A behavioural characterization of neonatal infection-facilitated memory impairment in adult rats

We have reported that exposure to bacteria (Escherichia coli) during the neonatal period in rats is associated with impaired memory for a novel context in adulthood. However, impairment is only observed if a peripheral immune challenge (bacterial lipopolysaccharide (LPS)) is administered immediately following context exposure. The goal of the current study was to more fully characterize this phenomenon. In Experiment 1, memory impairment as a result of neonatal infection and subsequent LPS challenge was observed in juvenile rats, indicating that the changes induced by infection occur early on and are then manifest throughout the lifespan. In Experiment 2, infection in juvenile rats did not lead to LPS-induced memory impairment in adulthood, suggesting there is a critical period for early infection-induced alterations. In Experiments 3 and 4, memory for a novel context was impaired in neonatally infected rats, a task that is dependent on the hippocampus, whereas cued memory for a tone, which does not depend on the hippocampus, was not impaired. Furthermore, long-term, but not short-term contextual memory was impaired in adult rats infected as neonates following an LPS challenge either 24 h before or immediately after conditioning. Finally, in Experiment 5, no neonatal group differences were observed in corticosterone or open field behaviour, suggesting that decreased freezing to a conditioned context reflects impaired memory, and not simply hyperactivity or altered stress reactivity. Taken together, we have demonstrated that neonatal infection results in robust hippocampal-dependent memory impairment following an immune challenge in adulthood using a number of conditioning paradigms.     

Microglia and memory: modulation by early-life infection

The proinflammatory cytokine interleukin-1β (IL-1β) is critical for normal hippocampus (HP)-dependent cognition, whereas high levels can disrupt memory and are implicated in neurodegeneration. However, the cellular source of IL-1β during learning has not been shown, and little is known about the risk factors leading to cytokine dysregulation within the HP. We have reported that neonatal bacterial infection in rats leads to marked HP-dependent memory deficits in adulthood. However, deficits are only observed if unmasked by a subsequent immune challenge [lipopolysaccharide (LPS)] around the time of learning. These data implicate a long-term change within the immune system that, upon activation with the "second hit," LPS, acutely impacts the neural processes underlying memory. Indeed, inhibiting brain IL-1β before the LPS challenge prevents memory impairment in neonatally infected (NI) rats. We aimed to determine the cellular source of IL-1β during normal learning and thereby lend insight into the mechanism by which this cytokine is enduringly altered by early-life infection. We show for the first time that CD11b(+) enriched cells are the source of IL-1β during normal HP-dependent learning. CD11b(+) cells from NI rats are functionally sensitized within the adult HP and produce exaggerated IL-1β ex vivo compared with controls. However, an exaggerated IL-1β response in vivo requires LPS before learning. Moreover, preventing microglial activation during learning prevents memory impairment in NI rats, even following an LPS challenge. Thus, early-life events can significantly modulate normal learning-dependent cytokine activity within the HP, via a specific, enduring impact on brain microglial function.     

Early-life infection leads to altered BDNF and IL-1beta mRNA expression in rat hippocampus following learning in adulthood

Neonatal bacterial infection in rats leads to profound hippocampal-dependent memory impairments following a peripheral immune challenge in adulthood. Here, we determined whether neonatal infection plus an immune challenge in adult rats is associated with impaired induction of brain-derived neurotrophic factor (BDNF) within the hippocampus (CA1, CA3, and dentate gyrus) following fear conditioning. BDNF is well characterized for its critical role in learning and memory. Rats injected on postnatal day 4 with PBS (vehicle) or Escherichia coli received as adults either no conditioning or a single 2min trial of fear conditioning. Half of the rats in the conditioned group then received a peripheral injection of 25mug/kg lipopolysaccharide (LPS) and all were sacrificed 1 or 4h later. Basal (unconditioned) BDNF mRNA did not differ between groups. However, following conditioning, neonatal infection with E. coli led to decreased BDNF mRNA induction in all regions compared to PBS-treated rats. This decrease in E. coli-treated rats was accompanied by a large increase in IL-1beta mRNA in CA1. Taken together, these data indicate that early infection strongly influences the induction of IL-1beta and BDNF within distinct regions of the hippocampus, which likely contribute to observed memory impairments in adulthood.     

Neonatal maternal separation alters the development of glucocorticoid receptor expression in the interpositus nucleus of the cerebellum

Adverse early experience impairs adult learning and memory. Previously, we showed that neonatal maternal separation impaired eyeblink conditioning in adult male rats. This impairment was correlated with increases in glucocorticoid receptor expression in the posterior region of the cerebellar interpositus nucleus, a key structure in the neural circuitry controlling eyeblink conditioning. To begin to establish how separation results in altered glucocorticoid receptor expression in adulthood, we assessed the developmental pattern of glucocorticoid receptor expression in the interpositus nucleus in controls versus rats that had undergone maternal separation for 1 h per day on postnatal days 2–14. Rat pups were exposed to either standard rearing (control) or maternal separation and glucocorticoid receptor expression was assessed at postnatal day 15, postnatal day 21, and adulthood. In control males, glucocorticoid receptor expression in the interpositus nucleus declined between postnatal days 15 and 21, then increased into adulthood. On postnatal day 15, there was less glucocorticoid receptor expression in the interpositus nucleus in males that were maternally separated than in controls. However, neonatal separation significantly attenuated the normal decline in the third postnatal week, resulting in significantly greater glucocorticoid receptor expression in the interpositus in separated males than in control rats at postnatal day 21. The developmental pattern of glucocorticoid receptor expression was not altered by maternal separation in female rats. Thus, maternal separation may impair learning and memory in adult males by altering normal developmental changes in glucocorticoid receptor expression.     

Neonatal handling affects learning, reversal learning and antioxidant enzymes activities in a sex-specific manner in rats

Early life experiences have profound influences on behavior and neurochemical parameters in adult life. The aim of this study is to verify neonatal handling-induced sex specific differences on learning and reversal learning as well as oxidative stress parameters in the prefrontal cortex and striatum of adult rats. Litters of rats were non-handled or handled (10 min/day, days 1-10 after birth). In adulthood, learning and reversal learning were evaluated using a Y maze associated with palatable food in male and female rats. Morris water maze reversal learning was verified in males. Oxidative stress parameters were evaluated in both genders. Male neonatal handled animals had a worse performance in the Y maze reversal learning compared to non-handled ones and no difference was observed in the water maze reversal learning task. Regarding females, neonatal handled rats had a better performance during the Y maze learning phase compared to non-handled ones. In addition, neonatal handled female animals showed a decreased SOD/CAT ratio in the PFC compared to non-handled females. We conclude that neonatal handling effects on learning and memory in adult rats are sex and task specific. The sex specific differences are also observed in the evaluation of antioxidant enzymes activities with neonatal handling affecting only females.     

Maternal dietary zinc supplementation prevents aberrant behaviour in an object recognition task in mice offspring exposed to LPS in early pregnancy

Maternal infection during pregnancy is associated with an increased risk of neurodevelopmental damage. While the mechanism is unclear accumulating evidence suggests that the maternal inflammatory response may be responsible. Metallothionein (MT) is a zinc (Zn)-binding protein that when induced in the mother's liver during the acute phase response has been found to cause a fetal Zn deficiency. Infection-mediated fetal Zn deficiency in early pregnancy has been shown to cause teratogenicity which can be prevented by dietary Zn supplementation throughout pregnancy. This study examined whether cognitive impairments can be caused by lipopolysaccharide (LPS) administration early in pregnancy and whether dietary Zn supplementation can ameliorate these changes. Maternal inflammation induced by LPS at gestation day (GD) 8 did not affect spatial learning or memory of adult mice offspring in a water cross-maze escape task. However, in an object recognition task, where control mice demonstrated good visual recognition memory by exploring a novel object more than a familiar object, LPS-treated offspring demonstrated abnormal perseverant exploration towards the familiar object that cannot be explained in full by impaired object recognition memory. In comparison, offspring of mice from dams given LPS and dietary Zn supplementation displayed normal object recognition task performance. Microarray analysis on the brain of GD 12 fetuses did not identify any differentially expressed genes between treatment groups. This study demonstrates that LPS administration in early pregnancy can cause an anomaly in object recognition that can be measured in adult offspring. This aberrant behaviour can be prevented by dietary Zn supplementation during pregnancy, thus providing a nutritional strategy to limit neurodevelopmental damage caused by infections early in pregnancy.     

Maternal immune activation increases seizure susceptibility in juvenile rat offspring

Epidemiological data suggest a relationship between maternal infection and a high incidence of childhood epilepsy in offspring. However, there is little experimental evidence that links maternal infection with later seizure susceptibility in juvenile offspring. Here, we asked whether maternal immune challenge during pregnancy can alter seizure susceptibility and seizure-associated brain damage in adolescence. Pregnant Sprague–Dawley rats were treated with lipopolysaccharide (LPS) or normal saline (NS) on gestational days 15 and 16. At postnatal day 21, seizure susceptibility to kainic acid (KA) was evaluated in male offspring. Four groups were studied, including normal control (NS–NS), prenatal infection (LPS–NS), juvenile seizure (NS–KA), and “two-hit” (LPS–KA) groups. Our results demonstrated that maternal LPS exposure caused long-term reactive astrogliosis and increased seizure susceptibility in juvenile rat offspring. Compared to the juvenile seizure group, animals in the “two-hit” group showed exaggerated astrogliosis, followed by worsened spatial learning ability in adulthood. In addition, prenatal immune challenge alone led to spatial learning impairment in offspring but had no effect on anxiety. These data suggest that prenatal immune challenge causes a long-term increase in juvenile seizure susceptibility and exacerbates seizure-induced brain injury, possibly by priming astroglia.     

Transgenerational transmission of anxiety induced by neonatal exposure to lipopolysaccharide: implications for male and female germ lines

Neonatal lipopolysaccharide (LPS) exposure increases anxiety-like behaviour and alters neuroendocrine responses to stress in adult rats. The current study assessed whether this anxiety-related phenotype observed in rats neonatally exposed to LPS is transferable to subsequent generations. Wistar rats were exposed to LPS (0.05 mg/kg, Salmonella enteritidis) or non-pyrogenic saline (equivolume) on postnatal days 3 and 5. In adulthood, animals were subjected to restraint and isolation stress or no stress, and subsequently evaluated for anxiety-like behaviours on the elevated plus maze, acoustic startle response, and holeboard apparatus. Blood was collected to examine corticosterone responses to stress and behavioural testing in adulthood. Animals from both treatment groups which exhibited the anxiety-like phenotype were bred with untreated partners. Maternal care of the second generation (F2) was monitored over the first week of life. In adulthood, the F2 generation underwent identical testing procedures as the parental (F1) generation. The F2 offspring of females exposed to LPS as neonates exhibited an anxiety-like phenotype in adulthood and a potentiated corticosterone response to stress (p<.05). F2 offspring of males exposed to LPS as neonates also exhibited an anxiety-like phenotype (p<.05), however, no differences in corticosterone responses were observed. To determine the impact of maternal care on the anxiety-like phenotype, a cross-fostering study was conducted in which offspring of LPS-treated females were fostered to saline-treated mothers and vice versa, which was found to reverse the behavioural and endocrine phenotypes of the F2 generation. These data indicate that a neonatally bacterially induced anxiety phenotype is transferable across generations in both sexes. Maternal care is the mediating mechanism along the maternal line. We suggest that transmission may be dependent upon heritable epigenetic phenomena for the paternal line. The implications of this study apply to potential neuroimmune pathways through which psychopathology may be transmitted along filial lines.     

Bacterial infection early in life protects against stressor-induced depressive-like symptoms in adult rats

Both early-life stress and immune system activation in adulthood have been linked independently to depression in a number of studies. However, the relationship between early-life infection, which may be considered a "stressor", and later-life depression has not been explored. We have reported that neonatal bacterial infection in rats leads to exaggerated brain cytokine production, as well as memory impairments, to a subsequent peripheral immune challenge in adulthood, and therefore predicted that stressor-induced depressive-like symptoms would be more severe in these rats as well. Rats treated on postnatal day 4 with PBS or Escherichia coli were as adults exposed to inescapable tailshock stress (IS), and then tested for sucrose preference, social exploration with a juvenile, and overall activity, 1, 3, 5, and 7 days following the stressor. Serum corticosterone and extracellular 5-HT within the basolateral amygdala were measured in a second group of rats in response to the IS. IS resulted in profound depressive-like behaviors in adult rats, but, surprisingly, rats that suffered a bacterial infection early in life had blunted corticosterone responses to the stressor and were remarkably protected from the depressive symptoms compared to controls. These data suggest that early-life infection should be considered within a cost/benefit perspective, in which outcomes in adulthood may be differentially protected or impaired. These data also suggest that the immune system likely plays a previously unsuspected role in "homeostatic" HPA programming and brain development, which may ultimately lend insight into the often-contradictory literature on cytokines, inflammation, and depression.     

Neonatal lipopolysaccharide induces pathological changes in parvalbumin immunoreactivity in the hippocampus of the rat

Early exposure to infection is known to affect brain development and has been linked to an increased risk for schizophrenia. The present study aimed to determine whether neonatal infection produced long-term disruptions in behaviour and pathology that might provide a parallel with that observed in schizophrenia. Rats were administered lipopolysaccharide (LPS; 500 μg/kg i.p.) on postnatal day 7 and 9. Locomotor activity and object recognition memory were tested at day 35 and day 70. LPS animals were observed to be less active at adulthood as measured by locomotor activity. With regards to object recognition memory, LPS administration produced no early impairment in task performance, however, at day 70 LPS animals spent significantly less time exploring the novel object than control animals. Analysis of brains showed a reduction in expression of parvalbumin immunoreactive neurons in the hippocampus of LPS animals with significant reductions selectively localised to the CA1–CA3 region, and not the dentate gyrus. No changes were observed in prefrontal cortex. These results show that neonatal LPS results in pathophysiological brain changes in hippocampal CA1–CA3 subregions.     

Acute nicotine treatment prevents rem sleep deprivation‐induced learning and memory impairment in rat

Rapid eye movement (REM) sleep deprivation (SD) is implicated in impairment of spatial learning and memory and hippocampal long‐term potentiation (LTP). An increase in nicotine consumption among habitual smokers and initiation of tobacco use by nonsmokers was observed during SD. Although nicotine treatment was reported to attenuate the impairment of learning and memory and LTP associated with several mental disorders, the effect of nicotine on SD‐induced learning and memory impairment has not been studied. Modified multiple platform paradigm was used to induce SD for 24 or 48 h during which rats were injected with saline or nicotine (1 mg kg^?1 s.c.) twice a day. In the radial arm water maze (RAWM) task, 24‐ or 48‐h SD significantly impaired learning and short‐term memory. In addition, extracellular recordings from CA1 and dentate gyrus (DG) regions of the hippocampus in urethane anesthetized rats showed a significant impairment of LTP after 24‐ and 48‐h SD. Treatment of normal rats with nicotine for 24 or 48 h did not enhance spatial learning and memory or affect magnitude of LTP in the CA1 and DG regions. However, concurrent, acute treatment of rats with nicotine significantly attenuated SD‐induced impairment of learning and STM and prevented SD‐induced impairment of LTP in the CA1 and DG regions. These results show that acute nicotine treatment prevented the deleterious effect of sleep loss on cognitive abilities and synaptic plasticity. © 2010 Wiley‐Liss, Inc.     

Enduring consequences of early-life infection on glial and neural cell genesis within cognitive regions of the brain

Systemic infection with Escherichia coli on postnatal day (P) 4 in rats results in significantly altered brain cytokine responses and behavioral changes in adulthood, but only in response to a subsequent immune challenge with lipopolysaccharide [LPS]. The basis for these changes may be long-term changes in glial cell function. We assessed glial and neural cell genesis in the hippocampus, parietal cortex (PAR), and prefrontal cortex (PFC), in neonates just after the infection, as well as in adulthood in response to LPS. E. coli increased the number of newborn microglia within the hippocampus and PAR compared to controls. The total number of microglia was also significantly increased in E. coli-treated pups, with a concomitant decrease in total proliferation. On P33, there were large decreases in numbers of cells coexpressing BrdU and NeuN in all brain regions of E. coli rats compared to controls. In adulthood, basal neurogenesis within the dentate gyrus (DG) did not differ between groups; however, in response to LPS, there was a decrease in neurogenesis in early-infected rats, but an increase in controls to the same challenge. There were also significantly more microglia in the adult DG of early-infected rats, although microglial proliferation in response to LPS was increased in controls. Taken together, we have provided evidence that systemic infection with E. coli early in life has significant, enduring consequences for brain development and subsequent adult function. These changes include marked alterations in glia, as well as influences on neurogenesis in brain regions important for cognition.     

Early postnatal maternal deprivation in rats induces memory deficits in adult life that can be reversed by donepezil and galantamine

Early postnatal maternal deprivation is known to cause long-lasting neurobiological effects. Here, we investigated whether some of the cognitive aspects of these deficits might be related to a disruption of the cholinergic system. Pregnant Wistar rats were individually housed and maintained on a 12:12 h light/dark cycle with food and water freely available. The mothers were separated from their pups for 3 h per day from postnatal day 1 (PND-1) to PND-10. To do that, the dams were moved to a different cage and the pups maintained in the original home cage, which was transferred to a different room kept at 32 °C. After they reached 120–150 days of age, maternal-deprived and non-deprived animals were either sacrificed for brain acetylcholinesterase measurement, or trained and tested in an object recognition task and in a social recognition task as described by Rossato et al. (2007) [Rossato, J.I., Bevilaqua, L. R.M., Myskiw, J.C., Medina, J.H., Izquierdo, I., Cammarota, M. 2007. On the role hippocampal synthesis in the consolidation and reconsolidation of object recognition memory. Learn. Mem. 14, 36–46] and Lévy et al. (2003) [Lévy, F., Melo. A.I., Galef. B.G. Jr., Madden, M., Fleming. A.S. 2003. Complete maternal deprivation affects social, but not spatial, learning in adult rats. Dev. Psychobiol. 43, 177–191], respectively. There was increased acetylcholinesterase activity in hippocampus and perirhinal cortex of the deprived animals. In addition, they showed a clear impairment in memory of the two recognition tasks measured 24 h after training. Oral administration of the acetylcholinesterase inhibitors, donepezil or galantamine (1 mg/kg) 30 min before training reversed the memory impairments caused by maternal deprivation. The findings suggest that maternal deprivation affects memory processing at adulthood through a change in brain cholinergic systems.     

Maternal deprivation affects behaviour from youth to senescence: amplification of individual differences in spatial learning and memory in senescent Brown Norway rats

Previous studies have shown that deprivation of the infant rat from maternal care has pronounced effects on the stress system during ontogeny. Here we test the hypothesis that 24 h of maternal deprivation at postnatal day 3 will cause persistent changes in behaviour. Spatial learning and memory of male Brown Norway rats deprived as infants were observed in the Morris water maze at 3, 12, 24 and 30-32 months of age (young, adult, aged, senescent). Their nondeprived mother-reared littermates served as controls. (i) With increasing age, water maze performance declined in deprived and nondeprived groups. However, once the task was learned the animals maintained their good performance during retest at later ages. (ii) Maternal deprivation delayed acquisition until adulthood and caused at every age a higher degree of persistent behaviour as judged from the performance of deprived rats' free swim trials and reversal trials. (iii) At senescence the mean performance in the water maze did not differ between the groups. Instead, the individual performance was strikingly different within each group. Senescent deprived rats were either nonimpaired or impaired with only a few animals showing an intermediate performance. Thus, a large group of animals ( approximately 40%) ages successfully as they are resistant to the effect of maternal deprivation. In contrast, the majority of the control animals displayed intermediate performance. Taken together, maternal deprivation has life-long consequences for behaviour and culminates at senescence in amplification of individual differences in learning ability rather than in a generalized deterioration of cognitive functions.     

Effects of maternal deprivation of CD1 mice on performance in the water maze and swim stress

Rat pups subjected to a single 24h maternal deprivation show altered stress responsiveness and cognitive performance in the water maze in adulthood. Here we show in 6-month-old male CD1 mice (deprived 24h at postnatal day 8) an initial impairment in reversal learning: relocating the platform revealed perseverance in search for the former location. Spatial learning, long-term memory and swim-induced corticosterone responses were not affected. We conclude that reduced flexibility is a subtle long-lasting behavioural change induced by maternal deprivation.     

Dissociation in the effects of neonatal maternal separations on maternal care and the offspring's HPA and fear responses in rats

The development of the hypothalamic-pituitary-adrenal (HPA) response to stress is influenced by the early mother-infant relationship. In rats, early handling (brief daily mother-offspring separations) attenuates the adult offspring's HPA and fear responses compared to both nonhandling (no separations) and maternal separation (prolonged daily separations). It has been proposed that variation in the amount of maternal care mediates these effects of neonatal manipulations on the adult offspring's stress and fear responses. Here we tested this hypothesis by assessing maternal care and the adult offspring's HPA and fear responses in Lister hooded rats which were subjected to either early handling (EH) or maternal separation (MS) from postnatal day 1-13, or were left completely undisturbed (nonhandled, NH) throughout this period. Both EH and MS induced a more active nursing style and elevated levels of maternal care compared to NH. Total levels of maternal care were indistinguishable between EH and MS, but diurnal distribution differed. MS dams showed elevated levels of maternal care following the 4-h separation period, thereby fully compensating for the amount of maternal care provided by EH dams during the time MS dams were separated from their pups. However, while EH resulted in reduced HPA and fear responses in the adult offspring compared to NH, MS and NH offspring did not differ. Our findings therefore demonstrate dissociation in the effects of EH and MS on maternal care and on the stress and fear responses in the offspring. This indicates that maternal care cannot be the sole mediator of these effects.     

Importance of early lighting conditions in maternal care by dam as well as anxiety and memory later in life of offspring

Rodent studies have revealed that the early rearing environment plays an important role in the development of stress vulnerability, memory and cognition. Although early lighting conditions (ELC) are involved in these neuronal developments through both maternal and offspring behavior, their influence has not been fully elucidated. Thus, by using Sprague-Dawley rats, we examined whether ELC affected maternal care by the dam and the subsequent neurodevelopment of the offspring. Prolonged dark phase conditions (PDC) (light/dark, 6/18 h) and prolonged light phase conditions (light/dark, 18/6 h) were administered from postnatal day 2 to postnatal day 14. Throughout this period, maternal care and the circadian rhythmicity of dams were investigated. In adolescence and adulthood of the offspring, we measured anxiety-like behavior, social interaction, object recognition memory, activity rhythm and corticosterone response to stress with hippocampal expression of N-methyl-D-aspartate and glucocorticoid receptor mRNAs. PDC altered maternal care and circadian rhythmicity in the dam compared with normal lighting conditions and prolonged light phase conditions. PDC markedly increased anxiety-like behavior, decreased social interaction and object recognition memory, and inhibited corticosterone feedback in offspring later in life. Furthermore, hippocampal levels of glucocorticoid receptor mRNA and N-methyl-D-aspartate receptor 2B mRNA in rats subjected to PDC were significantly lower than in animals subjected to normal lighting conditions. In the adult offspring, the circadian rhythm of locomotor activity was not affected. These findings suggested that ELC affect mother-infant interactions and subsequently at least partially alter the neurobehavioral development of offspring.     

Rats exposed prenatally to alcohol exhibit impairment in spatial navigation test

Prenatal exposure to ethanol causes learning disabilities and low I.Q. scores. The objective of the present studies was to investigate whether exposure of rats to ethanol in utero, would induce a deficit in spatial memory in adult life. Pregnant rats were fed with an ethanol diet from day 1 of pregnancy till parturition. Control rats were either pair-fed with an isocaloric sucrose diet or were fed with lab-chow ad libitum. On the first day of birth, offspring exposed to ethanol in utero were placed with a control mother fed with lab-chow, while offspring of the lab-chow fed dams were placed with ethanol-treated dams. At 40, 60 and 90 days postnatally, behavioral testing was performed using the Morris swim maze, a test of spatial memory. Results indicated that the offspring exposed to ethanol in utero presented deficits in spatial memory processes. Ethanol did not completely block the learning of the swim maze task but the alcohol-exposed offspring exhibited longer latencies to perform the task, swam longer distances prior to locating and climbing onto the platform, and when the platform was removed, searched for it in all 4 quadrants of the pool. Restricted caloric intake during gestation and maternal behavior in early postnatal life also induced deficits in the performance on the swim maze task. However, these deficits were mild and short-lasting being absent at 60 and 90 days of age. In contrast, the deficits induced by ethanol were more severe and longer-lasting, being present in adult life.     

Enhanced hippocampal neuronal excitability and LTP persistence associated with reduced behavioral flexibility in the maternal immune activation model of schizophrenia

Individuals with schizophrenia display a number of structural and cytoarchitectural alterations in the hippocampus, suggesting that other functions such as synaptic plasticity may also be modified. Altered hippocampal plasticity is likely to affect memory processing, and therefore any such pathology may contribute to the cognitive symptoms of schizophrenia, which includes prominent memory impairment. The current study tested whether prenatal exposure to infection, an environmental risk factor that has previously been associated with schizophrenia produced changes in hippocampal synaptic transmission or plasticity, using the maternal immune activation (MIA) animal model. We also assessed performance in hippocampus‐dependent memory tasks to determine whether altered plasticity is associated with memory dysfunction. MIA did not alter basal synaptic transmission in either the dentate gyrus or CA1 of freely moving adult rats. It did, however, result in increased paired‐pulse facilitation of the dentate gyrus population spike and an enhanced persistence of dentate long‐term potentiation. MIA animals displayed slower learning of a reversed platform location in the water maze, and a similarly slowed learning during reversal in a spatial plus maze task. Together these findings are indicative of reduced behavioral flexibility in response to changes in task requirements. The results are consistent with the hypothesis that hippocampal plasticity is altered in schizophrenia, and that this change in plasticity mechanisms may underlie some aspects of cognitive dysfunction in this disorder. © 2013 Wiley Periodicals, Inc.     

Postnatally induced differences in adult pain sensitivity depend on genetics,gender and specific experiences: reversal of maternal deprivation effects by additional postnatal tactile stimulation or chronic imipramine treatment

Postnatal endotoxin exposure, handling or maternal deprivation produce long-lasting individual differences in various neuroendocrine and behavioural responses. However, the impact of postnatal experiences on adult pain sensitivity and its reversibility by postnatal additional tactile stimulation or antidepressants in adulthood is not well understood. Therefore, postnatal endotoxin application as a model for infection, maternal deprivation as a model for depression, and postnatal handling as a model for stimulation were compared with respect to the effects on pain sensitivity in adult Fischer 344 (F344) and Lewis (LEW) rats. Handling increased hot plate latencies in adult F344 and LEW rats, while maternal deprivation shortened hot plate latencies only in LEW rats. Prophylactic treatment strategies, such as tactile stimulation of the dorsal neck region of pups directly after maternal deprivation, or chronic treatment of adult maternally deprived rats using imipramine, successfully provide protection against the maternal deprivation-induced shortening of hot plate latencies. Thus, there is considerable specificity of certain postnatal experiences in modulating adult pain sensitivity and the maternal deprivation-induced hyperalgesia is reversible by different interventional regimes. These findings may explain some of the individual differences in pain sensitivity of humans and the differential efficacy of antidepressants in pain syndromes.