QUANTITATIVE HISTOCHEMISTRY OF ACETYL-CHOLINESTERASE IN RAT HIPPOGAMPAL REGION CORRELATED TO HISTOCHEMICAL STAINING

Abstract— The quantitative histochemistry of acetylcholinesterase (AChE) has been examined in hippocampus (regio superior) and area dentata. Samples (0–05–2 μg) were dissected from freeze-dried tissue sections and assayed by either a colorimetric or a radiometric micromethod. In hippocampus the highest AChE activity occurred in a narrow zone just beneath the layer of pyramidal cells. Stratum oriens had a higher activity than stratum radiatum. A small peak of activity occurred in the lacunosal layer. In area dentata the overall activity was about 60 per cent higher than in the hippocampus. The highest activities were found in two zones adjacent to the granular layer.
When the results were expressed as activities per volume of tissue they correlated well with microdensitometric measurements on sections stained for AChE by the Koelle method.
Following transection of the fimbria the activity decreased to a low level, approaching a common value in the layers examined.
The results are discussed in relation to the significance of AChE in the hippocampal region.     

Differential neuronal loss following early postnatal alcohol exposure

Neonatal rats were exposed to 6.6 g/kg of alcohol each day between postnatal days 4 and 10 while artificial-rearing procedures were used, in a manner which produced high peak and low trough blood alcohol concentrations each day. Gastrostomy controls were reared artificially with maltose/dextrin isocalorically substituted for alcohol in the milk formula, and suckle controls were reared normally by dams. The pups were sacrificed on day 10 and tissue sections (2 microns thick) were obtained in the sagittal plane through the cerebellum and in the horizontal plane through the hippocampal formation. Overall area measures were obtained for the hippocampus proper, area dentata, and cerebellum, along with areas of the cell layers of these regions. In the hippocampal formation, cell counts were made of the pyramidal cells of the hippocampus proper, the multiple cell types of the hilus, and the granule cells of the area dentata. In the cerebellum, cell counts of Purkinje cells, granule cells of the granular layer, granule cells of the external granular layer, and mitotic cells of the external granular layer were obtained from lobules I, V, VII, VIII, and IX. Alcohol selectively reduced areas and neuronal numbers in the cerebellum but had no significant effects on neuronal numbers in the hippocampal formation. Purkinje cells exhibited the greatest percent reductions, and cerebellar granule cells were significantly reduced in the granular layer but not in the external granular layer. All lobules showed these effects, but lobule I was significantly more affected than the other four lobules that were analyzed. The results demonstrate the differential vulnerability of selected neuronal populations to the developmental toxicity of alcohol exposure during the brain growth spurt.     

Distribution of GAD67-expressing neurons and morphological changes in hippocampal structures during pubertal period after acute perinatal hypoxia in rats

We investigated structural changes in the Wistar rat hippocampal CA1 field and fascia dentate during the pubertal period (on P60) after perinatal hypoxic exposure as well as the distribution of GAD67-expressing neurons in these structures. It was established that in the granular layer of the fascia dentata and in the CA1 field acute perinatal hypoxia leads to irreversible homotypic abnormalities as expressed in the reduced number of neurons and their rows as well as injury of a considerable portion of cells, which exhibit the signs of chromatolysis and vacuolization of the cytoplasm. Both in experimental and control animals, GAD67-expressing neurons in the fascia dentata are scattered diffusely and share approximately the same size of their populations. In the CA1 field, immunoreactive neurons lie in the lower rows of the pyramidal layer, while neurons in the upper layers exhibit no immunolabeling and have less synaptic structures in experimental animals than in control. We suggest that neurons in the hippocampal structures are involved in the regulation of functions and formation of prenatal pathology.     

TOPOGRAPHICAL AND SUBCELLULAR LOCALIZATION OF CHOLINE ACETYLTRANSFERASE IN RAT HIPPOCAMPAL REGION

—Choline acetyltransferase (ChAc) was localized in discrete layers in hippocampus regio superior and in area dentata. The highest activity in hippocampus was found in a narrow infrapyramidal zone, but high activities were also observed in the rest of stratum oriens and in stratum pyramidale. In area dentata the highest activities were found in a narrow supragranular zone and in hilus fasciae dentatae. The localization corresponded very closely to that of acetylcholinesterase. The main part of ChAc activity was confined to the synaptosome fraction. The results are compatible with the view that pyramidal and granular cells are excited by cholinergic boutons, mainly located on the basal or apical dendrites near the somata.     

The features of the hippocampal structure as a neuroanatomical basis for differences in behavior

Neuromorphological and behavioural studies have been made on several strains of mice (C57B1, DBA/2, SEC) and on the spiny mouse Acomys cahirinus. It was shown that animals with different genotypes differ by the size of fascia dentata and by the extension of the pyramidal layer in CA3 field of the hippocamp. Animals with a higher learning capacity exhibited smaller layer of granular cells in the fascia dentata, which may be due to a lower density of neurones in this region. Terminals of the mossy fibers--the axons of granular cells--were found mainly on the apical dendrites of the pyramidal cells in CA3 field. On the contrary, in animals with lower capacities to learning, mossy fiber terminals were observed mainly on the basal dendrites of the pyramidal cells, the extent of the granular layer in these animals being significantly larger.     

Structure of the fetal sheep brain in experimental growth retardation

A quantitative morphometric study of brain development has been made in growth-retarded fetal sheep. Intrauterine growth retardation was induced by removal of endometrial caruncles in the ewe prior to conception thereby reducing the size of the placenta in a subsequent pregnancy. Total brain and cerebellar weights were reduced by 21% (P less than 0.002) and the cerebrum by 20% (P less than 0.05) in the growth-retarded fetuses at 139 +/- 1 day (term = 146 days) compared with age matched control fetuses. Measurements of mean neuronal diameters were made on Purkinje cells, cerebellar granule cells, cortical cells in the motor and visual areas and hippocampal pyramidal cells; none were significantly different from control values. In growth-retarded fetuses compared with controls, there was a significant reduction in the thickness of the motor and visual cortices and the numerical density of neurones was significantly higher in these areas. In the cerebellar vermis, the number of Purkinje cells per unit surface area of Purkinje cell layer was higher, the numerical density of granule cells was significantly higher concomitant with a reduction in the area of the inner granular layer, and the area of the molecular layer was also reduced. In the hippocampal formation, the numerical density of pyramidal neurones was higher and the width of the stratum moleculare (dentate gyrus) was reduced. Migration of pyramidal neurones from the germinal layer to stratum pyramidale was not affected. These findings indicate that intrauterine growth retardation does not markedly affect cell size or neuronal migration (in the hippocampus) but does cause a significant reduction in the growth of the neuropil in the cerebellum, motor and visual cortices and the hippocampal formation.     

Localization of biogenic amines and monoamine oxidase in the rabbit hippocampus

Comparison of the localization of monoamines and monoamine oxidase in the rabbit hippocampus shows that most pyramidal and all granular neurons contain no monoamines. Up to 1% of pyramidal and about 3% of polymorphic neurons are noradrenergic, and some of the latter are basket cells. Their terminals, containing both noradrenalin and monoamine oxidase, are in contact with the bodies and processes of the pyramidal and granular neurons. Single serotoninergic polymorphic neurons are found in sectors H₁ and H₂ of the cornu ammonis and in sector H₅ of the fascia dentata of the hippocampus; they have few terminals. Noradrenergic afferents enter the cornu ammonis in the external bundle of the alveus and in the septal tract, which runs along the inner surface of the fimbria. Noradrenergic terminal plexuses surround the bodies of the pyramidal cells and are concentrated at the level of the apical dendrites of the pyramids and at the base of the granular neurons of the fascia dentata. Convergence of noradrenergic and serotoninergic terminals is found on some pyramidal, granular, and polymorphic neurons. The high concentration of serotonin in the hippocampus despite the minimal number of serotoninergic neurons can be explained by the large number of serotonin-containing stellate cells of nonneural nature. They are localized on groups of pyramidal neurons in sectors H₁ and H₂ and also on blood vessels. Individual variations are found in the number of serotonin-containing neurons in the hippocampus and in the number and distribution of serotonin-containing stellate cells.A. A. Bogomolets' Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 5, No. 1, pp. 40–46, January–February, 1973.     

Co-Expression of Glutamic Acid Decarboxylase Isoform 67, Membrane Nicotinic Acetylcholine Receptors,and Connexin 36 in Ischemia-Resistant Hippocampal Interneurons

As is known, hippocampal pyramidal neurons are highly sensitive to cerebral ischemia, while some other hippocampal neurons (particularly, interneurons) survive and keep their functional activity under these conditions for a longer time. We studied interneurons of the rat hippocampal organotypic culture after 30-min-long oxygen-glucose deprivation (OGD) using immunohistochemical approaches. Four and 24 h after OGD, the somata of interneurons with no signs of degeneration (revealed by propidium iodide, PI, staining) were immunopositive to antibodies against glutamic acid decarboxylase isoform 67 (GAD67) and to an extracellular domain of a7 nicotinic acetylcholine receptor (nAChR) but negative with respect to choline acetyltransferase (ChAT). GAD67/nAChR-positive interneurons were abundant within all layers of the hippocampal CA1-CA4 zones and also in the dentate gyrus. Co-localized GAD67/nAChR immunopositivity was also observed on numerous punctuate terminals close to the somata of pyramidal neurons stained by PI. After OGD followed by incubation with a blocker of gap junctions, carbenoxolone, only single PI-stained units were revealed in the pyramidal layer. In experiments with connexin 36 cyan fluorescent protein (Cx36-CFP) on gene-reporter mice, we have found that the combination of GAD67/nAChR immunopositivity and ChAT negativity in the hippocampus is specific for the interneuronal somata expressing Cx36-CFP, a component of electrotonic gap contacts in the neuronal networks. Our results indicate that OGD-resistant hippocampal interneurons display co-localization of GAD67, a7 nAChR, and Cx36-CFP. By these neurochemical features, OGD-resistant neurons can be classified as inhibitory GABA-ergic acetylcholine-sensitive interneurons able to couple electrotonically with other hippocampal units through Cx36-CFP-containing gap junctions. The existence of hippocampal interneurons coexpressing the above factors shows that further investigations towards elucidation of cooperative endogenic mechanisms responsible for cerebral neuroresistance are expedient.     

Are embryonal neurones used for transplantation "sufficiently immature"?

Live neuronal suspensions, prepared from the hippocampal region of donors aged 20 embryonal days, were observed in the Nomarski Differential Interference Contrast. Many neurones displayed profiles, resembling dendrites or axons and both principal hippocampal neurones (pyramidal and granular cells) were identified. For transplantation studies, donors of a younger embryonal age are thus recommended.     

Proteolytic degradation of glutamate decarboxylase mediates disinhibition of hippocampal CA3 pyramidal cells in cathepsin D-deficient mice

Although of clinical importance, little is known about the mechanism of seizure in neuronal ceroid lipofuscinosis (NCL). In the present study, we have attempted to elucidate the mechanism underlying the seizure of cathepsin D-deficient (CD-/-) mice that show a novel type of lysosomal storage disease with a phenotype resembling late infantile NCL. In hippocampal slices prepared from CD-/- mice at post-natal day (P)24, spontaneous burst discharges were recorded from CA3 pyramidal cells. At P24, the mean amplitude of IPSPs after stimulation of the mossy fibres was significantly smaller than that of wild-type mice, which was substantiated by the decreased level of gamma-aminobutyric acid (GABA) contents in the hippocampus measured by high-performance liquid chromatography (HPLC). At this stage, activated microglia were found to accumulate in the pyramidal cell layer of the hippocampal CA3 subfield of CD-/- mice. However, there was no significant change in the numerical density of GABAergic interneurons in the CA3 subfield of CD-/- mice at P24, estimated by counting the number of glutamate decarboxylase (GAD) 67-immunoreactive somata. In the hippocampus and the cortex of CD-/- mice at P24, some GABAergic interneurons displayed extremely high somatic granular immunoreactivites for GAD67, suggesting the lysosomal accumulation of GAD67. GAD67 levels in axon terminals abutting on to perisomatic regions of hippocampal CA3 pyramidal cells was not significantly changed in CD-/- mice even at P24, whereas the total protein levels of GAD67 in both the hippocampus and the cortex of CD-/- mice after P24 were significantly decreased as a result of degradation. Furthermore, the recombinant human GAD65/67 was rapidly digested by the lysosomal fraction prepared from the whole brain of wild-type and CD-/- mice. These observations strongly suggest that the reduction of GABA contents, presumably because of lysosomal degradation of GAD67 and lysosomal accumulation of its degraded forms, are responsible for the dysfunction of GABAergic interneurons in the hippocampal CA3 subfield of CD-/- mice.     

Lack of correlation between trace metal staining and trace metal content of the rat hippocampus following colchicine microinjection

Summary Following the intrahippocampal injection of colchicine, the trace metal staining with Timm's method is shown to change in the hippocampus. The histochemical examinations were supplemented with atomic absorption spectrophotometric measurement of the trace metals (Zn, Fe, Cu). It was found that intrahippocampal colchicine treatment induces the temporary disappearance of the trace metal staining of the pyramidal cells of the regio superior, while there is a considerable reduction in the staining in the granular cells of the area dentata and in their mossy fibre terminals. Simultaneously, in contrast with the histochemical results, quantitative studies on the trace metal levels showed that colchicine does not lead to evacuation of the trace metals from the hippocampal formation. The combined atomic absorption and trace metal staining investigations prove that there is no correlation between the trace metal staining and the quantitative amounts of the trace metals.Supported by the Scientific Research Council, Ministry of Health, Hungary (4-12-0303-01-0/K)     

Immunohistochemical changes in vulnerable rat brain regions after reversible global brain ischaemia

Human global ischaemia was simulated in adult rats by inducing 20 min brain ischaemia and 60 min post-ischaemic recirculation. Immunohistochemical expression of MMP-9, TIMP-3, Bax and Bcl-2, and DNA fragmentation (with the TUNEL reaction) were investigated. The morphological data showed different neuronal responses in the hippocampus compared with the cerebral and cerebellar cortices. MMP-9 immunoreactivity was different in the hippocampus, particularly in dentate gyrus and the CA1 region, compared with these cortices. Negative TIMP-3 staining in ischaemic hippocampal neurons may indicate a loss of its inhibitory activity on MMP-9 that could enhance cell death. Bcl-2 down regulation, Bax positivity and TUNEL+ type II cells in the dentate gyrus granular layer could be responsible for induction of apoptotic death in CA1 hippocampal pyramidal cells via loss of fibre input. Results suggest differential behaviours of neural cells after 60 min reperfusion.     

AVP_（4－8）结合点在大鼠海马内的分布和AVP_（4－8）对其受体发育的影响：放射自显影研究

本文利用放射自显影方法结合神经毒对海马神经元的选择性损毁观察ＡＶＰ（４－８）结合点在大鼠海马内的分布和定位;利用外源性ＡＶＰ（４－８）对新生大鼠的处理,观察海马ＡＶＰ（４－８）结合点的发育调节。在成年大鼠海马内,ＡＶＰ（４－８）结合点集中分布在整个海马的锥体细胞层和齿回的颗粒细胞层。秋水仙碱处理后,齿回颗粒细胞层消失,齿回区的ＡＶＰ（４－８）结合点也消失。红藻氨酸（Ｋａｉｎｉｃａｃｉｄ）处理后海马ＣＡ３－ＣＡ４的锥体细胞层消失,该区的ＡＶＰ（４－８）结合点也消失。新生大鼠海马锥体细胞层的ＡＶＰ（４－８）结合点在出生后第６天开始出现,齿回颗粒细胞层的ＡＶＰ（４－８）结合点在出生后第７天开始出现。然而,新生大鼠每天经外源性ＡＶＰ（４－８）处理,海马锥体细胞层和齿回颗粒细胞层的结合点均在出生后第５天已变得十分稠密。本文就大鼠海马ＡＶＰ（４－８）结合点的特异性分布和ＡＶＰ（４－８）处理促进海马ＡＶＰ（４－８）结合点的发育与成年后大鼠学习能力的提高的相互关系作了讨论。     

The theta modulation of rabbit hippocampal neurons and its correlation with other indices of spontaneous and evoked activity]

Reliability of the existing functional criteria for differentiation of pyramidal ("complex spike neurones") and inhibitory ("theta neurones") cells in the hippocampus of waking rabbit is evaluated on the basis of statistical analysis of neuronal spontaneous and evoked activity. The analysis shows, that the criteria of mean frequency, presence of theta modulation, neuronal behaviour in situations provoking EEG theta rhythm (e.g., excitation or inhibition during presentation of sensory stimuli), effects of medial septum and intrahippocampal stimulation do not permit reliable identification of the hippocampal neuronal types in the waking rabbit. The data on functional classification of the hippocampal neurones are discussed in connection with existing suggestions about their state in situations inducing theta rhythm generation.     

The magnetism responsive gene Ntan1 in mouse brain

We have previously identified Ntan1 as a magnetism response gene by differential display screening in cultured rat hippocampal neurons. Ntan1 mRNA was ubiquitously expressed in all the mouse tissues examined but relatively abundant in brain, retina and testis. Ntan1 mRNA expression was detectable in the embryonic 12-day mouse brain and gradually increased with ageing. In situ hybridization analysis showed high localization of Ntan1 mRNA in pyramidal cell layer of CA region and granular cell layer of dentate gyrus in the hippocampus, and Purkinje and granular cell layers in the cerebellum, respectively. Ntan1 mRNA expression was significantly increased about two-fold 12 h after brief exposure for 15 min to magnetism at 100 mT with a gradual decrease thereafter in cultured mouse hippocampal neurons. When embryonic 12-day-old or newborn mice were successively exposed to magnetic fields at 100 mT for 2 h, four times per day until the postnatal seventh day, Ntan1 mRNA was significantly increased about 1.5-2-fold in the hippocampus in vivo. The mice exposed to magnetic fields under the same condition showed significantly decreased locomotor activity. These results suggest that magnetic exposure affects higher order neural functions through modulation of genes expression.     

Comparative mapping of opioid receptors and enkephalin immunoreactive nerve terminals in the rat hippocampus. A radiohistochemical and immunocytochemical study

Opioid receptors can be localized to the hippocampal formation of the rat by autoradiography. The binding of 3H-enkephalinamide to fixed and mounted tissue sections has all the characteristics associated with binding to opioid receptors. It is saturable, of high affinity and displays stereospecificity. The opioid receptor distribution shows striking regional variation throughout the hippocampal formation. Areas with high density include the pyramidal cell layer of both regio superior (CA1) and regio inferior (CA3), stratum moleculare of the hippocampus, the cell layer of subiculum, the superficial part of presubiculum and the deep layer (VI) of the medial and lateral entorhinal cortices. Areas with low to medium densities include regions corresponding to the dendritic field of the pyramidal cells (str. oriens, str. radiatum and the mossy fiber zone), the dentate granule cell layer and the molecular layer of the dentate area. Enkephalin-like immunoreactivity is detected in both intrinsic neuronal systems: 1) the mossy fibers which terminate on the proximal part of the CA3 pyramidal cell dendrites and on CA4 pyramidal cells, 2) cell bodies with multiple short processes, probably interneurons, dispersed throughout the hilus of the dentate area, the pyramidal cell layer of hippocampus, the str. radiatum, and occasionally in the str. moleculare and in the str. oriens, and extrinsic neuronal systems: 1) the lateral perforant path and 2) the lateral temporo-ammonic tract. Thus, the hippocampus contains intrinsic systems of enkephalin-like immunoreactive nerve terminals which may exert their effect on the opioid receptors with a localization corresponding to the pyramidal cells and their apical dendrites. Extrinsic enkephalinergic systems corresponding to the terminal fields of the lateral perforant path and the temporoammonic tract, both of entorhinal origin, may influence the opioid receptors located in the molecular layer of the dentate area, and in the molecular layer of the hippocampus and the subiculum. Thus, the enkephalin-like immunoreactive nerve terminals are all located in areas which contain opioid binding sites. This suggests that the "opioid peptide-opioid receptor" systems may regulate hippocampal neuronal activity via neurotransmission or neuromodulation. However, a high or medium number of opioid binding sites occur over the pyramidal cell bodies and the dentate granule cell bodies, and these opioid binding sites are not in close contact with the major enkephalinergic systems.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cellular Targets of Nitric Oxide in the Hippocampus

In the hippocampus, as in many other CNS areas, nitric oxide (NO) participates in synaptic plasticity, manifested as changes in pre- and/or postsynaptic function. While it is known that these changes are brought about by cGMP following activation of guanylyl cyclase-coupled NO receptors attempts to locate cGMP by immunocytochemistry in hippocampal slices in response to NO have failed to detect the cGMP elevation where expected, i.e. in the pyramidal neurones. Instead, astrocytes, unidentified varicose fibres and GABA-ergic nerve terminals are reported to be the prominent NO targets, raising the possibility that NO acts indirectly via other cells. We have re-investigated the distribution of cGMP generated in response to endogenous and exogenous NO in hippocampal slices using immunohistochemistry and new conditions designed to optimise cGMP accumulation and, hence, its detectability. The conditions included use of tissue from the developing rat hippocampus, a potent inhibitor of phosphodiesterase-2, and an allosteric enhancer of the NO-receptive guanylyl cyclase. Under these conditions, cGMP was formed in response to endogenous NO and was found in a population of pyramidal cell somata in area CA3 and subiculum as well as in structures described previously. The additional presence of exogenous NO resulted in hippocampal cGMP reaching the highest level recorded for brain tissue (1700 pmol/mg protein) and in cGMP immunolabelling throughout the pyramidal cell layer. Populations of axons and interneurones were also stained. According with these results, immunohistochemistry for the common NO receptor β1-subunit indicated widespread expression. A similar staining pattern for the α1-subunit with an antibody used previously in the hippocampus and elsewhere, however, proved to be artefactual. The results indicate that the targets of NO in the hippocampus are more varied and extensive than previous evidence had suggested and, in particular, that the pyramidal neurones participating in NO-dependent synaptic plasticity are direct NO targets.     

Fucose incorporation into rat hippocampus structures after acquisition of a brightness discrimination. A histoautoradiographic analysis

Using a brigthness discrimination model in rats, the labeling of discrete hippocampus formation structures was studied after intraventricular application of [3H]-fucose. This substance was injected 5 min before training as well as 5 min, 3, 7 and 23 h after training, the pulse period lasting 120 min in all cases. A significantly training-related enhanced labeling of CA1, CA3 and CA4 cell bodies and fibres revealed that a biphasic time course occurring when radioactive fucose was applied 5 min before training and 7 h after training, whereas the increased labeling of area dentata structures was evidenced only after application of radioactive fucose 5 min before and after training. In all structures under investigation the training-related increase in labeling was more pronounced in the fibre layers than in the pyramidal and granular cell bodies.     

The remote consequences of hypoxia influence in perinatal development period on structurally functional characteristics of the rat brain

The study has shown that influence of acute hypoxia in perinatal period leads to structural changes in motor and visual of the neocortex for 20 postnatal days in the form of disturbance of the structural organisation of the neocortex layers. Different fields of hippocampus in perinatal period differently react to hypoxia, and evidence of existence of a long-term perinatal hypoxia was obtained. It is established that after action of acute hypoxia in all the fields there is a cellular destruction, and thinning of pyramidal neurones layers. The most expressed cellular destruction takes place in fields CA4 and CA3. In process of augmentation, the destruction of cells remains appreciable in the field CA4, reduced in the field CA3 and not found in the field CA1; however, in fascia dentate, the destruction of granular neurones with age augmentation increases. Along with in reduction of the dimensions of cellular bodies pyramidal neurones in all fields of hippocampus takes place. Also in all fields of hippocampus, activation of astrocytic reaction occurs, more expressed in the field CA4. The hypoxia influence in the early postnatal period can affect synaptogenes, particularly the formation of giant synapses in a dentate fascia. Study of functional features of the excitatory system of such animals has shown that hypoxia can induce appreciable disturbances of behavioural responses. In rats, disturbances of inhibiting functions of the cerebral cortex, raised anxiety, and spatial learning and working memory disturbances have been noted.