Human Retinas Synthesize and Release Acetylcholine

Human retinas have the capacity to synthesize and release [3H]acetylcholine ([3H]ACh) after an incubation in [3H]choline ([3H]Ch). Synthesis of [3H]Ch by retinal homogenates was determined using either high-voltage paper electrophoresis (HVPE) or a two-step enzymatic/extraction assay for separating [3H]ACh from [3H]Ch. The enzymatic/extraction assay is shown to be accurate over a wide range of concentrations (10(-6)-10(-12) M). Homogenates of human retina synthesize [3H]ACh from [3H]Ch. We find an approximate Km of 50 microM and a Vmax of about 20 nmol/mg protein/h (at 37 degrees C) for the synthesis of labeled ACh by retinal homogenates. Human retinas also release [3H]ACh after a pulse of [3H]Ch. Release of labeled transmitter is stimulated by potassium depolarization. The potassium-stimulated release is partially blocked by magnesium or cobalt ions. Release data were analyzed by both the enzymatic/extraction assay and HVPE; the results are qualitatively identical in both cases. The data reported here provide additional evidence for cholinergic neurotransmission in the human retina.     

Mechanisms controlling choline transport and acetylcholine synthesis in motor nerve terminals during electrical stimulation

Electrical stimulation of the chick ciliary nerve leads to a frequency-dependent increase in the Na+-dependent high affinity uptake of [3H]choline (SDHACU) and its conversion to acetylcholine (ACh) in the nerve terminals innervating the iris muscle. The forces that drive this choline (Ch) uptake across the presynaptic membrane were evaluated. Depolarization with increased [K+] out or veratridine decreases Ch accumulation. In addition to the electrical driving force, energy is provided by the Na+ gradient. Inhibition of the Na,K-ATPase decreased the Ch taken up. Thus, changes in the rate of Ch transport are dependent on the electrochemical gradients for both Ch and Na+. Ch uptake and ACh synthesis were increased after a conditioning preincubation with high [K+] out or veratridine. As is the case for electrical stimulation, this acceleration of Ch uptake and ACh synthesis was strongly dependent on the presence of Ca++ in the incubation medium. Na+ influx through a TTX-sensitive channel also contributed to this acceleration. Inasmuch as membrane depolarization reduces the initial velocity of Ch uptake and ACh synthesis, their increases during electrical stimulation therefore cannot be the direct effect of the depolarization phase of the action potential. Instead they are the result of the ionic fluxes accompanying the presynaptic spike. It is concluded that stimulation of Ch uptake and ACh synthesis by nerve activity depends first, on the ACh release elicited by Ca++ influx after depolarization and second, on the activation of the Na,K-ATPase due to Na+ entry. Furthermore, it is suggested that the release of ACh after stimulation drives translocation of cytoplasmic ACh into a protected compartment (probably vesicular). This recompartmentation of intraterminal ACh stimulates ACh synthesis by mass action, allowing further accumulation of Ch.     

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.     

Differential Labeling of Depot and Active Acetylcholine Pools in Nondepolarized and Potassium-Depolarized Rat Brain Synaptosomes

Abstract: To test the hypothesis that a pool of newly synthesized acetylcholine (ACh) turns over independently of preformed ACh, compartmentation and K⁺ -evoked release of ACh were examined in perfused synaptosomal beds intermittently stimulated by 50 m M K⁺. In resting synaptosomes, endogenous and labeled ACh was distributed between synaptic vesicles and the cytoplasm in a dynamic equilibrium ratio of 4:6. In the absence of new ACh synthesis, five sequential K⁺ -depolarizations caused a decremental release of preformed labeled ACh totaling 30% of the initial transmitter store. Further depolarization evoked little additional release, despite the fact that 60% of the labeled ACh remained in these preparations. Release of the preformed [¹⁴C]ACh was unaltered while new ACh was being synthesized from exogenous [³H]choline. Since the evoked release of [³H]ACh was maintained while that of [¹⁴C]ACh was decreasing, the [³H]ACh/[¹⁴C]ACh ratio in perfusate increased with each successive depolarization. This ratio was six to ten times higher than the corresponding ratio in vesicles or cytoplasm. These results indicate that the newly synthesized ACh did not equilibrate with either the depot vesicular or cytoplasmic ACh pools prior to release.     

Selective Expression of Factors Preventing Cholinergic Dedifferentiation

Chicken retina neurons from 8-9-day-old embryos developed prominent cholinergic properties after several days in stationary dispersed cell (monolayer) culture. These cells accumulated [3H]choline by a high-affinity, hemicholinium-sensitive transport system, converted [3H]choline to [3H]-acetylcholine [( 3H]ACh), released [3H]ACh in response to depolarization stimuli, and developed choline acetyltransferase (ChAT) activity to levels comparable to those of the intact retina. The cholinergic state, however, was not permanent. After 7 days in culture, the capacity for [3H]ACh release decreased drastically and continued to diminish with longer culture periods. Loss of this capacity seemed not to be due to loss of cholinergic neurons, because high-affinity choline uptake was unchanged. However, a substantial decrease of ChAT activity was observed as a function of culture age, and probably accounted for the low level of ACh synthesis in long-lasting cultures. The loss of ChAT activity could be prevented in at least two different ways: (a) Maintaining the neurons in rotary (aggregate) rather than stationary culture completely blocked the loss of enzyme activity and gave a developmental profile identical to the known "in situ" pattern of differentiation; and (b) Conditioned medium from aggregate cultures significantly reduced the drop in ChAT activity of neurons maintained in stationary, dispersed cell cultures. Activity that stabilized cholinergic differentiation was nondialyzable, heat-sensitive, and not mimicked by functional nerve growth factor. Production of activity by aggregates was developmentally regulated; medium obtained from aggregates after 3 days in culture had no effect on cholinergic differentiation, whereas medium obtained from aggregates between 6 and 10 days in culture produced a fivefold increase of ChAT in monolayers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ciliary ganglion neurons in cell culture: high affinity choline uptake and autoradiographic choline labeling

Chick ciliary ganglion neurons grown in dissociated cell culture have a high affinity uptake mechanism for choline that has the properties expected for cholinergic neurons. The uptake has an apparent K_m of ca. 0.3 μM and is blocked by addition of 10 μM hemicholinium-3 or replacement of Na⁺ by Li⁺ in the uptake medium. When the choline uptake mechanism is used to label ciliary ganglion neuron-myotube cultures autoradiographically, over 99% of the neurons are labeled. A few cells with neuronal morphologies in such cultures (<1%) are labeled by γ-[³H]aminobutyric acid uptake. The number of [³H]choline-labeled neurons and the amount of Na⁺-dependent choline uptake is the same for ciliary ganglion neurons grown with and without skeletal myotubes. Rat superior cervical ganglion neurons, grown in cell culture under conditions that induce them to synthesize acetylcholine and form cholinergic synapses, are labeled by [³H]choline uptake, though not as heavily as ciliary ganglion neurons. In contrast, chick dorsal root ganglion neurons, a presumed population of noncholinergic neurons, are not labeled by [³H]choline uptake. Thus high affinity choline uptake can be used to label autoradiographically the cholinergic neurons tested, while at least one population of noncholinergic neurons remains unlabeled.     

Mode of Action of Palytoxin on the Release of Acetylcholine from Rat Cerebrocortical Synaptosomes

Palytoxin (PTX; 10(-14)-10(-6) M) caused a dose-dependent increase in the release of [3H]acetylcholine ([3H]ACh), cytosolic free Ca2+ concentration ([Ca2+]i), and uptake of 22Na+ and decrease in membrane potential in rat cerebrocortical synaptosomes. The dose-response curves for the PTX-induced increases in [3H]ACh release and in [Ca2+]i were depressed by removing extracellular Ca2+ or by decreasing extracellular Na+ concentrations. The release of [3H]ACh induced by concentrations of PTX less than 10(-10) M was more dependent on the simultaneous presence of both Ca2+ and Na+ than the release induced by higher concentrations of PTX. The PTX-induced increase both in [3H]ACh release and in [Ca2+]i was almost completely abolished by the combination of Ca2+ deprivation and Na+ concentration reduction. All responses to PTX were highly resistant to 10(-6) M tetrodotoxin. These results suggest that low concentrations of PTX cause depolarization as a result of an increase in Na+ permeability through tetrodotoxin-insensitive channels. This, in turn, increases Ca2+ influx and leads to an increase in the release of ACh. It appears that at high concentrations PTX increases the release of [3H]ACh by directly increasing the influx of Ca2+ into synaptosomes and by releasing Ca2+ from intracellular storage sites via an Na(+)-Ca2+ exchange mechanism.     

Ca2+-Surrogate Action of Pb2+ on Acetylcholine Release from Rat Brain Synaptosomes

The effect of lead ions on the release of acetylcholine (ACh) was investigated in intact and digitonin-permeabilized rat cerebrocortical synaptosomes that had been prelabeled with [3H]choline. Release of ACh was inferred from the release of total 3H label or by determination of [3H]ACh. Application of 1 microM Pb2+ to intact synaptosomes in Ca2(+)-deficient medium induced 3H release, which was enhanced by K+ depolarization. This suggests that entry of Pb2+ into synaptosomes and Pb2(+)-induced ACh release can be augmented by activation of the voltage-gated Ca2+ channels in nerve terminals. The lead-induced release of [3H]ACh was blocked by treatment of synaptosomes with vesamicol, which prevents uptake of ACh into synaptic vesicles without affecting its synthesis in the synaptoplasm. This indicates that Pb2+ selectively activates the release of a vesicular fraction of the transmitter with little or no effect on the leakage of cytoplasmic ACh. Application of 1-50 nM (EC50 congruent to 4 nM) free Pb2+ to digitonin-permeabilized synaptosomes elicited release of 3H label that was comparable with the release induced by 0.2-5 microM (EC50 congruent to 0.5 microM) free Ca2+. This suggests that Pb2+ triggers transmitter exocytosis directly and that it is a some 100 times more effective activator of exocytosis than is the natural agonist Ca2+.     

Choline and acetylcholine metabolism in rat neostriatal slices

Choline (Ch) uptake and release and acetylcholine (ACh) synthesis and release have been studied by gas chromatography mass spectrometry (GCMS) in slices of rat neostriatum in vitro to assess the effects of depolarization by 25 mM K+ and the influence of elevated concentrations of Ch in the incubation medium. During the first 60 min after preparation, 25 mM K+ increased ACh release by 182% and reduced ACh levels by 40%. The rate of ACh synthesis was unchanged. After a 1-h equilibration period, the rate of ACh synthesis was considerably less (2.41 nmol mg-1 h-1, compared to 9.78 nmol mg-1 h-1). Exposure to 25 mM K+ during the second hour increased the rate to 6.47 nmol mg-1 h-1. During the first 10 min of exposure to 25 mM K+, ACh synthesis was reduced, regardless of incubation. Increasing concentrations of external [2H4]Ch apparently favored initial rates of net ACh synthesis, since the rank order of initial net ACh synthesis rates is the same as the rank order of external [2H4] Ch concentration under both normal and depolarized conditions. However, the only significant effect of external [2H4]Ch on ACh metabolism was that it increased ACh release during the initial 10 min, when the preparation was depolarized with K+. The efflux of endogenous [2H0]Ch was increased initially (10 min) and slowed over a 60-min period by 25 mM K+, and increased when [2H4]Ch in the medium was increased. Changes in ACh synthesis and release were dependent upon the time exposure of slices to high K+, and the results suggest that Ch favors initial rates of ACh synthesis, but that Ch influences ACh release primarily under conditions of stress (i.e., depolarization).     

Autoradiographic labeling of spinal cord neurons with high affinity choline uptake in cell culture

Embryonic chick spinal cord neurons grown in dissociated cell culture have a high affinity uptake mechanism for choline. We find that, in addition to acetylcholine synthesis, the accumulated choline is used for the synthesis of metabolites such as lipids that are retained in part by conventional fixation techniques. As a result autoradiographic methods can be used to identify the cells that have the uptake mechanism in spinal cord cultures. About 60% of the neurons are labeled by [³H]choline uptake in cultures prepared with spinal cord cells from 4-day-old embryos, and about 40% are labeled in cultures prepared with cord cells from 7-day-old embryos. Neurons that innervate skeletal myotubes in spinal cord-myotube cultures are consistently labeled by [³H]choline uptake. Neurons unlabeled by the procedure are viable: they exclude the dye trypan blue and accumulate ¹⁴C-amino acids for protein synthesis. Most of the neurons unlabeled by [³H]choline uptake can instead be labeled by uptake of γ-[³H]aminobutyric acid, and vice versa. These results suggest that high affinity choline uptake can be used to label cholinergic neurons in cell culture, and that at least some populations of noncholinergic neurons are not labeled by the procedure. It cannot yet be concluded, however, that all labeled neurons are cholinergic since more labeled neurons are obtained per cord than would be expected from the number of neurons making up identified cholinergic populations in vivo. A three- to fourfold increase in the amount of high affinity choline uptake is observed between Days 3 and 15 in culture for spinal cord cells obtained from 4-day-old embryos. The number of [³H]choline-labeled neurons in such cultures decreases slightly during the same period, suggesting that the increase in uptake reflects neuronal growth or development rather than an increase in population size. Both the magnitude of the uptake and the number of [³H]choline-labeled neurons are the same for spinal cord cells grown with and without skeletal myotubes.     

Translocation of cytosolic acetylcholine into synaptic vesicles and demonstration of vesicular release

The rate of translocation of newly synthesized acetylcholine (ACh) from the presynaptic cytosol of Torpedo electric organ nerve terminals into synaptic vesicles and the extent to which ACh release from these neurons is mediated by a vesicular mechanism were investigated. For this purpose the compound 2(4-phenylpiperidino)cyclohexanol (AH5183), which inhibits the active transport of ACh into isolated cholinergic synaptic vesicles, was employed. Preincubation of purified Torpedo nerve terminals (synaptosomes) with AH5183 does not affect the intraterminal synthesis of [3H]ACh but results in a marked inhibition (85%) of its Ca2+-dependent K+-evoked release. By contrast, the evoked release of the endogenous nonlabeled ACh is not affected by this compound. When AH5183 is added during radiolabeling, it causes a progressively smaller inhibition of [3H]ACh release which is completely abolished if the drug is added after the preparation has been labeled. These findings suggest that most of the newly synthesized synaptosomal [3H]ACh (85%) is released by a vesicular mechanism and that some [3H]ACh (15%) may be released by a different process. The translocation of cytosolic [3H]ACh into the synaptic vesicles was monitored by determining the time course of the loss of susceptibility of [3H]ACh release to AH5183. It was found not to be coupled kinetically to [3H]ACh synthesis and to lag behind it. The nature of the intraterminal processes underlying this lag is discussed.     

Effect of ryanodine receptor mutations on interleukin-6 release and intracellular calcium homeostasis in human myotubes from malignant hyperthermia-susceptible individuals and patients affected by central core disease

In this study we report for the first time the functional properties of human myotubes isolated from patients harboring the native RYR1 I4898T and R4893W mutations linked to central core disease. We examined two aspects of myotube physiology, namely excitation-contraction and excitation-secretion coupling. Our results show that upon activation of the ryanodine receptor (RYR), myotubes release interleukin-6 (IL-6); this was dependent on de novo protein synthesis and could be blocked by dantrolene and cyclosporine. Myotubes from the two patients affected by central core disease showed a 4-fold increase in the release of the inflammatory cytokine IL-6, compared with cells derived from control or malignant hyperthermia susceptible individuals. All tested myotubes released calcium from intracellular stores upon stimulation via surface membrane depolarization or direct RYR activation by 4-chloro-m-cresol. The functional impact on calcium release of RYR1 mutations linked to central core disease or malignant hyperthermia is different: human myotubes carrying the malignant hyperthermia-linked RYR1 mutation V2168M had a shift in their sensitivity to the RYR agonist 4-chloro-m-cresol to lower concentrations, whereas human myotubes harboring C-terminal mutations linked to central core disease exhibited reduced [Ca2+]i increase in response to 4-chloro-m-cresol, caffeine, and KCl. Taken together, these results suggest that abnormal release of calcium via mutated RYR enhances the production of the inflammatory cytokine IL-6, which may in turn affect signaling pathways responsible for the trophic status of muscle fibers.     

On the Mechanism of Ouabain-Induced Release of Acetylcholine from Synaptosomes

Ouabain (5 x 10(-8)-5 x 10(-4) M) was confirmed to cause a dose-dependent increase in [3H]acetylcholine ([3H]ACh) release, cytosolic free Ca2+ concentration ([Ca2+]i), and 22Na+ uptake in cerebrocortical synaptosomes of rats in the presence of extracellular Ca2+. Ouabain also caused a dose-dependent decrease in membrane potential. In a low-Na+ (10 mM) medium, ouabain failed to increase [3H]ACh release and [Ca2+]i. Tetrodotoxin (10(-6) M) had no effect on the ouabain-induced increase in both [3H]ACh release and [Ca2+]i but abolished the increase in 22Na+ uptake and partially inhibited the depolarizing effect. Verapamil (10(-6)-5 x 10(-4) M) inhibited the ouabain-induced increase in both [3H]ACh release and [Ca2+]i in a dose-dependent manner. Removal of extracellular Ca2+ abolished the effect of ouabain on [Ca2+]i but not on [3H]ACh release and 22Na+ uptake, regardless of the presence or absence of EGTA. In the absence of extracellular Ca2+, 10 mM Mg2+ blocked ouabain-induced [3H]ACh release, which was resistant to verapamil. These results suggest that ouabain can increase ACh release from synaptosomes without the preceding increases in intracellular Ca2+ and/or Na+ content. It seems likely that the removal of extracellular Ca2+ unmasks mechanisms of ouabain action different from those operating in the presence of Ca2+.     

Growth factor dependent cholinergic function and survival in primary mouse spinal cord cultures

In primary embryonic spinal cord cultures, synaptic transmission can be conveniently studied by monitoring radiolabeled neurotransmitter release or by recording of electrophysiological responses. However, while the mature spinal cord contains an appreciable number of cholinergic motoneurons, cultures of embryonic spinal cord have a paucity of these neurons and release little or no acetylcholine upon stimulation. To determine whether the proportion of cholinergic neurons in primary mouse spinal cord cultures can be augmented, the effects of several classes of growth factors were examined on depolarization- and Ca(2+)-evoked release of choline/acetylcholine (Ch/ACh). In the absence of growth factors, little or no evoked release of radiolabeled Ch/ACh could be demonstrated. Media supplemented with brain-derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF) or basic fibroblast growth factor (bFGF) were examined for their ability to preserve the population of neurons in culture. CNTF was found to increase the number of surviving neurons and to enhance the release of radiolabeled Ch/ACh; the other factors were without effect. The action of CNTF was transient, and the neuronal population decreased to levels observed in cultures lacking growth factor after 20 days in vitro. The correlation between enhanced neuron survival and increased Ch/ACh release suggests that CNTF protected cholinergic neurons, albeit transiently, from cell death.     

Synthesis and ubiquitination of histones during myogenesis

One and two-dimensional polyacrylamide gel electrophoresis have revealed that cultures of postmitotic (G0) chicken skeletal myotube cells synthesize significant but reduced quantities of histone proteins as compared to their proliferating myoblast precursors. In addition, modulation of variant synthesis within the histone H2A and H3 classes may accompany myotube formation. That the histone bands contain no nonhistone contaminants was shown by exclusion of [3H]tryptophan. It is unlikely that these results reflect synthesis of histone by contaminating replicating cells, since a single treatment with cytosine arabinoside at the time of fusion effectively removed unfused cells while suppressing synthesis of DNA in the myotube cultures. The relatively sparse incorporation of label by major variants of the H2A class in dividing myoblasts was shown to be caused by heterogeneity due to phosphorylation and extensive ubiquitination, which decline at the time of myotube formation. As determined by quantitative Western-blotting, dividing myoblasts and myotubes contain an average of 1.0 and 0.4 molecules of ubiquitinated H2A (uH2A), respectively, per 10 nucleosomes.     

Ca2(+)-dependent synthesis of prostaglandin I2 and mobilization of arachidonic acid from phospholipids in cultured endothelial cells permeabilized with saponin

The feasibility of using saponin as a permeabilization agent to study the effect of free Ca2+ concentration ([Ca2+]f) on prostaglandin I2 (PGI2) synthesis and mobilization of arachidonic acid from membrane phospholipids was investigated in cultured bovine pulmonary artery endothelial cells (BPAEC). Treatment of BPAEC with 20 micrograms/ml saponin caused selective permeabilization of the plasma membrane as determined by measurements of the release of lactate dehydrogenase and beta-hexosaminidase. In cells prelabeled with [3H]arachidonic acid for 22 h, permeabilization with 20 micrograms/ml saponin induced PGI2 synthesis and release of [3H]arachidonic acid from membrane phospholipids. These effects were dependent upon [Ca2+]f in the range 72 nM to 5 microM. Release of [3H]arachidonic acid from phospholipid classes was determined in suspensions of BPAEC prelabeled with [3H]arachidonic acid and permeabilized with 20 micrograms/ml saponin. At [Ca2+]f optimal for PGI2 synthesis, 16.2% of the total incorporated [3H]arachidonic acid was released from phosphatidylinositol (3.4%), phosphatidylethanolamine (3.5%) and phosphatidylcholine (9.3%). The time course and dependence upon [Ca2+]f of [3H]arachidonic acid release from phospholipids correlated with PGI2 synthesis. The amount of PGI2 synthesized in permeabilized BPAEC was similar to that in cell cultures treated with the calcium ionophore A23187. In comparison, however, PGI2 synthesis induced by A23187 was associated with less release of [3H]arachidonic acid from membrane phospholipids, e.g., 2.3% versus 16.2%. The greater loss of [3H]arachidonic acid from phospholipids in saponin-permeabilized BPAEC was most likely due to the loss of cell integrity and/or nonspecific effects of the detergent on phospholipases. Despite these limitations, the Ca2+ dependence observed for PGI2 synthesis and [3H]arachidonic acid mobilization suggest that saponin-permeabilization may provide a useful system for studies of the intracellular events triggered by the rise in intracellular Ca2+ which culminate in PGI2 synthesis.     

Increased acetylcholine synthesis and release following presynaptic activity in a sympathetic ganglion

Abstract: The acetylcholine (ACh) content of sympathetic ganglia increases above its normal level following a period of preganglionic nerve stimulation. In the present experiments, this extra ACh that accumulates following activity was labeled radioactively from [³H]choline and its specific activity was compared with that of ACh subsequently released during preganglionic nerve stimulation. The specific activity of the released ACh was similar to that of the total tissue ACh, suggesting that the extra ACh mixes fully with endogenous stores. The present experiments also show that transmitter release during neuronal stimulation is necessary for the poststimulation increase in transmitter store. However, the increase was not evident when transmitter release was induced by K⁺. It is concluded that both transmitter release and impulse invasion of the nerve terminals are necessary for the adaptive phenomenon to manifest itself. The role of choline delivery and choline acetyltransferase activity in generating the poststimulation increase in transmitter store was tested. When choline transport activity measured as choline analogue (homocholine) accumulation increased, ACh synthesis was increased and when transport activity was not increased, neither was ACh synthesis. There was no poststimulation increase in measured choline acetyltransferase activity.     

The induction of acetylcholine synthesis in primary cultures of dissociated rat sympathetic neurons : II. Developmental aspects

Dissociated sympathetic neurons from the neonatal rat, grown in cell culture in the virtual absence of other cell types, can develop many of the properties expected of differentiated adrenergic neurons including the ability to synthesize and accumulate catecholamines (CA)². However, in the presence of high concentrations of appropriately conditioned medium (CM), the cultures develop the ability to synthesize and accumulate acetylcholine (ACh); correspondingly, their ability to synthesize CA decreases. In this paper several developmental aspects of the CM effect are described. The time course of development of cultures grown with or without CM was followed using synthesis and accumulation of [³H]CA from [³H]tyrosine and production of [³H]ACh from [³H]choline as assays for adrenergic and cholinergic differentiation. The ability to produce CA or ACh developed along parallel time courses in the two sets of cultures, rising primarily during the second week in vitro and reaching a plateau during the fourth week. When CM was used as a cholinergic developmental signal, the sympathetic neurons showed a decreasing response to addition of CM as they matured adrenergically; addition of CM during the third or fourth 10 days in vitro was not as effective in inducing ACh production as addition during the first or second 10 days. Similarly, removal of CM at various times from cultures previously grown in CM showed that the cholinergic induction caused by CM was not easily reversible in older cultures. Thus, as with the adrenergic decision, the cholinergic decision becomes less reversible as the phenotype becomes fully expressed.     

Depolarizing stimuli and neurotransmitters utilize separate pathways to activate protein kinase C in sympathetic neurons.

Several types of extracellular signals affect the function of peripheral neurons. Depolarizing stimuli cause sudden increases in permeability to various ions leading to propagation of nerve impulses and release of transmitter substances. Neurons also receive external signals via neurotransmitter receptors located on the membrane. Different types of receptors present on sympathetic neurons are believed to modulate stimulation-evoked release of norepinephrine. We have investigated the effects of depolarizing stimuli and neurotransmitters on different signaling pathways in homogeneous cultures of chick sympathetic neurons. Depolarizing stimuli (35 mM KCl; electrical stimulation, 1 Hz for 5 min) and neurotransmitters (acetylcholine and 5-hydroxytrypatmine) enhanced membrane binding of protein kinase C by 2-5-fold. 35 mM KCl increased formation of 1,2-diacylglycerol and hydrolysis of [3H]phosphatidycholine without affecting [3H] phosphoinositide hydrolysis. Neurotransmitters increased [3H]inositol phosphates and 1,2-diacylglycerol without affecting the hydrolysis of [3H]phosphatidylcholine. 5-Hydroxytryptamine and acetylcholine (muscarinic component) did not increase Ca2+ concentration in the Indo-1-loaded neuronal cell body or the growth cone, but 35 mM KCl and electrical stimulation caused a marked increase in Ca2+ concentration in both regions of sympathetic neurons. We believe this to be the first demonstration of these two types of signalling mechanisms co-existing in sympathetic neurons; depolarization activate the phosphatidylcholine pathway and neurotransmitters activate the phosphatidylinositol pathway. The importance of two pathways in controlling neuronal Ca2+ concentration and the release of transmitter is discussed.     

Time course of decline of radiolabeled acetylcholine formed following intracerebroventricular administration of tritiated choline: Effects of oxotremorine and scopolamine

Rats were injected intracerebroventricularly with 5 Ci of [methyl-³H]choline. The time course of decline of the rediolabeled acetylcholine (ACh) formed was estimated in the ispilateral cerebral cortex and striatum. The [³H]ACh levels declined biphasically from the cerebral tissue. The initial decline proceeded rapidly, after which labeled ACh declined more slowly. Scopolamine (1 mg/kg, i.v.) caused a significant increase in the rat of [³H]ACh disappearance, which can be interpreted as an enhancement of ACh release. By contrast, oxotremorine (0.8 mg/kg, i.v.) markedly reduced the [³H]ACh disappearance. The results show that drug-induced changes in cholinergic neuronal activities can be estimated from the disappearance of radioactive ACh after labeling the endogenous transmitter through intracerebroventricular administration of labeled choline.