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The Journal of Neuroscience, September 15, 2002, 22(18):7840-7843
BRIEF COMMUNICATION
Environmental Enrichment Reverses the Effects of Maternal Separation on Stress ReactivityDarlene D. Francis1, Josie Diorio1, Paul M. Plotsky2, and Michael J. Meaney1 1 Developmental Neuroendocrinology Laboratory, Douglas Hospital Research Centre, Departments of Psychiatry, and Neurology and Neurosurgery, McGill University, Montréal, Québec H4H 1R3, Canada, and 2 Department of Psychiatry and Behavioral Science, Emory University, Atlanta, Georgia 30322
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Postnatal maternal separation increases hypothalamic corticotropin-releasing factor (CRF) gene expression and hypothalamic-pituitary-adrenal (HPA) and behavioral responses to stress. We report here that environmental enrichment during the peripubertal period completely reverses the effects of maternal separation on both HPA and behavioral responses to stress, with no effect on CRF mRNA expression. We conclude that environmental enrichment leads to a functional reversal of the effects of maternal separation through compensation for, rather than reversal of, the neural effects of early life adversity.
Key words: early experience; environmental enrichment; maternal separation; stress; corticotropin-releasing factor; glucocorticoid receptors
INTRODUCTION
In rodents or nonhuman primates, prolonged periods of maternal separation (MS) in early life increase the magnitude of neuroendocrine and fear responses to stress and thus vulnerability for stress-related illness (Higley et al., 1991
; Plotsky and Meaney, 1993
Postnatal MS (3 hr/d; days 2-14 of life) enhances HPA responses to stressors (Plotsky and Meaney, 1993
To examine the question of reversibility, animals were exposed to either handling or MS daily for the first 2 weeks of life. At the time of weaning, animals were then transferred into conditions of either environmental enrichment or standard social housing until day 70. In adulthood, the animals were tested for the reversal of early life conditions at the level of both function (behavioral and HPA responses to stress) and mechanism (CRF and GR mRNA expression).
MATERIALS AND METHODS
Animals. Litters from pregnant Long-Evans rats from an in-house breeding colony of Charles River Laboratories (St. Constant, Québec, Canada) stock were standardized to 8-13 pups per dam and exposed to one of the following rearing conditions from days 1-14 inclusive: (1) handled (H) animals were exposed to a daily 15 min period in which the dam was removed to an adjacent cage and the litter removed and placed in an incubator or (2) MS in which dams and pups were treated in the same manner for a 180 min period of separation. Litters were removed as a group, weighed, and placed as a group into a plastic cage (15 × 15 cm) in an adjacent room lined with bedding material and contained within an incubator maintained at 32 ± 0.5°C (days 1-5) or 30 ± 0.5°C (days 6-14). After the separation period, pups were returned to the nest and rolled in home cage bedding material, and the dam was returned. In the rat, the mother is routinely off the litter for periods of 20-25 min (Jans and Woodside, 1990
Offspring were weaned on day 22 and housed in same-rearing groups under either standard or enriched conditions with food and water available ad libitum. Animals in the enrichment condition were housed in groups of eight animals within a series of large 60 × 30 × 60 cm cages interconnected with a burrow system and filled with toys that were replaced regularly. Standard laboratory conditions were defined as two animals housed in a 20 × 40 × 30 cm clear plastic cage. At 70 d of age, all animals were then housed in same-treatment groups, two per cage until testing began on day 110. All procedures were approved by the McGill University Animal Care Committee.
Behavioral testing. For the measures of novelty-induced suppression of appetitive behavior (Britton and Thatcher-Britton, 1981
Another set of animals were examined in an open-field test of exploration. Animals were placed, one at a time, in a novel, circular open field, 1.6 m in diameter for 5 min. The critical measure was the time (in seconds) the animal spent exploring the inner area of the novel arena. Exploration was defined as the entire body of the animal being away from the immediate vicinity of the wall (>10 cm) enclosing the open field. The open field was cleaned between each subject to prevent olfactory cues from affecting the behavior of subsequently tested rats.
Stress testing and blood sampling. Restraint stress was performed between 12:00 P.M. and 3:00 P.M. Prestress blood samples were taken from rats within 30 sec of removal from the cage, and restraint stress was performed between 12:00 P.M. and 3:00 P.M. with blood sampling (300 µl) from the tail vein at 0, 20, 60, and 120 min after the onset of restraint (Meaney et al., 1989
In situ hybridization. Brains were rapidly removed and frozen in isopentane (
70°C). Coronal sections (15 µm) were thaw mounted onto poly-D-lysine-coated slides and stored at
CRF mRNA in situ hybridization was performed using an 48 bp oligonucleotide sequence (CAG TTT CCT GTT GCT GTG AGC TTG CTG AGC TAA CTG CTC TGC CCT GGC). Slides were warmed to room temperature, postfixed in 4% paraformaldehyde in 0.1 phosphate buffer, pH 7.4 for 10 min, washed in 2× SSC in sterile water containing 0.2% diethylpyrocarbonate, rinsed once in TEA (triethanolamine and HCl)-2× SSC-0.25% acetic anhydride for 10 min and once in 2× SSC, dehydrated in increasing concentrations of ethanol, and placed in chloroform for 10 min and then 100 and 95% EtOH.
Hybridization was performed at 37°C for 18 hr in buffer containing 50% deionized formamide, 1.2 M NaCl, 20 mM Tris, pH 7.5, 100× Denhardt's solution, 20 mM EDTA, pH 8.0, 200 µg/ml denatured salmon sperm DNA, 200 µg/ml yeast tRNA, 10% dextran sulfate, 10 mM dithiothreitol, and 1 × 107 cpm/ml [35S]ATP-labeled CRF oligoprobe. Slides were washed four times for 30 min in 1× SSC at 55°C, rinsed briefly in water, dried, and apposed to Hyperfilm for 21 d along with sections of 35S-labeled standards prepared with known amounts of 35S in a brain paste.
Preparation of glucocorticoid receptor riboprobes as well as the in situ hybridization procedure and sense controls have been described previously (Liu et al., 1997
-mercaptoethanol) at 60°C. Sections were dehydrated in increasing concentrations of ethanol (in 0.3 M sodium acetate), dried, and apposed to Hyperfilm for 21 d along with sections of 35S-labeled standards.
The hybridization signal within the parvocellular subregion of the paraventricular nucleus of the hypothalamus (CRF mRNA) or the dorsal hippocampus (GR mRNA) was quantified using densitometry with an image analysis system (microcomputer imaging device; Imaging Research, St. Catherines, Ontario, Canada). The data are presented as arbitrary optical density (absorbance) units after correction for background. The anatomical level of analysis was verified using the rat brain atlas of Paxinos and Watson (1986)
Statistical analysis. Statistical comparisons were performed using the appropriate ANOVA model with Tukey's post hoc tests.
RESULTS
Enrichment reverses effects of MS on HPA function
Plasma corticosterone responses to stress were significantly greater in MS compared with H rats (Fig. 1a,b), and the group differences were completely eliminated among animals reared under conditions of environmental enrichment. Statistical analysis revealed a significant postnatal rearing × peripubertal rearing × time interaction (F = 5.5; df = 3,84; p < 0.05). Post hoc analysis revealed that plasma corticosterone levels during and after acute stress were significantly (p < 0.01) lower in H animals compared with control MS rats but not compared with MS rats exposed to environmental enrichment during the peripubertal period. There was no effect of peripubertal rearing condition on the HPA responses to stress in the H animals. For the area-under-the-curve analysis (Fig. 1b), the statistical analysis revealed a significant interaction between the postnatal and peripubertal rearing conditions (F = 20.8; df = 1,28; p < 0.0001), reflecting the significantly increased corticosterone levels in the MS control animals.
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Figure 1. a, Mean ± SEM plasma level of corticosterone (in micrograms per deciliters; n = 8 per group) in response to a 20 min period of restraint stress (open bar) in H and MS animals reared under standard lab procedures (Ctl) or environmental enrichment (EE) during postnatal days 22-70 and tested on days 110-120. b, Mean ± SEM area-under-the-curve analysis for the corticosterone data displayed in a calculated using the trapezoidal rule. c, Mean ± SEM time spent exploring the inner area of a 2 × 2 m novel open-field environment (n = 8-10 per group). d, Mean ± SEM latency to begin eating food presented to food-deprived animals in a novel environment (n = 8-9 per group). e, Mean ± SEM levels of glucocorticoid receptor mRNA in the dentate gyrus (DG) and CA1 and CA3 cell fields of the hippocampus, expressed as optical density units, on autoradiograms from in situ hybridization studies with a 35S-labeled riboprobe for the rat glucocorticoid receptor (n = 3-5 per group). f, Mean ± SEM levels of CRF mRNA in the paraventricular nucleus of the hypothalamus, expressed as optical density units, on autoradiograms from in situ hybridization studies with a 35S-labeled oligonucleotide probe for the rat CRF (n = 3-5 per group).
A similar pattern of results emerged from behavioral tests of fearfulness. Statistical analysis revealed a significant postnatal rearing × peripubertal rearing interaction (F = 5.0; df = 1,31; p < 0.05). Post hoc analysis revealed a significantly (p < 0.01) decreased exploration in the MS control animals. In an open-field test of exploration, H animals as well as MS-environmental enrichment animals spent significantly more time exploring the inner area of the novel environment than did control MS rats (Fig. 1c). Likewise, there was a significant postnatal rearing × peripubertal rearing interaction (F = 5.0; df = 1,28; p < 0.05) in the test of novelty-induced suppression of appetitive behavior. There was a significantly (p < 0.01) increased novelty-induced suppression of feeding in the MS control animals when animals were food deprived for 24 hr and provided lab chow in a novel environment; H as well as MS-environmental enrichment animals ate more readily than did control MS rats (Fig. 1d). In each case, the control MS rats, unlike those reared in environmental enrichment, were more behaviorally inhibited under conditions of novelty. Thus, peripubertal environmental enrichment completely reversed the effects of postnatal MS on both HPA and behavioral responses to stress.
Enrichment does not reverse effects of MS on CRF gene expression
Environmental enrichment did not reverse the effects of MS on CRF gene expression We found significant effects only for the postnatal rearing condition on levels of either CRF mRNA in the PVNh or glucocorticoid receptor mRNA in the hippocampus. Environmental enrichment had no effect on either measure in the MS rats. For glucocorticoid receptor mRNA expression, there was a significant effect of postnatal rearing for each region (dentate gyrus, F = 16.5, df = 1,12, p < 0.005; CA1, F = 51.2, df = 1,12, p < 0.0001; CA3, F = 5.5, df = 1,12, p < 0.05) but no significant interaction effect. Likewise, the statistical analysis revealed a significant effect of postnatal rearing (F = 6.5; df = 1,12; p < 0.01) on CRF mRNA levels in the paraventricular region of the hypothalamus, with no significant interaction effect.
DISCUSSION
Child intervention programs in humans can serve to offset the risk associated with family stress for intellectual and emotional development, and such effects are most apparent in individuals whose development was compromised as a function of early life adversity (Ramey and Ramey, 1998
Animals studies reveal an apparent reversal of the effects of early life events. For example, postnatal handling reverses the effects of prenatal stress on the development of the HPA axis as well as on behavioral reactivity to stress (Maccari et al., 1995
These findings suggest that alterations in gene expression associated with MS are rather resistant to subsequent environmental influences. This finding may be related to the mechanisms underlying the changes in gene expression. In recent studies, we (Weaver et al., 2001
The nature of the proposed compensatory effect remains a matter of speculation, but the hippocampus and prefrontal cortex emerge as potentially interesting sites for consideration. Environmental enrichment alters frontal cortex function, and the medial prefrontal cortex provides inhibitory regulation over HPA responses to stress (Diorio et al., 1993
Although the nature of compensatory mechanisms is currently a matter of speculation, these findings clearly suggest that the development of individual differences in behavioral and neuroendocrine responses to stress can be influenced by events occurring at multiple stages in development, including the peripubertal period, and that these effects occur as a result of alterations at different levels with the relevant neural systems. Effects at later stages in development might then serve to effectively compensate for the influence of adversity in earlier stages of development. Moreover, the environmental effects occurring at one stage of development appear to depend on previous forms of experience. The current data are clear in suggesting that possible compensatory effects derived from enrichment can serve to mask the effects of previous adversity. The question now lies in the identification of these processes and the mechanisms by which they serve to mask effects from earlier events. The data presented here are consistent with a hierarchical organization within neural systems that regulate behavioral and endocrine stress responses, suggesting that later developing systems, or at least systems with a more prolonged period of plasticity, can serve to override effects at other levels within the system.
FOOTNOTES Received Jan. 23, 2002; revised June 11, 2002; accepted June 27, 2002.
This work was supported by grants from the National Institute of Mental Health (P.M.P., M.J.M) and the Canadian Institutes for Health Research (M.J.M.). M.J.M. holds a Senior Scientist award, and D.D.F. holds a postdoctoral fellowship from the Canadian Institutes for Health Research.
Correspondence should be addressed to Michael J. Meaney, Developmental Neuroendocrinology Laboratory, Douglas Hospital Research Centre, 6875 Boulevard LaSalle, Montréal, Québec H4H 1R3, Canada. E-mail: michael.meaney{at}mcgill.ca.
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