Varda Greenberger

Quantitative histochemistry of brain acetylcholinesterase and learning rate in the aged rat

Using a newly developed method for quantitative acetylcholinesterase (AChE) histochemistry we find a substantial decrease in AChE content in aged rats compared to young controls in the cholinergic cell body regions (the ventral pallidum and the medial septal nuclei) and, to a smaller extent in the projection areas (the cortex and hippocampus). In the same group of aged rats we find a severe deficit in the acquisition of a water maze task. Quantitative histochemistry is a potent method for detecting localized changes in AChE content in otherwise intact, learning-impaired aged rats.

Aging and brain cholinergic muscarinic receptor subtypes: an autoradiographic study in the rat.

Cholinergic M1 and M2 muscarinic receptors in aged and young rat brains were studied by quantitative autoradiography of tritiated QNB in the presence of pirenzepine or carbachol. A selective pattern of decreased binding density was observed in the aged rat. A large number of regions showed no effect of aging; these include subdivisions of the hippocampal formation and most thalamic and hypothalamic nuclei. M1 and M2 receptors showed small but significant decreases in cortical regions and in the striatum. The largest effects were seen in M2 receptors of the ventral forebrain cholinergic nuclei where binding was reduced by up to 40%. No similar reductions were seen in the M1 receptor population in these regions. The results suggest that both muscarinic receptor subtypes show an anatomically selective pattern of decrease with age, with the M2 receptor subtype in the basal forebrain nuclei being specially vulnerable to the effects of aging.

Formation of dendritic spines in cultured striatal neurons depends on excitatory afferent activity.

The role of afferent innervation in the formation of dendritic spines was studied in cultured rat striatum. The striatum is a unique structure in that it contains highly spiny GABAergic projection neurons, with no known local excitation. Grown alone in culture, striatal neurons did not express spontaneous network activity and were virtually devoid of dendritic spines. Adding GFP‐expressing mouse cortical neurons to the striatal culture caused the appearance of spontaneous and evoked excitatory synaptic currents in the striatal neurons and a 10‐fold increase in the density of spines on their dendrites. This effect was blocked by a continuous presence of TTX in the growth medium, while removal of the drug caused a rapid appearance of spines. Exposure to glutamate, or the presence of cortex‐conditioned medium did not mimic the effect of cortical neurons on formation of spines in the striatal neurons. Also, the cortical innervation did not cause a selective enhancement of survival of specific subtypes of spiny striatal neurons. These experiments demonstrate that excitatory afferents are necessary for the formation of dendritic spines in striatal neurons.

Aging and Brain Cholinergic Muscarinic Receptors: An Autoradiographic Study in the Rat

Abstract: Cholinergic muscarinic receptors in aged and young rat brains were studied by quantitative autoradiography of tritiated quinuclidinyl benzilate. A selective pattern of decreased binding density was observed in the aged rat. A large number of regions showed no effect of aging; these include subdivisions of the hippocampal formation and most tha‐lamic and hypothalamic nuclei. Small but significant decreases were found in cortical regions and in the striatum. The largest effects were seen in ventral forebrain cholinergic nuclei, where 40‐60% depletions were found in the diagonal band, nucleus basalis magnocellularis, ventral pallidum, and substantia innominata.

Septal transplants ameliorate spatial deficits and restore cholinergic functions in rats with a damaged septo-hippocampal connection.

Behavioral effects of septal lesion and fornix-fimbria transection were compared in absence and presence of a septal transplant in the hippocampus. The transplant grew in the hippocampus and projected acetylcholinesterase (AChE)-containing fibers throughout the extent of the denervated hippocampus. There were no differences in graft size or AChE reinnervation pattern after septal lesion or fornix transection. An increase in the density of M1 binding sites seen in hippocampal CA3 region after a cholinergic lesion, was restored back to normal after reinnervation of the hippocampus by the graft. Fornix-transected rats were more impaired in water maze acquisition than septal-lesioned rats which were impaired compared to controls. Septal-grafted rats were not different from lesioned rats in the behavioral tasks. However, an injection of physostigmine improved their performance relative to lesioned non-grafted rats. These experiments indicate that grafts can ameliorate behavioral deficits when the efficacy of acetylcholine of graft origin is enhanced.

Cyclic AMP-generating systems in rat hippocampal slices.

Properties of the norepinephrine (NE) stimulated, cAMP-generating system were studied in rat hippocampal slices. NE but not other putative neurotransmitters, caused a 3--4-fold rise in cAMP levels in the slices. All 3 main subdivisions of the hippocampus (HPC), the dentate gyrus, areas CA3 and CA1, possessed the capacity to produce cAMP. The latency to the NE stimulation of cAMP formation was about 20 sec but maximal stimulation was reached only after 5--10 min of incubation. Intrahippocampal injection of kainic acid (KA) caused a nearly complete destruction of hippocampal neurons and a marked increase in number of glial cells. NE caused a 12--15-fold rise in cAMP levels in KA-treated HPC. Compared to normal HPC where potency order of noradrenergic agonists indicated activation of a beta-1 receptor type, the pattern for the KA-treated HPC indicated the dominance of beta-2 receptors. The beta-1 antagonist, practolol, and the beta-2 antagonist, H35/25, were about equipotent in blocking the NE-stimulated cAMP formation in normal HPC. In KA-treated HPC, on the other hand, H35/25 was much more potent than practolol in inhibiting NE-stimulated cAMP formation. It is suggested that in the HPC beta-1 adrenergic receptors are primarily neuronal and beta-2 receptors, glial, and that activation of both receptor species results in activation of a cAMP-generating system.

Regional specificity of raphe graft-induced recovery of behavioral functions impaired by combined serotonergic/cholinergic lesions.

We compared the effects of embryonic raphe grafted into either the hippocampus or the entorhinal cortex on the ability of rats to perform a spatial memory water-maze task. Serotonin depletion or partial cholinergic lesion of the hippocampus (by injection of colchicine into the septum) did not affect the ability of rats to perform the task, but the combined treatment did. Double-lesioned rats, with raphe grafts in the hippocampus, but not in the entorhinal cortex, performed similar to control or single-lesioned rats. The results suggest that the functioning of the serotonergic innervation of the hippocampus, and not of its afferents, is crucial for the ability of rats to perform spatial memory tasks, especially when the septohippocampal cholinergic connection is disrupted.

A functional analysis of connections between grafted septal neurons and host hippocampus

Publisher Summary This chapter discusses the efficacy of using neural grafting to restore physiological and behavioral functions following damage to the cholinergic septohippocampal system. It presents a study in which embryonic septal regions were injected into the hippocampi of fimbria–fornix (FF) transected rats. The grafts developed an extensive innervation of the host hippocampus and, when stimulated, produced a slow depolarizing response that was blocked by atropine and facilitated by physostigmine. There is evidence that the graft restored hippocampal theta rhythm, which had been eliminated by FF transactions or septal lesions. However, unlike unlesioned controls, theta in grafted animals is not correlated with movement. Performance in a water maze, which was markedly impaired by fornix transection, showed no improvement 6 months after transplantation, but was restored in septal lesioned, septal grafted rats. The results indicate that grafting may provide a useful tool for studying the action of neurotransmitter systems and their involvement in higher brain functions.

The effects general and restricted serotonergic lesions on hippocampal electrophysiology and behavior

Depletion of the forebrain serotonergic system was found in previous studies to induce an increased excitability of the dentate gyrus (DG) granule cells and, when combined with a cholinergic deficiency, to impair spatial learning. We now compared the effects of general forebrain serotonergic lesions induced by intracerebroventricular injection of 5,7-dihydroxytryptamine (5,7-DHT), to those of a more restricted injection of 5,7-DHT into fornix-fimbria and cingulum, to eliminate hippocampal serotonergic innervation. Control and lesioned rats were injected with atropine and tested in the spatial learning water-maze task. Following the behavioral tests, rats were anesthetized and the responsiveness of the DG to perforant path (PP) stimulation was measured. To assess the lesions functionally, responses to application of the serotonin releasing drug fenfluramine (FFA) were measured. Finally, the reduction, in the hippocampus, of serotonergic innervation was evaluated by [3H]imipramine binding. The effects of the lesions on the responsiveness to FFA confirmed that the ICV lesions were functionally more general than the FF lesions. [3H]Imipramine binding indicated that both lesions reduced the serotonergic innervation of the hippocampus significantly. Behaviorally, both lesioned groups were impaired in the water-maze. Electrophysiologically, in both DG excitability was higher than in controls and in both hyperexcitability was associated with an increase in feed-forward inhibition. The results suggest that the serotonergic innervation of the hippocampus proper is involved in cognitive functions associated with the hippocampus.

Is fragile X mental retardation protein involved in activity-induced plasticity of dendritic spines?

Dendritic morphology of 2-week-old cultured neurons, taken from postnatal day 1 fragile X mental retardation gene1 knock out (FMR1-/-) mice hippocampus, were compared with cells taken from wild type mice. Under control conditions the FMR1-/- neurons displayed significantly lower spine densities compared to wild type neurons. Pharmacological stimulation of electrical activity, induced by bicuculline, caused a reduction in dendritic spine density in both the FMR1-/- and the wild type cells. In both groups, bicuculline induced a significant shrinkage of spines that were occupied by one or more synaptophysin-immunoreactive presynaptic terminals. The concentration of FMR1 in the wild type cultures was not affected by bicuculline treatment. These experiments indicate that FMR1 is not likely to be an essential factor in activity-modulated morphological plasticity of dendritic spines in cultured hippocampal neurons.