A coeruleo-spinal system in culture

The capacity of central and peripheral catecholaminergic neurons to innervate the pineal organ and cerebral cortex of the rat: in vitro immunohistochemical observations

The locus coeruleus (LC) or superior cervical ganglion (SCG) of neonatal rats were co-cultured either with the pineal organ or cerebral cortex (CX) to investigate the innervating capacity of central and peripheral catecholamine neurons under these experimental conditions. After 2 weeks of co-culturing, cultures were fixed for tyrosine hydroxylase (TH) immunohistochemistry to examine the distribution of catecholamine neurons and their fibers. Glial fibrillary acidic protein and fibronectin immunohistochemistry was performed to determine the cell types proliferating around the explants. In LC/CX co-cultures, numerous astrocytes spread between the two explants, and TH-immunoreactive neurites were generally seen to invade CX explants. In contrast, neurite extension from LC to pineal explants occurred only when a glial cell sheet grew between the two explants, and when the pineal explants were not surrounded by a tight fibronectin-positive cell layer. Neurites of the SCG usually invaded both CX and pineal explants, regardless of the existence of glial or non-glial cell layer. These results indicate that central and peripheral catecholamine neurites have the potential of invading both the cortex and pineal, although they are distributed only in particular regions of the intact brain. The distribution of LC neurites, however, seems to be profoundly affected by the cell types spreading around the explants; glial cells appear to support LC neurite extension, whereas non-glial cells appear to inhibit it.

Developmental aspects of the locus coeruleus-noradrenaline system

The locus coeruleus-noradrenaline (LC-NA) system exhibits an early developmental pattern, so that its nerve terminals are present in target areas before formation of most synapses. Several properties of the source neurons in the LC change substantially during early postnatal periods: spontaneous activity patterns, responsiveness to sensory stimulation, and responsiveness to NA. The effect may be to confer enhanced responsiveness of LC neurons, and an enhanced release of NA in target areas, during early postnatal development. Developmental changes in density of adrenoceptors or adrenergic responsiveness in target areas have also been documented. The usual pattern is a progressive increase in adrenergic ligand binding, with some reduction during later phases of development. However, there are a number of examples of receptor subtypes and region-specific transient binding during the first few weeks of postnatal life, followed by reductions to very low levels. These observations may reflect developmentally transient adrenergic responsiveness in certain target areas. NA and the LC-NA system have been implicated in the control of morphological and functional properties of neurons in target areas, and in the control of developmentally important biochemical systems (ornithine decarboxylase). NA, as well as other neurotransmitters, may individually, or in cooperation, exert important trophic influences during a restricted developmental period.

Evidence for functional contact between cografted locus coeruleus and spinal cord in oculo: electrophysiological studies

The functional consequences of the locus coeruleus innervation of the spinal cord are not yet clearly understood. In a recent histological study it was shown that intraocular spinal cord grafts will become innervated by tyrosine hydroxylase-positive nerve fibers from a cografted locus coeruleus. In the present study we use this intraocular model of the descending coeruleo-spinal pathway to investigate functional contact between locus coeruleus and the spinal cord. We have pharmacologically characterized the receptor mediation of norepinephrine-induced, as well as locus coeruleus-mediated depressions of spinal cord neurons grafted in oculo. We found that electrical stimulation of the locus coeruleus part of the double grafts predominantly caused an inhibition of cografted spinal cord neurons. Norepinephrine-induced inhibition of the firing rate of single grafted spinal cord neurons was antagonized by phentolamine, an alpha-adrenergic antagonist, but was unaffected by timolol, a beta-adrenergic antagonist. Similarly, inhibition of the firing rate of grafted spinal cord neurons by stimulation of cografted locus coeruleus was antagonized by phentolamine but not by timolol. Interestingly, single spinal cord grafts were more sensitive to the depressant effects of perfused norepinephrine than was the spinal cord cografted with locus coeruleus. We conclude that spinal cord grafts can be functionally innervated by cografted locus coeruleus and that the noradrenergic inputs to spinal cord from cografted locus coeruleus are alpha-adrenergically mediated. Furthermore, the postsynaptic receptors in single spinal cord grafts appear to be supersensitive to norepinephrine application.

Effects of noradrenaline on the responsiveness of cultured cerebellar neurons to excitatory amino acids

The effects of noradrenaline (NA) on the responsiveness of cultured cerebellar neurons to excitatory amino acids were intracellularly investigated. NA applied to external medium to a final concentration of 10 microM or lower slightly decreased the firing frequency of spontaneous spikes, induced a small hyperpolarization or slightly increased the input resistance of Purkinje cells. In addition, bath-applied NA was found to enhance the depolarizations induced by iontophoretically applied glutamate and aspartate but to a smaller extent for the latter. These direct and modulating effects of NA were also observed when NA was applied by iontophoresis. The sites sensitive to iontophoresed NA were found to be not uniformly distributed but localized in restricted regions on individual Purkinje cells. The enhancement by NA of the glutamate or aspartate response was blocked by beta-adrenergic antagonists, propranolol or pindolol, and extracellularly applied cAMP mimicked the NA action. These results suggest the possibility that NA physiologically modulates excitatory amino acid-mediating synaptic transmission in the cerebellum probably by acting on beta-rather than alpha-adrenergic receptors.

Membrane excitability changes in hindlimb motoneurons induced by stimulation of the locus coeruleus in cats

The present analysis describes the cellular mechanisms underlying the heightened membrane excitability of hindlimb flexor and extensor motoneurons upon stimulation of the locus coeruleus (LC) in unanesthetized, decerebrate cats. In a total of 73 cells, brief train stimuli to the LC at 50-300 microA intensity evoked one of 4 patterns of motoneuronal responses: a simple excitatory postsynaptic potential (EPSP) with weak trailing depolarization, a double-peak EPSP, an EPSP succeeded by a weak hyperpolarization, or a slow rising EPSP. As the initial dominant EPSP was a consistent finding among all cells and the ensuing potentials were variable in polarity, quantitative characterization was focused on the initial EPSP only. In all cells tested (n = 11), the LC-EPSP was accompanied by a decrease in input resistance. The excitatory LC action was further demonstrated by the consistent (n = 25 cells) motoneuron rheobase decrease when the latter was measured coincident with the summit of an LC-EPSP. Furthermore, the time course of the single-spike afterhyperpolarization became shortened during the LC conditioning stimuli (n = 16 motoneurons). Our data show that the descending LC action on motoneurons is typified by an EPSP accompanied by a net decrease in input resistance as well as a concurrent increase in motoneuron electrical excitability.

Effects of norepinephrine on rat neocortical neurons in dissociated cell culture

Intracellular recordings were made from neurons in dissociated cell culture of neocortex during application of norepinephrine (NE) or other adrenergic agonists. In the population of neurons generally studied, greater than 18 micron in diameter, adrenergic agonists from 1 nM to 50 microM produced no change in membrane potential or input resistance 120 cells). Adrenergic agonists increased synaptic activity impinging on the impaled cell in 25/120 neurons (21%). In neurons in cocultures of locus coeruleus and cerebral cortex, again the same synaptic response to perfusion with NE was noted in 13/93 neurons (14%). In addition, direct effects of NE were noted on 6/93 neurons recorded from in cocultures, all close to the explant. In these cells, NE hyperpolarized the membrane in association with a small decrease in input resistance (11%). These responsive cells may have originated within the explant. A paradigm was used for testing the possibility of a responsive element in the cultures distinct from the impaled soma. 'Hot spots' were found using concentrations of isoproterenol as low as 10 nM.

Cerebellum plus locus coeruleus in tissue culture: I. Catecholamine histofluorescence and extracellular electrophysiology

Neonatal mouse cerebellar cultures with incorporated dorsal pons contained groups of catecholamine histofluorescent locus coeruleus neurons that projected axons to cerebellar cortical regions. Electrical stimulation of local areas of the dorsal pontine fragments evoked complex inhibitory extracellular cortical responses that resembled cerebellar cortical responses to locus coeruleus stimulation in vivo. The apparent structural and functional integrity of the coeruleo-cerebellar system in tissue culture indicates that this model might reasonably be used for biochemical studies of catecholamine development and metabolism.

Physiology and pharmacology of olfactory bulb neurons in dissociated cell culture

Cells from olfactory bulbs of embryonic rats were grown in dissociated cell culture for up to 5 weeks. Both neurons and non-neuronal cells grew in these cultures, with a variety of neuronal populations appearing. A population of 20-25% of the neurons were GABAergic by the criterion of [3H]GABA uptake. Electrophysiologic measurements were made of the baseline activity of the cultured neurons. Cells showed a mean resting potential of 60.1 +/- 1.2 mV and a mean input resistance of 87.6 +/- 9.5 M omega. All cells were sensitive to microperfusion of GABA with half-maximal effect occurring at about 20 microM. Glutamate was universally excitatory but with variations in degree. Carnosine (beta-Ala-L-His), tested over the concentration range of 10 nM to 100 microM, had no effect on input resistance, resting potential, action potential shape, on-going synaptic activity or the responsiveness to either GABA or glutamate. These results are further evidence against a role for carnosine as the excitatory transmitter of the primary olfactory afferents.

Development of catecholaminergic phenotypic characters in the mouse locus coeruleus in vivo and in culture

While abundant studies have begun to elucidate ontogeny of the peripheral nervous system, molecular mechanisms underlying brain development remain obscure. To approach this problem, we initiated parallel in vivo and in vitro studies of the mouse locus coeruleus (l.c.), a brainstem noradrenergic nucleus. The catecholaminergic enzymes tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH) were used to monitor phenotype expression and development. TH catalytic activity and immunocytochemical reactivity were initially detectable on gestational Day 13 (E-13) in vivo, and adult levels of activity were approximately by the third postnatal week. Immunotitration studies indicated that the developmental increase was due to accumulation of enzyme molecules and not enzyme activation. The in vivo developmental profile of DBH approximated that of TH. To begin defining regulatory mechanisms, explants of embryonic brainstem were placed in culture. Explantation on E-12, prior to expression of TH or DBH, resulted in the de novo appearance of these phenotypic characters after 4 days. Explantation on E-18, after the enzymes are already expressed, was followed by a striking sixfold rise in TH activity. Immunotitration studies revealed that the increase in TH activity in E-18 cultures was attributable to increased molecule number, reproducing the in vivo results. Moreover, the E-18 explants, cultured for 3 weeks, attained higher plateau levels of TH activity than E-12 cultures, and this differences was due to increased molecule number. Morphometric analysis indicated that 3-week E-12 cultures actually had more l.c. cells than E-18 cultures, indicating that differences in TH were not due to increased cells in the E-18 l.c. Finally, systemic study revealed that the development of TH activity in culture increased progressively from E-11 to E-12 to E-13, suggesting that critical regulatory events occur at this time. Our studies suggest that the l.c. is an excellent model for the study of brain development in vivo and in vitro. Initial phenotypic expression and dramatic development occur in culture in the absence of normal targets, normal afferent innervation and, presumably, normal humoural milieu.

Development of catecholaminergic nerves in the spinal cord of the rat

The development of the noradrenergic and dopaminergic innervations in the spinal cord of rat was studied using fluorescence histochemical and neurochemical methods. From fetal day (FD) 16 to neonatal day (ND) 26, the cord increased in weight by 4-6 mg/day, except for the period between ND 14 and 20, when the increase was 13 mg/day. Norepinephrine was first detectable in the whole cord at ND 18, and then increased rapidly thereafter, peaking at ND 14, then declining at the end of neonatal life to the values found in the young adult spinal cord. The innervation in the intermediolateral cell column of the thoracic cord appeared to be more extensive at ND 14 than in the adult, raising the possibility of the selective destruction of a part of this noradrenergic innervation during later development. The nerve terminals in the ventral horn were first visualized clearly at birth, with a pattern similar to that of the adult. When the fetal locus coeruleus is transplanted into the transected spinal cord of the adult rat, it induces an extensive proliferation of the cut rostral axons in the ventral horn specifically. It is proposed that the transplanted fetal locus coeruleus produces a neurotrophic substance which stimulates the proliferation of the cut rostral axons derived from the locus coeruleus. Dopamine was first detectable in the cord at ND 20. Unlike noradrenergic nerves, dopaminergic nerves developed slowly throughout neonatal life. The adult innervation presumably develops slowly between ND 26 and young adulthood. In the fetus and very young neonate, DA was most concentrated in the thoracic region. Dopamine metabolism in the cord during neonatal life was a fraction of that found in the adult. It is concluded that the spinal dopaminergic and noradrenergic innervations develop with quite different time sequences. The rapid peaking of the noradrenergic innervation of ND 14 may play a significant role in the overall development and functional maturation of the cord.

Cultured cerebellar neurons: endogenous and exogenous components of Purkinje cell activity and membrane response to putative transmitters

Modified explant cultures of fetal rat cerebellum were developed for electrophysiological and pharmacological studies, at the membrane level, of Purkinje neurons. The goals of the present series of experiments were to identify possible endogenous and exogenous components to the electrical activity of Purkinje neurons, to assess the sensitivity of these neurons to putative excitatory and inhibitory neurotransmitters, and to characterize the membrane response to the transmitters. Intracellular recordings were made from Purkinje neurons, identified on a morphological basis, using conventional electrophysiological techniques. Virtually all Purkinje neurons displayed spontaneous activity. A contribution of both endogenous and exogenous components to the spontaneous activity was indicated by alterations in the pattern and amount of activity when the membrane potential was varied and by the characteristics of the individual potentials themselves. Several types of activity were considered to be endogenous: the most common type consisted of pacemaker-like potentials which generated a pattern of firing similar to that characterized as simple spike activity in previous in vivo studies; another type of endogenous activity consisted of large membrane depolarizations that evoked one or two spikes. These depolarizing responses were similar to the membrane response generated by climbing fiber input to Purkinje cells in vivo. The exogenous components to the spontaneous activity consisted of synaptic potentials including excitatory (EPSPs) and inhibitory (IPSPs) synaptic potentials and biphasic EPSP/IPSPs. Several putative transmitters thought to mediate these synaptic potentials were tested by focal micropressure application to determine if they could mimic the action of the endogenous transmitters. The putative transmitter glutamate depolarized the cultured Purkinje neurons and evoked action potentials, characteristics which were displayed by the excitatory synaptic potentials. The putative inhibitory transmitter GABA hyperpolarized the cultured Purkinje neurons and depressed activity, characteristics which were displayed by the inhibitory synaptic potentials. The putative inhibitory transmitters glycine and taurine were ineffective. Norepinephrine, the transmitter mediating the inhibitory input from the locus coeruleus to Purkinje neurons, was also tested. When applied in the microM range, NE effects were variable. When applied in the mM range, NE depressed the spontaneous activity in a manner suggestive of a presynaptic action.

Electrophysiological techniques in dissociated tissue culture

The application of electrophysiological techniques to tissue culture is still evolving. We have attempted in this chapter to give a practical summary of intracellular recording techniques used in our laboratory, as well as give some examples of new experimental strategies and electrophysiological methods that should provide further information on a number of interesting neurobiological questions. The combination of an increasing knowledge of the cell biology of cultured neurons and advances in electrophysiology should continue to be a fruitful interaction.

Evidence for the existence of alpha- and beta-adrenoceptors on neurones and glial cells of cultured rat central nervous system--an autoradiographic study

The cellular localization of the binding of radioactive noradrenaline and alpha- and beta-adrenoceptor antagonists was studied in organotypic cultures of rat cerebellum, brain stem and spinal cord using autoradiography. In cerebellar cultures, many neurones, which appeared to be Purkinje cells, were labelled by [3H]noradrenaline and by the beta-antagonists [3H]dihydroalprenolol and [3H]carazolol, whereas no binding of the alpha-antagonists [3H]prazosin and [3H]rauwolscine was detected. In cultures of spinal cord and brain stem, [3H]noradrenaline and the beta-antagonists were bound to many large neurones. Binding of [3H] alpha-antagonists was observed to a small number of brain stem and spinal neurones, the labelling being much weaker than that produced by the [3H] beta-antagonists. The antidepressant [3H]desmethylimipramine was bound to many neurones and glial cells in cerebellar, brain stem and spinal cord cultures. Glial cells also possessed binding sites for [3H]noradrenaline and alpha- and beta-adrenoceptor antagonists, findings that are consistent with recent electrophysiological observations which indicate the existence of alpha- and beta-adrenoceptors on cultured astrocytes.