Zinc-positive presynaptic boutons of the rabbit hippocampus during early postnatal development

The dentate mossy fibers: structural organization, development and plasticity

Hippocampal mossy fibers are the axons of the dentate granule cells and project to hippocampal CA3 pyramidal cells and mossy cells of the dentate hilus (CA4) as well as a number of interneurons in the two areas. Besides their role in hippocampal function, studies of which are still evolving and taking interesting turns, the mossy fibers display a number of unique features with regard to axonal projections, terminal structures and synaptic contacts, development and variations among species and strains, as well as to normal occurring and lesion-induced plasticity and neural transplantation. These features are the topic of this review, which will use the mossy fiber system of the rat as basis and reference in its aim to provide an up-to-date, yet historically based guide to students in the field.

Cytosolic labile zinc: a marker for apoptosis in the developing rat brain

Cytosolic zinc accumulation was thought to occur specifically in neuronal death (necrosis) following acute injury. However, a recent study demonstrated that zinc accumulation also occurs in adult rat neurons undergoing apoptosis following target ablation, and in vitro experiments have shown that zinc accumulation may play a causal role in various forms of apoptosis. Here, we examined whether intraneuronal zinc accumulation occurs in central neurons undergoing apoptosis during development. Embryonic and newborn Sprague-Dawley rat brains were double-stained for terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labelling (TUNEL) detection of apoptosis and immunohistochemical detection of stage-specific neuronal markers, such as nestin, proliferating cell nuclear antigen (PCNA), TuJ1 and neuronal nuclear specific protein (NeuN). The results revealed that apoptotic cell death occurred in neurons of diverse stages (neural stem cells, and dividing, young and adult neurons) throughout the brain during the embryonic and early postnatal periods. Further staining of brain sections with acid fuchsin or zinc-specific fluorescent dyes showed that all of the apoptotic neurons were acidophilic and contained labile zinc in their cell bodies. Cytosolic zinc accumulation was also observed in cultured cortical neurons undergoing staurosporine- or sodium nitroprusside (SNP)-induced apoptosis. In contrast, zinc chelation with CaEDTA or N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN) reduced SNP-induced apoptosis but not staurosporine-induced apoptosis, indicating that cytosolic zinc accumulation does not play a causal role in all forms of apoptosis. Finally, the specific cytosolic zinc accumulation may have a practical application as a relatively simple marker for neurons undergoing developmental apoptosis.

Retrograde transport of sodium selenite and intracellular injection of micro-ruby: a combined method to describe the morphology of zinc-rich neurones

Zinc is found in synaptic vesicles in a large number of glutamatergic systems. Its involvement in neurotransmission and neurological disorders has been suggested. There are methods for tracing these circuits, but they do not fill the dendritic tree. In this study, extracellular selenite injections in vivo were combined with intracellular injection of fluorochromes in fixed tissue to reveal the morphology of these zinc-rich neurones. Intraperitoneal and intracerebral injections of sodium selenite alone or intracerebral injections of selenite combined with bisbenzimide were made in the visual cortex of the rat in order to locate the somata of zinc-rich neurones. After 24 h of retrograde transport, animals were killed and fluorescent markers were injected intracellularly into fixed slices to show neuronal morphology: (a) Lucifer Yellow (LY) followed by biocytin, (b) LY coupled to biocytin or (c) micro-ruby (MR) (dextranamines bound to rhodamine and biotin). Double-labelled somata (selenite+fluorochrome) were plotted. Details of the dendritic morphology were then revealed by incubation in avidin-biotin complex and development in 3,3'-diaminobenzidine and H(2)O(2). Camera lucida drawings showed that zinc-rich neurones in layers II-III involved in cortico-cortical visual projections were typical pyramidal neurones. This technique is noteworthy for its analysis of the morphology (and connections) of zinc-rich neurones.

Postnatal development of zinc-rich terminal fields in the brain of the rat

The appearance and distribution of zinc-rich terminal fields in the rat forebrain was analyzed at 12 stages of postnatal development using the selenium method. Zinc stain was detected in neonates in piriform, cingulate, and motor cortices, septal area, and hippocampal formation. In the neocortex, a laminar pattern appeared progressively following an inside-out gradient: layer VI at postnatal day 0 (P0), layer V at P1, layers Va and Vb at P5, layer II-III at P9, and layer IV at P12. In the hippocampal formation the layered pattern in the dentate molecular layer appeared at P1-P3, and in the hilus and mossy fibers the stain was observed at P5. Patches in the caudate-putamen were sharply delimited at P1-P3. At these ages, staining was observed in the amygdaloid complex. In the thalamic and hypothalamic nuclei, stain appeared at P5-P7. Thus, a general increase in vesicular zinc over different telencephalic areas was determined until P15-P21, which was followed by a slight decrease thereafter (at P41). The increased stain in zinc-rich terminal fields is consistent with the development of telencephalic circuits. The rise in zinc might be relevant for the establishment and maturation of these circuits. On the other hand, the decrease in staining for zinc at later stages might be due to methodological problems but it might also reflect pruning of supernumerary connections and programmed cell death affecting zinc-rich circuits.

Cytochemical techniques for zinc and heavy metals localization in nerve cells

Zinc is one of the most abundant oligoelements in the living cell. It appears tightly bound to metallothioneins, loosely bound to some metalloproteins and nucleic acids, or even as free ion. Small amounts of zinc ions (in the nanomolar range) regulate a plentitude of enzymatic proteins, receptors, and transcription factors; thus, cells need accurate homeostasis of zinc ions. Some neurons have developed mechanisms to accumulate zinc in specific membrane compartments ("vesicular zinc") which can be revealed using histochemical techniques. This article is a short report on the different direct-indirect experimental approaches for zinc and heavy metal detection in neurons. Substances giving a bright color or emitting fluorescence when in contact with divalent metal ions are currently used to detect them inside cells; their use leads to the so called "direct" methods. The fixation and precipitation of metal ions as insoluble salt precipitates, their maintenance along the histological process, and their demonstration after autometallographic development are essential steps for other methods, the so-called "indirect methods" (Timm and Danscher Neo-Timm methods).

Age-dependent influence of dietary zinc restriction on short-term memory in male rats

Zinc is an essential micro-nutrient involved in numerous physiological functions. The high content of zinc in the hippocampus, coupled with the integral involvement of the hippocampus in memory, strongly implicates zinc in memory processing. The hypothesis of the current study was that dietary zinc restriction influenced short-term memory in postweaned rats, and this influence was age-dependent. Male rats (43 days to 18 months old) were divided into five experimental groups based on age, and fed zinc-adequate (zinc at 20 mg/kg as zinc chloride) or zinc-deficient (zinc less than 1-2 mg/kg) diets for a minimum of 3 weeks. Short-term memory was assessed using the distal-cue version of the Morris water maze (MWM). All rats fed the zinc-restricted diet exhibited cyclic anorexia, decreased weight gain, and significantly lower liver and femur zinc concentrations compared to age-matched controls. Further, whole brain, hippocampal, and cerebral wet weights were significantly reduced in the zinc-restricted treatment groups of all the age groups. Only zinc-restricted rats that were less than 62 days of age at the start of zinc restriction demonstrated significantly prolonged escape latencies in the water maze, indicating deficits in short-term memory. Regression analyses confirmed that the short-term memory deficits were correlated with significantly lower hippocampal and cerebral zinc concentrations compared to age-matched control and pair-fed rats. These results emphasize the significance of a critical age of influence for dietary zinc in memory processing, and the importance of considering age when studying zinc nutriture and CNS function.

Early histological maturation in the hippocampus of the guinea pig

The vesicular zinc-rich synaptic systems of the principal neurons of the hippocampus are well developed in newborn guinea pigs, a precocial species. In addition, alvear and fimbrial myelinated fibers as well as significant inhibitory interneurons (i.e. somatostatin, parvalbumin and opioid immunoreactive hippocampal interneurons) are also well developed. On the contrary, neither vesicular zinc synapses nor myelinated fibers nor the above mentioned immunoreactive interneurons are detectable in newborn specimens of other related altricial species such as rats or rabbits. These data suggest that early maturation of a highly integrative center related to cognitive map building such as the hippocampus is characteristic of precocial species.

Distribution of metallothionein I + II and vesicular zinc in the developing central nervous system: correlative study in the rat

Because zinc (Zn) is a co-factor in enzymes and participates in neurotransmission, it is essential for brain development. However, because excess Zn may cause neuronal injury, cerebral mechanisms for Zn regulation must operate. The metallothionein isoforms I and II (MT I + II) are putative candidates for chelating unbound Zn released from Zn-containing nerve terminals or transported into the brain. Whether vesicular Zn and MT I + II occur in identical regions of the developing brain is unknown. Accordingly, the developmental distribution of MT I + II and vesicular Zn was mapped. By using double-labeling fluorescence histochemistry, MT I + II immunoreactivity (ir) was attributed to astrocytes and cells of myelomonocytic lineage. The cells of the myelomonocytic lineage shared the morphology of monocytes and macrophages but not of microglia and occurred primarily around vessels and ventricles in the brainstem. By contrast, astrocytes were widespread throughout the developing brain. In embryonic and neonatal brain, MT I + IIir astrocytes were almost selectively observed in the septum and fascia dentate hilus (hi) of the hippocampus. With increasing postnatal age, they also occurred in hippocampal cortex, basal forebrain, neocortex, cerebellar cortex, and cranial nerve nuclei. MT I + II mRNAs were detected in regions of the brain that also displayed MT I + IIir, indicating transcriptional events. Vesicular Zn was recorded in neonatal brain solely in the dentate hi of the hippocampus. With increasing age, the amount of vesicular Zn increased in the hippocampus and other forebrain regions. The presence of MT I + II proteins in the developing brain was confirmed by radioimmunoassay. The regional distribution of astrocytic MT I + IIir and vesicular Zn suggests that MT I + II are implicated in Zn metabolism in the developing forebrain.