Organotypic monolayer cultures of nervous tissue

Effects of dihydropyridines on calcium currents in CA3 pyramidal cells in slice cultures of rat hippocampus

Slow inward Ca-currents were recorded from CA3 pyramidal cells in rat hippocampus slice cultures when these cells were voltage-clamped at -40 mV and depolarizing commands applied. Ca-currents were increased in amplitude by the dihydropyridine Ca-agonist BAY K8644 (0.1-1 microM) and reduced by the Ca-antagonists nifedipine and PY 108-068 (0.1-1 microM). Ca-current inhibition by the latter could be temporarily relieved by membrane hyperpolarization. In unclamped cells, dihydropyridines did not alter membrane potential, Ca-spike amplitude, excitatory or inhibitory synaptic current amplitude, or spontaneous synaptic activity. Their principal effects were to alter the threshold for Ca/Ba spike generation and for pitrazepin-induced burst-depolarization. BAY K8644 also induced an after-spike following the normal Na spike, which was reduced by PY 108-068. It is concluded that the slow inward Ca-current in hippocampal neurones is sensitive to dihydropyridine drugs and that the absence of functional effects of antagonists is due to other causes such as the voltage-dependence of dihydropyridine block and the presence of an additional transient Ca-current which may be less sensitive to block.

Selective kainic acid lesions in cultured explants of rat hippocampus

The influence of the excitotoxin kainic acid (KA) on cultivated explants of rat hippocampus was investigated. Addition of 3 microM KA to the culture medium over 24-48 h induced a destruction of the pyramidal cells in the CA3 region, whereas the CA1 pyramidal cells and the granule cells were left undamaged. Higher concentrations (10-100 microM) of KA destroyed also the latter cell groups. The selectivity of the KA lesion at 3 microM was further indicated by the fact that the acetylcholinesterase-positive neurons in the hippocampus were not destroyed through KA administration and that the stereoisomer dihydrokainic acid was ineffective in inducing lesions. Application of tetrodotoxin did not protect the CA3 pyramidal cells from KA lesion, whereas gamma-glutamylaminomethylsulphonic acid (GAMS) only offered a very small, statistically not significant, protection. Baclofen protected the cultures slightly from KA lesions but not when added together with GAMS. Possible mechanisms responsible for the KA lesions in these cultures are discussed.

Development of serotoninergic neurons from ventricular cells of the mouse neural plate in vitro

Cephalic neural plates and neural tubes of mice (pros- and rhombencephalic anlagen), developmental stages Theiler 11-18 [Th 11-18; embryonic day 7 1/2-11 (E7 1/2-11)], were prepared and cultured in a plasma clot with horse serum-containing MEM medium. Differentiation of the ventricular cells was studied in order to investigate the expression of serotoninergic properties. Serotoninergic neurons were not detected in preparations derived from neural plates of stage Th 11 (E7 1/2), but were demonstrated in increasing numbers from the early stage Th 12 (E8) onwards. The exclusively originated from the rhombencephalic floor caudal to the mesencephalic flexure. The serotoninergic neurons developed from these areas, irrespective of whether being cultured in their natural position within the neural plate, or separated as microcultures, or transplanted into the prosencephalic anlage. Every other region of the neural plate remained free of serotoninergic neurons. The in vitro findings are highly reproducible due to the following properties: the morphological and immunocytochemical peculiarities of the serotoninergic neurons, their tendency to appear in increasing numbers with age, their localization within the cultured neural plates and their appearance in all cultures from stage Th 12 (E8) on. Due to these findings it is considered possible that the progenitor cells of serotoninergic neurons might already have been determined within distinct areas in the mouse neural plates as early as stage Th 12 (E8).

Ultrastructural investigation of fetal rat brain hemisphere tissue in nonadherent stationary organ culture

Fetal rat brain fragments grown in nonadherent stationary organ culture for 50 days have been investigated ultrastructurally. Synaptogenesis and myelin formation occurred at the same time as the corresponding time-dependent events in the developing brain in vivo. Intermediate junctions were observed between cellular processes lining a central cavity in the fragments and later associated with astrocytes at the surface. Gap junctions and tight junctions were also present. In some fragments cilia were observed in the central cavity. Subependymal basement membrane labyrinths were observed in all fragments after 10 days in culture. The ultrastructural characteristics and the tissue-like structure in general were preserved for at least 50 days in this tissue culture system. The brain fragments may therefore be a valuable supplement to existing culture methods for nervous tissue.

Muscarinic receptors in slice cultures of rat brain

Muscarinic acetylcholine receptors in organotypic slice cultures of hippocampus of the rat, have been examined using the tritiated muscarinic antagonist quinuclidinylbenzilate [( 3H]QNB) as a as a marker. Maximum specific binding of [3H]QNB in mature explants of hippocampus amounted to 316 fmol/mg protein and a dissociation constant (KD) of 185 pM was determined. Scatchard analysis suggested binding to one single binding site. In younger cultures smaller KDs were registered. This decrease in ligand affinity in maturer cultures possibly reflects a decrease in the turnover of acetylcholine. Muscarinic antagonists inhibited the total binding of [3H]QNB significantly, whereas muscarinic agonist, nicotinic antagonists and cholinesterase inhibitors had no influence whatsoever on the total binding of [3H]QNB. The content of muscarinic acetylcholine receptors varied between cultures with explants from different brain areas: hippocampus greater than striatum greater than septum greater than spinal cord greater than cerebellum. These in vitro results are generally in good agreement with results obtained in situ by other investigators and suggest that the binding of [3H]QNB observed in these cultures is indeed correlated to specific muscarinic receptor sites.

Influence of adenohypophyseal tissue on the development of the rat fascia dentata in vitro

In hippocampal slice cultures, the mossy fibers from the dentate granule cells were previously shown by Timm staining to retain their normal connections to CA4 and CA3 pyramidal cells. While the granule cells of the suprapyramidal (hidden) blade remained in a distinct layer, the granule cells of the infrapyramidal (free) blade of the fascia dentata, however, often spread. This aberrant trait was strikingly enhanced in the presence of a co-cultured adenohypophyseal explant. This infrapyramidal blade of the fascia dentata largely disappeared as a cell layer; granule cell-like neurons, displaying a monopolar dendritic structure directed towards the pituitary, would migrate toward the hypophyseal explant, whilst their axons still functionally innervated CA3 pyramidal cells. Axon collaterals projected in the opposite direction and presumably terminated on dendrites, thus giving rise to the intense black labelling which was observed in Timm-stained preparations as a bridge connecting the two explants. The morphological alterations induced in the fascia dentata by co-cultured adenohypophysis were tissue-specific since co-cultured neurohypophysis, pineal gland and cerebellum failed to produce similar effects. These results suggest that cultured adenohypophyseal tissue is capable of releasing yet unidentified factors which apparently enhance neuronal migration.

Immunohistochemical localization of a spectrin-like protein (fodrin) in nerve cells in culture

The distribution of fodrin in neurones in culture was demonstrated by immunohistochemistry with anti-spectrin antibodies. There was strong staining of the plasma membrane and cell extensions and also labelling of a cytoskeletal network throughout the cytoplasm.

In vitro cytotoxicity and demyelination induced by Theiler viruses in cultures of spinal cord slices

The cytopathic effects caused by Theiler viruses to myelinated organotypic spinal cord cultures was studied by light and electron microscopy. Heavily myelinated cultures, 2-3 weeks in vitro were infected with WW and GD VII viruses. Mock infection served as control. On light microscopy cytopathic effects and demyelination became evident about 16-17 hr after infection. Demyelination observed in WW virus-infected cultures was much more pronounced than in cultures infected with GD VII viruses. The myelin in mock-infected cultures remained undamaged. Electron microscopy revealed that in control cultures cells were intact, exhibiting numerous synapses and a network of axons enwrapped by multilayered myelin sheaths. Virus-infected spinal cord slices showed that a more severe cytotoxicity was caused by GD VII virus than by WW virus. The cytopathology included accumulation of cytoplasmatic vacuoles, margination of chromatin, synapse and cell disintegration, and various degrees of demyelination. Several GD VII virions were observed, arranged in crystalline arrays, mainly in electron-opaque cells, but not within axons. WW virions on the other hand were only occasionally encountered.

Fetal rat brain hemisphere tissue in nonadherent stationary organ culture

A simple organ culture system for brain tissue is described. Fragments of fetal rat brain hemisphere tissue are explanted to multiwell dishes base-coated with semisolid agar. In this system nonadherent organ culture can be performed for at least 50 days. Cell migration, biochemical and morphological differentiation and the formation of a layered architecture seem to mimic some of the phenomena occurring in the developing rat brain in vivo. The fragments may therefore be a useful organ culture model for nervous tissue.

Cell and tissue culture of the central nervous system: recent developments and current applications

A survey of methods for cell and tissue culture of the central nervous system (CNS) is given. This includes a brief historical outline and description of methods in current use. Recent methodological improvements are emphasized, and it is shown how these are applied in modern neurobiological research. Both monolayer cell cultures and three-dimensional organ culture systems are widely used, each having advantages and limitations. In recent years, there has been considerable improvement of culture for prolonged periods in chemically defined media. Brain tissue from a wide spectrum of species have been used, including different types of human brain cells which can be propagated for several months. At present, these culture systems are employed for dynamic studies of the developing, the adult and ageing brain. It is possible to select neurons and the different classes of glial cells for culture purposes. Cell culture of the CNS has given new insights into the biology of brain tumours. Culture systems for experimental tumour therapy in vitro are also available. Recently, it has been shown that organ cultures of brain tissue can be used as targets for invasive glioma cells, enabling a direct study of the interactions between tumour cells and normal tissue to take place.

Development of cholinergic projections in organotypic cultures of rat septum, hippocampus and cerebellum

ChAT and AChE activity in the hippocampus originate primarily in axons from cholinergic neurons located in the medial septum. The development of cholinergic projections in organotypic explant cultures of rat septum, hippocampus, cerebellum and habenula was studied using AChE histochemistry and biochemical ChAT and AChE determinations. Hippocampal and cerebellar explants cultured without a septum contain negligible amounts of ChAT after 6 days of culture. When the hippocampus was cultured for several days in the presence of a septal explant, a massive increase in ChAT was observed in the hippocampal explant. When co-cultures were stained for AChE, AChE-positive projections were seen to grow out from the septum to invade the hippocampal explant. To a certain extent this ingrowth of septal cholinergic fibers into the hippocampus is target-specific, since cerebellar explants cultured with septum showed neither an ingrowth of AChE-containing septal fibers, nor an increase in ChAT activity. Also, habenular AChE-positive fibers fail to grow into a co-cultivated hippocampal explant. Further, in septal explants co-cultivated with hippocampal explants an increase in ChAT activity was seen as compared to septal explants cultivated alone. The possible factors responsible for the observed specificity and the increase in ChAT activity under co-culture conditions are discussed.

GABAB-receptor-activated K+ current in voltage-clamped CA3 pyramidal cells in hippocampal cultures

GABAB receptors are a subclass of receptors for gamma-amino-n-butyric acid (GABA) that are also activated by the antispastic drug beta-p-chlorophenyl-GABA (baclofen). One effect of baclofen is to inhibit excitatory transmission from CA3 to CA1 hippocampal pyramidal cells. To identify the ionic mechanism of GABAB-receptor-mediated depression, we have studied the effect of baclofen and GABA on ionic currents in voltage-clamped CA3 pyramidal cell somata in rat hippocampal slice cultures. Baclofen (10 microM) induced an inwardly rectifying outward current that reversed at -74 +/- 4.3 mV (mean +/- SD). This appeared to be a K+ current since (i) its reversal potential showed the expected shift when extracellular K+ concentration was changed and (ii) it was blocked by external Ba2+ or internal Cs+. The action of baclofen was closely imitated by GABA after the GABAA-mediated Cl- current had been abolished with pitrazepin (10 microM); under these conditions, GABA (100 microM) also produced an inwardly rectifying, Ba2+-sensitive current with a reversal potential identical to that of the baclofen-induced current. When outward currents were blocked with internal Cs+, the residual inward voltage-dependent Ca2+ current was not changed by baclofen. It is concluded that the primary effect of GABAB-receptor activation in these neurones is to increase K+ permeability rather than to reduce Ca2+ permeability.

Functional innervation of cultured hippocampal neurones by cholinergic afferents from co-cultured septal explants

The rat hippocampus receives a strong cholinergic innervation from the medial septum; information about the development and function of this pathway could help to elucidate the mechanisms of memory functions. Previous electrophysiological studies have shown that septal stimulation in vivo facilitates commissural and perforant path inputs and that stimulation of intrahippocampal cholinergic fibres in vitro produces a slow depolarization of rat hippocampal CA3 pyramidal neurones and increases their excitability. We describe here a different approach to the investigation of this system, by co-culturing slices of young rat hippocampus and septum, then recording the effects of septal nucleus stimulation on single voltage-clamped hippocampal CA3 pyramidal neurones. Under these conditions acetylcholinesterase-staining (presumed cholinergic) fibres grow out from the septum into the hippocampus. Single septal stimuli produce a short-latency non-cholinergic fast excitatory postsynaptic current, whereas trains of stimuli produce a slow inward current augmented by neostigmine and suppressed by atropine; hence this has a cholinergic origin. Our experiments provide both the first demonstration that functional synapses can be established between explanted cholinergic and cholinoceptive neuronal systems from the mammalian brain in organotypic culture and the first description of cholinergic slow excitatory postsynaptic currents in the mammalian central nervous system.

Valorphin: a novel chemical structure with opioid activity

Valorphin is a semisynthetic derivative of dihydrovaltrate with opioid analgesic activity. In vitro binding studies using brain homogenates from rat and guinea-pig indicate a preference for the mu-receptor site. Bath application to cultured cerebellar Purkinje cells inhibited the spontaneous firing, similar to the effect seen with morphine. Analgesic activity has been demonstrated in the hot plate and the tail flick test in the mouse and the Randall-Selitto test in the rat. In the rhesus monkey valorphin was self-administered, but naloxone challenge induced only mild withdrawal signs. Valorphin is a novel chemical entity, structurally not related to known opioids, which interacts preferentially with opiate mu-receptors.

Striatal acetylcholinesterase-containing interneurons innervate hippocampal tissue in co-cultured slices

Co-cultures of hippocampal and striatal slices were prepared from 7-day-old rats. After a month in vitro they were examined by histochemical and electrophysiological techniques. Acetylcholinesterase-positive fibers, originating in presumed cholinergic local circuit neurons of the striatum, invaded the adjacent hippocampus, resulting in a functional innervation displaying the characteristics of muscarinic inputs. These observations demonstrate that interneurons, when offered an appropriate target, are capable of mimicking projection neurons. Such a target-induced change in growth characteristics can take place even during relatively advanced phases of their development.

Guidance of acetylcholinesterase-containing fibres by target tissue in co-cultured brain slices

Slices of various brain regions were prepared from newborn and from 7-day old rats and co-cultured in different combinations. In the majority of co-cultures of septal and hippocampal slices, acetylcholinesterase-positive fibres originating in the septal nuclei invaded the adjacent hippocampal slice. A similar pattern of hippocampal ingrowth by acetylcholinesterase-positive fibres occurred with slices prepared from the nucleus basalis of Meynert and from spinal cord. Septal neurones also projected to cortical slices, an effect which even occurred in the presence of their natural target tissue. In contrast to these massive projections to brain areas which in situ receive cholinergic inputs, no significant acetylcholinesterase-positive fibre ingrowth was observed in tissues which lack major cholinergic afferents in situ (hypothalamus, substantia nigra and cerebellum). These results indicate that under our culture conditions, acetylcholinesterase-positive fibres selectively invade cholinergic target areas. This effect is independent of the brain area from which the cholinergic neurones were derived.

Cellular and connective organization of slice cultures of the rat hippocampus and fascia dentata

This study examined the cellular and connective organization of hippocampal tissue taken from 6-8-day-old rats and cultured by the roller tube technique for 3-6 weeks. In the cultures containing the fascia dentata and the hippocampus proper (CA1, CA3, CA4) the main cell and neuropil layers were organotypically organized when observed in ordinary cell stains. The normal distribution of smaller cell populations of AChE-positive neurons and somatostatin-reactive neurons was demonstrated by histochemical and immunohistochemical methods. Both cell types were mainly confined to str. oriens of CA3 and CA1 and the dentate hilus (CA4). Individual dentate granule cells and hippocampal pyramidal cells were injected with lucifer yellow and HRP, revealing great stability of the dendritic patterns of these cells in the culture condition. The same was found for the axonal branching and termination of HRP-filled mossy fibers arising from an HRP-injected granule cell. The preservation of organotypic afferent patterns in the cultures was also shown by Timm staining of the terminal distribution of the mossy fiber system. Mossy fiber terminals, with characteristic ultrastructural features verified in the electron microscope, were thus found in the hilus (CA4) and along the CA3 pyramidal cell layer onto the CA3-CA1 transition. Depending on the amount of dentate tissue relative to CA3 the terminals could stop before reaching CA1 (small fascia dentata) or take up additional intra and infrapyramidal locations along CA3 (small CA3). In cultures with a gap in the CA3 pyramidal cell layer some mossy fiber terminals were found in contact with the CA3 pyramidal cells beyond the gap. In all cultures there was an aberrant projection of supragranular mossy fibers. This projection is analogous to the one known from lesion and transplant studies to form in the absence of the entorhinal perforant path input to the dentate molecular layer. Also, in accordance with these studies the Timm staining pattern of the outer parts of the dentate molecular layer and the entire molecular layer of the hippocampus was altered corresponding to the spread of afferents normally confined to the inner zone of the dentate and str. radiatum of CA3 and CA1. Possibly as a consequence of the lack of normal targets for projections from CA1, this subfield contained an unusually dense Timm staining suggestive of autoinnervation.(ABSTRACT TRUNCATED AT 400 WORDS)

Towards an improved serum-free, chemically defined medium for long-term culturing of cerebral cortex tissue

The present study describes a series of experiments which have led to a substantially improved serum-free, chemically defined medium (CDM) for long-term culturing of reaggregated fetal rat cerebral cortex tissue. A reduction of the original medium concentrations of the hormones insuline, T3 and corticosterone, on the one hand, and an enrichment of the medium with the vitamins A, C and E, the unsaturated fatty acids linoleic and linolenic acid, and biotin, L-carnitine, D(+)-galactose, glutathione (reduced) and ethanolamine, on the other hand, formed the most important chemical adjustments of the medium. With the aid of this CDM (encoded R12), the light- and electron microscopic architecture of the tissue could be kept in a good condition (superior to that seen earlier in serum-supplemented medium) up to 23 days in vitro. From that time on, the neuronal network lying between the reaggregates degenerated for the largest part, while a portion of the large neurons (probably pyramidal cells) plus some of the neuronal network within the reaggregates degenerated too. This degeneration process continued during the following weeks, but the reaggregates nevertheless retained most of their mass, so that both small and large neuronal cell bodies (visible in transparent regions at the edge of the reaggregates) remained in good condition up to at least 103 DIV. Stout, thick nerve bundles interconnecting the reaggregates, also survived up to this point. Electron microscopic evaluation of such 'aged' reaggregates revealed degenerating as well as healthy regions. The latter had indeed retained healthy-looking pyramidal and non-pyramidal neurons, embedded within a dense neuropil which was often traversed by myelinated axons. The numerical synapse density in such selected, healthy tissue regions reached its maximum during the sixth week in vitro, followed by a rapid decrease and a stabilization at about half the peak values. The present culture system has opened the possibility for performing controlled quantitative studies on the relationship between structure and function of cerebral cortex tissues during development and aging, on its dependence on nutrients, hormones and drugs, and on special factors synthesized by the tissue and released into the nutrient medium.

Pitrazepin, a novel GABAA antagonist

Pitrazepin is a potent new GABA antagonist which differs from bicuculline in its chemical structure and its interaction with both [3H]muscimol and [3H]flunitrazepam binding sites, whereby the potency of pitrazepin in displacing [3H]muscimol exceeds that of bicuculline by at least a factor of 10. In physiological experiments, blockade of synaptically released GABA by pitrazepin was shown to reduce inhibitory postsynaptic potentials and resulted in the onset of bursting activity which persisted for hours following drug application. The effect of pitrazepin was not tissue specific since it induced a bursting discharge pattern in cultures derived from hippocampus and hypothalamus. Bursting activity was abolished by GABA, baclofen and pentobarbital, but only weakly reduced by midazolam. Pitrazepin also antagonized the action of exogenous GABA, but failed to influence the action of baclofen, an effect which was associated with a decreased membrane input resistance and which was blocked by barium. These results indicate that pitrazepin selectively interacts with the putative GABAA site, thereby antagonizing the chloride-dependent GABA response.

Slice cultures of cerebellar, hippocampal and hypothalamic tissue

Cerebellar, hippocampal and hypothalamic slices prepared from newborn and 7-day-old rats were cultured by means of the roller-tube technique. Identification of cells was made easier by the fact that at least part of the characteristic cytoarchitecture of the tissue was preserved in vitro. Cerebellar Purkinje cells and neurones of the deep cerebellar nuclei were recognized on the basis of their size, their location within the culture and their dendritic arborization. Pyramidal cells of all hippocampal subfields displayed their characteristic basal and apical dendritic trees with numerous spinous processes. Hippocampal granule cells gave rise to a monopolar dendritic arbor; their axons terminated in the dentate hilus and CA3 region. Golgi-like immuniperoxidase staining allowed localization of groups of neurophysin-positive neurones in slices prepared from the anterior hypothalamus. These neurones, bilaterally bordering the third ventricle, usually displayed a simple dendritic arborization and fine beaded axons. - Cultivation of brain slices prepared from young rats offers particular advantages in that the cultured cells are organized in an organotypic monolayer and individual living neurones may be directly visualized.

Organotypic development of neonate rabbit hippocampus in roller tube culture

Maintenance of organotypic cultures of hippocampus derived from neonate rabbit has not been previously reported. The study described here was undertaken to define the conditions most suitable for organotypic development, in vitro, of this structure. Slices of hippocampus, on flying cover-slips, were maintained on plasma clots in roller tubes, for periods of up to 6 weeks. The results showed that the explanted, immature hippocampus developed in a manner which parallels the in vivo development, previously described. Specifically, pronounced neuronal differentiation was noted as the cultures matured. There is evidence that the hippocampus of rabbit, in vivo, at 3 weeks of age has assumed the mature pattern of neuronal and synaptic differentiation. Such differentiation similarly occurred in the cultured hippocampus described in this study. This system would serve as an ideal tool in applications in experimental neuropathology, where the use of a model of a phylogenetically advanced central nervous system is preferred.

Facilitation by acetylcholine of tetrodotoxin-resistant spikes in rat hippocampal pyramidal cells

The electrical activity of hippocampal pyramidal cells was studied in slice cultures during blockade of the regenerative Na currents. In the presence of tetrodotoxin, these neurones had a mean resting potential of -68 mV, a membrane input resistance of 87 M omega and displayed marked non-linearities in their current voltage relationship. In response to depolarizing stimuli, pyramidal cells generated action potentials of small amplitude, slow rise and long duration. These tetrodotoxin-resistant spikes were abolished by calcium conductance blockers such as cobalt and cadmium ions. Acetylcholine applied to the bath or by iontophoresis depolarized pyramidal cells, elicited spontaneous tetrodotoxin-resistant spikes and facilitated spiking evoked by depolarizing rectangular current pulses or a current ramp. The effects of acetylcholine were not only slow in onset, but also prolonged; they were completely reversible and sensitive to atropine and calcium-antagonists such as cadmium and cobalt ions which, respectively, reduced and abolished these effects. After hyperpolarizations following injection of depolarizing current pulses were suppressed by acetylcholine and often transformed into depolarizing afterpotentials. Acetylcholine had no effect on voltage-independent conductances as determined by application of hyperpolarizing current pulses. These results could be explained by inhibition of the voltage-dependent K+-current, i.e. the M current (blockade of the calcium current could remove any depolarizing influence resulting from M current inhibition) or by a direct activation of a voltage-dependent calcium current by muscarinic agonists.

Choline acetyltransferase in organotypic cultures of rat septum and hippocampus

Choline acetyltransferase (CAT) activity in the hippocampus originates almost exclusively in axons from neurons located in the medial septum. In the rat, the development of CAT in the hippocampus takes place during the first 3 weeks after birth. The development of CAT was studied in organotypic cultures of fetal rat septum and early postnatal rat hippocampus. In some septal explants, enzyme activity increased up to 10-fold during the first 3-4 weeks in vitro. Acetylcholinesterase (AChE) histochemistry showed the presence of AChE-positive cells and fibers in many explants. Thus it appears that septal cholinergic neurons develop CAT and AChE activity even without making contact with their target cells. However, the development of CAT was accelerated by the presence of hippocampal tissue. No CAT activity was found in the hippocampal cultures, confirming that there are few, if any, intrinsic cholinergic cell bodies in the hippocampus.

Cellular, histochemical and connective organization of the hippocampus and fascia dentata transplanted to different regions of immature and adult rat brains

The aims of the present study were to examine the survival and the cellular and connective differentiation of intracerebral transplants of fascia dentata and hippocampus. Pieces of immature dentate and hippocampal tissue were taken from late embryonic (E18) and early postnatal (1-9 days old) rats and transplanted into the brains of 1- to 13-day-old and adult rats. After survival times from 4 days to 2 years the cellular and connective organization of the transplants was monitored in parallel series of sections stained with thionin (cell bodies), Timm's sulphide silver method (terminal fields). Nauta and Fink-Heimer methods (normal and degenerating fibers) and a method for AChE activity (cholinergic afferents). The transplants survived well in all combinations of donor and recipient ages used, and they survived and differentiated in all parts of the recipient brains, although relations to pial and ventricular surfaces appeared to be optimal. Cell differentiation continued after transplantation, and a characteristic laminar organization was retained, although least in embryonic donor tissues. The distribution of intrinsic connections was determined by the types of subfields present in the transplants and interaction with ingrown host afferents. All aberrant intrinsic connections observed corresponded to aberrant connections formed in the hippocampus and fascia dentata denervated in situ and included supragranular mossy fibers in the fascia dentata, aberrant infrapyramidal mossy fibers in CA3, spread of CA4-associated afferents beyond the normal commissural-associational zone in the dentate molecular layer together with ingrowth of CA3-associated and CA1-subiculum-associated afferents. Most transplants received a cholinergic input of host origin irrespective of the localization in the host brain, but also non-cholinergic host pathways innervated the transplants, in particular when the transplants were in close contact with host fiber tracts, and when the recipients were immature. At various transplant locations the non-cholinergic host afferents belonged to the commissural hippocampo-dentate system, the commissural hippocampal system and the callosal system. Other cases suggested innervation of dentate transplant by host entorhinal afferents. The formation and distribution of intrinsic transplant connections and connections between transplant and host appeared to be regulated by the same factors that regulate the development and reorganization of fiber connections in the normal and the in situ denervated hippocampus and fascia dentata. As a special variety of this, the distribution of cholinergic afferents adjusted to the distribution of the major intrinsic and extrinsic non-cholinergic pathways.

Single neuron cultivation of embryonic and perinatal rabbit or rat brains based on plasma clot technique

Isolated neuronal cells dissociated from the brain of embryonic rabbits on the sixteenth day of gestation and of perinatal rats (eighteenth embryonic day, to E18, thirteenth day postnatum, p.n. 13) were selectively cultured using a plasma clot technique. The cells grown were shown to be neurons by means of the neuron-specific synaptosomal plasma membrane antibody (SPM). They differentiated at a very high frequency from rounded cells lacking processes into different shapes characteristic for several neuronal cell types. Morphological differences could be distinguished even after 24 h in culture. The neurons differentiated in vitro for up to 11 days, apparently without need of any direct intercellular contact. Cells caught inside the plasma clot were prevented from decreasing in number. This provides the opportunity to culture few neurons even from an extremely small area of a single brain. As an example, different cell types are shown originating from rat cerebella aged E18 to p.n. 13. Their appearance apparently corresponds to the genesis of cerebellar cell types, as is known from the in vivo situation. The high degree of characteristic neuronal differentiation and the prevention of direct intercellular contacts indicate that this culture method may serve as an in vitro assay for genetically fixed properties acquired in vivo.

A method for defined sectioning of fresh young brains and collection of small regions for cell and tissue culture

A method for the collection of defined small regions from fresh brain under sterile conditions is described. Its reproducibility allows the cultivation of well-defined, corresponding regions from similar brains. After controlled orientation in agarose, the brain can be sectioned by means of a Vibratome in spite of its softness. The section level is defined by co-ordinates of a stereotaxic atlas, produced for this purpose from brains orientated in the same way. Areas desired for cultivation are punched out from tissue slices with 200-550 microns diameter needles according to the atlas pictures. The plugs can then be stored in cold buffer solution until preparation for culture. Exact locations of tissue samples collected can be determined histologically. Either whole or dissociated plugs cultivated by a plasma clot technique lead to morphologically differentiating neurons surviving for more than or up to 14 days, respectively.

Multiple actions of acetylcholine on hippocampal pyramidal cells in organotypic explant cultures

Hippocampal cultures were prepared from 7- to 10-day-old rats by means of the roller-type technique. The preservation of the characteristic hippocampal cytoarchitecture allowed, after many weeks in vitro, impalement of pyramidal cells by microelectrodes under visual control. Application of 10(-7) to 10(-5) M acetylcholine to the bath depolarized hippocampal pyramidal cells, strongly increased their rate of firing and induced paroxysmal depolarization shifts. This depolarizing action was accompanied by a reduction in the amplitude of evoked postsynaptic potentials. Whereas it was not clear whether the decrease in the amplitude of the excitatory postsynaptic potentials was only a result of membrane depolarization, acetylcholine clearly and reversibly reduced the potency of evoked inhibitory postsynaptic potentials. Iontophoresis of acetylcholine to the perisomatic region of pyramidal neurons, like acetylcholine applied to the bath, increased their firing rate and powerfully decreased the amplitude and duration of spontaneous and evoked inhibitory postsynaptic potentials. In contrast, iontophoresis of acetylcholine in the pyramidal cell layer at a distance from the recorded neuron generated a hyperpolarizing response associated with a reduction in firing rate. At high current strength, the initial hyperpolarization was (often) followed by a paroxysmal depolarization shift. High frequency electrical stimulation with electrodes located close to the acetylcholine pipette in the pyramidal cell layer (i.e. about 1 mm away from the recorded neuron) mimicked the acetylcholine effect. Resistance measurements indicated that membrane input resistance was decreased in the majority of cells during application of acetylcholine. This decrease in membrane resistance may result from a direct action of acetylcholine or from an increased synaptic activity. Synaptic alterations induced by acetylcholine were quick in onset and in recovery, while the increase in the rate of firing occurred somewhat later. Atropine (10(-5) M), which had no significant action by itself, completely abolished the action of acetylcholine applied to the bath or by iontophoresis. In contradistinction, naloxone did not influence the acetylcholine effects, although opiates and opioid peptides produce paroxysmal depolarization shifts in pyramidal cells which resemble those induced by acetylcholine. Addition of 8-16 mM magnesium to the bathing solution or exposure of the cultures to a calcium-free solution containing 1 mM cobalt abolished the effects of acetylcholine. In the presence of 10(-6) g/ml tetrodotoxin, 10(-5) M acetylcholine decreased the membrane input resistance of pyramidal cells, reduced their threshold for the generation of tetrodotoxin-resistant spikes and generated paroxysmal depolarization shifts in a proportion of pyramidal cells...