Acetylcholine synthesis by chick spinal cord neurons in dissociated cell culture

Acetylcholine (ACh) synthesis was examined in cultures of chick spinal cord cells to follow the development of the cholinergic neurons. The cells, prepared from 4-day-old embryonic chick spinal cords, were grown either alone in dissociated cell cultures (SC cultures) or with chick myotubes (SC-M cultures). ACh synthesis was measured by incubating the cultures in [³Hcholine and using high-voltage paper electrophoresis to quantitate the amount of [³H]ACh present in cell extracts prepared from the labeled cultures. The amount of [³H]ACh synthesized in SC-M cultures was strictly proportional to the number of spinal cord cells used to prepare the cultures, and was linear with the time of incubation in [³H]choline for periods up to 1 hr. Maximal rates of synthesis were observed with [³H]choline concentrations in excess of 100 μM. Such rates for 1-week-old SC-M cultures were approximately 10–20 pmoles of [³H]ACh/hr/10⁵ spinal cord cells. Studies on the stability of the intracellular [³H]ACh revealed the presence of a major pool with a half-time of 20–30 min. A second, small pool decayed more rapidly. No detectable [³H]ACh was spontaneously released from the cells, suggesting that most of the decay represented intracellular degradation. Development of cholinergic neurons as monitored by [³H]ACh synthesis continued over a 2-week period in SC-M cultures and paralleled general cell growth. When examined at 1 week, SC-M cultures had about a 50% greater capacity for [³H]ACh synthesis and 60% more choline acetyltransferase activity than did SC cultures. No difference was observed in the stability of the [³H]ACh formed for the two types of cultures at 1 week, and no further difference was observed in the rates of [³H]ACh synthesis at 2 weeks. Growth of SC cultures in medium containing different amounts of chick embryo extract (2–10%) or in medium with fetal calf serum (10%) instead of extract produced only small differences in the measured rates of [³H]ACh synthesis. Thus chick spinal cord cells can undergo some of the early stages of cholinergic development in cell culture without sustained contact with skeletal myotubes, one of the normal postsynaptic target cells for the cholinergic neuron population. No absolute requirement for muscle factors was revealed under these conditions, although such factors may have been provided by other cell types in the spinal cord population or may have been present in other additions to the culture medium.     

High affinity choline uptake by spinal cord neurons in dissociated cell culture

Spinal cord-myotube cultures prepared with dissociated embryonic chick spinal cord cells and myoblasts exhibit a high affinity mechanism for accumulating choline. The uptake mechanism has a K_m of 3.4 ± 0.5 μM (7) and a V_m of 40.0 ± 0.1 (7) pmoles/min/mg of protein (mean ± SEM; number of determinations in parentheses). It is inhibited 90–95% by 10 μM hemicholinium-3 or by replacement of Na⁺ in the incubation solution with Li⁺. Part of the choline (10–20%) accumulated by the high affinity system is converted to acetylcholine (ACh). Uptake studies on spinal cord cells and myotubes grown separately demonstrate that the spinal cord cells can account for virtually all of the choline uptake observed in the mixed cultures. Myotubes are unnecessary under these conditions for the expression of the high affinity uptake mechanism by spinal cord cells. Neurons are not the only cell type in culture to exhibit high affinity choline uptake. Chick fibroblasts in both rapidly growing and stationary phase can accumulate choline with kinetics similar to those observed for the high affinity uptake by spinal cord cells. Little if any of the choline accumulated by fibroblasts, however, is converted to ACh. In most uptake studies with spinal cord cells, contributions from fibroblasts were minimized by carrying out the analysis at a time when few non-neuronal cells were present in the spinal cord cultures. These observations suggest that a population of chick central nervous system (CNS) neurons develop a high affinity choline uptake mechanism in cell culture that has many of the properties described for uptake by cholinergic neurons in vivo and that at least part of the choline accumulated by the system can be used for neurotransmitter synthesis.     

3H]-Nitrendipine binding in developing dissociated fetal mouse spinal cord neurons

The development of [3H]-nitrendipine binding was investigated in spinal cord neurons. Kinetic studies indicated two classes of binding sites which were present throughout development and the dissociation constants (Kd) and Bmax increased during development. [3H]-nitrendipine binding during development was characterized by a plateau on days 3-5 with maximal binding observed on day 19 after plating.     

Excessive release of [3H] noradrenaline by veratridine and ischemia in spinal cord

In this study, the properties of ischemic condition-induced and veratridine-evoked [3H]noradrenaline ([3H]NA) release from rat spinal cord slices were compared. It was expected that ischemia mimicked by oxygen and glucose deprivation results in the impairment of Na+/K+ -ATPase with a consequent elevation of the intracellular Na+ -level which reverses the NA carrier and promotes excessive NA release, and veratridine, by the activation of Na+ channels, releases NA both carrier-mediated and Ca2+ -dependent, i.e. vesicular manner. In our experiments, veratridine (1-100 microM) dose-dependently increased the resting [3H]NA release, and its effect was only partially blocked by low temperature or the lack of external calcium, whereas the sodium channel inhibitor tetrodotoxin (TTX, 1 microM) completely prevented it, indicating that veratridine induces NA release via axonal depolarization and reversing the transporters by eliciting Na+ -influx. In contrast to TTX, the local anesthetic lidocaine (100 microM) only partially blocked the veratridine-induced [3H]NA release due to its inhibitory action on K+ channels. The ischemia-induced [3H]NA release was abolished at 12 degrees C, a temperature known to block only the transporter-mediated release of transmitters. However, lidocaine was also partially effective to reverse the action of ischemia on the NA release, indicating that lidocaine is not a useful compound in the treatment of spinal cord-injured patients against the excessive excytotoxic NA release.     

TTX displacement of [H3]-nitrendipine binding in developing spinal cord neurons

[3H] Nitrendipine binding was partially blocked by the presence of tetrodotoxin in developing spinal cord neurons. In young cultures, 1 micron tetrodotoxin displaced 29% and 26% of [3H] nitrendipine binding from the high and low affinity binding sites, respectively. In one month old cultures, tetrodotoxin had no effect on [3H] nitrendipine binding. The interaction between tetrodotoxin and nitrendipine in young cultures suggests ligand binding site similarities during development.     

Pharmacology of GABA-mediated inhibition of spinal cord neurons in vivo and in primary dissociated cell culture

Summary In this paper it is shown that the postsynaptic GABA-receptor chloride ion channel complex is composed of several functional subunits. There are probably at least two stereospecific locations on the receptor for GABA-binding and both must be occupied to obtain an increase in chloride conductance. The interaction between these sites is uncertain but there could be either positive cooperativity between the sites or only a requirement that both sites are occupied without occupation of either site affecting the affinity for GABA of the other site. There is a chloride conductance channel coupled to the GABA receptor which opens for an average of 20 msec and has an average conductance of 18 pS. The GABA-coupled chloride channel may or may not have the same composition as the glycine coupled chloride channel.In addition to the GABA-recognition site and the chloride ion channel, GABA-receptors must have additional binding sites or modulator sites where drugs can bind to modify GABA activation of the GABA-receptor. The convulsant PICRO binds to a site which is independent of the GABA-recognition site and PICRO reduces GABA responses. Barbiturates and benzodiazepines augment GABA-responses without reducing GABA-binding and thus they must bind to a modulator site independent of the GABA recognition site. Whether or not this is the same site as the PICRO binding site is uncertain. Thus, the GABA-receptorchloride ion channel complex is composed of at least: 1) two GABA-binding sites; 2) a chloride ion channel; 3) a convulsant binding site (PICRO-binding site) and 4) an anticonvulsant binding site. This organization serves several obvious purposes. First, since two GABA-molecules are required to activate GABA-coupled chloride ion channels, the dose-response relationship for GABA is sigmoidal and steep. Thus minor shifts in GABA affinity will produce large alterations in GABA-responses and the GABA receptor can be easily modulated. Second, since the receptor has binding sites for convulsant and anticonvulsant compounds which decrease and increase GABA-responses, GABAergic inhibition can easily be modulated.     

Electrophysiologic and morphologic properties of neurons in dissociated chick spinal cord cell cultures

Neurons dissociated from embryonic chick spinal cords mature in relatively sparse cell culture and survive in vitro for several weeks. They generate action potentials and form both excitatory and inhibitory chemical synapses with one another. By electrophysiologic and morphologic criteria, it appears that the neuronal population (after 2–3 weeks) is made up of a variety of different cell types; few, if any, are motoneurons. Neuron cell bodies are not covered by glia or satellite cells and nerve processes are not myelinated. Thus, the cultures should permit more direct microelectrode and pharmacologic analysis of differentiation of cell specific properties and of synapse formation than is possible in the intact central nervous system.     

Nerve growth factor-independent development of embryonic mouse sympathetic neurons in dissociated cell culture

Although ganglia from neonatal mouse sympathetic ganglia require nerve growth factor (NGF) for survival in culture, explanted sympathetic ganglia from early embryonic stages do not require added NGF for survival and growth. To determine whether the change in growth factor requirement is due to changes in the neurons themselves, to variations in neuronal populations, or to changes in nonneuronal cells, we examined the response to growth factors by dissociated sympathetic neurons at various stages of development. Results indicate that neurons from the 14-day gestational (E14) superior cervical ganglion (SCG) do not require NGF for initial survival and neurite extension, but do require the conditioned medium neurite extension factor, CMF. By 2 to 3 days thereafter, whether in vivo or in culture, most neurons have developed a requirement for NGF for survival in culture. During the same period, there is a concomitant increase in responsiveness to NGF alone as a trophic agent. Changes in response to NGF are not due to changes in NGF content of ganglia, to interactions in culture with nonneuronal cells, or to age-related differences in NGF requirements for maximum survival. The changes in growth factor requirements may be related to mechanisms regulating specificity of nerve-target connections.     

Uptake and metabolism of l-[3H]pyroglutamic acid in neuronal and glial cells in culture

The presence of an efficient uptake system for l-pyroglutamate was demonstrated in cultured glial cells originating from newborn rats. This compound is also transported by a high affinity uptake mechanism in neurons cultured from rat embryos cerebral hemispheres, but the V_max is 6 times lower than for glial cells. It is shown that l-pyroglutamate like l-glutamate is preferentially transported by glial cells, but with a V_max 40 to 60 times lower than for glutamate. The metabolism of l-pyroglutamate was also studied in cultured rat neuronal and glial cells, using l-[³H]pyroglutamate. Pyroglutamate, its metabolites and the various amino acids were separated by thin-layer electrophoresis. [³H]Pyroglutamate is more actively metabolised in glial cells than in neurons and glutamate is the main metabolite. Glutamate maximal specific activity is 4 times higher in glial than in neuronal cultures. It should also be noted that some [³H]pyroglutamate is transformed in [³H]GABA after longer incubation periods, but only in neurons. These results show the importance of glial cells for pyroglutamate uptake and metabolism in nervous tissue. They also suggest that pyroglutamate may interfere with glutamate neurotransmission in vivo.     

Synaptic connections in a dissociated mixed culture of rat dorsal root ganglion and spinal cord neurons

Postsynaptic currents and action potentials recorded from neurons in a mixed culture of rat dorsal root ganglion and spinal cord cells are described. The existence of mutual synaptic connections between the above two types of neurons is demonstrated. Neirofiziologiya/Neurophysiology, Vol. 38, No. 4, pp. 358–360, July–August, 2006.     

Urotensin-II regulates intracellular calcium in dissociated rat spinal cord neurons

Urotensin-II (U-II), a peptide with multiple vascular effects, is detected in cholinergic neurons of the rat brainstem and spinal cord. Here, the effects of U-II on [Ca2+]i was examined in dissociated rat spinal cord neurons by fura 2 microfluorimetry. The neurons investigated were choline acetyltransferase-positive and had morphological features of motoneurons. U-II induced [Ca2+]i increases in these neurons with a threshold of 10-9 m, and a maximal effect at 10-6 m with an estimated EC50 of 6.2 x 10-9 m. The [Ca2+]i increase induced by U-II was mainly caused by Ca2+ influx from extracellular space, as the response was markedly attenuated in a Ca2+-free medium. Omega-conotoxin GVIA (10-7 m), a N-type Ca2+ channel blocker, largely inhibited these increases, whereas the P/Q Ca2+ channel blocker, omega-conotoxin GVIIC (10-7 m) and the l-type Ca2+ channel blocker, verapamil (10-5 m) had minimal effects. Down-regulation of protein kinase C by 4-alpha-phorbol 12-myristate 13-acetate (10-6 m) or enzyme inhibition using the specific inhibitor bisindolylmaleimide I (10-6 m) did not inhibit the observed effects. Similarly, inhibition of protein kinase G with KT5823 (10-6 m) or Rp-8-pCPT-cGMPS (3 x 10-5 m) did not modify U-II-induced [Ca2+]i increases. In contrast, protein kinase A inhibitors KT5720 (10-6 m) and Rp-cAMPS (3 x 10-5 m) reduced the response to 25 +/- 3% and 42 +/- 8%, respectively. Present results demonstrate that U-II modulates [Ca2+]i in rat spinal cord neurons via protein kinase A cascade.     

GDAF对原代培养脊髓神经元的影响

The effect of GDNF on long-term cultured spinal cord neurons was studied. GDNF could promote spinal cord neurons survival after 7 d or 14 d culture by MTT assay. The effect of GDNF on growth cones, neuron soma magnitude, neurite length and spines formulation of spinal cord neurons in cell culture was observed by phase microscopy, Nissl stain and NSE immunocytochemistry stain. The results indicated that GDNF had significant trophic effects on long-term cultured spinal cord neurons.     

Target influences on [3H]ACh synthesis and release by ciliary ganglion neurons in vitro

The developmental influence of neuron-target interaction upon transmitter synthesis from labeled precursor and the capacity to release labeled transmitter were examined in dispersed cell cultures of embryonic ciliary ganglion neurons by comparing cultures of neurons plated alone and neurons plated upon pectoral myotubes. Of the total ACh synthesized from radiolabeled choline by neurons plated alone, more than half is via a Na+-dependent path, but a larger fraction of the synthesis is Na+ insensitive in culture than in mature neurons in vivo. In addition, at 1 week in culture the neurons lacking target failed to significantly increase ACh synthesis from the labeled choline in response to a previous high [K+]0 depolarization. Synthetic responsiveness to depolarization is a characteristic of mature nerve terminals in this preparation. One week after plating neurons onto myotube cultures, synthesis of ACh from the exogenous precursor is double that of sibling cultures lacking muscle, and prior depolarization with [K+]0 results in an increase in labeled product. Release from the labeled transmitter pool by the neurons with myotubes was also enhanced. [3H]ACh release elicited by depolarization via a Ca2+-dependent mechanism was more than fivefold higher in the cocultures. The influence of coculture with myotubes upon neuronal development is not duplicated by the neurons themselves despite formation of apparent interneuronal synapses (G. Crean, G. Pilar, J. Tuttle, and K. Vaca, 1982, J. Physiol. (London). 331, 87-104), by "fibroblasts" or medium conditioned over myotube cultures. Neurons under these conditions neither increase synthesis of [3H]ACh in response to a prior depolarization nor demonstrate enhanced basal [3H]ACh synthesis and release. Thus, coculture of embryonic ciliary ganglion neurons with a striated muscle target has a somewhat specific inductive effect, enhancing the capacity for neuronal [3H]ACh synthesis and release toward mature levels. This influence of a readily accessible target upon ciliary neuron cholinergic development in vitro may reflect a normal neuromuscular interaction occurring during embryogenesis.     

Uptake of gamma-aminobutyric acid by catfish brain

Using homogenates of catfish whole-brain in an isotonic medium, we observed an accumulation of [3H]GABA that was temperature-sensitive and was dependent on the presence of sodium ions, the optimum concentration of which was 75 mM. A kinetic analysis showed that the [3H]GABA uptake mechanism became saturated with increasing GABA concentrations. A high-affinity system, only, was evident whose Km was calculated as 12 microM. Four structural analogues of GABA were found to be competitive inhibitors of uptake, and Ki values were determined. Nipecotic acid (Ki = 1.8 microM) and guvacine (Ki = 3.9 microM) were the most potent compounds, however 2,4-diaminobutyric acid (Ki = 8.9 microM) and beta-alanine (Ki = 55 microM) also had an effect. The characteristics of the uptake mechanism in catfish brain that we have studied are similar to those reported for uptake by mammalian brain except that in the latter, both a high- and a low-affinity transport processes are present. Our data, taken together with what is already known, strongly suggest that the biochemistry of the GABA system in lower vertebrates does not differ significantly from that in mammals.     

Biochemical characterization of [3H]norepinephrine uptake in dissociated brain cell cultures from chick embryos

The uptake of [³H]norepinephrine ([³H]NE) was studied in dissociated brain cell cultures prepared from 8-day-old chick embryos using the whole brain (minus optic lobes). Uptake of [³H]NE, 5×10^–9 M, 10 min incubation, in freshly dissociated noncultured embryonic chick brain cells, was detected in 6-day-old embryos; it was temperature and drug (cocaine, metanephrine) sensitive and increased with brain development. In cultured cells, which were assayed at various days in culture, the increase in [³H]NE accumulation per culture was less than that seen in freshly dissociated noncultured embryonic cells. When [³H]NE uptake was expressed per mg protein, a decrease with days in culture was observed, reflecting perhaps a dilution of growth or proliferation of cells not accumulating NE. Metanephrine, 5×10^–6 M, an inhibitor of extraneuronal uptake, inhibited [³H]NE in 5-day-old cultures whereas desmethylimipramine, an inhibitor of neuronal uptake, inhibited [³H]NE uptake in 15- and 20-day-old cultures. Cocaine, another neuronal inhibitor, inhibited [³H]NE at 10 and 15 days only. We interpret these findings to suggest that during early growth in culture most neuroblasts accumulate NE nonspecifically and, as neuronal maturation proceeds, NE accumulation becomes specific.     

Uptake and metabolism ofl-[3H]glutamate andl-[3H]glutamine in adult rat cerebellar slices

Using very low concentrations (1 mumol range) of L-2-3-[3H]glutamate, (3H-Glu) or L-2-3-[3H]glutamine (3H-Gln), we have previously shown by autoradiography that these amino acids were preferentially taken up in the molecular layer of the cerebellar cortex. Furthermore, the accumulation of 3H-Glu was essentially glial in these conditions. We report here experiments in which uptake and metabolism of either (3H-Glu) or (3H-Gln) were studied in adult rat cerebellar slices. Both amino acids were rapidly converted into other metabolic compounds: after seven minutes of incubation in the presence of exogenous 3H-Glu, 70% of the tissue accumulated radioactivity was found to be in compounds other than glutamate. The main metabolites were Gln (42%), alpha-ketoglutarate (25%) and GABA (1,4%). In the presence of exogenous 3H-Gln the rate of metabolism was slightly slower (50% after seven minutes of incubation) and the metabolites were also Glu (29%), alpha-ketoglutarate (15%) and GABA (5%). Using depolarizing conditions (56 mM KCl) with either exogenous 3H-Glu or 3H-Gln, the radioactivity was preferentially accumulated in glutamate compared to control. From these results we conclude: i) there are two cellular compartments for the neurotransmission-glutamate-glutamine cycle; one is glial, the other neuronal; ii) these two cellular compartments contain both Gln and Glu; iii) transmitter glutamate is always in equilibrium with the so-called "metabolic" pool of glutamate; iv) the regulation of the glutamate-glutamine cycle occurs at least at two different levels: the uptake of glutamate and the enzymatic activity of the neuronal glutaminase.     

Uptake and release of [3H]-serotonin in photophores of the midshipman fish, Porichthys notatus

A kinetic analysis of [3H]-5-HT uptake in the photocytes of the photophores of Porichthys notatus revealed a high affinity (Km: 1.71 X 10(-7] and low affinity component (Km: 1.10 X 10(-5) M). The high affinity uptake was sodium- and potassium-dependent but largely insensitive to temperatures between 0 and 20 C. Ouabain (5 X 10(-3) M) and dinitrophenol (10(-3) M) reduced uptake significantly. DMI, imipramine and fluoxetine, in that order of potency, greatly inhibited [3H]-5-HT uptake. Noradrenaline and adrenaline reduced uptake in a non-competitive manner, while dopamine, tryptophan, 5-hydroxytryptophan and Cypridina luciferin had little or not effect on uptake. Non-facilitated luminescent responses to electrical stimulation were accompanied by release of [3H]-5-HT accumulated in the photocytes. Facilitatory luminescence excitation consistently failed to induce the release of [3H]-5-HT. Electrical and adrenaline (10(-5) M) stimulation of photophores after [3H]-5-HT release has occurred, failed to elicit any additional luminescent response. The photophores were responsive to KCN (10(-3) M) under these conditions. The results indicate that a specific carrier-mediated transport system is responsible for photocytic [3H]-5-HT uptake, and that release of photocytic [3H]-5-HT is stringently regulated and followed by inhibition of luminescence excitability.     

Uptake of [3H]-arachidonic acid by human endometrium. Differences between normal and menorrhagic tissue

Human proliferative and secretory endometrium from normal women and from menorrhagic patients was maintained in culture for up to 24 h in the presence of [3H]-arachidonic acid (3H-AA). This prostaglandin (PG) precursor was incorporated into endometrial neutral lipids and phospholipids in a time-dependent manner. Uptake of 3H-AA into phospholipids was significantly higher in normal secretory endometrium than in normal proliferative endometrium. However, this increased uptake of 3H-AA into phospholipids between the 2 phases of the cycle did not occur in menorrhagic endometrium. In contrast, uptake of 3H-AA into neutral lipids (especially triglyceride) was approximately 2-fold higher in menorrhagic endometrium compared to normal endometrium at both stages of the cycle, particularly during the proliferative phase. Abnormalities apparently exist in menorrhagic endometrium in the uptake processes which control arachidonic acid (AA) turnover. These abnormalities may be responsible, in part for abnormal PG production by menorrhagic endometrium.