthesis from findings with rats, monkeys, and humans. Psychol Rev 99:195-231[ISI][Medline].
Stickgold R, James L, Hobson JA (2000a) Visual discrimination learning requires sleep after training. Nat Neurosci 3:1237-1238[ISI][Medline].
Stickgold R, Whidbee D, Schirmer B, Patel V, Hobson JA (2000b) Visual discrimination task improvement: a multi-step process occurring during sleep. J Cogn Neurosci 12:246-254[Abstract/Free Full Text].
Stickgold R, Hobson JA, Fosse R, Fosse M (2001) Sleep, learning, and dreams: off-line memory reprocessing. Science 294:1052-1057[Abstract/Free Full Text].
Sukhatme VP, Cao XM, Chang LC, Tsai-Morris CH, Stamenkovich D, Ferreira PC, Cohen DR, Edwards SA, Shows TB, Curran T, Le Beau MM, Adamson ED (1988) A zinc finger-encoding gene coregulated with c-fos during growth and differentiation, and after cellular depolarization. Cell 53:37-43[ISI][Medline].
Thiel G, Schoch S, Petersohn D (1994) Regulation of synapsin I gene expression by the zinc finger transcription factor zif268/egr-1. J Biol Chem 269:15294-15301[Abstract/Free Full Text].
Thomson D (1982) Spectrum estimation and harmonic analysis. Proc IEEE 70:1055-1096.
Timo-Iaria C, Negrao N, Schmidek WR, Hoshino K, Lobato de Menezes CE, Leme da Rocha T (1970) Phases and states of sleep in the rat. Physiol Behav 5:1057-1062[Medline].
Wallace CS, Withers GS, Weiler IJ, George JM, Clayton DF, Greenough WT (1995) Correspondence between sites of NGFI-A induction and sites of morphological plasticity following exposure to environmental complexity. Brain Res Mol Brain Res 32:211-220[Medline].
Williams JA, Comisarow J, Day J, Fibiger HC, Reiner PB (1994) State-dependent release of acetylcholine in rat thalamus measured by in vivo microdialysis. J Neurosci 14:5236-5242[Abstract].
Winson J (1985) In: Brain and psyche. New York: Anchor.
Winson J, Dahl D (1986) Long-term potentiation in dentate gyrus: induction by asynchronous volleys in separate afferents. Science 234:985-988[Abstract/Free Full Text].
Wisden W, Errington ML, Williams S, Dunnett SB, Waters C, Hitchcock D, Evan G, Bliss TV, Hunt SP (1990) Differential expression of immediate early genes in the hippocampus and spinal cord. Neuron 4:603-614[ISI][Medline].
Worley PF, Bhat RV, Baraban JM, Erickson CA, McNaughton BL, Barnes CA (1993) Thresholds for synaptic activation of transcription factors in hippocampus: correlation with long-term enhancement. J Neurosci 13:4776-4786[Abstract].

Copyright © 2002 Society for Neuroscience 0270-6474/02/222410914-10$05.00/0

This article has been cited by other articles: