Acetyl-CoA metabolism in amprolium-evoked thiamine pyrophosphate deficits in cholinergic SN56 neuroblastoma cells

Inhibition of pyruvate (PDHC) and ketoglutarate (KDHC) dehydrogenase complexes induced by thiamine pyrophosphate deficits is known cause of disturbances of cholinergic transmission in the brain, yielding clinical symptoms of cognitive, vegetative and motor deficits. However, particular alterations in distribution of key acetylcholine precursor, acetyl-CoA, in the cholinergic neuron compartment of thiamine pyrophosphate-deficient brain remain unknown. Therefore, the aim of our work was to find out how amprolium-induced thiamine pyrophosphate deficits (TD) affect distribution of acetyl-CoA in the compartment of pure cholinergic neuroblastoma SN56 cells originating from murine septum. Amprolium caused similar concentration-dependent decreases in thiamine pyrophosphate levels in nondifferentiated (NC) and differentiated (DC) cells cultured in low thiamine medium. In such conditions DC displayed significantly greater loss of viability than the NC ones, despite of lesser suppressions of PDHC activities and tetrazolium salt reduction rates in the former. On the other hand, intramitochondrial acetyl-CoA levels in DC were 73% lower than in NC, which explains their greater susceptibility to TD. Choline acetyltransferase activity and acetylcholine content in DC were two times higher than in NC. TD caused 50% decrease of cytoplasmic acetyl-CoA levels that correlated with losses of acetylcholine pool in DC but not in NC. These data indicate that particular sensitivity of DC to TD may result from relative shortage of acetyl-CoA due to its higher utilization in acetylcholine synthesis.     

Differential toxicity of nitric oxide,aluminum, and amyloid beta-peptide in SN56 cholinergic cells from mouse septum

A characteristic feature of several encephalopathies is preferential impairment of cholinergic neurons. Their particular susceptibility to cytotoxic insults may result from the fact that they utilise acetyl-CoA both for energy production and acetylcholine synthesis. In addition, phenotypic modifications of cholinergic neurons are likely to influence their susceptibility to specific harmful conditions. SN56 cholinergic cells were differentiated by the combination of dibutyryl cAMP and retinoic acid. Al and sodium nitroprusside (SNP, NO donor) exerted direct additive inhibitory effects on mitochondrial aconitase activity. However, NO, Al, or amyloid beta (Abeta)(25-35) caused none or only slight changes of choline O-acetyl transferase (ChAT) and pyruvate dehydrogenase (PDH) activity and relatively small loss of non-differentiated cells (NCs). On the other hand, in differentiated cells (DCs) these neurotoxins brought about marked decreases of these enzyme activities along with greater than in non-differentiated ones increase of cell-death rate. Abeta(35-25) had no effect on these cell parameters. NO and other compounds aggravated detrimental effect of each other particularly in differentiated cells. Thus, differential vulnerability of brain cholinergic neurons to various degenerative signals may result from their phenotype-dependent ratios of acetylcholine to acetyl-CoA synthesising capacities.     

Expression of the cholinergic gene locus in the rat placenta

High amounts of acetylcholine (ACh) and its synthesising enzyme choline acetyltransferase (ChAT) have been detected in the placenta. Since the placenta is not innervated by extrinsic or intrinsic cholinergic neurons, placental ACh and ChAT originate from non-neuronal sources. In neurons, cytoplasmic ACh is imported into synaptic vesicles by the vesicular acetylcholine transporter (VAChT), and released through vesicular exocytosis. In view of the coordinate expression of VAChT and ChAT from the cholinergic gene locus in neurons, we asked whether VAChT is coexpressed with ChAT in rat placenta, and investigated this issue by means of RT-PCR, in situ hybridisation, western blot and immunohistochemistry. Messenger RNA and protein of the common type of ChAT (cChAT), its splice variant peripheral ChAT (pChAT), and VAChT were detected in rat placenta with RT-PCR and western blot. ChAT in situ hybridisation signal and immunoreactivity for cChAT and pChAT were observed in nearly all placental cell types, while VAChT mRNA and immunolabelling were detected in the trophoblast, mesenchymal cells and the visceral yolk sac epithelial cells. While ChAT is nearly ubiquitously expressed in rat placenta, VAChT immunoreactivity is localised cell type specifically, implying that both vesicular and non-vesicular ACh release machineries prevail in placental cell types.     

Intracellular Storage and Evoked Release of Acetylcholine from Postnatal Rat Basal Forebrain Cholinergic Neurons in Culture with Nerve Growth Factor

Cholinergic neurons from the septum area, the vertical limb of the diagonal band of Broca, and the nucleus basalis of Meynert of postnatal 13-day-old rats were cultured with or without nerve growth factor (NGF) conditions. Total choline acetyltransferase (ChAT) activities, acetylcholine (ACh) contents, and survival numbers of cholinergic neurons in culture from each of three distinct regions were increased by NGF treatment, but little difference was found in cellular ChAT activities and ACh contents obtained in cultures with or without NGF. The result shows that NGF promotes the survival of cholinergic neurons from 13-day-old rats. Furthermore, the release of ACh from cultured neurons was investigated. The cells cultured with NGF showed a larger increase of the high K+-evoked ACh release than those cultured without NGF. However, NGF had no effect on spontaneous release. This suggests that NGF could regenerate and sustain the stimulation-evoked release mechanisms of ACh in cultured cholinergic neurons from postnatal rats.     

Effect of Aluminum on Acetyl-CoA and Acetylcholine Metabolism in Nerve Terminals

Abstract: The potential ability of Al to affect cholinergic transmission was studied on synaptosomal fractions of rat brain incubated with pyruvate in depolarizing medium containing 30 m M K⁺. Addition of 1 m M Ca caused a 266% increase in the acetylcholine (ACh) release despite decreased pyruvate oxidation. Under these conditions, 0.25 m M Al did not affect pyruvate oxidation but raised mitochondrial and decreased synaptoplasmic acetyl-CoA. Simultaneously, a 61% inhibition of Ca-evoked ACh release was observed. Verapamil (0.1 and 0.5 m M ) decreased the acetyl-CoA concentration in synaptoplasm and inhibited ACh release. Al (0.012 m M ) partially reversed these inhibitory effects. Omission of P_i from the medium abolished suppressive effects of Al on acetyl-CoA content and Ca-evoked transmitter release. We conclude that the Al(PO₄)OH⁻ complex may be the active form of Al, which, by interaction with the verapamil binding sites of Ca channels, is likely to restrict the Ca influx to the synaptoplasm. This may inhibit the provision of acetyl-CoA to the synaptoplasm as well as the Ca-evoked ACh release. One may suppose that excessive accumulation of Al in some encephalopathic brains may, by this mechanism, suppress still-surviving cholinergic neurons and exacerbate cognitive deficits caused by already-existing structural losses in the cholinergic system.     

4-(1-Naphthylvinyl)pyridine Decreases Brain Acetylcholine In Vivo, but Does Not Alter the Level of Acetyl-CoA

The effects of intraperitoneally administered 4-(1-naphthylvinyl)pyridine (NVP; 200 mg/kg) on the concentrations of acetylcholine (ACh), choline (Ch), and acetyl-CoA (AcCoA) in rat striatum, cortex, hippocampus, and cerebellum were investigated. Twenty minutes after treatment, the content of ACh was significantly diminished, whereas that of Ch was increased. In response to stress (swimming for 20 min), these changes were enhanced. However, the AcCoA content did not change in any of the brain regions. It is thus very likely that the decrease of brain ACh concentration induced by NVP is due to the drug's effect on choline acetyltransferase (ChAT) and/or the reduction of the high-affinity Ch uptake, and not on the availability of AcCoA. Presumably, the pharmacologically diminished activity of ChAT may become the rate-limiting factor in the maintenance of ACh levels in cholinergic neurons.     

Inhibition of choline acetyltransferase as a mechanism for cholinergic dysfunction induced by amyloid-β peptide oligomers

Dysregulated cholinergic signaling is an early hallmark of Alzheimer disease (AD), usually ascribed to degeneration of cholinergic neurons induced by the amyloid-β peptide (Aβ). It is now generally accepted that neuronal dysfunction and memory deficits in the early stages of AD are caused by the neuronal impact of soluble Aβ oligomers (AβOs). AβOs build up in AD brain and specifically attach to excitatory synapses, leading to synapse dysfunction. Here, we have investigated the possibility that AβOs could impact cholinergic signaling. The activity of choline acetyltransferase (ChAT, the enzyme that carries out ACh production) was inhibited by ~50% in cultured cholinergic neurons exposed to low nanomolar concentrations of AβOs. 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) reduction, lactate dehydrogenase release, and [(3)H]choline uptake assays showed no evidence of neuronal damage or loss of viability that could account for reduced ChAT activity under these conditions. Glutamate receptor antagonists fully blocked ChAT inhibition and oxidative stress induced by AβOs. Antioxidant polyunsaturated fatty acids had similar effects, indicating that oxidative damage may be involved in ChAT inhibition. Treatment with insulin, previously shown to down-regulate neuronal AβO binding sites, fully prevented AβO-induced inhibition of ChAT. Interestingly, we found that AβOs selectively bind to ~50% of cultured cholinergic neurons, suggesting that ChAT is fully inhibited in AβO-targeted neurons. Reduction in ChAT activity instigated by AβOs may thus be a relevant event in early stage AD pathology, preceding the loss of cholinergic neurons commonly observed in AD brains.     

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)     

Cholinergic Surface Antigen Chol-1 Is Present in a Subclass of VIP-Containing Rat Cortical Synaptosomes

The colocalization of vasoactive intestinal polypeptide (VIP) with the cholinergic specific surface antigen Chol-1 was investigated in synaptosomes derived from the rat cerebral cortex. Immunoaffinity purification of cortical synaptosomes using antisera to Chol-1 resulted in the copurification of VIP and cholinergic nerve terminals. VIP was purified with a yield of 75% of that of choline acetyltransferase (ChAT). These results suggest that approximately 53% of the cortical cholinergic terminals contain VIP, whereas 75% of the cortical VIP content is present in these cholinergic terminals. Both hypotonic lysis and depolarization of the nerve terminals resulted in the differential release of VIP and acetylcholine (ACh), indicating the different compartmentalization in the same nerve terminal. Complement-mediated lysis of cholinergic nerve terminals, using antisera to Chol-1, resulted in the release of 64% of the ChAT, 71% of ACh, and 27% of the VIP. The application of our method enables quantifying and mapping, with a fast, efficient, and specific technique, the coexisting peptides in cholinergic neurons of distinct brain areas.     

Acetyl-CoA the Key Factor for Survival or Death of Cholinergic Neurons in Course of Neurodegenerative Diseases

Glucose-derived pyruvate is a principal source of acetyl-CoA in all brain cells, through pyruvate dehydogenase complex (PDHC) reaction. Cholinergic neurons like neurons of other transmitter systems and glial cells, utilize acetyl-CoA for energy production in mitochondria and diverse synthetic pathways in their extramitochondrial compartments. However, cholinergic neurons require additional amounts of acetyl-CoA for acetylcholine synthesis in their cytoplasmic compartment to maintain their transmitter functions. Characteristic feature of several neurodegenerating diseases including Alzheimer’s disease and thiamine diphosphate deficiency encephalopathy is the decrease of PDHC activity correlating with cholinergic deficits and losses of cognitive functions. Such conditions generate acetyl-CoA deficits that are deeper in cholinergic neurons than in noncholinergic neuronal and glial cells, due to its additional consumption in the transmitter synthesis. Therefore, any neuropathologic conditions are likely to be more harmful for the cholinergic neurons than for noncholinergic ones. For this reason attempts preserving proper supply of acetyl-CoA in the diseased brain, should attenuate high susceptibility of cholinergic neurons to diverse neurodegenerative conditions. This review describes how common neurodegenerative signals could induce deficts in cholinergic neurotransmission through suppression of acetyl-CoA metabolism in the cholinergic neurons.     

Roles played by lymphocyte function-associated antigen-1 in the regulation of lymphocytic cholinergic activity

Lymphocytes possess the essential components of a cholinergic system, including acetylcholine (ACh); choline acetyltransferase (ChAT), its synthesizing enzyme; and both muscarinic and nicotinic ACh receptors (mAChRs and nAChRs, respectively). Stimulation of lymphocytes with phytohemagglutinin, which activates T cells via the T cell receptor/CD3 complex, enhances the synthesis and release of ACh and up-regulates expression of ChAT and M(5) mAChR mRNAs. In addition, activation of protein kinase C and increases in intracellular cAMP also enhance cholinergic activity in T cells, and lymphocyte function associated antigen-1 (LFA-1; CD11a/CD18) is an important mediator of leukocyte migration and T cell activation. Anti-CD11a monoclonal antibody (mAb) as well as antithymocyte globulin containing antibodies against CD2, CD7 and CD11a all increase ChAT activity, ACh synthesis and release, and expression of ChAT and M(5) mAChR mRNAs in T cells. The cholesterol-lowering drug simvastatin inhibits LFA-1 signaling by binding to an allosteric site on CD11a (LFA-1 alpha chain), which leads to immunomodulation. We found that simvastatin abolishes anti-CD11a mAb-induced increases in lymphocytic cholinergic activity in a manner independent of its cholesterol-lowering activity. Collectively then, these results indicate that LFA-1 contributes to the regulation of lymphocytic cholinergic activity via CD11a-mediated pathways and suggest that simvastatin exerts its immunosuppressive effects in part via modification of lymphocytic cholinergic activity.     

Expression of muscarinic acetylcholine receptors and choline acetyltransferase enzyme in cultured antennal sensory neurons and non-neural cells of the developing moth Manduca sexta

Antennal sensory neurons of Manduca sexta emerge from epidermal cells that also give rise to sheath cells surrounding the peripheral parts of the neurons and to glial cells that enwrap the sensory axons in the antennal nerve. Reciprocal interactions between sensory neurons and glial cells are believed to aid in axon growth and guidance, but the exact nature of these interactions is not known. We investigated the possibility of cholinergic interactions in this process by locating muscarinic acetylcholine receptors (mAChRs) and choline acetyltransferase (ChAT) enzyme in cultured antennal sensory neurons and non-neural cells. ChAT and mAChRs were present in the sensory neurons from the first day in culture. Therefore, the sensory neurons are probably cholinergic, as previously suggested, but they may also be controlled by ACh. In 7-day-old cultures a subgroup of small non-neural cells with processes expressed ChAT activity, and in 14-day-old cultures non-neural cells that formed lamellipodia and scaffoldlike structures on the culture substrate were labeled with ChAT antibody. mAChR activity was detected in similar non-neural cells but only in areas surrounding the nuclei. In addition, mAChRs were found in flat lamellipodia and filopodia forming cells that were present in 1-day-old cultures and grew in size during the 2 week investigation period. These findings suggest muscarinic cholinergic interactions between the neural and non-neural cells during the development of Manduca antenna.     

Recovery of acetylcholine release and choline acetyltransferase activity after freezing-induced degeneration of rat soleus muscle

In order to study the effect of synaptic contact on the amounts of choline acetyltransferase (ChAT) and acetylcholine (ACh) in the nerve terminals and on their ability to release ACh, a freeze—thaw procedure was developed as a means to induce long lasting degeneration of rat soleus muscle. It was found that 4 days after the freeze—thaw procedure the preparation did not contract upon direct electric stimulation and the level of creatine kinase (CK) was below detection. The preparation contained about 15% of the ChAT activity and 15% of the ACh content of the controls. The ACh release evoked by 50 mM KCl was 25% of controls, but it was, when expressed as a fraction of the ACh content, about twice as high as that in control muscles. At day 12, the preparation still did not contract and the level of CK was less than 5% of controls. The ChAT activity and the ACh content were 40%) and 20% of controls, respectively. However, no release of ACh could be evoked by 50 mM KCl. At days 28 and 58 the preparation contracted upon stimulation of the nerve; the CK activity had recovered to about 20% and the ACh content to 40%, while the ChAT activity did not increase above 40%. The KCl–evoked ACh release had recovered to 20—30% of controls. The results indicate that freezing destroyed muscle cells and most intramuscular nerve branches. Subsequent regeneration of muscle fibres was slow, probably because freezing had killed many satellite cells in the muscle. Because the ChAT activity at day 12 had recovered when CK was almost absent and the preparation failed to contract, we conclude that there was expression of ChAT activity in ‘nerve terminals’ which do not make contact with regenerated muscle cells, although little if any ACh was released from these sites. ©1998 Elsevier Science Ltd. All rights reserved.     

RS-alpha-lipoic acid protects cholinergic cells against sodium nitroprusside and amyloid-beta neurotoxicity through restoration of acetyl-CoA level

The work presented here verifies the hypothesis that RS-alpha-lipoic acid may exert its cholinoprotective and cholinotrophic activities through the maintenance of appropriate levels of acetyl-CoA in mitochondrial and cytoplasmic compartments of cholinergic neurons. Sodium nitroprusside (SNP) and amyloid-beta decreased pyruvate dehydrogenase, choline acetyltransferase activities, acetyl-CoA content in mitochondria and cytoplasm, as well as increased fraction of non-viable, trypan blue positive cells in cultured differentiated cholinergic SN56 neuroblastoma cells. Lipoic acid totally reversed toxin-evoked suppression of choline acetyltrasferase and pyruvate dehydrogenase activities, as well as mitochondrial and cytoplasmic acetyl-CoA levels, and partially attenuated increase of cell mortality. Significant negative correlations were found between enzyme activities, acetyl-CoA levels and cell mortality in different neurotoxic and neuroprotective conditions employed here. The level of cytoplamic acetyl-CoA correlated with mitochondrial acetyl-CoA, whereas choline acetyltransferase activity followed shifts in cytoplasmic acetyl-CoA. Thus, we conclude that, in cholinergic neurons, particular elements of the pyruvate-acetyl-CoA-acetylcholine pathway form a functional unit responding uniformly to nerotoxic and neuroprotectory conditions.     

Regulation of acetylcholine synthesis in presynaptic endings of cholinergic CNS neurons

Data on acetylcholine (ACh) synthesis in nerve cells are summarized and the mechanism of regulation of this process is described. Under conditions of relative rest on moderate synaptic activity the ACh concentration in the compartment of its synthesis in cholinergic nerve endings is probably maintained at a level corresponding to equilibrium of the reaction catalyzed by the enzyme choline-acetyltransferase (CAT). ACh release is followed by its transport from the compartment of synthesis into the compartment of secretion and automatic resynthesis of new ACh, until equilibrium is restored in the compartment of synthesis. At the same time synaptic activity and ACh release promote synthesis of new ACh by the following pathways. First, a fall in the ACh concentration in the nerve endings disinhibits carriers for choline, and facilitates choline transfer from the extracellular fluid into the cell in accordance with the electrochemical gradient. Second, hydrolysis of liberated ACh increases the choline concentration in the extracellular fluid in the neighborhood of the nerve endings. Third, postactivation hyperpolarization of the nerve endings facilitates transport of choline and an increase in its concentration in the nerve endings. Fourth, there are grounds for considering that stimulation of muscarine receptors promotes a further increase in the choline concentration in the region of the nerve endings by intensification of phosphatidylcholine hydrolysis in postsynaptic cells. Fifth, a decrease in the acetyl-CoA content on account of ACh resynthesis increases pyruvate dehydrogenase activity and acetyl-CoA production. Sixth, it is possible that an increase in the Ca⁺⁺ concentration in nerve endings promotes direct transport of acetyl-CoA from the mitochondria into the cytosol of nerve endings, where ACh is synthesized. It is postulated that under conditions of intensive synaptic activity the rate of supply of acetyl-CoA and choline and also CAT activity in the nerve endings may be factors limiting the velocity of ACh resynthesis.Institute of Physiology, Czechoslovak Academy of Sciences, Prague. Translated from Neirofiziologiya, Vol. 16, No. 5, pp. 603–611, September–October, 1984.     

Expression of muscarinic acetylcholine receptors and choline acetyltransferase enzyme in cultured antennal sensory neurons and non‐neural cells of the developing moth Manduca sexta

Antennal sensory neurons of Manduca sexta emerge from epidermal cells that also give rise to sheath cells surrounding the peripheral parts of the neurons and to glial cells that enwrap the sensory axons in the antennal nerve. Reciprocal interactions between sensory neurons and glial cells are believed to aid in axon growth and guidance, but the exact nature of these interactions is not known. We investigated the possibility of cholinergic interactions in this process by locating muscarinic acetylcholine receptors (mAChRs) and choline acetyltransferase (ChAT) enzyme in cultured antennal sensory neurons and non‐neural cells. ChAT and mAChRs were present in the sensory neurons from the first day in culture. Therefore, the sensory neurons are probably cholinergic, as previously suggested, but they may also be controlled by ACh. In 7‐day‐old cultures a subgroup of small non‐neural cells with processes expressed ChAT activity, and in 14‐day‐old cultures non‐neural cells that formed lamellipodia and scaffoldlike structures on the culture substrate were labeled with ChAT antibody. mAChR activity was detected in similar non‐neural cells but only in areas surrounding the nuclei. In addition, mAChRs were found in flat lamellipodia and filopodia forming cells that were present in 1‐day‐old cultures and grew in size during the 2 week investigation period. These findings suggest muscarinic cholinergic interactions between the neural and non‐neural cells during the development of Manduca antenna. © 2004 Wiley Periodicals, Inc. J Neurobiol, 2005     

Acetyl-CoA Synthesizing Enzymes in Cholinergic Nerve Terminals

The activities of five enzymes involved in acetyl-CoA synthesis, pyruvate dehydrogenase complex, ATP citrate lyase, carnitine acetyltransferase, acetyl-CoA synthetase, and citrate synthase, were determined in normal nucleus interpeduncularis and nucleus interpeduncularis in which cholinergic terminals were removed following lesion of the habenulointerpeduncular tract. The activities of aspartate transaminase, fumarase, and GABA transaminase also were determined to compare the effect of lesion on other mitochondrial enzymes which are not linked to the biosynthesis of ACh. In normal nucleus interpeduncularis the activities of carnitine acetyltransferase and pyruvate dehydrogenase complex were higher than the activity of ChAT (choline acetyltransferase), whereas the activities of acetyl-CoA synthetase and citrate synthase were considerably lower than that of ChAT. The effect of the lesion separated the enzymes into two groups: the activities of pyruvate dehydrogenase complex, carnitine acetyltransferase, fumarase and aspartate transaminase decreased by 30--40%, whereas the activities of the other enzymes descreased 5--15%. ChAT activity was in all cases less than 15% of normal. It could be concluded that none of the acetyl-CoA synthesizing enzymes decreased to the degree that ChAT did. Only pyruvate dehydrogenase complex and carnitine acetyltransferase seem to be localized in cholinergic terminals to a significant degree. ATP citrate lyase as well as acetyl-CoA synthetase seem to have less significance in supporting acetyl-CoA formation in cholinergic nerve terminals.     

Effects of Colchicine Application to Preganglionic Axons on Choline Acetyltransferase Activity and Acetylcholine Content and Release in the Superior Cervical Ganglion

Abstract: These experiments investigate the effect of block, by colchicine, of fast axonal transport in the cat's cervical sympathetic trunk (CST) on the superior cervical ganglion's choline acetyltransferase (ChAT) enzyme activity, acetylcholine (ACh) content, and ACh release. Electron microscopy on the segment of the CST exposed to colchicine 1 or 4 days earlier showed disappearance of microtubules and accumulation of vesicles and smooth membrane tubules but no disruption of the axonal cytomatrix. At 4 days following colchicine treatment, the number and size of synaptic boutons per grid square in the ganglion ipsilateral to the colchicine-treated CST were similar to those in the control ganglion. At 2 and 4 days following exposure of the CST to colchicine, ChAT activity in the ipsilateral ganglion was reduced to 76 ± 8 and 54 ± 6% of control values, respectively. ACh stores in the ganglia were also reduced (to 81 ± 6% of control values at 2 days and to 51 ± 5% of control values at 4 days). Ganglionic transmission and its sensitivity to blockade by hexamethonium during 2-Hz CST stimulation were not impaired at day 4 postcolchicine. ACh release evoked by 2-Hz stimulation of colchicine-treated axons was similar to release from untreated axons, despite the decrease in the ganglionic ACh content. In contrast, ACh release evoked by 20-Hz stimulation was depressed. The amount of ACh released during 5-Hz stimulation in the presence of vesamicol by the terminals of colchicine-treated axons was similar to that released by the terminals of untreated axons. These results suggest the following conclusions: (a) Colchicine-sensitive fast axonal transport contributes significantly to maintaining ChAT stores in preganglionic axon terminals. (b) The half-life of ChAT in sympathetic preganglionic terminals is ～4 days. (c) One consequence of colchicine-induced block of axonal transport is a reduced ACh content of preganglionic nerve terminals. (d) This decrease in ACh content appears to be the result of a loss in a reserve transmitter pool, whereas the size of the readily releasable compartment is maintained.     

Effects of NGF on acetylcholine, acetyl-CoA metabolism, and viability of differentiated and non-differentiated cholinergic neuroblastoma cells

Nerve growth factor (NGF) is a peptide displaying multiple cholinotropic activities. The aim of this work was to explain mechanisms of the positive and negative effects of NGF on phenotypic properties and viability of cholinergic cells. To discriminate these effects we used two p75NTR receptor-positive lines of cholinergic neuroblastoma cells, SN56 and T17 that are devoid of or express high affinity NGF (TrkA) receptors, respectively. cAMP and retinoic acid caused differentiation of both cell lines. In addition to the morphologic maturation, the increase of choline acetyltransferase activity, acetylcholine, Ca and cytoplasmic acetyl-CoA levels and decrease of mitochondrial acetyl-CoA and cell viability were observed. NGF caused similar effects in non-differentiated T17 cells but had no influence on non-differentiated SN56 cells. On the contrary, in both cAMP/all-trans-retinoic acid (RA) differentiated cell lines, NGF resulted in a similar suppression of cholinergic phenotype along with an increase of mitochondrial acetyl-CoA and cell susceptibility to nitric oxide and amyloid-beta25-35. These effects of NGF were prevented by an antibody against the p75NTR receptor. Data indicate that: (i) positive cholinotrophic effects of NGF required activation of both TrkA and p75NTR receptors; (ii) cAMP/RA-evoked differentiation inhibited NGF effects mediated by TrkA receptors and activated its p75NTR-dependent suppressing influences and (iii) a differentiation-evoked decrease of mitochondrial acetyl-CoA and an elevation of mitochondrial Ca could augment impairment of cholinergic neurons by neurotoxic signals.