Effects of maternal stress and perinatal fluoxetine exposure on behavioral outcomes of adult male offspring.

UNLABELLED: Women of child-bearing age are the population group at highest risk for depression. In pregnant women, fluoxetine (Flx) is the most widely prescribed selective serotonin reuptake inhibitor (SSRI) used for the treatment of depression. While maternal stress, depression, and Flx exposure have been shown to effect neurodevelopment of the offspring, separately, combined effects of maternal stress and Flx exposure have not been extensively examined. The present study investigated the effects of prenatal maternal stress and perinatal exposure to the SSRI Flx on the behavior of male mice as adults. METHODS: C57BL/6 dams exposed to chronic unpredictable stress from embryonic (E) day 4 to E18 and non-stressed dams were administered Flx (25 mg/kg/d) in the drinking water from E15 to postnatal day 12. A separate control group consisted of animals that were not exposed to stress or Flx. At 12 days of age, brain levels of serotonin were assessed in the male offspring. At two months of age, the male offspring of mothers exposed to prenatal stress (PS), perinatal Flx, PS and Flx, or neither PS or Flx, went through a comprehensive behavioral test battery. At the end of testing brain-derived neurotropic factor (BDNF) levels were assessed in the frontal cortex of the offspring. RESULTS: Maternal behavior was not altered by either stress or Flx treatment. Treatment of the mother with Flx led to detectible Flx and NorFlx levels and lead to a decrease in serotonin levels in pup brains. In the adult male offspring, while perinatal exposure to Flx increased aggressive behavior, prenatal maternal stress decreased aggressive behavior. Interestingly, the combined effects of stress and Flx normalized aggressive behavior. Furthermore, perinatal Flx treatment led to a decrease in anxiety-like behavior in male offspring. PS led to hyperactivity and a decrease in BDNF levels in the frontal cortex regardless of Flx exposure. Neither maternal stress or Flx altered offspring performance in tests of cognitive abilities, memory, sensorimotor information processing, or risk assessment behaviors. These results demonstrate that maternal exposure to stress and Flx have a number of sustained effects on the male offspring.

Behavioural outcomes of perinatal maternal fluoxetine treatment.

During and following pregnancy, women are at considerable risk of experiencing depression. For treatment, selective serotonin reuptake inhibitor drugs, such as fluoxetine, are commonly prescribed, yet the potential effects of perinatal exposure to these drugs on the brain and behaviour have not been examined in humans beyond childhood. This is despite abundant evidence from studies using rodents indicating that altered serotonin levels early in life affect neurodevelopment and behavioural outcomes. These reported effects on behaviour are inconsistent, however, and the testing of females has often been overlooked. In the present study, the behavioural outcomes of female mice perinatally (embryonic day 15 to postnatal day 12) treated with fluoxetine (25mg/kg/day) via a non-stressful method of maternal administration were assessed using a battery of tests. Maternal treatment resulted in subtle alterations in anxiety-like and depression-like behaviour in early adulthood, with a decrease in both types of behaviour as well as body weight. Though altered anxiety and depression have previously been reported in this area of research, decreased anxiety is a novel finding. While there was little effect of perinatal maternal fluoxetine treatment on many of the behaviours assessed, the capacity to alter "emotional" behaviours in mice has implications with regard to research on human infant fluoxetine exposure.

Dynamic, experience-dependent modulation of synaptic zinc within the excitatory synapses of the mouse barrel cortex.

Increasing evidence suggests that synaptic zinc, found within the axon terminals of a subset of glutamatergic neurons in the cerebral cortex, is intricately involved in cortical plasticity. Using the vibrissae/barrel cortex model of cortical plasticity, we have previously shown manipulations of sensory input leads to rapid changes in synaptic zinc levels within the corresponding regions of the somatotopic map in the cortex. Here, using electron microscopy, we show how some of these changes are mediated at the synaptic level. We found that the density of zincergic synapses increased significantly in layers II/III, IV, and V. In layers IV and V, this change occurred in the absence of a significant increase in excitatory synapse density, which seems to indicate that excitatory synapses, which previously did not contain synaptic zinc, begin to newly house zinc within its synaptic vesicles. Our results show that excitatory neurons can dynamically change the phenotype of the vesicular content of their synapses in response to changes in sensory input. Given the range of modulatory effects zinc can have on neurotransmission, such a change in the complement of vesicular contents presumably allow these neurons to utilize synaptic zinc to facilitate plasticity. Thus, our results further support the role of zinc as an active participant in the processes contributing to experience-dependent cortical plasticity.

Zincergic innervation of the forebrain distinguishes epilepsy-prone from epilepsy-resistant rat strains.

Zinc is released from a subset of cerebral cortical neurons whereupon it exerts a powerful modulatory influence on excitatory and inhibitory neurotransmission. A number of studies have suggested that alterations in the regulation of zinc may contribute to the genesis of epilepsy. Here, we tested this hypothesis by examining the distribution of zinc-containing axon terminals in rats selectively bred for an innate susceptibility (FAST) or resistance (SLOW) to the development of kindling-induced seizures. Zinc was stained histochemically and levels of staining were quantitatively assessed. We found that the levels of synaptic zinc were significantly lower in the SLOW rats throughout the telencephalon. This relative reduction was most pronounced in limbic cortices where levels were less than 30% of FAST rats. These results suggest that innate differences in the homeostatic regulation of synaptic zinc, particularly in limbic cortices, may underlie differences in epileptogenicity.

Modulation of synaptic zinc in barrel cortex by whisker stimulation.

The cortical representation of the body surface is not fixed, but rather, is continuously modified by ongoing changes in sensory experience. Although the cellular and molecular mechanisms that subserve these changes are uncertain, increasing evidence suggests that synaptically-released zinc may play a role. Zinc is released from a subset of glutamatergic neurons and can modulate postsynaptic excitability by regulating the activation of glutamate and GABA receptor-gated ion channels. Previously, we have shown that whisker plucking, a manipulation commonly used to induce cortical map plasticity, results in a rapid and robust increase in staining levels for synaptic zinc in deprived regions of the barrel cortex. In the present study, we examined the effect of increased whisker activity, analogous to what may happen during tactile learning or exploratory behavior in a natural setting, on synaptic zinc levels in the adult barrel cortex. Our results indicate that stimulation of whiskers caused a selective decrease in zinc levels within layer 4 of the barrel hollow corresponding to the stimulated whisker. Quantitatively, levels of staining were significantly reduced at 3 h, and showed even greater reductions following 12 and 24 h of stimulation. However, these changes were not long-lasting, as levels of staining in the stimulated barrel returned to control values within 24 h after stimulation had ceased. These data indicate that zincergic circuits are highly sensitive to ongoing changes in sensory experience and may participate in moment-to-moment changes in the functional connectivity of the cerebral cortex.

Reovirus as an experimental therapeutic for brain and leptomeningeal metastases from breast cancer.

Brain and leptomeningeal metastases are common in breast cancer patients and our current treatments are ineffective. Reovirus type 3 is a replication competent, naturally occurring virus that usurps the activated Ras-signaling pathway (or an element thereof) of tumor cells and lyses them but leaves normal cells relatively unaffected. In this study we evaluated reovirus as an experimental therapeutic in models of central nervous system (CNS) metastasis from breast cancer. We found all breast cancer cell lines tested were susceptible to reovirus, with > 50% of these cells lysed within 72 h of infection. In vivo neurotoxicity studies showed only mild local inflammation at the injection site and mild communicating hydrocephalus with neither diffuse encephalitis nor behavioral abnormalities at the therapeutically effective dose of reovirus (intracranial) (ie 10(7) plaque-forming units) or one dose level higher. In vivo, a single intratumoral administration of reovirus significantly reduced the size of tumors established from two human breast cancer cell lines and significantly prolonged survival. Intrathecal administration of reovirus also remarkably prolonged survival in an immunocompetent racine model of leptomeningeal metastases. These data suggest that the evaluation of reovirus as an experimental therapeutic for CNS metastases from breast cancer is warranted.

Experience-dependent regulation of synaptic zinc is impaired in the cortex of aged mice.

Zinc plays an important role in synaptic signaling in the mammalian cerebral cortex. Zinc is sequestered into presynaptic vesicles of subpopulations of glutamatergic neurons and is released by depolarization, in a calcium-dependent manner. As the majority of mechanisms that have been suggested to participate in experience-dependent alterations in synaptic strength in the cerebral cortex implicate signaling by glutamate, it stands to reason that zincergic signaling might also be crucial. Here we show that synaptic zinc is rapidly and dynamically modulated in relation to alterations in sensory input and that this response is highly age-dependent. Juvenile, adult, and aged mice were subjected to whisker removal and levels of staining for synaptic zinc in deprived and non-deprived cortical barrels were quantitatively assessed at post-deprivation times ranging from 3 h to 21 days. In the first 12 h, zinc levels increased slightly, but significantly, in all groups. At later time points, zinc levels increased robustly (23%) in the youngest group by 24 h and remained elevated through 7 days. By contrast, deprivation-induced changes in zinc staining in aged animals, achieved their maximal levels at 12 h (approximately 10%) and steadily declined thereafter. Adult animals revealed a biphasic, intermediate change with time. In all age groups, levels of zinc staining returned to baseline by 21 days after whisker plucking. However, only in juvenile and adult mice did we observe that the level of zinc staining in deprived barrel hollows, was correlated with the length of whiskers as they regrew. Our data suggest that alterations in the regulation of synaptic zinc may be involved with decrements of synaptic plasticity that accompany senescence.

Columnar distribution of serotonin-dependent plasticity within kitten striate cortex.

Recent studies have identified the potential for an important role for serotonin (5-HT) receptors in the developmental plasticity of the kitten visual cortex. 5-HT(2C) receptors are transiently expressed in a patchy fashion in the visual cortex of kittens between 30-80 days of age complementary to patches demarcated by cytochrome oxidase staining. 5-HT, operating via 5-HT(2C) receptors, increases cortical synaptic plasticity as assessed both in brain slices and in vivo. Herein, we report that bath application of 5-HT substantially increases the probability of long-term potentiation within 5-HT(2C) receptor-rich zones of cortex, but this effect is not observed in the 5-HT(2C) receptor-poor zones. Instead, in these zones, 5-HT application increases the probability of long-term depression. These location-specific effects of 5-HT may promote the formation of compartment-specific cortical responses.

The Dalila effect: C57BL6 mice barber whiskers by plucking.

Group-housed laboratory mice are frequently found with their whiskers and facial hair removed. It has been proposed that dominant mice are responsible for barbering the hair of the recipient (the Dalila effect), and early studies suggest that the hair is removed by nibbling. In the present study, pairs of C57BL6 mice, composed of a barber and recipient, were separated to allow hair to regrow. The animals were then placed together in an observation box and their social behavior was videorecorded. The videorecording was subjected to frame-by-frame analysis. Barbering was found to occur during acts of mutual grooming. During grooming, one member of a mouse pair removed the vibrissae of the conspecific and did so by grasping individual whiskers with the incisors and plucking them out. Although plucking appeared 'painful', recipients were passive in accepting barbering, and even pursued conspecifics for further grooming. Other measures indicated that barbers were heavier than recipients and brain weights were not different. Although cortical barrel fields appeared normal to cytochrome oxidization and zinc staining, Golgi analysis of layer three, barrel-field basilar dendrites indicated changes in cell morphology. The results are discussed in relation to the hypothesis that barbering is an expression of social dominance, the origins of the barbering behavior, and the consequences of barbering on brain function.

Generation and analysis of GluR5(Q636R) kainate receptor mutant mice.

The physiological significance of RNA editing of transcripts that code for kainate-preferring glutamate receptor subunits is unknown, despite the fact that the functional consequences of this molecular modification have been well characterized in cloned receptor subunits. RNA editing of the codon that encodes the glutamine/arginine (Q/R) site in the second membrane domain (MD2) of glutamate receptor 5 (GluR5) and GluR6 kainate receptor subunits produces receptors with reduced calcium permeabilities and single-channel conductances. Approximately 50% of the GluR5 subunit transcripts from adult rat brain are edited at the Q/R site in MD2. To address the role of glutamate receptor mRNA editing in the brain, we have made two strains of mice with mutations at amino acid 636, the Q/R-editing site in GluR5, using embryonic stem cell-mediated transgenesis. GluR5(RloxP/RloxP) mice encode an arginine at the Q/R site of the GluR5 subunit, whereas GluR5(wt(loxP)/wt(loxP)) mice encode a glutamine at this site, similar to wild-type mice. Mutant animals do not exhibit developmental abnormalities, nor do they show deficits in the behavioral paradigms tested in this study. Kainate receptor current densities were reduced by a factor of six in acutely isolated sensory neurons of dorsal root ganglia from GluR5(RloxP/RloxP) mice compared with neurons from wild-type mice. However, the editing mutant mice did not exhibit altered responses to thermal and chemical pain stimuli. Our investigations with the GluR5-editing mutant mice have therefore defined a set of physiological processes in which editing of the GluR5 subunit is unlikely to play an important role.

Effects of tetrodotoxin treatment in LGN on neuromodulatory receptor expression in developing visual cortex.

The expression and distribution patterns of transmitter receptors change dramatically during pre- and post-natal development of the visual cortex, but the factors that control these processes are largely unknown. We have tested the hypothesis that input activity from the lateral geniculate nucleus (LGN), one major input source to visual cortex, may contribute to the processes underlying transmitter receptor redistributions in the visual cortex during development. We found that a short period of tetrodotoxin (TTX) treatment in LGN retarded the developmental expression and age-dependent reorganization of neuromodulatory receptors, including muscarinic, serotonergic and adrenergic receptors, in kitten primary visual cortex. The visual cortices ipsilateral to the TTX infusion site displayed a 'younger' receptor pattern than that of their contralateral control counterparts in the same animals. The results suggest that active input from LGN regulates the expression profile of a broad range of receptors in the developing visual cortex.

Development, critical period plasticity, and adult reorganizations of mammalian somatosensory systems.

This review covers recent progress in three major areas of investigation in somatosensory systems: development, developmental plasticity and functional reorganization. Important findings relate to the development of periphery-related patterning in thalamic afferents to somatosensory cortex, the controversial role of neural activity in the development and plasticity of periphery-related afferent patterning in the brainstem and cortex, experience-dependent reorganizations in adult somatosensory cortex, and the locus of these changes.

Autoradiographic localization of serotonin receptor subtypes in cat visual cortex: transient regional, laminar, and columnar distributions during postnatal development.

Postnatal changes in the distribution of 5-HT receptor subtypes in the visual cortex of cats were assessed both qualitatively and quantitatively using in vitro autoradiographic methods. The 5-HT 1A, 1C, 2, and 3 receptor subtypes and the 5-HT uptake (5-HTUp) site were visualized with 3H-8-hydroxy-2(di-n-propyl-amino)tetralin, 3H-mesulergine, (2,5-dimethoxy-4-125I-iodophenyl)-2-aminopropane, 3H-BRL43694, and 3H-cyanoimipramine, respectively. Although specific labeling of 5-HT3 receptors was not detected in the cat visual cortex at any age, each of the remaining 5-HT receptor subtypes exhibited unique temporal, regional, and laminar patterns of expression in visual cortical areas 17, 18, and 19 and lateral suprasylvian cortex (LS). 5-HT1A receptors were the earliest to demonstrate visual cortex-specific changes in expression. They exhibited peak levels of expression in all visual cortical areas, predominantly in supra- and infragranular layers, between postnatal day 10 (PD10) and PD30. Their levels in all areas declined progressively with increasing age. 5-HT1c receptors demonstrated their highest levels of expression in the deeper half of layer IV, but only in area 17, between PD40 and PD75. The most striking feature of their distribution throughout this period was that, in layer IV and extending into layer III, the 5-HT1c receptors were concentrated in columns that were 400 microns wide and had a center-to-center spacing of about 900 microns. This transient pattern of expression was not present beyond PD90. 5-HT2 receptors were most densely expressed in layer IV between PD40 and PD120, but they displayed a distinctly different distribution pattern. The densest binding of 5-HT2 receptors was limited to the upper half of layer IV and found in areas 17, 18, and LS. The distribution of layer 5-HT2 receptors along the dense band in layer IV of area 17 was discontinuous, exhibiting patches that were found in the same vertical columns as were the 5-HT1c receptors. Intermediate binding levels for the 5-HT2 receptors were found through layers I-III, the remainder of layer IV, and the subcortical white matter. The levels of 5-HT uptake sites increased gradually to reach adult levels by PD40, but with a distribution pattern that was basically homogeneous, both across cortical regions and across laminae.(ABSTRACT TRUNCATED AT 400 WORDS)

An interdigitated columnar mosaic of cytochrome oxidase, zinc, and neurotransmitter-related molecules in cat and monkey visual cortex.

There is considerable physiological evidence for the compartmentalization of mammalian visual cortex into functional columnar modules, representing features of visual information processing such as eye and orientation specificity. However, anatomical markers of visual cortical compartmentalization have been described only for primate visual cortex. In this report, we describe an interdigitated mosaic of four neuroactive molecules which demarcate two distinct columnar systems in the kitten visual cortex. Serotonin 1C receptors and synaptic zinc were found to demarcate columns within layer IV of kitten visual cortex, which were interdigitated with a second, patchy system characterized by increased levels of cytochrome oxidase and acetylcholinesterase. In primate visual cortex, as well as in the kitten, synaptic zinc was periodically distributed in a manner precisely complementary to cytochrome oxidase. These findings provide an anatomical framework on which unifying hypotheses of the functional organization of columnar systems in mammalian visual cortex can be built.

Immunohistochemical localization of the S-100 beta protein in postnatal cat visual cortex: spatial and temporal patterns of expression in cortical and subcortical glia.

The ontogenic expression of the glial-specific protein S100 beta was examined in postnatal cat visual cortex using immunocytochemical methods. Astrocytes in visual cortex and oligodendrocytes in the subcortical white matter exhibited distinct spatio-temporal gradients in their expression of the S100 beta protein. In the visual cortex, S100 beta-immunoreactivity was detected in astroglial cytoplasm, as well as in the extracellular interstitium, in a lamina-specific manner throughout postnatal development. Using double labeling procedures, the S100 beta protein was found to be strictly colocalized with GFAP-immunoreactive astrocytes when GFAP was present. The glial fibrillary acidic protein (GFAP), a marker of mature astrocytes, was not present at high levels until the 4th postnatal week. From the 2nd through 5th postnatal weeks, the expression of S100 beta was highest in the thalamocortical recipient, layer IV, of visual cortical areas 17 and 18. At ages beyond 6 postnatal weeks, S100 beta-immunoreactivity increased disproportionately in supra- and infragranular layers such that areas 17 and 18 were demarcated from adjacent cortices by lower levels in layer IV. The S100 beta protein was also highly expressed in oligodendroglial somata and processes in the subcortical white matter between the 2nd and 6th postnatal weeks. The levels of S100 beta in the subcortical white matter progressively diminished to adult levels, where it was localized only to a few remaining oligodendroglial somata. The differential laminar expression of the S100 beta protein in astrocytes during the period within which the visual cortex exhibits input- and experience-dependent synaptic modifications suggests that astrocytes, possibly via their release of S100 beta, may play a special role in mediating plasticity in visual cortical development. A consistent feature of the appearance of the S100 beta protein was its expression in immature astroglia and oligodendroglia, well before they are considered morphologically mature. This characteristic underscores the potential of S100 beta as a marker of distinct populations of glial cells and of their role in normal and abnormal development.

Increased cytochrome oxidase activity of mesencephalic neurons in developing rats displaying methylmercury-induced movement and postural disorders.

Subcutaneous administration of the neurotoxin methylmercuric chloride to developing rats produced movement and postural disorders during the 4th postnatal week. Cytochrome oxidase histochemistry revealed an increase in the oxidative metabolic activity of small neurons within the magnocellular red nucleus (RMC) and the interrubral mesencephalon. A concurrent suppression of cytochrome oxidase activity in the large neurons and neuropil of RMC was apparent relative to controls. Decortication on postnatal day 3 did not alter the course of motor impairment or the cytochrome oxidase histopathology, suggesting that the role of neocortex in the pathogenesis of methylmercury-induced movement and postural disorders is minimal.