Neonatal 6-hydroxydopamine attenuates the neural and behavioral effects of enriched rearing in the rat

Behavioral responses to anxiogenic tasks in young adult rats with neonatal dopamine depletion

The dopaminergic neural system plays a crucial role in motor regulation as well as regulation of anxiety-related behaviors. Although rats with neonatal dopamine depletion exhibit motor hyperactivity and have been utilized as animal models of attention deficit hyperactivity disorder, characterization of their behavior under anxiogenic conditions is lacking. In the present study, we investigated behavioral responses to anxiogenic stimuli in young adult rats with neonatal dopamine depletion using the open field (OF), elevated plus maze (EPM), and light/dark (L/B) box tests. The OF and EPM tests were performed under low-light and bright-light conditions. The ameliorative effects of pretreatment with methamphetamine (MAP) or atomoxetine (ATX) on abnormal behaviors induced by neonatal dopamine depletion were also assessed. Rats that underwent 6-hydroxydopamine treatment 4 day after birth showed significant increases in motor activity and decreases in anxiety-related behaviors in OF tests under both conditions and in EPM tests under bright-light conditions. Furthermore, rats with neonatal dopamine depletion did not show normal behavioral responsiveness to changes in the intensity of anxiogenic stimuli. Pretreatment with MAP (4 mg/kg) and ATX (1.2 mg/kg/day) ameliorated motor hyperactivity but not abnormal anxiety-related behaviors. These results suggest that the dopaminergic system plays a crucial role in the development of neural networks involved in locomotion as well as in those involved in anxiety-related behavior. The results indicate that the mechanisms underlying the abnormal anxiolytic responses partially differ from those underlying motor hyperactivity.

Environmental housing affects the duration of mechanical allodynia and the spinal astroglial activation in a rat model of chronic inflammatory pain

In this study, we aimed at investigating the effect of an enriched environment (EE) on the recovery from chronic inflammatory pain. Inflammatory pain was induced by the injection of 2 mg of carrageenan (CAR) into the right knee of male Sprague-Dawley rats (n=34). Rats were housed either singly (S-housed) or in an EE (EE-housed). The EE consisted of a large cage (L x W x H=2.0 x 1.0 x 0.8 m) containing various attributes (e.g. running wheels, shelter house, climbing frame). Withdrawal response to von Frey filament was used to assess mechanical allodynia at days post-operative (DPO) -1, 1, 7, 14, 21 and 28. S-housed animals showed a marked tactile sensitivity in the ipsilateral paw from DPO1 to DPO21. Four weeks after the CAR injection, S-housed rats were no longer allodynic. In contrast, EE-housed rats showed a significantly faster recovery: already at DPO21, they were no longer allodynic. In a first attempt to analyse the possible role of astroglial cells in the EE-induced effect, histological analysis at DPO21 was performed. Immunohistochemical staining of the spinal dorsal horn at L3-L5 indeed showed that spinal levels of astroglial activation are different between the two housing groups and therefore may play a role in the EE-induced effect on the duration of mechanical allodynia. In conclusion, our results showed that EE-housing results in a reduced duration of mechanical allodynia in chronic inflammatory pain in rats. Astroglial activation is suggested to be involved in this housing effect.

Developmental forebrain cholinergic lesion and environmental enrichment: behaviour, CA1 cytoarchitecture and neurogenesis

Intraventricular injections of 192 IgG saporin in 7-day-old rat severely reduced hippocampal cholinergic innervation as reflected by both decreased acetylcholinesterase staining and immunoreactivity for the p75 neurotrophin receptor. It was determined if this altered the effects of environmental enrichment on spatial learning, hippocampal CA1 cell cytoarchitecture as reflected by the Golgi stain, and neurogenesis in the dentate gyrus as indicated by doublecortin immunoreactivity. At weaning, lesioned and control rats were either group housed in large, environmentally enriched cages or housed two per standard cage for 42 days. When subsequently assessed with a working-memory spatial navigation task, both lesioned and control rats showed enhanced learning as a result of enrichment. Quantitative analysis of Golgi stained sections indicated that enrichment did not affect CA1 dendritic branching, total dendritic length or dendritic spine density. However, the lesion reduced the number of apical branches, spine density on intermediate to distal apical dendrites, and the length of basal branches. It also reduced the number of doublecortin immunoreactive neurons in the dentate gyrus and appeared to prevent their increase due to environmental enrichment. It is concluded that developmental cholinergic lesioning does not attenuate neurobehavioral plasticity, at least as reflected by the behavioral consequences of enrichment. It does, however, attenuate neurogenesis in the dentate gyrus, like adult-inflicted cholinergic lesions. As previously found for cortical neurons, it also reduces CA1 pyramidal cell dendritic complexity and spine density in adulthood. The results have implications for the loss of synapses that occurs in both developmental and aging-related brain disorders involving cholinergic dysfunction.

Sensory experience determines enrichment-induced plasticity in rat auditory cortex

Our previous studies demonstrated that only a few days of housing in an enriched environment increases response strength and paired-pulse depression in the auditory cortex of awake and anesthetized rats [Engineer, N.D., Percaccio, C.R., Pandya, P.K., Moucha, R., Rathbun, D.L., Kilgard, M.P., 2004. Environmental enrichment improves response strength, threshold, selectivity, and latency of auditory cortex neurons. J Neurophysiol. 92, 73-82 and Percaccio, C.R., Engineer, N.D., Pruette, A.L., Pandya, P.K., Moucha, R., Rathbun, D.L., Kilgard, M.P., 2005. Environmental enrichment increases paired-pulse depression in rat auditory cortex. J Neurophysiol. 94, 3590-3600]. Multiple environmental and neurochemical factors likely contribute to the expression of this plasticity. In the current study, we examined the contribution of social stimulation, exercise, auditory exposure, and cholinergic modulation to enrichment-induced plasticity. We recorded epidural evoked potentials from awake rats in response to tone pairs and noise bursts. Auditory evoked responses were not altered by social stimulation or exercise. Rats that could hear the enriched environment, but not interact with it, exhibited enhanced responses to tones and increased paired-pulse depression. The degree to which enrichment increased response strength and forward masking was not reduced after a ventricular injection of 192 IgG-saporin. These results indicate that rich auditory experience stimulates physiological plasticity in the auditory cortex, despite persistent deficits in cholinergic activity. This conclusion may be beneficial to clinical populations with sensory gating and cholinergic abnormalities, including individuals with autism, schizophrenia, and Alzheimer's disease.

Enriched environment exposure regulates excitability, synaptic transmission, and LTP in the dentate gyrus of freely moving rats

Performance in hippocampus-dependent and other tasks can be improved by exposure to an enriched environment (EE), but the physiological changes in neural function that may mediate these effects are poorly understood. To date, there have been conflicting reports regarding potential mechanisms, such as an increase in basal synaptic transmission, an increase in cell excitability, or altered synaptic plasticity. Here, we reexamined in freely moving animals the conditions under which varying degrees of EE exposure might lead to increases in synaptic or neural function in the dentate gyrus of the hippocampus. Adult male Sprague-Dawley rats were chronically implanted with stimulating and recording electrodes in the perforant path and dentate gyrus, respectively, and housed singly in standard cages. After stable recordings were established for field excitatory postsynaptic potentials (fEPSPs) and population spikes (PSs), the effects of various degrees of periodic novel environment exposure for 19 days were assessed. Exposure to an EE increased fEPSPs, but only when animals were kept in nominally low-stress housing conditions. An increase in granule-cell excitability, as evidenced by PS increases, was induced by all environmental treatments with the greatest effect being induced by overnight EE exposure. EE exposure did not change the level of long-term potentiation (LTP) induced by a moderate high-frequency tetanus, but continued EE exposure post-tetanus produced a significantly faster decay of LTP relative to control animals. These results suggest that, in adult animals, EE exposure may augment hippocampal information processing, but may also speed turnover of information in the hippocampus during the maintenance period.

Caffeine as a performance-enhancing drug in rats: sex, dose, housing, and task considerations

Past animal studies of the performance-enhancing properties of stimulant drugs, such as caffeine, may have suffered from a number of procedural and ethical problems. For example. the housing condition of the animals was often not taken into consideration. As well, endurance tests, such as the forced swim task, sometimes involved ethically (and procedurally) questionable interference with natural swimming behaviour. Some of the manipulations, such as attaching a weight to the swimming animal's tail to increase the difficulty of the task and using mortality as a dependent variable, seem grotesque, even unnecessary. In this experiment, the performance-enhancing effects of caffeine in a modified forced swim task and a dominance task were evaluated using male and female rats as subjects (N=60), housed in either enriched or isolated environments. Analysis indicated that rats respond to caffeine as an interactive function of sex, housing, dose, and task characteristics. It was concluded that performance-enhancing properties of stimulant drugs may be the result of a complex interplay of variables, making simple generalizations questionable.

Functional deficits following neonatal dopamine depletion and isolation housing: circular water maze acquisition under pre-exposure conditions and motor activity

Seven experiments and several behavioural tests were performed to study the effects of housing condition and experimental test conditions upon the behavioural responses and performance of adult rats neonatally treated with 6-hydroxydopamine (6-OHDA, 100 ug intracisternally, i.c.) or with vehicle. Postnatal 6-OHDA induced locomotor and total activity hyperactivity and deficits in navigational learning in a circular swim maze that were blocked by pretreatment with a dopamine (DA) reuptake inhibitor but not a noradrenaline (NA) reuptake inhibitor. Isolation-housing induced deficits in maze learning performance. Grouped housing improved the maze learning performance of 6-OHDA treated rats whereas vehicle treated rats that were isolation housed performed better following latent learning (LL) pre-exposure trials. 6-OHDA treated rats that received both Grouped housing and latent learning trials performed better on the spatial navigation task than those that received Grouped housing but no latent learning or Isolation housing and latent learning. Analysis of habituation quotients indicated marked deficits by 6-OHDA-treated rats suggesting inability to acquire this simple, nonassociative form of learning. Methylphenidate increased all three parameters of motor activity: locomotion, rearing and total activity, in both Isolation-housed and Group-housed rats from 60- to 90- or 120-min post-injection. NDO 008 induced variable and parameter-dependent effects: locomotion was elevated initially in both Isolated and Grouped rats by the compound and then reduced in the Isolated rats only whereas total activity was only elevated initially in the Isolated rats and unaffected in the Grouped rats. Rearing behaviour was reduced markedly, directly post-injection, in the Isolation-housed rats. DA, DOPAC and HVA concentrations in the striatum, nucleus accumbens, olfactory tubercle and midbrain were reduced but most markedly in the striatum. 5-Hydroxytryptamine (5-HT) and 5-hydroxyindole acetic acid (5-HIAA) concentrations were elevated in the striatum, nucleus accumbens (not 5-HIAA) and olfactory tubercle.

An enriched environment increases noradrenaline concentration in the mouse brain

Exposure to an enriched environment has been shown to have many positive effects on brain structure and function. In the present study, we examined the effects of environmental enrichment on monoaminergic neurons in the mouse brain. After being exposed to an enriched environment for 40 days, noradrenaline content was increased significantly in the parieto-temporo-occipital cortex, the cerebellum and the pons/medulla oblongata. In contrast, no changes were observed in serotonin or dopamine levels in these same regions.

Cortical plasticity and the development of behavior after early frontal cortical injury

It has been known for over 100 years that frontal lobe injury in children is often associated with considerably more functional recovery than after similar injury in adulthood. Systematic study of frontal cortical injury in laboratory animals has shown that this recovery is tightly tied to developmental age: There is a brief window of time during cortical development during which the brain is able to compensate. Simply being young is not sufficient because injury prior to this critical period leads to miserable behavioral outcomes. For humans, the least favorable time for cortical injury is likely at the end of the gestational period, perhaps including the 1st month or so of life whereas the most favorable time is around 1 to 2 years of age. In addition to age, the extent of behavioral recovery is influenced by age at assessment, the nature of the behavioral assessment, sex, and lesion size. Anatomical studies have shown that functional recovery following early cortical injury is correlated with a reorganization of remaining cortical circuitry, including increased dendritic arborization and increased spine density. Recovery, and the compensatory anatomical changes, can also be potentiated by application of different treatments including behavioral therapy, trophic factors, and neuromodulators. Finally, there is preliminary evidence in laboratory animals to suggest that it may be possible to induce neural regeneration in the injured brain and that the regenerated brain functions to support functional recovery.

Changes in steady-state levels of tryptophan hydroxylase protein in adult rat brain after neonatal 6-hydroxydopamine lesion

A recently developed technique of immunoautoradiography on nitrocellulose transfers of serial frozen sections was used to determine tryptophan hydroxylase concentration in selected areas of the adult rat brain following neonatal 6-hydroxydopamine destruction of nigrostriatal dopamine neurons. Particular attention was paid to the neostriatum, known to be serotonin-hyperinnervated under these conditions, and to the nucleus raphe dorsalis, containing the cell bodies of origin for these nerve terminals. The hippocampus was also investigated as a territory of structurally intact serotonin innervation arising primarily from the nucleus raphe medianus. Tryptophan hydroxylase protein was measured at successive transverse levels across the entire caudorostral extent of all these regions. Similar measurements of tyrosine hydroxylase protein across the substantia nigra and the neostriatum verified the disappearance of the nigrostriatal dopamine neurons. The average tryptophan hydroxylase tissue concentration in the dorsal third of the serotonin-hyperinnervated neostriatum was up by 36% above control, i.e. significantly less than the number of its serotonin axon terminals or varicosities. This was therefore indicative of a lowering of the tryptophan hydroxylase protein content per serotonin ending. Interestingly, a tight correlation between the respective level-by-level concentrations of tryptophan hydroxylase and tyrosine hydroxylase protein in the control neostriatum allowed the prediction the tryptophan hydroxylase concentration after dopamine denervation with a serotonin hyperinnervation. Tryptophan hydroxylase concentration was also significantly reduced in both the nucleus raphe dorsalis and nucleus raphe medianus, notably at those raphe dorsalis levels known to give rise to the serotonin hyperinnervation of neostriatum. It is hypothesized that the lower steady-state level of tryptophan hydroxylase inside the terminals and cell bodies of hyperinnervating serotonin neurons was the result of a feedback inhibition of the synthesis of the enzyme by its end-product, presumably because of the increased amount of serotonin in these terminals.

Enhanced but delayed axonal sprouting of the commissural/associational pathway following a combined entorhinal cortex/fimbria fornix lesion

From previous lesion studies of the hippocampus it has been reported that axons of the commissural/associational pathway expand their termination zone in the molecular layer of the dentate gyrus by 20-25% in response to loss of input from the entorhinal cortex. However, although much is known about the response of the commissural/associational pathway with regard to extent, latency, and speed of the reinnervation response following an entorhinal cortex lesion, little is known about how the loss of additional afferent systems might modulate this response. To address this issue, we examined at 14, 30, and 45 days postlesion, the sprouting of commissural/associational afferents following either a unilateral fimbria fornix transection, a unilateral entorhinal cortex lesion, or combined lesions of both the entorhinal cortex and the fimbria fornix. Loss of septal innervation to the hippocampus was assessed using the cholinesterase stain, whereas sprouting from the commissural/associational pathway was determined from Holmes fiber-stained sections. In addition, the Timms stain was used to examine the time course of the loss of terminal fields of the various zinc-containing afferent systems within the hippocampus. Following the removal of input to the hippocampus via the fimbria fornix transection, there was no evidence of sprouting of the commissural/associational fibers into the deafferented portion of the dentate gyrus. In contrast, rats receiving an entorhinal cortex lesion showed a significant increase (28%) in the width of the commissural/associational fiber plexus that was present by 14 days postlesion. By comparison, the magnitude of the expansion of the commissural/associational fiber plexus was significantly larger after lesioning both the entorhinal cortex and the fimbria than after the entorhinal cortex lesion alone (45% vs. 28%). In addition, the expansion of the commissural/associational fiber plexus was not increased at 14 days postlesion but was significantly increased at 30 days postlesion. The delay in the sprouting of the commissural/associational pathway coincided with the time course of loss of zinc-containing fibers in the outer molecular layer of the dentate gyrus as assessed with the Timms stain. These results suggest that the magnitude and time course for the sprouting of axons from the commissural/associational pathway into the partially deafferented hippocampus of the adult rat is lesion dependent and that the effect of the loss of input from the entorhinal cortex can be modulated and enhanced by the concomitant depletion of input from the fimbria fornix.

Enriched environment primes forebrain choline acetyltransferase activity to respond to learning experience

Weanling rats were raised in an enriched or an impoverished environment. The enriched rats subsequently learned the Morris water maze faster than their impoverished counterparts. The enriched rats, both maze-trained and untrained, showed higher choline acetyltransferase (ChAT) activity in the caudate than did the impoverished, untrained rats. Maze training increased caudate ChAT in impoverished rats. Enriched but not impoverished rats showed increased hippocampal and anterior cortical ChAT activity after maze training. Thus, enrichment causes a long-lasting increase in caudate acetylcholine (Ach) synthesis and it also primes cortex and hippocampus to respond to a training experience with increased Ach synthesis.

Neonatal brain dopamine depletion and the cortical and behavioral consequences of enriched postweaning environment

This study investigated the effects of neonatal intraventricular administration of 6-hydroxydopamine (6-OHDA, 15 micrograms total with and without desmethylimipramine pretreatment) on the cortical thickening and behavioral effects of 35 days of enriched postweaning housing (ENR) in the rat. The 6-OHDA treatment depleted cortical dopamine (DA) to about 40% of control. It did not affect the thickness of the cerebral cortex nor did it affect the capacity for the cortex to be thickened by ENR. In addition, it did not alter the superior performance on two spatial water maze tasks that was caused by ENR. Thus, the potential for neurobehavioral plasticity was not changed by neonatal DA depletion. ENR eliminated the spatial learning/memory deficits that were caused by neonatal DA depletion and that were manifested when the rat was raised in standard (impoverished) laboratory conditions. Hence, environmental factors can modulate the cognitive effects of neonatal DA depletion. ENR did not attenuate the hyperactivity of the neonatal DA-depleted rat. This may reflect the subcortical mediation of this behavioral abnormality.

Neonatal 6-OHDA lesions and rearing in complex environments: regional effects on adult brain 14C-2-deoxyglucose uptake revealed by exposure to novel stimulation

Behavioral and neuromorphological data have suggested at least a partial interaction between the effects of norepinephrine-depleting neonatal 6-OHDA lesions and the effects of rearing in enriched environments. The present study examined the impact of both of these early manipulations upon regional brain uptake of 14C-2-deoxyglucose (14C-2DG) in adulthood. Newborn rats received 6-OHDA (50 mg/kg s.c.) or vehicle and, after weaning at 25 days, were reared in isolated versus enriched conditions. Regional brain 14C-2DG uptake was then examined at 70-80 days of age--either in the home cage or while animals were being exposed to novel, presumably arousing, stimulation. Ninety-seven brain regions were examined in eight separate groups. Results indicated that (1) Under baseline conditions, neither neonatal 6-OHDA nor differential rearing conditions produced widespread alterations in regional brain 14C-2DG uptake profiles. An overall enrichment effect was seen on only five brain areas, with rats reared in enriched environments showing lower levels of 14C-2DG uptake (-20% to -30%) than isolated rats. Neonatal 6-OHDA produced no main effect on 14C-2DG uptake in any brain region. (2) In contrast, when 14C-2DG uptake was assessed during exposure to a novel environment, five brain areas showed differential 14C-2DG uptake in 6-OHDA-treated rats, and 20 brain areas showed differential uptake in rats reared in enriched conditions. (3) No significant interaction effect on brain regional 14C-2DG uptake was observed between neonatal 6-OHDA and environmental complexity factors. These results are consistent with the notion that enduring effects of rearing and early 6-OHDA treatment may, independently, relate to a general reactivity factor. They also indicate that some effects of early neurochemical injury and subsequent experiential factors may not be apparent under normal resting conditions, but only become evident in the presence of appropriate "activating" stimulation.

A computer-aided procedure for measuring Lashley III maze performance

As an animal swims through the Lashley III maze, an observer types into a Macintosh computer the path taken. The computer program, Observe Software, then breaks the string of choices into two-step sequences and counts the number of such sequences. These data are then sent to a spreadsheet, where the sequences are sorted into forward and backward responses. Forward choices are Correct Path, T Choice Errors and Cul Entry Errors. All backward choices are errors, by definition. They are classified as T Choices, Cul Entries, Cul Exits, and Return to Start. The animal's behavior is then described by the various error classes plus a measure called Learning Index. Examples of learning by rats and mice are presented.

Norepinephrine depletion reduces the effects of social and olfactory experience

Control juvenile rats adapted normally to a new home-cage bedding odor if they were caged with rats neonatally treated with 6-hydroxydopa, but not DSP-4. Neither social nor olfactory experience influenced preferences of NE-depleted rats. In some forebrain regions of controls caged with DSP-4 rats, monoamine concentrations were depressed and a metabolite elevated, suggesting the situation was stressful. DSP-4 treatment decreased the effect of footshock on hippocampal cholinergic activity, implying that NE depletion reduced sensitivity to stress. Thus, norepinephrine may modulate the biobehavioral effects of the postweaning olfactory and social environment.

Neonatal and adult forebrain norepinephrine depletion and the behavioral and cortical thickening effects of enriched/impoverished environment

Two experiments examined the effects of neonatal or adult intracerebral injections of 6-hydroxydopamine (6-OHDA) on the effects of enriched (ENR) vs. impoverished (IMP) housing conditions. In Expt. 1, neonatal rats received intraventricular injections of 6-OHDA after pretreatment with buproprion to destroy norepinephrine (NE) terminals while lessening damage to dopamine (DA) terminals. The rats were subsequently raised in either enriched or impoverished environments and then tested for their spatial problem-solving ability in an automated Hebb-Williams maze. Littermates did not undergo this testing but were instead assessed for cortical thickness. Despite the substantial depletion of NE in the forebrains of the 6-OHDA-treated rats, they responded to enriched rearing as did the control rats, i.e., they solved the Hebb-Williams problems more efficiently than their impoverished reared counterparts and they showed thicker cortices. In Expt. 2, adult rats received 6-OHDA lesions of the dorsal noradrenergic bundle and were then relegated to enriched or impoverished housing for 42 days. Subsequently, the enriched-housed rats solved the Hebb-Williams mazes more efficiently than their impoverished-housed counterparts and this effect of housing was not altered by the dorsal bundle lesion which severely depleted forebrain NE. These two experiments do not support a role for forebrain NE in the alteration of the rat cortex and behavior by environmental enrichment. It was concluded that the cognitive effects of enriched rearing do not require intact forebrain NE but that they may be influenced by the peripheral sympathectomy that is one consequence of neonatal systemic 6-OHDA injections.

The role of norepinephrine in adult rat somatosensory (SmI) cortical metabolism and plasticity

Stimulation of rat facial vibrissae increases glucose utilization in the corresponding barrels (lamina IV) and associated columns in laminae I-VIa of the contralateral first somatosensory (SmI) cortex as assessed autoradiographically by the uptake of [14C]2-deoxy-glucose (2-DG). Chronic deafferentation (2 months) by bilateral vibrissectomy with sparing of the C3 vibrissa (SC3) in adult Sprague-Dawley rats produced no change in the rate of LCGU but led to an increased areal extent of the metabolic representation of the SC3 barrel (39%, P less than 0.001) and column (31%, P less than 0.003) as compared to rats with fully intact vibrissae. In other rats with intact facial vibrissae, 6-hydroxydopamine lesions of the locus coeruleus (LC) depleted ipsilateral cortical norepinephrine (NE) by more than 90% and, 2 months later, led to an 11% and 21% increase in C3 barrel and column metabolic representations, respectively, as compared to the contralateral SmI cortex with intact NE levels (P less than 0.05). When bilateral vibrissectomy was combined with a unilateral LC lesion, the SC3 barrel and column metabolic representation on the LC-intact side enlarged as expected but no enlargement occurred on the NE-depleted side (20% difference; P less than 0.05). Therefore, the effect of NE on the SmI cortex depends on the status of its afferent input. NE inhibits the spread of metabolic activity beyond the activated barrel and column in the intact cortex, but independently modulates plastic enlargement in the partially deafferented SmI cortex.

Forebrain norepinephrine and neurobehavioral plasticity: neonatal 6-hydroxydopamine eliminates enriched-impoverished experience effects on maze performance

Newborn male rats were depleted of forebrain norepinephrine (NE) by systemic 6-hydroxydopamine injection and then reared from 25 to 60 days under either isolated or enriched conditions. They were subsequently tested for acquisition of either the Lashley III maze or the Hebb-Williams maze problems. Isolated rearing impaired Lashley maze performance of the controls but not the 6-OHDA injected rats. Similarly, for the Hebb-Williams maze, the isolation-reared controls made more errors than their enriched-reared counterparts while no differences were observed between the isolated and enriched reared, 6-OHDA injected rats. These results are consistent with the hypothesis that forebrain NE is permissive to the deleterious behavioral consequences of restricted experience during maturation.

Regional brain catecholamines and memory: effects of footshock, amygdala implantation, and stimulation

Previous findings have revealed a correlation between post-training release of whole brain norepinephrine (NE) and later retention performance. The present experiment examined changes after a training footshock in NE levels, as well as the levels of the major central NE metabolite, 3-methoxy-4-hydroxyphenylglycol (MHPG), dopamine (DA), and epinephrine (EPI) in eight brain regions. Brain levels of these amines and the metabolite were assessed 10 min after training in a one-trial inhibitory (passive) avoidance task. The results indicate that NE levels decreased significantly in neocortex, neostriatum, hypothalamus, frontal pole, septum, and brainstem, but not in hippocampus or thalamus. The decreases in NE levels were generally accompanied by increases in MHPG; the MHPG/NE ratio increased significantly in all areas in which decreases in NE were observed. DA levels decreased in neostriatum and increased in neocortex and brainstem. Epinephrine levels decreased only in the brainstem sample. Thus, the effects of training on NE are widespread, probably reflecting the release of the amine in most brain regions. Such findings are consistent with the view that posttraining release of brain NE may modulate the storage of new information in many brain regions. One especially potent treatment for modulating memory storage is electrical stimulation of the amygdala. Therefore, we also examined the effects of amygdala implantation and stimulation on brain catecholamine levels to determine whether such changes might be correlated with the effects of amygdala stimulation on memory. The results indicate that electrode implantation into the amygdala results in pervasive changes in NE levels in most brain regions tested. Against this modified baseline, the results of training and electrical stimulation were region specific and very difficult to interpret. The major conclusion which can be derived from this portion of the experiment is that the amygdala damage produced by electrode implantation produces a brain which is substantially different from that of intact animals.

Effects of neonatal 6-hydroxydopamine treatment upon morphological organization of the posteromedial barrel subfield in mouse somatosensory cortex

While recent studies indicate that proposed regulation of visual cortex plasticity by norepinephrine (NE) probably involves 6-hydroxydopamine (6-OHDA) effects other than NE depletion, reports of diminished neuronal maturation and reduced postweaning sensitivity to environmental conditions in animals treated with anti-adrenergic compounds continue to suggest a role for NE in neocortical development. To assess its possible role in development of a highly organized neocortical structure, the effects of postnatal 6-OHDA administration upon development of the somatosensory cortical posteromedial barrel subfield (PMBSF), which subserves the large facial whiskers, were observed in mice with whiskers in the middle row of the face removed unilaterally. Treatment with 6-OHDA caused 96-98% depletion of NE in parietal cortex. There were no effects of (or lesion interactions with) 6-OHDA treatment on barrel size in measures of Nissl-stained neurons, and 6-OHDA effects on numerical measures of dendritic branching of Golgi-impregnated non-pyramidal neurons in PMBSF were negligible. There were, however, effects of 6-OHDA treatment upon the highly ordered arrangement of dendrites within barrels. In 6-OHDA-treated animals, the class I (spiny and sparsely spined) cell dendrites were less attracted to the barrel hollow. In controls, for class I cells with their somata within the barrel wall, there was a high correlation between the distance from the soma to the hollow and the amount of dendrite in the wall, reflecting the distance the dendrite traverses to the hollow. In 6-OHDA-treated animals, this correlation was absent, i.e., cells at any distance from the hollow tended to have a high percentage of dendrite in the wall.(ABSTRACT TRUNCATED AT 250 WORDS)

Near-total loss of 'learning' and 'memory' as a result of combined cholinergic and serotonergic blockade in the rat

Previous work has indicated that activation of the cerebral cortex (i.e. elicitation of low-voltage fast activity in the neocortex and rhythmical slow activity in the hippocampus) is dependent on corticipetal cholinergic and serotonergic projections. Treatment with a combination of p-chlorophenylalanine (an inhibitor of the synthesis of serotonin) plus atropine or scopolamine (muscarinic cholinergic antagonists) can suppress all cerebral activation. In this paper, the behavioral effects of single or combined blockade of cholinergic and serotonergic neurotransmission were studied using a shock avoidance test, an open field test, a swim-to-platform test, a hypothalamic self-stimulation test and a test of grooming behavior. The results show that blockade of cerebral activation produces a condition analogous to global dementia but does not produce sleep or coma. The hypothesis that cholinergic and serotonergic neurotransmission provides a basis for learning and memory is discussed critically.

Peripheral, autonomic regulation of locus coeruleus noradrenergic neurons in brain: putative implications for psychiatry and psychopharmacology

In 1946 von Euler identified the major transmitter of sympathetic nerve fibers, norepinephrine (NE), and about a decade later Vogt (1954) provided the first evidence that NE may also serve as a neurotransmitter in the central nervous system (CNS). Since that time, a literal explosion in CNS neurotransmitter research has taken place involving histological, biochemical, physiological, pharmacological and clinical investigations. Yet, it is only now that we are beginning to understand the biological function of NE in brain, in particular because of recent advances regarding the physiology and regulation of NE neurons in locus coeruleus (LC), a bilateral pontine structure with a uniquely wide-spread terminal network reaching throughout the neuroaxis and in primates accounting for about 70% of all brain NE. Recently, the neurobiology of the LC noradrenergic network was extensively reviewed by Foote et al. (1983), and its implication in vigilance as well as global orientation of behavior towards imperative, environmental sensory stimuli was outlined. Yet, more recent information regarding the peripheral, autonomic regulation of LC neurons in brain provides fundamentally new biological aspects on behavior and mental function which seem to allow a more integrated view of the rôle of brain NE in the overall function of the individual than previously understood. The purpose of this review is to summarize these findings and, furthermore, to outline some putative implications for psychiatry and neuropsychopharmacology.(ABSTRACT TRUNCATED AT 250 WORDS)

Selective lesioning of forebrain noradrenaline neurons at birth abolishes the improved maze learning performance induced by rearing in complex environment

The effect of selective destruction of forebrain noradrenaline (NA) neurons induced by 6-hydroxydopamine (6-OHDA) at Day 1 after birth on Hebb-Williams maze performance was investigated in adult rats housed after weaning in a complex environment (EC) or an isolated (IC) environment for 35 days. Saline treated control rats raised in the EC made fewer errors than those raised in the IC. This effect of EC was completely abolished in 6-OHDA treated rats; for these animals no improved performance due to the housing condition was obtained. Protection of the NA neurons against 6-OHDA neurotoxicity by pretreatment with desipramine (DMI) resulted in an effect of EC identical to that seen in saline-treated controls. Postweaning housing in the IC led to an increased locomotion as compared to housing in EC, but this effect was not affected by neonatal 6-OHDA and/or DMI treatment. Neurochemical analysis confirmed cortical NA and metabolite depletion as well as a good protection by the DMI pretreatment. The present results indicate that central NA neurons are involved critically in mediating mainly the cognitive components of behavioral alterations induced by EC.

Forty minutes of experience increase the weight and RNA content of cerebral cortex in periadolescent rats

The goal of this work was to determine the shortest period of exposure to environmental complexity (EC) that would produce measurable changes in brain weight or RNA content. This period varied with the age of subjects. In young adult rats, 3 months old, 4 days of exposure to EC increased the RNA concentration in the occipital cortex above the level of littermates kept in impoverished condition (IC). Cortical weight was not affected. Seven or one daily hrs of exposure to EC did not produce significant differences between rats in EC and IC. In periadolescent rats, 30- to 40-day-old, 1 daily hr of enrichment for 4 days increased both the weight of occipital cortex and its RNA content. Exposures of 7 or 24 hrs/day produced similar results. In another experiment with periadolescent rats 1 hr or even 10 min of exposure to EC per day, for 4 days, increased total cortical weight and RNA content. Thus, periadolescent rat brain display remarkably high plasticity. These very short exposure periods are comparable to the duration of learning sessions in simple formal trainings.

Effects of neonatal forebrain noradrenaline depletion on recovery from brain damage: performance on a spatial navigation task as a function of age of surgery and postsurgical housing

The experiments examined the contributions of forebrain noradrenaline and environmental enrichment to recovery of place navigation ability in rats after hemidecortication in infancy or adulthood. Noradrenaline depletion did not affect recovery from neonatal hemidecortication, although the early hemidecortications did allow sparing of function relative to adult operates. Noradrenaline depletion also failed to attenuate the positive effects of enriched housing on otherwise normal rats. Noradrenaline depletion did retard recovery of adult hemidecorticate rats housed in standard laboratory cages, but it did not retard recovery of adult hemidecorticate rats housed in enriched environments. The results suggest that noradrenaline is importantly involved in enhancing recovery from brain damage when other sources of compensation (e.g., neonatal injury, enriched environment) are absent.

Acetylcholine-rich neuronal grafts in the forebrain of rats: effects of environmental enrichment, neonatal noradrenaline depletion, host transplantation site and regional source of embryonic donor cells on graft size and acetylcholinesterase-positive fibre outgrowth

The importance of several factors influencing the survival of cholinergic-rich embryonic tissue transplanted to the adult rat forebrain and the extent of acetylcholinesterase-positive fibre innervation of the host brain was investigated in 3 experiments. In the first two experiments, embryonic ventral forebrain tissue was grafted to the neocortex of rats in which the intrinsic cortical cholinergic innervation had been removed by nucleus basalis lesions. Housing the host rats in an enriched environment produced a temporary enhancement of fibre outgrowth 4 weeks after transplantation, but this was not maintained after 10 weeks. Fibre outgrowth was greater when the grafts were transplanted to the noradrenaline-depleted neocortex than to the intact neocortex. Neither environmental enrichment nor noradrenaline depletion influenced graft survival or size. In the third experiment, the embryonic donor tissue was dissected to separate regions containing precursors of the nucleus basalis cholinergic cells from regions containing precursors of the septal cholinergic cells, and transplanted to either the neocortex following nucleus basalis lesions or to the hippocampus following fimbria-fornix lesions. Nucleus basalis grafts showed greater growth in size than septal grafts, and grafts placed into the hippocampus showed greater growth in size than grafts placed into the neocortex. More interestingly, the extent of fibre outgrowth depended on the appropriateness of the donor tissue to the host transplantation site: nucleus basalis tissue showed greater acetylcholinesterase-positive outgrowth than septal tissue in the neocortex, whereas septal tissue showed greater outgrowth than nucleus basalis tissue in the hippocampus.

Neonatal 6-hydroxydopamine lesion of forebrain norepinephrine does not eliminate critical period for behavioral effects of gonadal hormone manipulation

Newborn rats were injected s.c. with 6-hydroxydopamine to deplete forebrain norepinephrine (NE) or with the vehicle. The males were then castrated at 4 days and the females injected with testosterone at 5 days of age. Both sexes were tested for female-like sexual responsiveness to a stud male at 6 months of age. The loss of forebrain NE did not prevent the feminization of the males due to castration or the masculinization of the females due to testosterone. This result contraindicates a general permissive-requisite role for forebrain NE for the mammalian brain's plasticity during its critical periods.

Growth and plasticity of rat cerebral cortex after central noradrenaline depletion

Male Wistar rats (aged 31 to 33 days) received bilateral intraventricular injections of saline or 6-hydroxydopamine and were subjected to either "standard" or "enriched" rearing conditions for 42 days. The treatment reduced cerebral cortical noradrenaline by 80% and decreased the growth of the cerebral cortex. It did not, however, prevent experience in an enriched environment from enhancing the growth of the cerebral cortex.

The role of noradrenaline in tuning and dopamine in switching between signals in the CNS

Neuronal catecholaminergic activity modulates central nervous function. Specifically noradrenaline can exert a tuning or biassing function whereby the signal to noise ratio is altered. Dopamine activity may promote switching between inputs and outputs of information to specific brain regions. It has been ten years since evidence for a tuning function was advanced for noradrenaline and in the last 5 years the switching hypothesis for dopamine has been tentatively put forward. Recent studies are reviewed to show that while catecholamine activity contributes to neural interactions in separate brain regions that give rise to the organization of different functions, their working principles may be common between species and independent of the nucleus of origin. Behavioral examples are discussed and an attempt is made to integrate this with evidence from intracellular recording studies. It is suggested that the tuning principle in noradrenergic systems is particularly important for the formation of associations and neural plasticity (interference control) and that the switching principle of dopaminergic systems modulates the timing, time-sharing and initiation of responses (program-control).

Amphetamine with experience promotes recovery of locomotor function after unilateral frontal cortex injury in the cat

In cats, a single dose of D-amphetamine (AMP) given at 10 days after unilateral frontal cortex ablation produced an immediate and enduring (60 day) acceleration of beam-walking ability compared to saline control animals. Four doses of AMP at 4-day intervals promoted recovery faster than a single dose of AMP. Subjects with no beam-walking experience while under AMP intoxication were not different from saline controls after two doses of AMP. However, after 4 doses these cats recovered significantly faster than saline controls and were comparable to animals that received AMP and experience under the drug.