Morphology and electrophysiology of ventral mesencephalon nerve cell cultures

Use of TH-EGFP transgenic mice as a source of identified dopaminergic neurons for physiological studies in postnatal cell culture

The physiological and pharmacological properties of dopaminergic neurons in the brain are of major interest. Although much has been learned from cell culture studies, the physiological properties of these neurons remain difficult to study in such models because they are usually in minority and are difficult to distinguish from other non-dopaminergic neurons. Here we have taken advantage of a recently engineered transgenic mouse model expressing enhanced green fluorescence protein (EGFP) under the control of the tyrosine hydroxylase promoter to establish a more effective dopaminergic neuron cell culture model. We first evaluated the specificity of the EGFP expression. Although ectopic expression of EGFP was found in cultures derived from postnatal day 0 pups, this decreased over time in culture such that after 2 weeks, approximately 70% of EGFP-expressing neurons were dopaminergic. We next sought to validate this dopaminergic neuron culture model. We evaluated whether EGFP-expressing dopaminergic neurons displayed some of the well-established properties of dopaminergic neurons. Autoreceptor stimulation inhibited the activity of dopaminergic neurons while neurotensin receptor activation produced the opposite effect. Confocal imaging of the synaptic vesicle optical tracer FM4-64 in EGFP-expressing dopaminergic neurons demonstrated the feasibility of high resolution monitoring of the activity of single terminals established by these neurons. Together, this work provides evidence that primary cultures of postnatal TH-EGFP mice currently represent an excellent model to study the properties of these cells in culture.

Morphometric characteristics of cryopreserved mesencephalic dopamine neurons in culture

Blocks of embryonic rat mesencephalon were freeze-stored for 1-2 years in liquid nitrogen at -196 degrees C with 7.5% dimethyl sulfoxide (DMSO) as cryoprotectant. After thawing, pooled mesencephalic tissues were mechanically dissociated. The cells, plated at two different densities (4.10[5] and 2.10[5]/cm2) were cultured in a serum-supplemented medium for at least 2 weeks before immunocytochemical staining with highly specific antidopamine (DA) antibodies. The cryopreserved DA-immunoreactive (IR) neurons were compared, by means of computerized morphometry, to the fresh ones plated at the same densities. A separate analysis of the dendritic and axonal morphometric parameters revealed that the cryopreserved DA-IR cells, whatever the experimental conditions, had significantly larger dendritic fields and, less significantly, larger axonal fields than their fresh counterparts. A principal component analysis, mainly based on the dendritic morphometric parameters, allowed to individualize only two populations (cryopreserved and fresh) among the four groups studied. These findings underline the role of dendrites as potential sites of release and/or re-uptake of dopamine and their possible implications in functionally effective cryopreserved nigral grafts.

Cryopreserved GABAergic neurons in cultures of rat cerebral cortex and mesencephalon: a comparative morphometric study with anti-GABA antibodies

Blocks of embryonic rat cerebral cortex and mesencephalon were cryopreserved and stored for up to 1 year in liquid nitrogen at -196 degrees C with 7.5% dimethylsulfoxide (DMSO) as cryoprotectant. After thawing, these tissues were only mechanically dissociated and the cells were cultured for 2-7 weeks before immunocytochemical staining with anti-GABA (gamma-aminobutyric acid) antibodies. The freeze-stored GABA-immunoreactive (IR) mesencephalic neurons were compared, with computerized morphometry, to fresh mesencephalic cells and to their fresh and frozen cerebral cortical counterparts. A part of the cortical cells was treated with thienyl-phencyclidine (TCP) in order to assess the potential morphological effects of this neuroprotective agent upon these cortical neurons. Two types of GABA-IR neurons (small and large neuritic field cells) could be evidenced in both structures without any difference between fresh and frozen materials, but with significant quantitative morphological differences linked to their anatomical source. GABAergic phenotype is expressed similarly in fresh and frozen cultured neurons with intrinsically programmed morphological features and only minor influences of epigenetic factors. Small and large neuritic field GABA-IR neurons represent, respectively, local and long-range circuits of inhibition, strongly reminiscent of those described in vivo and which remain unchanged in culture even after freeze-storage.

Electrophysiological characterization of dopaminergic and non-dopaminergic neurones in organotypic slice cultures of the rat ventral mesencephalon

The aim of the present study was to characterize electrophysiologically neurones in organotypic cultures of the rat ventral mesencephalon and to compare these results with results published for the same neurones in other types of preparation. Intracellular recordings were obtained in 3- to 8-week-old organotypic slice cultures of the ventral mesencephalon prepared from new-born rats. Dopaminergic neurones were distinguished from non-dopaminergic neurones by staining with the autofluorescent serotonin analogue 5,7-dihydroxytryptamine and briefly viewing the preparation with short exposures to ultraviolet (UV) light (365 nm). Short exposures to UV light did not affect the electrophysiological properties. There were no significant differences between dopaminergic and non-dopaminergic neurones with regard to resting membrane potential or action potential threshold and amplitude, and in both types of neurone spontaneous burst activity and glutamatergic excitatory postsynaptic potentials were seen. There were differences in the following parameters, which can be used to distinguish between the two types of neurone. Dopaminergic neurones had broad action potentials (2-9 ms), high input resistance (mean 81 M omega), were silent or fired spontaneously at a low frequency (0-9 Hz), and no spontaneous GABAA-ergic inhibitory postsynaptic potentials or inward rectification were present. In contrast, non-dopaminergic neurones had fast action potentials (0.6-3.2 ms), low input resistance (mean 32 M omega), were silent or fired spontaneously at relatively high firing frequency (0-28 Hz), and sometimes inhibitory postsynaptic potentials and inward rectification were seen. In the presence of 1 microM tetrodotoxin and 10 mM tetraethylammonium, Ca2+ spikes could be evoked in both dopaminergic and non-dopaminergic neurones. Dopaminergic neurones in 3- to 8-week-old organotypic slice cultures have a number of distinguishing electrophysiological characteristics similar to those recorded in other types of acute or cultured preparations. However, some intrinsic regulatory mechanisms, namely the slow oscillatory potentials, inward rectification and the K+ current, IA, seem to be missing in the cultured neurones.

Dissociated high-purity dopaminergic neuron cultures from the substantia nigra and the ventral tegmental area of the postnatal rat

We have developed dissociated primary neuronal cultures obtained from the substantia nigra and from the ventral tegmental area of postnatal rats (two to three days old). After making brain slices, the regions of the substantia nigra and the ventral tegmental area were separately dissected. The removed fragments of brain tissue were dissociated and cultured on a glial feeder layer. Double immunocytochemical labeling for tyrosine hydroxylase and GABA on cultures grown for two to three weeks showed the presence of 42% dopaminergic and 39% GABAergic neurons in substantia nigra cultures, whereas in ventral tegmental area cultures there were 65% dopaminergic and 21% GABAergic neurons. The dopaminergic neurons were characterized by thick and straight primary processes dividing into several branches. Varicosities were found mainly on distal parts of the processes. In contrast, GABAergic neurons possessed highly branched thick and thin primary processes with intensive arborization and numerous varicosities. Co-existence of dopamine and cholecystokinin was found in about 70% of dopaminergic neurons from the substantia nigra and in about 35% of dopaminergic neurons from the ventral tegmental area. Physiological properties of these cultured dopaminergic neurons were investigated with the whole-cell version of the patch-clamp method. After each physiological experiment, immunocytochemical labeling confirmed that the cell was dopaminergic. Properties of single action potentials, with an action potential height of 92 mV and duration of 1.6 ms, were similar to those reported for dopaminergic neurons in brain slices. The neurons showed a high resting potential, and no spontaneous firing of action potentials. Constant current depolarizations elicited trains of action potentials. In the majority of cells, the train stopped firing within a few seconds, while in some cells it lasted indefinitely. When the cell was hyperpolarized, the voltage response started to decline slowly (sag), indicating the presence of hyperpolarization-activated currents (time-dependent inward rectification). These results show that by using our culture method it is possible to obtain separate dissociated cultures of the substantia nigra and the ventral tegmental area from newborn rats. Because they are rich in functional dopaminergic neurons, these cultures will be a useful tool for studying various properties of dopaminergic neurons.

A high percentage yield of tyrosine hydroxylase-positive cells from rat E14 mesencephalic cell culture

In the ventral mesencephalon of the E14 rat fetus, 90% of the dopaminergic, tyrosine hydroxylase positive (TH+) cells are localized in 1.0 mm3 of tissue. This same ventral mesencephalic region also contains 90% of the dopamine content of the E14 ventral brainstem (2.2 +/- 0.3 nmol/mg protein). When cells were prepared for culturing from this localized area, and plated at a density of 2.5 x 10(5) cells/cm2, 17-21% of the cells were TH+, at 4 and 12 h, and at 1, 5, 7 and 10 days after plating. The percentage of TH+ cells was also 17-21% when examined at 4 h, 12 h or 5 days after plating at densities ranging from 7.8 x 10(3) to 2.5 x 10(5) cells/cm2. However, cell survival at a density of less than 6.2 x 10(4) cells/cm2 was poor after 5 days in culture. Based on the degree of neurite elongation and complexity, cell maturation appeared to be complete at 5 days in culture (DIV5), and appeared to be maintained at this level up to DIV10. By DIV14, neurite retraction was evident, and the cells were more rounded. These signs may indicate the inception of senescence in the cultures. A benztropine-sensitive, concentration-dependent dopamine uptake mechanism was demonstrated in the cultures at DIV7, and DA could be released from preloaded cells using 50 mM K+. Five morphological subtypes of TH+ cells were identified in the cultures. This primary culture of the ventral mesencephalic, dopaminergic area, with a high percentage of TH+ cells, is suitable for use in acute biochemical and cellular studies, between DIV 5 and DIV10.

Membrane properties of identified mesencephalic dopamine neurons in primary dissociated cell culture

Dopamine (DA)-containing neurons in primary dissociated cell cultures derived from the embryonic mouse mesencephalon (day E13) were studied by histochemical and electrophysiological techniques. DA neurons exhibited two distinct morphologies, fusiform and multipolar, tended to reside in groups and organize dendrites into common fascicles. While these neurons expressed the cell-surface marker acetylcholinesterase, the presence of this enzyme could not be used to identify DA neurons unequivocally, since it was also observed in nondopaminergic cells. Neurons were therefore identified as DA by their distinct morphology, and this identification was validated with a double-labeling procedure that entailed the intracellular deposition of a fluorescent dye (Lucifer yellow or ethidium bromide), followed by processing for tyrosine hydroxylase immunocytochemistry. DA neurons identified in this manner were observed to have resting membrane potentials between -50 and -75 mV, input resistances of 50-360 M omega, and membrane time constants of 4.1-14.1 msec. Forty-seven percent of these cells displayed spontaneous activity that was irregular in nature and often contained bursts (burst length was between two and six action potentials). The DA neurons displayed a variety of ionic conductances, including (1) a Na+ conductance (gNa) that underlies the action potential, (2) Ca2+ conductances (gCa) that mediate the nonsomatic low- and high-threshold spikes observed, and (3) at least three K+ conductances (gK). Voltage-clamp analysis revealed several distinct transmembrane ionic currents, including (1) a large, rapidly inactivating tetrodotoxin-sensitive inward Na+ current (INa), (2) a 4-aminopyridine-sensitive, transient early outward K+ current that required a conditioning hyperpolarization of the membrane to be activated by a subsequent depolarization (A-current, IA), (3) a slowly developing inward current that was seen only after a conditioning hyperpolarization of the membrane and that was dependent on the presence of external Ca2+ ions (ICa), and (4) a late-onset, noninactivating K+ current. Between 25% and 54% of the late-onset K+ current was Ca(2+)-dependent and was not affected by tetraethylammonium ions. This current was termed IAHP. The remaining current was not sensitive to changes in the extracellular Ca2+ concentration but was blocked by external tetraethylammonium. This current was termed IK. The direct pressure application of DA (1-200 microM) onto the soma dose-dependently hyperpolarized these neurons; this effect was potentiated by the presence of the catecholamine reuptake blocker cocaine hydrochloride (10-200 microM). Under voltage-clamp conditions, DA was observed to increase IK significantly and had little effect on IAHP.(ABSTRACT TRUNCATED AT 400 WORDS)

Changes in membrane-bound and soluble molecular forms of acetylcholinesterase in mouse hippocampus after cholinergic denervation

In order to observe acetylcholinesterase (AChE) and its distribution into soluble and membrane-bound molecular forms in cholinergically denervated hippocampus, AChE was analyzed in the hippocampus of adult mice with and without bilateral fornix lesions made by stereotactically positioned knife cuts. Homogenates from lesioned mice contained an average of 3% of choline acetyltransferase-specific activity, 12% of AChE-specific activity and 98% of protein compared to homogenates from controls. After lesioning, the relative proportion of membrane-bound G4 decreased from 77% to 56% of total AChE while soluble G4, membrane-bound G1-G2, and soluble G1-G2 each increased in relative abundance.

A simple, fast and reliable method for obtaining dopamine histofluorescence from mesencephalic cultures

A modified glyoxylic acid technique for obtaining dopamine histofluorescence from cultured mesencephalic cells is described. This method requires only two solutions: one contains glyoxylic acid, sucrose and monobasic potassium phosphate and is used at room temperature, the other is a Hepes buffered solution used at 37 C. Relatively high concentrations of a monoamine oxidase inhibitor and dopamine are added to the cultures to load dopaminergic neurons; the cell bodies and their processes take up and hold dopamine quickly and evenly. The cultures are dipped in a glyoxylic acid solution, dried in air, heated for 5 min and coverslipped with mineral oil. Since the cultures remain in their culture dishes, the entire procedure takes less than 2 hr. The green histofluorescence characteristic of dopamine is seen when the cultures are viewed by standard fluorescence microscopy. Various cell body types and sizes can be distinguished, as well as the complete extent of their processes and varicosities.

Acetylcholine responses in synaptically active neurons in mouse ventral mesencephalon cultures

Acetylcholine (ACh) sensitivity was examined in neurons in dissociated cultures from fetal ventral mesencephalon (14-16 days gestational age); many neurons probably originate in substantia nigra. Direct responses to iontophoretically applied ACh were recorded by intracellular microelectrodes in 53 cells and indirect responses were recorded from 58 synaptically connected cells. Cultures (24-50 days old) were studied in growth media enriched with serum (10%) and calcium (6.8 mM). Direct responses: ACh caused a slow depolarization (seconds) in 94% (50/53); in 30% of these cells (15/50) the depolarization exceeded action potential threshold. Hyperpolarizing responses occurred in 4% (2/53) and another cell showed reduced action potential firing. Indirect responses: Application of ACh to adjacent cells caused an increase in postsynaptic potential (PSP) activity which was excitatory in 66% (38/58) and inhibitory in 17% (10/58). A reduced level of PSP activity occurred in 7% (4/58) of cells exhibiting excitatory PSPs and in 10% (6/58) of cells with inhibitory connections. Indirect responses were blocked by tetrodotoxin. ACh receptor types: Responses to ACh were predominantly muscarinic (77%, 10/13). Nicotinic responses were present in the remaining 23% (3/13).