Ultrastructural identification of neural elements containing trace metals

Histochemical localization of copper in various organs of brindled mice

In order to disclose histochemically the localization of copper in various organs in Menkes disease, untreated brindled mouse hemizygotes (BM) and normal male littermates were examined by the modified sulfide silver method of Kozma, where the specificity for copper staining has been proved to be enhanced by trichloroacetic acid treatment. When compared with normal controls, renal tubules--most of which were of proximal convoluted segments--and intestinal mucosal epithelium of BM clearly showed increased staining with copper. Hepatocytes in the liver and neurons in the brain, however, displayed an obvious reduction in staining despite a marked increase in staining of capillaries in these two organs. Electron microscopy of the specimens stained with the Kozma method revealed numerous fine silver grains which represented Cu++ localization, distributing within the cytoplasm outside both mitochondria and the nucleus. The intense staining of capillaries observed only in the liver and brain of BM may indicate a blockade of copper transport owing to trapping of copper in the capillary walls, and may be responsible for low tissue-copper concentrations of the two organs. Similarly, high tissue-copper concentrations of the kidney and intestine are attributed to excessive deposition of copper in their epithelial cells which are probably due to impaired intracellular copper-transportation.

Quantitative electron microscopic analysis of postnatal development of zinc-positive nerve endings in the rat amygdala using Timm's sulphide silver technique

The distribution and quantitation of zinc during postnatal development of the rat amygdala were investigated by light and electron microscopy with Timm's sulphide silver method. The adult rat amygdala could be divided into basolateral, basomedial, central, cortical, intercalated, lateral and medial subnuclei on the basis of Timm's plus Toluidine blue staining. Only a very weakly positive Timm's reaction could be observed in newborns, and a positive reaction was seen on the 5th postnatal day. The reaction became stronger with development, and reached adult levels by the 30th postnatal day. Electron microscopically, we investigated the basolateral subnucleus of the amygdala. The electron-dense deposits of silver grains from the Timm's reaction were only seen in nerve fibers endings containing many small clear vesicles. The results are similar to those described for mossy fiber endings in the rat hippocampus and in boutons of other telencephalic structures. The number of deposits of silver grains increased with age, and reached that of the adult between the 20th and 30th postnatal days. A significant increase in the number of silver grains per micron 2 area of the Timm's-positive nerve terminals occurred between the 10th and 20th postnatal days. Based on the available literature, these findings suggest that zinc exists in nerve fiber endings in the rat amygdala and that the amount increases with postnatal age. The findings are consistent with an important role for zinc in synaptic transmission.

An indirect method for quantitation of cellular zinc content of Timm-stained cerebellar samples by energy dispersive X-ray microanalysis

The absolute concentration of zinc in the Purkinje cells of the rat cerebellum was determined by means of energy dispersive X-ray microanalysis (EDAX). Gelatine blocks with known zinc concentrations were stained by Timm's sulphide-silver method, and their silver concentrations were measured by EDAX. A linear correlation was found between the zinc and silver concentrations and this linear function was used as a quantitative calibration for evaluation of sulphide-silver staining, after perfusion with sodium-sulphide solution, fixation with glutaraldehyde, cryostat sectioning and staining of cerebellar samples in Timm's reagent.

Timm-staining intensity is correlated with the density of Timm-positive presynaptic structures in the cerebral cortex of lizards

In cortical areas of the lizard, Podarcis hispanica, Timm staining reveals a distinct pattern of lamination. At the electron-microscope level, virtually all of the reaction product is located in the synaptic vesicles of Timm-positive boutons. Using linear-regression analysis, the area density of Timm-positive bouton profiles as well as the numerical and volume density of stained vesicles were found to be closely correlated with the light-microscopic densitometric values obtained for each Timm-positive cortical zone. We discuss the possibility of estimating stereological electron-microscopic data parameters from densitometric measurements at the light-microscope level.

Zinc accumulation in the telencephalon of lizards

The zinc concentration in the brains of two species of lizard was determined by atomic-absorption spectrophotometry. The zinc concentration was found to be highest in the telencephalon of Lacerta galloti (21.1 micrograms/g fresh weight) and Podarcis hispanica (16.77 +/- 0.8 micrograms/g) while the mesencephalon and brain stem exhibited lower zinc concentrations, i.e., 7.0 micrograms/g in Lacerta galloti and 6.08 +/- 0.4 micrograms/g in Podarcis hispanica. This high telencephalic concentration of zinc is paralleled by intense and well-defined Timm reactivity used for demonstrating the presence of zinc-containing boutons at the light-microscope level. Volumetric-densitometric studies of these Timm-reactive zones were performed using serial transverse sections of the same lizard brains.

Demonstration of reduced levels of zinc in rat brain after treatment with d-amphetamine, but not after treatment with reserpine

Histochemical and atomic absorption spectrophotometric methods were used to study the effects of reserpine and d-amphetamine on the neuronal trace metal distribution in various regions of the central nervous system (hippocampus, parietal cortex, cerebellum). Six hours after single d-amphetamine treatment (15 mg/kg i.p.), the neuronal zinc level was significantly decreased in the hippocampus and in the parietal cortex. The intensity of sulphide silver staining was similarly greatly decreased in all layers of the hippocampus and the parietal cortex. Such a change was not observed when d-amphetamine was administered in a lower dose (5 or 10 mg/kg i.p.). Twenty hours after single reserpine treatment (10 mg/kg i.p.), there were no changes in the tissue levels and distribution of zinc, copper, iron and manganese. In animals treated with reserpine on five consecutive days, in a dose of 10 mg/kg/day i.p., the trace metal distribution twenty hours following the final treatment was essentially the same as in the control. The results strongly suggest that zinc does not play a direct role in vivo in the storage and mobilization processes of the catecholamines. A high dose of d-amphetamine, however, has a non-specific, toxic effect that is not interrelated with the catecholaminergic neuronal function; this effect is manifested in a diminished intensity of sulphide silver staining and in a reduction of the tissue zinc level.

Effects of the cholinotoxin, AF 64A, on neuronal trace-metal distribution in the rat hippocampus and neocortex

Ethylcholine mustard aziridinium ion (AF64A) is a neurotoxin which is specific for cholinergic nerve terminals. Besides its effects on elements of the acetylcholine system, we observed that, after 2 and 8 days, a single 20-nmol intracerebroventricular dose altered the Timm's staining of certain regions of the central nervous system and reduced the tissue levels of trace metals. In the hippocampal formation, there was a considerable decrease in the staining of the neuropil of the stratum radiatum and stratum oriens, which contain cholinergic nerve terminals. A reduction in staining was also demonstrated in the perikarya of cortical pyramidal cells. The diminished trace-metal level in both regions was confirmed by quantitative measurements of zinc and copper levels. A similar reduction was not observed at a lower dose (8 nmol) of the cholinotoxin. The results led to the conclusion that AF64A may cause the decrease of the trace-metal content of the postsynaptic neurons through an indirect mechanism.

Variations in trace metal levels in rat hippocampus during ontogenetic development

The variations in trace metal (zinc, iron, copper and manganese) levels in rat hippocampus were followed by atomic absorption spectrophotometry from the 17th embryonic day to the 100th postnatal day. In agreement with histochemical observations, it was found that the greatest relative increase in the hippocampal zinc level occurs during the 11th-20th postnatal days, simultaneously with the morphological maturation of the mossy fibre terminals. The iron level falls dramatically from the 17th embryonic day to the 3rd postnatal day. Beginning from the 11th postnatal day, the iron level, similarly to the copper level, continuously increases with age. The manganese level rises up to the 20th postnatal day, and subsequently progressively decreases. It is suggested that all of these elements are indispensable for the normal development and functioning of the hippocampus and the mossy fibre terminals.

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

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.

Histochemical detection of zinc and copper in various neurons of the central nervous system

Trace elements (Zn2+, Cu2+, Fe2+) were localized with Timm's sulphide silver method in the neurons (pyramidal cells, Purkinje's cells, motoneurons) and in the axon terminals of various regions cortex, hippocampus, nucleus ruber, cerebellum, medulla spinalis) of the central nervous system. After treatment of the same tissues with 15% trichloroacetic acid, a considerable proportion of the coarse granular staining disappeared from certain neurons (Purkinje's cells, ncl. ruber cells, motoneurons) and axon terminals (hippocampus mossy fibres), while in other cells (cortex pyramidal cells) and axon terminals it remained. The results suggest that the decrease in the staining is a consequence of the loss of Zn2+ and Fe2+ from the neuronal perikaryon or axon terminal. The histochemical results are supported by quantitative atomic absorption measurements.

Histochemical and atomic absorption demonstration of trace metal mobilization in the central nervous system and liver of the rat

Histochemical and atomic absorption spectrophotometric analysis of trace metal mobilization caused by the action of ethanol in the central nervous system (CNS) and liver of the rat is described. Histochemically it has been shown that in all neurons examined (motoneurons, pyramidal and Purkinje cells) the trace metals (mainly Zn2+ and Cu2+) are mobilized. Most of the stained materials disappear from the perikaryon of the Purkinje cells, while in both the motoneurons and the pyramidal cells the trace metals are displaced from the perikaryon into the axon and axon hillock. At the same time, some of the glia cells display a high metal content. Quantitative determination of the Zn2+ and Cu2+ by means of atomic absorption spectrophotometry reveals that after 2 hours ethanol treatment both the Zn2+ and the Cu2+ levels are decreased in the archicerebellar cortex, while after 4 hours the Zn2+ levels are increased in the cerebrum and the spinal cord. The present observations on the histochemical localization and the contents of zinc and copper in different parts of the CNS and liver reveal the important role of the effect of ethanol on the trace metal mobilization.

Trace element localization and changes in zinc and copper concentrations during postnatal development of the rat CNS

Changes in concentration and localization of the trace metals during postnatal ontogenetic development in the archi-, paleo-, and neurocerebellum, the cortex and the spinal cord of the rat have been studied by means of histochemical and atomic absorption spectrophotometric analysis. It has been shown that the trace elements in the different regions of the nervous system become progressively detectable during the postnatal ontogenesis, and in the various structures (PURKINJE cells, pyramidal cells, motoneurons, mossy-fibre terminals) different times are necessary for the attainment of the localization observed in the mature animals. It is suggested that the trace elements may be transported not only intraneuronally, but also from neuron to neuron, from neuron to glia cell, and in the reverse direction, too.