Fmr1 knockout mice are impaired in a leverpress escape/avoidance task.

Fragile X syndrome (FXS) is the most common form of inherited mental retardation (MR). FXS is typically caused by a mutation of the Fmr1 gene (Verkerk et al. 1991, Cell 65, 905-914). To better understand the role of Fmr1 and its gene product fragile X mental-retardation protein (FMRP) in central nervous system function, researchers have turned to the use of animal model systems to generate an Fmr1 knockout (KO) mouse that is deficient in FMRP (Bakker et al. 1994, Cell 78, 23-33). Unfortunately, a number of studies have found no consistent, robust learning and memory impairment in the Fmr1 KO mice. We conducted a study to assess the performance of Fmr1 KO and wildtype (WT) animals in a leverpress escape/avoidance paradigm. Fmr1 KO and WT littermates were studied in four daily 1-h sessions. The Fmr1 KO mice performed fewer avoidance and total responses than WT mice. The KO animals were not simply deficient in avoidance, but a within-factor ANOVA revealed that they did not acquire the leverpress response to any appreciable degree. Observation during the sessions indicated that the Fmr1 KO animals clearly responded to the shock, eliminating an obvious sensory explanation for the deficit. The fact that other studies have found that the KO mice displayed increased exploratory and locomotor activity compared with WT controls argues against a motoric deficit. Future studies will attempt to delineate the nature of the behavioral deficit as well as attempt to rescue the response with glutamatergic or dopaminergic agents.

Neuroprotection of grafted neurons with a GDNF/caspase inhibitor cocktail.

Transplantation of fetal ventral mesencephalic (VM) tissue shows great promise as an experimental therapy for patients with Parkinson's disease. However, cell survival in brain tissue grafts is poor, with survival rates of only 5-15%. We have utilized a combination of the caspase inhibitor bocaspartyl (OMe)-fluoromethylketone (BOC-ASP-CH2F) and glial cell line-derived neurotrophic factor (GDNF) to enhance survival of grafted dopamine neurons. The VM tissue was dissected from embryonic day 13-15 rat fetuses, incubated in different doses of BOC-ASP-CH2F and GDNF, and transplanted to the anterior chamber of the eye of adult rats. Growth of the tissue was assessed through the translucent cornea. Doses of 50 and 100 micromolar of the general caspase inhibitor appeared to have detrimental effects on mesencephalic tissue, while 20 micromolar had beneficial effects on overall transplant growth. A combination of the caspase inhibitor and GDNF appeared to have more prominent effects on cell survival as well as dopaminergic fiber density than either agent by itself. The transplants doubled in size when they were treated with a combination of BOC-ASP-CH2F and GDNF, and cell death markers were significantly reduced at both 48 h and 4-6 days postgrafting. This is, to our knowledge, the first combined approach using apoptotic blockers with trophic factors, and demonstrates a viable strategy for protection of developing neurons, since several different aspects of graft function may be addressed simultaneously.

Long-term environmental enrichment leads to regional increases in neurotrophin levels in rat brain.

A number of studies have demonstrated that both morphological and biochemical indices in the brain undergo alterations in response to environmental influences. In previous work we have shown that rats raised in an enriched environmental condition (EC) perform better on a spatial memory task than rats raised in isolated conditions (IC). We have also found that EC rats have a higher density of immunoreactivity than IC rats for both low and high affinity nerve growth factor (NGF) receptors in the basal forebrain. In order to determine if these alterations were coupled with altered levels of neurotrophins in other brain regions as well, we measured neurotrophin levels in rats that were raised in EC or IC conditions. Rats were placed in the different environments at 2 months of age and 12 months later brain regions were dissected and analyzed for NGF, brain-derived neurotrophic factor (BDNF), and neurotrophin-3 (NT-3) levels using Promega ELISA kits. We found that NGF and BDNF levels were increased in the cerebral cortex, hippocampal formation, basal forebrain, and hindbrain in EC animals compared to age-matched IC animals. NT-3 was found to be increased in the basal forebrain and cerebral cortex of EC animals as well. These findings demonstrate significant alterations in NGF, BDNF, and NT-3 protein levels in several brain regions as a result of an enriched versus an isolated environment and thus provide a possible biochemical basis for behavioral and morphological alterations that have been found to occur with a shifting environmental stimulus.

Glial cell line-derived neurotrophic factor is essential for postnatal survival of midbrain dopamine neurons.

Glial cell line-derived neurotrophic factor (GDNF) is one of the most potent trophic factors that have been identified for midbrain dopamine (DA) neurons. Null mutations for trophic factor genes have been used frequently for studies of the role of these important proteins in brain development. One problem with these studies has been that often only prenatal development can be studied because many of the knockout strains, such as those with GDNF null mutations, will die shortly after birth. In this study, we looked at the continued fate of specific neuronal phenotypes from trophic factor knockout mice beyond the time that these animals die. By transplanting fetal neural tissues from GDNF -/-, GDNF +/-, and wild-type (WT) mice into the brain of adult wild-type mice, we demonstrate that the continued postnatal development of ventral midbrain dopamine neurons is severely disturbed as a result of the GDNF null mutation. Ventral midbrain grafts from -/- fetuses have markedly reduced DA neuron numbers and fiber outgrowth. Moreover, DA neurons in such transplants can be "rescued" by immersion in GDNF before grafting. These findings suggest that postnatal survival and/or phenotypic expression of ventral mesencephalic DA neurons is dependent on GDNF. In addition, we present here a strategy for studies of maturation and even aging of tissues from trophic factor and other knockout animals that do not survive past birth.

Changes in brain nerve growth factor levels and nerve growth factor receptors in rats exposed to environmental enrichment for one year.

This study examined the effects of long-term differential rearing on levels of brain nerve growth factor, its receptors, and their relationships to cognitive function. Adult rats (two months old) were placed into either enriched or standard housing conditions where they remained for 12 months. Animals from the enriched condition group had significantly higher levels of nerve growth factor in hippocampus, visual and entorhinal cortices compared with animals housed in isolated condition. Immunohistochemical analysis of brain tissue from the medial septal area revealed higher staining intensity and fibre density with both the low-affinity and the high-affinity nerve growth factor receptors. Enriched rats performed better than isolated rats in acquisition of spatial learning and had lower locomotion scores in the open field. These results provide further evidence that experimental stimulation results in increased production of trophic factors and structural reorganization in specific brain regions known to be involved in cognitive function.

Acute application of NGF increases the firing rate of aged rat basal forebrain neurons.

Nerve growth factor (NGF) has been widely used in animal models to ameliorate age-related neurodegeneration, but it cannot cross the blood-brain barrier (BBB). NGF conjugated to an antibody against the transferrin receptor (OX-26) crosses the BBB and affects the biochemistry and morphology of NGF-deprived basal forebrain neurons. The rapid actions of NGF, including electrophysiological effects on these neurons, are not well understood. In the present study, two model systems in which basal forebrain neurons either respond dysfunctionally to NGF (aged rats) or do not have access to target-derived NGF (intraocular transplants of forebrain neurons) were tested. One group of transplanted and one group of aged animals received unconjugated OX-26 and NGF comixture as a control, while other groups received replacement NGF in the form of OX-26-NGF conjugate during the 3 months preceding the electrophysiological recording session. Neurons from animals in both the transplanted and aged control groups showed a significant increase in firing rate in response to acute NGF application, while none of the conjugate-treated groups or young intact rats showed any response. After the recordings, forebrain transplants and aged brains were immunocytochemically stained for the low-affinity NGF receptor. All conjugate treatment groups showed significantly greater staining intensity compared to controls. These data from both transplants and aged rats in situ indicate that NGF-deprived basal forebrain neurons respond to acute NGF with an increased firing rate. This novel finding may have importance even for long-term biological effects of this trophic factor in the basal forebrain.

Effects of osteogenic protein-1 (OP-1) treatment on fetal spinal cord transplants to the anterior chamber of the eye.

Spinal cord injury represents a serious medical problem, and leads to chronic conditions that cannot be reversed at present. It has been suggested that trophic factor treatment may reduce the extent of damage and restore damaged neurons following the injury. We have tested the effects of osteogenic protein-1 (OP-1, also known as BMP-7), a member of the transforming growth factor-beta superfamily of growth factors, on developing spinal cord motor neurons in an intraocular transplantation model. Embryonic day 13 or 18 spinal cord tissue was dissected, incubated with OP-1 or vehicle, and injected into the anterior chamber of the eye of adult rats. Injections of additional doses of OP-1 were performed weekly, and the overall growth of the grafted tissue was assessed noninvasively. Four to 6 weeks postgrafting, animals were sacrificed and the tissue was processed for immunohistochemistry using antibodies directed against choline acetyltransferase, neurofilament, and the dendritic marker MAP-II. We found that OP-1 treatment stimulated overall growth of spinal cord tissue when dissected from embryonic day 18, but not from embryonic day 13. OP-1 treatment increased cell size and extent of cholinergic markers in motor neurons from both embryonic stages. The neurons also appeared to have a more extensive dendritic network in OP-1-treated grafts compared to controls. These findings indicate that OP-1 treatment may reduce the extent of axotomy-induced cell death of motor neurons, at least in the developing spinal cord.

A non-invasive system for delivering neural growth factors across the blood-brain barrier: a review.

Intraventricular administration of nerve growth factor (NGF) in rats has been shown to reduce age-related atrophy of central cholinergic neurons and the accompanying memory impairment, as well as protect these neurons against a variety of perturbations. Since neurotrophins do not pass the blood-brain barrier (BBB) in significant amounts, a non-invasive delivery system for this group of therapeutic molecules needs to be developed. We have utilized a carrier system, consisting of NGF covalently linked to an anti-transferrin receptor antibody (OX-26), to transport biologically active NGF across the BBB. The biological activity of this carrier system was tested using in vitro bioassays and intraocular transplants; we were able to demonstrate that cholinergic markers in both developing and aged intraocular septal grafts were enhanced by intravenous delivery of the OX-26-NGF conjugate. In subsequent experiments, aged (24 months old) Fischer 344 rats received intravenous injections of the OX-26-NGF conjugate for 6 weeks, resulting in a significant improvement in spatial learning in previously impaired rats, but disrupting the learning ability of previously unimpaired rats. Neuroanatomical analyses showed that OX-26-NGF conjugate treatment resulted in a significant increase in cholinergic cell size as well as an upregulation of both low and high affinity NGF receptors in the medial septal region of rats initially impaired in spatial learning. Finally, OX-26-NGF was able to protect striatal cholinergic neurons against excitotoxicity and basal forebrain cholinergic neurons from degeneration associated with chemically-induced loss of target neurons. These results indicate the potential utility of the transferrin receptor antibody delivery system for treatment of neurodegenerative disorders with neurotrophic substances.

A peptidergic basis for sexual behavior in mammals.

Vasopressin (VP) is a peptide neurotransmitter in the limbic system of rats. It is synthesized in the medial amygdaloid nucleus in the presence of sex steroids, transported to other limbic structures such as the hippocampus and septum and secreted there by a calcium-dependent process. In the hippocampus, VP acts on cerebral microvessels and local circuit interneurons. Its excitatory action on the inhibitory interneurons produces near-total shutdown of electrical activity of the efferent fibers of pyramidal cells, the projection neurons of the hippocampus. Stimulation of the medial amygdala and release of the endogenous VP duplicates these effects and, since they are blocked by ventricular application of a VP antagonist, the effects are almost certainly mediated by endogenous VP. Recording from the VP-containing cell bodies or of the hippocampal action of the peptide indicates that the system is selectively involved with the early stages of sexual behavior, specifically those appetitive behaviors that anticipate coitus. Stimulation of the VP cells produces alterations in sexual behavior in a manner consistent with the hypothesis that the medial amygdala organizes the appetitive phase of recognition of an appropriate partner and sexual arousal. This role for the medial amygdala complements the proposed role of nearby structures in the consummatory, reward and learned aspects of sexual behavior. Association between VP, oxytocin (OT) and homologs with sexual behavior is very widespread among vertebrates, including amphibians, reptiles, primates and humans. Humans and other primates display a phenomenon called 'concealed ovulation' that may have played a role in the evolution of social structures. The review concludes with a discussion of possible experimental strategies for evaluating the possible role of VP in concealed ovulation and other conditions in which sexual behavior occurs outside of estrus.

A non-invasive transport system for GDNF across the blood-brain barrier.

Glial cell line-derived neurotrophic factor (GDNF) is a neurotrophin which supports midbrain dopaminergic neurons and spinal cord motorneurons. GDNF has been proposed as a possible therapeutic agent for Parkinson's disease, spinal cord injury or motorneuron degenerative disorders. Administration of GDNF is complicated by its poor penetration across the blood-brain barrier (BBB). Central nervous system capillaries are uniquely enriched in transferrin receptors and antibodies to these receptors (OX-26) have been proposed as potential carriers to transport large molecules across the BBB. Intravenous administration of an OX-26-GDNF conjugate enhanced survival of spinal cord motorneurons in intraocular transplants, which possess an organotypic BBB. This suggests that the OX-26-GDNF conjugate could be utilized for non-invasive treatment of neurodegenerative diseases of the spinal cord or midbrain dopaminergic neurons.

Chronic social stress alters levels of corticotropin-releasing factor and arginine vasopressin mRNA in rat brain.

In the visible burrow system model of chronic social stress, male rats housed in mixed-sex groups quickly form a dominance hierarchy in which the subordinates appear to be severely stressed. A subgroup of subordinates have an impaired corticosterone response after presentation of a novel restraint stressor, leading to their designation as nonresponsive subordinates. To examine the mechanism underlying the blunted corticosterone response in these animals, in situ hybridization histochemistry was used to quantify corticotropin-releasing factor (CRF) and arginine vasopressin (AVP) mRNA expression in the brain. In two separate visible burrow system experiments, the nonresponsive subordinates expressed a significantly lower average number of CRF mRNA grains per cell in the paraventricular hypothalamic nucleus compared with stress-responsive subordinates, dominants (DOM), or cage-housed control (CON) rats. The number of CRF mRNA labeled cells was also significantly lower in nonresponders than in responsive subordinates or DOM. In the central amygdala, CRF mRNA levels were increased in both groups of subordinates compared with CON rats, whereas responsive subordinates exhibited higher levels than the DOM rats as well. AVP mRNA levels did not vary with behavioral rank in any subdivision of the paraventricular hypothalamic nucleus. In the medial amygdala, the number of cells expressing AVP mRNA was significantly greater in CON rats compared with both groups of subordinates, although the average number of AVP mRNA grains per cell did not vary with rank. In addition, the number of AVP-positive cells significantly correlated with plasma testosterone level.

Effects of adrenalectomy and type I or type II glucocorticoid receptor activation on AVP and CRH mRNA in the rat hypothalamus.

The brain contains two types of adrenal steroid receptors, which play a role in mediating adrenal steroid effects on neuropeptide and other types of gene expression in discrete brain regions. Because the paraventricular nuclei of the hypothalamus (PVN) have adrenal steroid-sensitive neuropeptide systems, they provide a bench-mark to assess the doses of receptor agonists that may act selectively via Type I and Type II receptors. In the present study, in situ hybridization histochemistry was used to examine the effects of adrenalectomy (ADX) and Type I and Type II receptor agonists on arginine vasopressin (AVP) mRNA and corticotropin-releasing hormone (CRH) mRNA in rat brain. In agreement with previous reports, adrenal steroid regulation of AVP and CRH mRNA was found to be mediated primarily through the Type II receptor. Furthermore, adrenalectomy significantly increased AVP mRNA in the parvocellular region of the hypothalamic paraventricular nucleus (PVN), and systemic administration of the specific Type II agonist, RU28362 (10 micrograms/microliters/h), as well as corticosterone (CORT) pellets of 50 and 300 mg, prevented this increase. CRH mRNA was not significantly increased after ADX, but was markedly decreased in the PVN of rats receiving either RU28362 or a 300 mg pellet of CORT. Aldosterone, a specific Type I agonist, did not significantly affect either AVP or CRH mRNA levels when administered at 10 micrograms/h. Moreover, in the magnocellular regions of the PVN and SON AVP mRNA did not vary as a function of steroid manipulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of adrenalectomy and type I or type II glucocorticoid receptor activation on 5-HT1A and 5-HT2 receptor binding and 5-HT transporter mRNA expression in rat brain.

We evaluated the effects of adrenalectomy (ADX) and replacement with glucocorticoid receptor agonists on serotonin (5-HT) 5-HT1A and 5-HT2 receptor binding in rat brain. 5-HT1A receptor binding was increased in the CA2-CA4 and the dentate gyrus of the hippocampus 1 week after ADX. This effect was prevented by the systemic administration of aldosterone (10 micrograms/microliters/h) but not by RU28362 (10 micrograms/microliters/h). No significant effect was observed on 5-HT2 receptor binding in rat cortex. The expression of 5-HT transporter mRNA was unchanged in the raphe nucleus as measured by in situ hybridization.

Activity of peptidergic neurons in the amygdala during sexual behavior in the male rat.

The medial amygdaloid nucleus (AME) occupies a central position in the circuitry that organizes sexual behavior in the male rat. It receives a projection from olfactory structures that are activated by pheromonal cues indicating receptivity in the female and projects in turn to limbic and hypothalamic structures that are thought to organize aspects of coitus. Electrical stimulation of the AME elicits a behavioral state that is indistinguishable by several measures from the post-ejaculatory interval. We used chronic single-unit recording techniques to determine the behavioral conditions in which the AME is normally active. We found that the cells indeed fired selectively during the presence of a receptive female, but that the discharge considerably anticipated copulation in time. We propose that sexual behavior in the male rat is a reaction chain of fixed action patterns, each one acting as a releaser for the next. The AME mediates an early event in the reaction chain, namely recognition of the receptive female, but electrical activation of the AME causes the reaction chain to proceed to its culminating behavior, the post-ejaculatory interval.

Antidromic activation of a peptidergic pathway in the limbic system of the male rat.

Stimulation of the medial amygdaloid nucleus (AME) produces a long-latency and long-lasting inhibition of pyramidal cells in both the dorsal and the ventral hippocampus. The inhibition is blocked by a specific antagonist to vasopressin, which is a candidate neurotransmitter in the system. Antidromic activation of the AME from the hippocampus occurs with a latency suggestive of the conduction velocity of small diameter unmyelinated fibers. Immunocytochemistry for vasopressin reveals small diameter, unmyelinated immunoreactive fibers in the vicinity of the stimulating electrode in the hippocampus, and immunoreactive cell bodies in the vicinity of the recording electrode in the AME.

A peptidergic circuit for reproductive behavior.

A projection from the medial amygdaloid nucleus to the hippocampus and septum probably uses vasopressin as a transmitter. The nucleus synthesizes vasopressin and activation of the nucleus has a hippocampal effect that is completely blocked by a vasopressin antagonist. The afferent and efferent projections of this peptidergic nucleus suggest a possible role for the system in sexual behavior. Stimulation of the nucleus inhibits the output of the hippocampus in both genders and reorganizes behavior for a period of 15-20 min. In males, the effect of peptidergic activation is to produce a behavior that resembles the post-ejaculatory interval in coitus. This state is characterized by an EEG that resembles slow-wave sleep and by ultrasonic vocalizations at a characteristic frequency of 22 kHz. Castration in either gender causes depletion of the peptide from the target fields and eliminates the peptidergic signal in the hippocampus after about 15 weeks. The effects of castration in males can be reversed by testosterone replacement. The fluctuation of estrogen levels in rat plasma during the estrus cycle happens too quickly to impact the peptidergic system, and thus there is no significant change in the strength of the peptidergic signal among the proestrus, estrus, metestrus and diestrus stages. This fact permits study of the physiology of the system without concern for stage of estrus but does not permit conclusions regarding its function in females.

Peptidergic transmission in the brain. V. Systemic correlates of central activation.

Inhibition of the hippocampus by the medial amygdala is mediated by vasopressin-like peptide. Because vasopressin has action on the periphery as well as the brain, we conducted experiments to evaluate the relationship between possible peripheral actions and the central effects of the endogenous peptide. In the acutely anesthetized rat, peptide-mediated inhibition of the hippocampus is not associated with significant changes in heart rate, blood pressure or body temperature. Peripheral injections of peptide agonist fail to evoke the central inhibition, and peripheral injections of peptide antagonist fail to block the central inhibition. Stimulation of central nuclei that contain vasopressin or a similar peptide also fail to duplicate the effect of stimulating the amygdala. We conclude that the peptidergic transmission is independent of peripheral causes or correlates.

Peptidergic transmission in the brain. VI. Behavioral consequences of central activation.

Having described a peptidergic transmitter system in the rat brain, we now begin to evaluate its behavioral function. We stimulated cell bodies in the medial amygdaloid nucleus (AME) with indwelling bilateral electrodes. These cell bodies contain a vasopressin-like peptide and send fibers to the hippocampus where the peptide is released upon stimulation. There the peptide inhibits hippocampal output in the awake rat just as it does in the anesthetized rat and in the rat brain slice. The stimulation reorganizes behavior with the same latency and duration as the hippocampal effect. For about 15-20 minutes after the brief stimulus, rats remain motionless with eyes wide open. This "freezing" state is punctuated by episodes of exploratory behavior. The stimulus appears to have a positive affective quality. Review of the literature in light of the present results indicates a probable role for this peptidergic system in the generation of sexual behavior in male rats.