The development of synapses in vitro between previously dissociated chick spinal cord neurons

Intracellular distribution of psychotropic drugs in the grey and white matter of the brain: the role of lysosomal trapping

1. Since the brain is not a homogenous organ (i.e. the phospholipid pattern and density of lysosomes may vary in its different regions), in the present study we examined the uptake of psychotropic drugs by vertically cut slices of whole brain, grey (cerebral cortex) and white (corpus callosum, internal capsule) matter of the brain and by neuronal and astroglial cell cultures. 2. Moreover, we assessed the contribution of lysosomal trapping to total drug uptake (total uptake=lysosomal trapping+phospholipid binding) by tissue slices or cells conducting experiments in the presence and absence of 'lysosomal inhibitors', i.e., the lysosomotropic compound ammonium chloride (20 mM) or the Na(+)/H(+)-ionophore monensin (10 microM), which elevated the internal pH of lysosomes. The initial concentration of psychotropic drug in the incubation medium was 5 microM. 3. Both total uptake and lysosomal trapping of the antidepressants investigated (imipramine, amitriptyline, fluoxetine, sertraline) and neuroleptics (promazine, perazine, thioridazine) were higher in the grey matter and neurones than in the white matter and astrocytes, respectively. Lysosomal trapping of the psychotropics occurred mainly in neurones where thioridazine sertraline and perazine showed the highest degree of lysosomotropism. 4. Distribution interactions between antidepressants and neuroleptics took place in neurones via mutual inhibition of lysosomal trapping of drugs. 5. A differential number of neuronal and glial cells in the brain may mask the lysosomal trapping and the distribution interactions of less potent lysosomotropic drugs in vertically cut brain slices. 6. A reduction (via a distribution interaction) in the concentration of psychotropics in lysosomes (depot), which leads to an increase in their level in membranes and tissue fluids, may intensify the pharmacological action of the combined drugs.

Trans-(+-)-1-amino-1,3-cyclopentanedicarboxylate (trans-ACPD) stimulates cAMP accumulation in rat cerebral cortical slices but not in glial or neuronal cultures

Recent cloning experiments indicate that multiple metabotropic receptors for excitatory amino acids (EAAs) exist, which are coupled to adenylate cyclase. Trans-(+-)-1-amino-1,3-cyclopentanedicarboxylate (trans-ACPD) is a selective agonist of metabotropic receptors for EAAs. One of the effects of trans-ACPD is stimulation of cAMP accumulation. In the present experiments, cAMP accumulation was measured using a [3H]adenine-prelabelling technique. It has been found that trans-AC-PD was able to induce significant stimulation of cAMP accumulation in rat cerebral cortical slices, with ED50 of 47.8 microM, which value is similar to that described earlier for hippocampal slices. However, trans-ACPD had no effect on cAMP accumulation either in primary neuronal or glial cell cultures. The reason for the lack of effects of trans-ACPD on cAMP accumulation in primary cultures from glial cells and neurons is discussed.

The development of neuropeptide Y-immunoreactive neurons in a model of pure cortical culture

The development of neuropeptide Y-immunoreactive neurons in the rat brain cerebral cortex was studied in a model of a pure cortical culture. In this model, development of neurons devoid of any afferents from other brain structures could be observed. Since mutual interactions between neuropeptide Y and catecholamines have been postulated, such a pure cortical culture offers a possibility of studying the development of neuropeptide Y neurons devoid of any brainstem monoaminergic afferents. A tissue dissected from 16-day-old rat fetuses and cultivated in a dissociated culture for 14 days was examined immunohistochemically for the presence of neuropeptide Y-immunoreactive neurons. Three main types of neuropeptide Y-immunoreactive neurons were found: unipolar, bipolar and multipolar. Cell processes and terminal varicose fibres were also observed. The results obtained indicate that neuropeptide Y-immunoreactive neurons and fibres may develop in a pure culture of the rat cerebral cortex without the influence of any other structures.

Changes in the amount and distribution of neuronal alkaline and acid phosphatase after chronic exposure of cultures of cingulate cortex to antidepressant drugs

Enzyme histochemistry was used to examine alkaline and acid phosphatases in cultures of embryonic rat cingulate cortex after 14 days exposure in vitro to two tricyclic antidepressants (amitriptyline and desipramine) and two non-tricyclic antidepressants (mianserin and citalopram). An increased amount of acid phosphatase reaction product was observed in lysosomes of neurons in cultures treated chronically with the non-tricyclic antidepressants, mianserin or citalopram. More strikingly, reaction product was also present in the inner lamellae of the Golgi apparatus after this treatment, but never in controls. These observations suggest that non-tricyclic antidepressants significantly increase the rate of degradative processes in cingulate neurons. In cultures, treated chronically with desipramine or amitriptyline, pre- and postsynaptic membranes contained heavy deposits of alkaline phosphatase reaction product, whereas in control cultures not exposed to these drugs the corresponding membranes were entirely devoid of reaction product. An increase in the amount of alkaline phosphatase reaction product was also observed on the plasma membranes of neuronal cell bodies. These observations suggest that chronic exposure to antidepressants may influence transmembrane transport in cingulate neurons.

The effects of various antidepressant drugs on the fine-structure of neurons of the cingulate cortex in culture

We have examined the effects of antidepressant drugs on the morphology and fine-structure of cingulate cortex neurons and synapses in vitro. Dissociated cell cultures from 16-day-old rat fetuses were maintained for up to three weeks in the presence of amitriptyline and desipramine (tricyclic antidepressants) mianserin and citalopram (non-tricyclic antidepressants) or without drugs as controls. Synapses in cultures exposed to amitriptyline and desipramine displayed increased numbers of presynaptic vesicles and more extensive membrane specializations than in control cultures, and increased numbers of coated vesicles both pre- and postsynaptically. In mianserin- and citalopram-treated cultures, synaptic specializations were increased in length, and aggregates of mitochondria at the base of neurites were observed. Our results indicate that long-term exposure to antidepressant drugs results in significant changes in intracellular structure, including changes in synaptic ultrastructure.

Primary dissociated cell culture of fetal rat central nervous tissue. I. Immunocytochemical and ultrastructural studies of cell development and synaptogenesis

We have tried to establish a method of primary dissociated cell culture of the central nervous system (CNS) for successful development of large numbers of synapses and myelinated axons. Cerebra from 18-day-old fetal rats were enzymatically dissociated into single cells and plated onto poly-D-lysine-precoated coverslips at high cell density. With the progress of cell maturation, mixed neuronal and non-neuronal cell processes grew heavily and piled up on each other, making three-dimensional structures which corresponded to 'neuropil' in vivo. Within these structures we could observe not only many mature neurons and remarkable synaptogenesis but also many myelinated axons. The synapses were mainly axo-dendritic but axo-somatic synapses were also occasionally observed. Although most of the axon terminals contained many round clear vesicles which were about 30 nm in diameter, some of them contained both round clear vesicles and 50 nm in diameter vesicles with electron-dense cores. Also a small number of large electron-dense core vesicles (about 130 nm in diameter) were found in the perikarya of mature neurons. The numerous synapse formations observed in 3-dimensional structures suggest that neurons can remain in a stable state and carry out an active metabolism through neurotransmitters. So these structures are considered to provide a favorable microenvironment for both synaptogenesis and myelinogenesis.

Distinctive structural and cytoskeletal properties of the long-surviving neurons in cell cultures of embryonic spinal cord

A distinctive population of neurons survives for longer than 3 months in cell cultures of chick or rat spinal cord. These neurons form a minor proportion (1%) of the neurons initially developing in the cultures, but are the only ones to survive longer than 30 days in vitro. In addition to their longevity, they share important morphological and cytoskeletal characteristics, which render them distinctive as a group even in early cultures which contain numerous other neurons of short-term viability. Each long-surviving neuron projects one neurite of great length relative to its other neurites, or to those of the shorter-lived neurons, and the length of this neurite is maintained constant for many weeks in vitro. This well-defined morphological feature may indicate the lineage(s) of these neurons. Structurally these cells are very different to the shorter-lived neurons. They are rich in neurofilaments and contain very few microtubules, whereas the shorter-lived neurons contain few neurofilaments but many microtubules. These differences in cytoskeleton coincide exactly with the distinction between limited and prolonged survival in vitro, and the possibility is considered that cytoskeletal stability in the presence of numerous small inflows of calcium might underlie "hardiness" in vitro. The state of development of the long-lived neurons is considered in the context of their shared features, and it is suggested that they may provide a model in which the regulation of development of neuronal function can be analysed.

Conjugate internalization of apposed plasma membranes in mouse olfactory bulb during postnatal development

Apposed plasma membranes of mitral cells and granule cell gemmules of mouse olfactory bulb are internalized in a conjugate fashion into mitral cell perikarya during postnatal development. Such conjugate internalization of plasma membranes occurs by way of double-walled coated vesicles (DWCVs) and becomes accelerated between 16 and 37 days of postnatal age. The formation of DWCVs appears to be a mechanism for the internalization of intercellularly adhered plasma membranes.

Plane reconstruction of the structure of mesencephalic tectum from hen embryos in dissociated culture

The changes in the glial and nerve cells in dissociated cultures of the hen embryo tectum opticum have been studied. The changes observed were of a dual character. The cells in dissociated culture take part in the formation of aggregates of dense clumps comprising astroblasts. In the process of cultivation contacts are established between such aggregates due to intensive radial growth of glial cell processes. Particular attention has been paid to the changes of another type leading to the plane reconstruction of the structure of tectum opticum on the surface of collagen. Due to the directed growth of neuroblasts an organized network is developed with a pronounced 'lamination' involving the neuroblasts with the vertically oriented bodies. These neuroblasts, as a result of continuous differentiation, form the initial parts of apical and basal dendrites, as well as the collaterals participating in the formation of neural components of neuropil. Plane reconstruction of the structure of tectum opticum may be considered as a manifestation of histogenesis in the conditions of tissue culture.

Affinity of chick microglia in vitro for ricin 120

The distribution of binding sites for ricin 120 in cell cultures of spinal cord from the chick embryo was examined. A characteristic pattern was observed, which remained similar in cultures fixed by a variety of methods. Light microscopy demonstrated that the most prominent staining was of small rounded or amoeboid cells. Electron microscopy showed that ricin was bound over their entire surfaces. The ultrastructural characteristics of these cells suggest their identification as microglia.

Patterns of reaggregation and formation of linear aggregate chains in collagen-well cultures of dissociated mouse brain and spinal cord cells

With the use of the newly developed collagen-well culture technique spontaneous reaggregation of cells from dissociated embryonic mouse brain and spinal cord were studied. Within 20 h in culture, aggregates are formed and settled onto collagen substrate. Two patterns of aggregate arrangement were observed; random and linear. Linear chains of aggregates appeared to be more characteristic of dissociated spinal cord cells, although the linear patterns were not uncommon in cultures of dissociated cortex. Formation of aggregate chains appeared to be dependent on the stage of neuronal and glial differentiation. After attachment to the collagen substrate, the general pattern of aggregate organization was not greatly altered except for changes which resulted from cellular migration and proliferation, the formation of connections between aggregates, or incorporation of small aggregates into larger ones. The number of non-aggregated cells in collagen-well cultures was small. Single, non-aggregated neurons seldom survived individually. Fiber connections between aggregates began to form after the first day in vitro, and by 2 or 3 days, the growing fibers formed neuritic bridges connecting aggregates. By the end of the first week growing fibers often organized compact bundles, but part connections between aggregates were presented by separate fibers in a diffused manner. Silver impregnation revealed that these connections were formed by the axons of neurons located in the aggregates. Thus, progression of the above described processes resulted in the de' novo' formation of linear organized or random systems of interconnected neuronal centers.

Tubulin immunohistochemistry. Fixation methods affect the response of spinal cord cells in vitro

We report here the results observed when tubulin fluorescence immunohistochemistry is performed upon dissociated cultures of nervous tissue, principally of chick embryo spinal cord. When fixation includes nonpolar solvents or detergents, a uniform fluorescence is seen in neuron perikarya (with the exception of their nuclei), and the processes to which they give rise. Fixation with formaldehyde or glutaraldehyde alone, however, results in a discontinuous staining of neurites, and a less regular staining of their perikarya. The former pattern of response can be elicited if aldehyde fixation is followed by exposure to non-polar solvents. Such results are obtained both in thinly spread regions of the cultures, where neurons and their processes can easily be seen, and in the cell aggregates that also characterise them. Possible interpretations of these results are discussed.

Presynaptic and postsynaptic organelles of synapses formed in cultures of previously dissociated mouse spinal cord

This study describes some of the ultrastructural features of presynaptic and postsynaptic organelles at synapses developed in cultures of previously dissociated mouse spinal cord cells. Particular attention was paid to the agranular reticulum which is well developed at many presynaptic and postsynaptic sites, either in the form of simple tubules or cisternae, or more complex networks and often closely associated with mitochondria. In addition, the disposition of microtubules at and close to synaptic specializations is described. These and other features of synaptic zones, such as granular vesicles in presynaptic sites, are discussed in relation to cultures developed on feeder layers and synapses in vivo, and in relations to possible degenerative and regenerative events in the cell cultures.

The development and ultrastructure of previously dissociated foetal human cerebral cortical cells in vitro

Cells from foetal human cerebral cortex were mechanically dissociated and subsequently maintained in vitro for periods ranging between three and twenty-eight days. The ultrastructure of these cells at different stages of their development in culture was extensively examined. Nuclear and cytoplasmic features were extremely variable and a wide range of cell types was evidently represented. Of the three principal cell types found i.e. neurons, neuroglia and mesenchymal cells, only a minority of cells was classified with confidence, particularly during the first two weeks in culture. Extensive intercellular junctions of the adhaerens variety, common after 14 days in vitro were present at an earlier stage of development than synaptic profiles. First indications of synapse formation were observed after 21 days in vitro and after 24 days presynaptic sites filled with synaptic vesicles and with well defined presynaptic and postsynaptic thickenings were found. The significance of some of the features observed are both considered and discussed.

Microtubule--synaptic vesicle associations in cultured rat spinal cord neurons

This paper describes new ultrastructural features of neural processes and of synapses in cultured CNS tissue treated with albumin before fixation using a modification of the technique recently introduced by Gray (1975). Nerve fibre bundles in explants of foetal spinal cord grown in vitro for 15-18 days were transected microsurgically. After transection the cultures were exposed to 20% albumin in distilled water and then fixed in unbuffered osmium tetroxide followed by unbuffered glutaraldehyde. In this material, but not in controls (injured but not exposed to albumin; exposed to albumin without injury) microtubules were found within many axonal varicosities, often situated close to presynaptic membrane specializations. These microtubules were closely associated with vesicles resembling synaptic vesicles, which were occasionally aligned in rows along the microtubules. Similar vesicle-microtubule associations were also found in non-terminal axons. Microtubules were also observed very close to some postsynaptic densities. The possiblity that the microtubule-vesicle associations are involved in vesicle movements (along axons and/or within axon terminals) is discussed. A more direct involvement of microtubules in terminals in the mechanism of transmitter release is also considered.

The culture of previously dissociated embryonic chick spinal cord cells on feeder layers of liver and kidney, and the development of paraformaldehyde induced fluorescence upon the former

Spinal cord cells from embryonic chicks were cultured upon liver and kidney feeder layers of similar species origin. Successful cultures were obtained with inocula of cord cells containing as few as 15 000 cells ml(-1), whereas without feeder layers at least 200 000 ml(-1) are ordinarily required. Upon liver, many neurons and processes became intensely fluorescent, a property seldom shared by those grown upon kidney. Many processes upon liver contained large numbers of dense-cored vesicles, significantly larger and more numerous than in those grown upon kidney. We conclude that association with liver feeder layers has the consequence of producing in cord cells fluorescence and ultrastructural characteristics appropriate to catecholamine content, through a mechanism as yet unknown.

A light and electron microscopical study of the nervous tissue of mouse teratomas

Teratomas are tumours which may arise spontaneously in the testis or ovary or may be induced experimentally by the implantation of young embryos into ectopic sites. In this study the nervous tissue within mouse teratomas was investigated by light and electronmicroscopy. Characteristic neuroepithelial tubules, neurons, glia and neuropil were recognized and showed no ultrastructural abnormality apart from collagenous infiltration. Synapses were frequently observed. However, other features of mature C.N.S. tissue including myelin and complex synaptic configurations were never seen, and it was not possible to recognize distinct classes of neurons, or organizations of cells and processes which characterized specific regions of the C.N.S. The limited differentiation of the nervous tissue of teratomas is discussed with reference to the normal development of C.N.A. in vivo and in vitro. The presence of synapses in the nervous tissue of teratomas is interpreted as a reflection of an intrinsic tendency of neuronal processes to form these specialized contacts even under conditions which prevent the development of certain other characteristics of nervous tissue.