AMPA glutamate receptor subunits 1 and 2 regulate dendrite complexity and spine motility in neurons of the developing neocortex.

Within neurons of several regions of the CNS, mature dendrite architecture is attained via extensive reorganization of arbor during the developmental period. Since dendrite morphology determines the firing patterns of the neuron, morphological refinement of dendritic arbor may have important implications for mature network activity. In the neocortex, a region of brain that is sensitive to activity-dependent structural rearrangement of dendritic arbor, the proportion of AMPA receptors increases over the developmental period. However, it is unclear whether changes in AMPA receptor expression contribute to maturation of dendritic architecture. To determine the effects of increasing AMPA receptor expression on dendrite morphology and connectivity within the neocortex, and to determine whether these effects are dependent on specific AMPA receptor subunits, we overexpressed the AMPA glutamate receptor subunit 1 (GluR1) and glutamate receptor subunit 2 (GluR2) in cultured rat neocortical neurons at the time that AMPA receptors would normally be incorporated into synapses. Following expression of GluR1 or GluR2 we observed increases in the length and complexity of dendritic arbor of cortical neurons, and a concurrent reduction in motility of spines. In addition, expression of either subunit was associated with an increased density of excitatory postsynaptic puncta. These results suggest that AMPA receptor expression is an important determinant of dendrite morphology and connectivity in neocortical neurons, and further, that contrary to other regions of the CNS, the effects of AMPA receptors on dendrite morphology are not subunit-specific.

Experience-dependent development of spinal motor neurons.

Locomotor activity in many species undergoes pronounced alterations in early postnatal life, and environmental cues may be responsible for modifying this process. To determine how these events are reflected in the nervous system, we studied rats reared under two different conditions-the presence or absence of gravity-in which the performance of motor operations differed. We found a significant effect of rearing environment on the size and complexity of dendritic architecture of spinal motor neurons, particularly those that are likely to participate in postural control. These results provide evidence that neurons subserving motor function undergo activity-dependent maturation in early postnatal life in a manner analogous to sensory systems.

Expression of the N-methyl-D-aspartate receptor subunit NR3B regulates dendrite morphogenesis in spinal motor neurons.

During postnatal development, the dendrites of spinal motor neurons are refined in an activity-dependent manner that can be influenced by blocking activation of N-methyl-D-aspartate (NMDA) receptors. In late postnatal life, dendritic refinement ceases, and dendrite architecture is unaffected by NMDA antagonists; however the molecular substrate for limiting dendritic plasticity is not understood. During late postnatal development, expression of the NR3B NMDA receptor subunit, a putative dominant-negative subunit that reduces glutamate-induced ionic currents, is upregulated within motor neurons. To investigate whether increasing NR3B expression may contribute to the loss in late development of activity-dependent dendritic reorganization in the spinal cord, we over-expressed NR3B in cultured rat spinal motor neurons, and compared its effects on dendrite morphology with the effects of pharmacological blockade of NMDA receptors. We found that over-expression of the NR3B receptor subunit increased the length and complexity of dendritic arbor, and increased numbers of dendritic filopodia, suggesting that NR3B promotes the addition of branch segments in developing motor neurons. In contrast, blockade of NMDA receptor activity by the NMDA antagonist DL-2-amino-5-phosphonovalerate (AP5) had little effect on the overall length or complexity of dendritic arbor. Instead, treatment with AP5 resulted in significant reorganization of dendritic arbor in a manner that favored addition of dendritic segments of high branch orders, at the expense of those closer to the cell body. These results suggest that expression of the NR3B subunit may participate in activity-dependent reorganization of dendritic architecture, but via a mechanism that may be inconsistent with loss of NMDA receptor activity.

Clozapine preferentially increases dopamine release in the rhesus monkey prefrontal cortex compared with the caudate nucleus.

Despite substantial differences between species in the organization and elaboration of the cortical dopamine innervation, little is known about the pharmacological response of cortical or striatal sites to antipsychotic medications in nonhuman primates. To examine this issue, rhesus monkeys were chronically implanted with guide cannulae directed at the principal sulcus, medial prefrontal cortex, premotor cortex, and caudate nucleus. Alterations in dopamine release in these discrete brain regions were measured in response to administration of clozapine or haloperidol. Clozapine produced significant and long-lasting increases in dopamine release in the principal sulcus, and to a lesser extent, in the caudate nucleus. Haloperidol did not produce a consistent effect on dopamine release in the principal sulcus, although it increased dopamine release in the caudate. Clozapine's preferential augmentation of dopamine release in the dorsolateral prefrontal cortex supports the idea that clozapine exerts its therapeutic effects in part by increasing cortical dopamine neurotransmission.

Increases in hippocampal and frontal cortical acetylcholine release associated with presentation of sensory stimuli.

In vivo microdialysis was employed to monitor acetylcholine release in the hippocampus and frontal cortex of freely behaving rats. Four stimuli were presented on separate occasions in the course of a dialysis session to rats with microdialysis probes implanted in the hippocampus or frontal cortex. Visual, auditory, olfactory and tactile stimuli elicited a number of different responses such as exploratory and consummatory behaviours. Presentation of two of the stimuli (auditory and tactile) also produced periods of alert immobility (freezing). All of the stimuli increased acetylcholine release in both the hippocampus and cortex: in the hippocampus, this increase was statistically significant with all except the olfactory stimulus, whereas in the cortex all but the visual stimulus resulted in significant increases. In the hippocampus, there were no significant differences between the increases in acetylcholine release produced by the four stimuli. In contrast, in the cortex, there was significant variation between the magnitude of acetylcholine release produced by the different stimuli: acetylcholine release elicited by tactile stimulation was greater than that produced by the other stimuli. There was no significant variation in the duration of increases in acetylcholine release produced by the stimuli in either the hippocampus or cortex. These results provide evidence that acetylcholine release is associated with a variety of behavioural responses to stimuli designed to produce arousal, and point to a role for cortical and hippocampal cholinergic mechanisms in arousal or attention. Further, the results suggest that under some circumstances cortical and hippocampal acetylcholine release may be regulated differentially.

Enhanced acetylcholine release in hippocampus and cortex during the anticipation and consumption of a palatable meal.

In rats trained for 14 days to consume a palatable liquid chocolate meal (Sustacal), in vivo brain microdialysis was used to measure release of acetylcholine in the frontal cortex and hippocampus during anticipation and consumption of the meal. Rats were trained in an experimental chamber in which they were separated from the Sustacal by a screen for 20 min (trained, rewarded group). The screen was then removed and the rats were allowed 20 min of access to the meal. Two control groups were run concurrently: these groups consisted of rats (i) that were trained over 14 days but only had access to water in the experimental chamber (trained, non-rewarded), or (ii) that were introduced into the experimental chamber for the first time on the final test (i.e. dialysis) session, and presented with Sustacal (naive). Different results were obtained in the hippocampus and frontal cortex. In the hippocampus there were no group differences with respect to acetylcholine release. Thus, in all three groups acetylcholine release increased to about 220% of basal values when animals were placed in the experimental chamber. In the frontal cortex, acetylcholine release also increased significantly in all three groups. However, the extent of this increase was significantly greater in the trained, rewarded group, reaching approximately 300% of basal values during the anticipatory and consummatory components of the task. The significant increases in acetylcholine release which occurred in both the hippocampus and frontal cortex of each of the three groups are consistent with an involvement of cholinergic basal forebrain neurons in the regulation of arousal or attention. In addition, however, acetylcholine release in the frontal cortex can be further selectively enhanced by the animal's past training experience, perhaps being associated with the anticipation of reward.

Modest cholinergic deafferentation fails to alter hippocampal G-proteins.

The integrity of hippocampal G-protein mediated signalling following ibotenate induced lesion of the medial septum was examined. The lesion was confined histologically to the septum and induced a 23% reduction in hippocampal choline acetyltransferase (ChAT) activity and G-proteins levels and related enzyme activities were measured in the hippocampus following a 21 day survival period. The relative levels of five G-protein subunits (Gbeta, G(alpha)o, G(alpha)i1, G(alpha)i2, and G(alpha)s-L), basal GTPase, the degree of carbachol- or baclofen-stimulated GTPase activities, and the basal and fluoroaluminate-stimulated adenylate cyclase activities were apparently unaffected. To determine if our assay methodology was sensitive to changes in pre-synaptic signalling, we compared G-protein density in synaptosomes with total hippocampal homogenates. The concentration of G(alpha)q/11, G(alpha)i1, and G(alpha)i2. were significantly lower in synaptosomes, while G(alpha)o, was only marginally reduced. Thus, modest lesions of the medial-septal nucleus fail to alter G-protein signalling. However, our findings that G-protein density is lower in synaptosomal membranes than in total homogenates, indicates that the analysis of signalling events in synaptosomes following deafferentation could clarify adaptive changes which may occur at the presynaptic level.

Focal increases in [3H]forskolin and [3H]phorbol 12,13-dibutyrate binding in the rat brain following lesions of the medial septum.

Quantitative autoradiography of [3H]forskolin binding to GS-adenylate cyclase and [3H]phorbol 12,13-dibutyrate (PDBu) binding to protein kinase C (PKC) was examined 21 days following ibotenate lesion of the rat medial septum. A significant reduction (-19%) in [3H]forskolin binding was observed at the lesion site in the medial septum compared to the sham-treated group. A significant increase in [3H]forskolin binding was demonstrated in the polymorph layer of the detante gyrus (19%) in animals with medial septal lesions whilst in all other brain regions, [3H]forskolin binding remained unaltered post-lesion. [3H]PDBu binding was significantly increased in the superficial layers (I-III) of entorhinal cortex (27%) following lesion of the medial septum, and remained unaltered in all other brain regions post-lesion. The nature and location of the alterations (namely elevations) in ligand binding sites remote from the lesioned area are supportive of plastic modifications of second messenger systems following denervation.

Transient glucose hypermetabolism after acute subdural hematoma in the rat.

Ischemic brain damage occurs in most patients with acute subdural hematoma, yet many aspects of the distribution and extent of this damage remain unexplained. Previous studies in rat model, which produces a region of infarction under the hematoma, have implicated an "excitotoxic" mechanism, suggesting that high concentrations of excitatory amino acids may exacerbate ischemic damage. A study is described in which local glucose utilization is measured 2 or 4 hours after induction of acute subdural hematoma in the rat. These changes are compared to those produced by introducing the same volume of inert silicone gel into the subdural space. Massive increases (up to 142%) in glucose utilization occurred throughout both hippocampi and in a variable zone around the ischemic core, but these had normalized by 4 hours after blood injection. Hippocampal hypermetabolism was not seen after introduction of the silicone mass, suggesting that diffusible substances from the clotted blood may be responsible for these changes. This transient hypermetabolism accords with an excitotoxic process, which may amplify brain damage after acute subdural hematoma.

Dopaminergic innervation of the amygdala is highly responsive to stress.

The amygdala has been implicated in the neuronal sequelae of stress, although little is known about the neurochemical mechanisms underlying amygdala transmission. In vivo microdialysis was employed to measure extracellular levels of dopamine in the basolateral nucleus of the amygdala in awake rats. Once it was established that impulse-dependent release of dopamine could be measured reliably in the amygdala, the effect of stress, induced by mild handling, on amygdala dopamine release was compared with that in three other dopamine-innervated regions, the medial prefrontal cortex, nucleus accumbens, and caudate nucleus. The magnitude of increase in dopamine in response to the handling stimulus was significantly greater in the amygdala than in the nucleus accumbens and prefrontal cortex. This increase was maximal during the application of stress and diminished after the cessation of stress. In contrast, the increases in extracellular dopamine levels in other regions, in particular the nucleus accumbens, were prolonged, reaching maximal values after the cessation of stress. These results suggest that dopaminergic innervation of the amygdala may be more responsive to stress than that of other dopamine-innervated regions of the limbic system, including the prefrontal cortex, and implicate amygdalar dopamine in normal and pathophysiological processes subserving an organism's response to stress.

Defective fluid and HCO(3)(-) absorption in proximal tubule of neuronal nitric oxide synthase-knockout mice.

Using renal clearance techniques and in situ microperfusion of proximal tubules, we examined the effects of N(G)-monomethyl-L-arginine methyl ester (L-NAME) on fluid and HCO(3)(-) transport in wild-type mice and also investigated proximal tubule transport in neuronal nitric oxide synthase (nNOS)-knockout mice. In wild-type mice, administration of L-NAME (3 mg/kg bolus iv) significantly increased mean blood pressure, urine volume, and urinary Na(+) excretion. L-NAME, given by intravenous bolus and added to the luminal perfusion solution, decreased absorption of fluid (60%) and HCO(3)(-) (49%) in the proximal tubule. In nNOS-knockout mice, the urinary excretion of HCO(3)(-) was significantly higher than in the wild-type mice (3.12 +/- 0.52 vs. 1. 40 +/- 0.33 mM) and the rates of HCO(3)(-) and fluid absorption were 62 and 72% lower, respectively. Both arterial blood HCO(3)(-) concentration (20.7 vs. 25.7 mM) and blood pH (7.27 vs. 7.34) were lower, indicating a significant metabolic acidosis in nNOS-knockout mice. Blood pressure was lower in nNOS-knockout mice (76.2 +/- 4.6 mmHg) than in wild-type control animals (102.9 +/- 8.4 mmHg); however, it increased in response to L-NAME (125.5 +/- 5.07 mmHg). Plasma Na(+) and K(+) were not significantly different from control values. Our data show that a large component of HCO(3)(-) and fluid absorption in the proximal tubule is controlled by nNOS. Mice without this isozyme are defective in absorption of fluid and HCO(3)(-) in the proximal tubule and develop metabolic acidosis, suggesting that nNOS plays an important role in the regulation of acid-base balance.

An antisense oligonucleotide reverses the footshock-induced expression of fos in the rat medial prefrontal cortex and the subsequent expression of conditioned fear-induced immobility.

The immediate-early genes, including c-fos, have been proposed to be involved in learning and memory. In this report, we examine stress-induced Fos-like immunoreactivity (Fos-li) in subregions of the prefrontal cortex during a conditioned fear paradigm. During the acquisition phase, the rats were conditioned to fear a formerly neutral tone by pairing the tone with a mild footshock. The rats were then tested for fearful behavior by reexposure to the tone without additional footshock. During acquisition, Fos-li was increased in the medial prefrontal cortex (infralimbic and prelimbic) but not the anterior cingulate and M1 motor cortex. However, during the extinction phase, no significant increase in Fos-li was observed in any region. These findings indicate that acquisition, but not extinction, of conditioned fear is associated with an increase in Fos-li in subregions of the medial prefrontal cortex. In other animals, an antisense oligonucleotide directed against the c-fos mRNA was injected into the infralimbic/prelimbic cortex 12 or 72 hr before the acquisition session. Antisense treatment given 12, but not 72, hr earlier suppressed Fos production without altering behavior during the acquisition session. Three days after the acquisition session, rats were tested for fearful behavior as before. The antisense oligonucleotide blockade of Fos production during acquisition was associated with a significantly less fearful response during the extinction session. These results support a role for Fos in the medial prefrontal cortex during the acquisition of aversive learning.

The role of nitric oxide and NMDA receptors in the development of motor neuron dendrites.

Nitric oxide (NO) has been implicated in the establishment of precise synaptic connectivity throughout the neuroaxis in several species. To determine the contribution of NO to NMDA receptor-dependent dendritic growth in motor neurons, we administered the NMDA antagonist MK-801 to wild-type mice and neuronal nitric oxide synthase (nNOS) knock-out mice between postnatal days 7 and 14. Compared to saline-treated wild-type animals the number of dendritic bifurcations was significantly reduced in nNOS knock-out animals and MK-801-treated wild-type animals. There was no significant difference in dendritic bifurcation between MK-801-treated wild-type, MK-801-treated nNOS knock-out, and saline-treated nNOS knock-out animals, suggesting that nNOS knock-out and NMDA receptor block had similar effects. The path of the longest dendrite and the number of primary dendrites was the same in all treatment groups, indicating an effect specific to bifurcation. Sholl analysis revealed that differences in bifurcation numbers occurred between 160 and 320 micrometers from the cell body, the distance at which second, third, and fourth order dendrites are most prevalent. Dendrite order analyses confirmed a significant reduction in numbers, but not lengths, of third and fourth order dendrites in nNOS knock-out and drug-treatment groups. Finally, immunohistochemical examination of the developing spinal cord indicated that NMDA receptors and nNOS are colocalized within interneurons surrounding the motor neuron pool. These results support the view that at least part of NMDA receptor-dependent arborization of motor neuron dendrites is mediated by the local production of NO within the developing spinal cord.

Ischaemic brain damage associated with tissue hypermetabolism in acute subdural haematoma: reduction by a glutamate antagonist.

Ischaemia results in elevated extracellular glutamate concentrations, and drugs which act at the N-methyl-D-aspartate sub-type of glutamate receptor have been shown to decrease ischaemic brain damage. Because almost all patients who die after severe head injury demonstrate ischaemic brain damage, and acute subdural haematoma (ASDH) is one of the commonest complications of severe head injury, we have studied this condition in a rat model. Using double-label autoradiography, we have measured the effects of ASDH on cerebral glucose utilization and cerebral blood flow (RCBF). Following ASDH, increased glucose utilisation was observed in some cortical and hippocampal structures, without concomitant increases in blood flow. Directly below the ASDH, blood flow and glucose utilization were profoundly reduced. Pre-treatment with D-CPP-ene, a competitive NMDA antagonist, resulted in amelioration of hypermetabolism induced by the ASDH. The results suggest that NMDA antagonists may prevent ischaemic brain damage after ASDH by reducing hypermetabolism, induced by glutamatergic mechanisms.