Studies on the Alkylation of Choline Acetyltransferase by Choline Mustard Aziridinium Ion

Although a potent irreversible inhibitor of high-affinity choline transport in rat brain synaptosomes, choline mustard aziridinium ion (ChM Az) appeared to be a relatively weak inhibitor of choline acetyltransferase (ChAT) in rat brain homogenates, and evidence for irreversible binding of this compound to the enzyme had not been established. Accordingly, the irreversible inactivation of partially purified rat brain ChAT by ChM Az was studied. This compound is a rather weak inhibitor of the enzyme, with 50% inhibition of ChAT activity achieved following 30 min incubation at 37 degrees C with 0.6 mM ChM Az. This result indicates that although ChM Az has affinity for many nucleophiles there was little diluting effect of the inhibitor in the crude brain homogenate which could be attributed to such reactions (50% inhibition caused by 1.8 mM ChM Az following 10 min incubation). Although the initial binding of ChM Az to ChAT may be of a competitive nature, irreversible bond formation resulted. The time-dependent alkylation reaction conformed to pseudo-first-order kinetics with an observed forward rate constant (kobs) of 0.173 min-1; the half-time (t 1/2) for irreversible binding was about 4 min. The irreversible inactivation of ChAT by ChM Az would appear to be slower than the alkylation of high-affinity choline carriers in synaptosomes by this compound, and the relatively weak inhibitory action of ChM Az against either partially purified ChAT or ChAT activity in crude rat brain homogenates is in striking contrast to previous evidence that ChAT in intact synaptosomes was inhibited irreversibly by lower concentrations of the inhibitor.     

Cytosolic Choline Acetyltransferase Binds Specifically to Cholinergic Plasma Membrane of Rat Brain Synaptosomes to Generate Membrane-Bound Enzyme

Uncovering the way membrane-bound choline acetyltransferase (ChAT) interacts with membranes and with which membrane in cholinergic neurons may help in understanding its role in acetylcholine metabolism. Subfractionation of rat hippocampal synaptosomes aiming to separate synaptic vesicles from plasma membranes shows that membrane-bound ChAT is bound to plasma membrane. Either detergents or urea and alkali can solubilize membrane-bound enzyme. Detergent-solubilized enzyme has a higher sedimentation rate than urea-alkali solubilized or cytosolic ChAT. Once dissociated, membrane-bound ChAT reassociates specifically with cholinergic plasma membranes, a process that was abolished by previous treatment of membranes with trypsin. Cytosolic ChAT behaves similarly. Thus, in cholinergic synaptosomes, ChAT exists as cytosolic and peripheral activity. Cytosolic ChAT generates peripheral enzyme most probably by interacting with a protein of plasma membrane of cholinergic nerve terminals. This receptor protein might regulate the amount of membrane-bound ChAT in cholinergic neurons.     

Affinity Labelling and Identification of the High-Affinity Choline Carrier from Synaptic Membranes of Torpedo Electromotor Nerve Terminals with [3H]Choline Mustard

The physiological mechanisms regulating activity of the sodium-dependent, high-affinity choline transporter and the molecular events in the translocation process remain unclear; the protein has not been purified or characterized biochemically. In the present study, [3H]choline mustard aziridinium ion [( 3H]ChM Az), a nitrogen mustard analogue of choline, bound irreversibly to presynaptic plasma membranes from Torpedo electric organ in a hemicholinium-sensitive, and sodium-, time-, and temperature-dependent manner. Specific binding of this ligand was greatest when it was incubated with membranes in the presence of sodium at 30 degrees C. Separation of the 3H-labelled membrane proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that most of the radiolabel was associated with a polypeptide of apparent molecular mass of approximately 42,000 daltons; labelling of this species was abolished in membranes incubated with ligand in the presence of HC-3. Two other 3H-labelled polypeptides were detected, with apparent molecular masses of approximately 58,000 and 90,000 daltons; radiolabelling of the former was also HC-3 sensitive. [3H]ChM Az may be a useful affinity ligand in the purification of the choline carrier from cholinergic neurons.     

An Evaluation of Irreversible Inhibition of Synaptosomal High-Affinity Choline Transport by Choline Mustard Aziridinium Ion

Abstract: Choline mustard aziridinium is a potent, irreversible and selective blocker of sodium-dependent, high-affinity transport of choline into rat forebrain synaptosomes; it was found to be 30 times less potent against low-affinity transport of choline. The IC₅₀ value for high-affinity transport was 0.94 μM, compared to 29 μM for low-affinity uptake. The inhibitory action of choline mustard aziridinium ion on high-affinity transport of choline was graded with respect to time; a 12-fold increase in potency was obtained by increasing the inhibitor preincubation times from 1 to 30 min. Low concentrations of choline mustard aziridinium ion could produce significant blockade of choline carriers providing the exposure time was prolonged. The characteristics of the blockade of synaptosomal high-affinity choline transport by choline mustard aziridinium ion also changed depending upon preincubation time. The kinetics of inhibition of high-affinity choline transport by choline mustard aziridinium ion showed apparent competitive inhibition initially, followed by noncompetitive characteristics at longer preincubations with inhibitor. The rate of irreversible inhibition of carriers by this nitrogen mustard analogue would appear to be rapid; the rate constant was determined to be 5 × 10^?2 s^?1for micromolar concentrations of inhibitor. This action may preclude the transport of the mustard analogue into the nerve terminal, although initially some reversible binding with the carrier may result in the translocation of some choline mustard aziridinium ion into the presynaptic ending. The progressive alkylation of high-affinity carriers by the analogue could indicate the presence of excess carrier sites in the presynaptic membrane, or subpopulations of carriers in an inactive state in equilibrium with active carriers. A model is described for the inhibitory action of choline mustard aziridinium ion on synaptosomal high-affinity choline carriers.     

Phosphorylation of Rat Brain Choline Acetyltransferase and Its Relationship to Enzyme Activity

Abstract— Choline acetyltransferase catalyzes the formation of acetylcholine from choline and acetyl-CoA in cholin-ergic neurons. The present study examined conditions for modulation of kinase-mediated phosphorylation of this enzyme. By using a monospecific polyclonal rabbit anti-human choline acetyltransferase antibody to immunoprecipi-tate cytosolic and membrane-associated subcellular pools of enzyme from rat hippocampal synaptosomes, we determined that only the cytosolic fraction of the enzyme (67,000 ± 730 daltons) was phosphorylated under basal, unstimulated conditions. The quantity of this endogenous phosphoprotein was dependent, in part, upon the level of intracellular calcium, with ³²P_i incorporation into the enzyme in nerve terminals incubated in nominally calcium-free medium only 43 ± 7% of control. The corresponding enzymatic activity of cytosolic choline acetyltransferase did not appear to be altered by lowered cytosolic calcium, whereas membrane-associated choline acetyltransferase activity was decreased to 58 ± 11 % of control. Depolarization of synaptosomes with 50 μ M veratridine neither altered the extent of phosphorylation or specific activity of cytosolic choline acetyltransferase, nor induced detectable phosphorylation of membrane-associated choline acetyltransferase, although the specific activity of the membrane-associated enzyme was increased to 132 ± 5% of control. In summary, phosphorylation of choline acetyltransferase does not appear to regulate cholinergic neurotransmission by a direct action on catalytic activity of the enzyme.     

Choline acetyltransferase in mammalian synaptosomes: Evidence for an integral membrane-bound form

Choline acetyltransferase activity was detected in extensively washed membranes prepared from rat and guinea pig synaptosomes. When these preparations were treated with the non-ionic detergent Triton X-114 and heated to 37°C to cause phase separation, a significant percentage was found to associate with the detergent-rich phase, indicating that the enzyme might be an integral membrane-bound protein. In guinea pigs receiving septal lesions, a large reduction in both total and in Triton X-114-extractable choline acetyltransferase in hippocampal synaptosomes was observed indicating that the detergent-extracted form is associated with cholinergic nerve terminals. When membrane-bound choline acetyltransferase from lysed, washed synaptosomes was incubated in Triton X-114, 30% of the membrane-associated enzyme could be extracted into the detergent-rich phase. This extraction could be improved by reducing the chloride content of the extraction medium. When the chloride content of synaptosomes, prepared from rat cerebral cortex, was manipulated, by either exposure to γ-aminobutyric acid, muscimol or to a medium containing reduced levels of chloride, the ability of antibodies against choline acetyltransferase to specifically immunolyse (in the presence of complement) the cholinergic synaptosome population was enhanced. These results suggest that the choline acetyltransferase found in the nerve terminal region exists in at least two forms (a soluble and a lipophilic form) which are partially interconvertible. The conversion between the two forms can be influenced by chloride ions.     

Effects of Extracellular Choline Concentration and K+ Depolarization on Choline Kinase and Choline Acetyltransferase Activities in Superior Cervical Sympathetic Ganglia Excised from Rats

The activities of choline kinase (CK) and choline acetyltransferase (ChAT) were examined in vitro in superior cervical sympathetic ganglia (SCG) excised from rats following aerobic incubation for 1 h in a medium containing various choline concentrations, with and without application of a high KCl level (70 mM). Ganglionic CK activity was strongly inhibited (by approximately 75%) at low extracellular choline concentrations (1-5 microM) but rose as the choline concentration was raised to 10-50 microM in the incubation medium, then fell and rose again with further increases in choline concentration. A similar but moderate accelerative effect on ganglionic CK activity was also observed after addition of acetylcholine (ACh; 1 mM) without eserine. Whereas specific CK activity did not change significantly in axotomized SCG, in which the ratio of glial cells to neurons is greatly increased for a week after the operation., it was remarkably increased after denervation, in which the preganglionic cholinergic nerve terminals had degenerated. When either a high KCl level or hemicholinium-3 (HC-3; 50 microM) was added to the medium in the presence or absence of choline, ganglionic CK activity was markedly inhibited. On the other hand, ChAT activity in the SCG remained at a significantly high level during incubation with low choline concentrations (1-10 microM), but the enhanced enzyme activity became inhibited as the extracellular choline concentration was raised to 50-100 microM in the medium. Addition of HC-3 to the medium did not alter ganglionic ChAT activity at low choline concentrations. However, application of quinacrine (10 microM) considerably reduced ganglionic CK activity and also suppressed ChAT activity induced by high KCl levels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of Rat Brain Synaptosomal [3H]Hemicholinium-3 Binding and [3H]Choline Transport Sites Following Exposure to Choline Mustard Aziridinium Ion

Abstract: Choline uptake by cholinergic nerve terminals is increased by depolarization; the literature suggests that this results from either the appearance of occult transporters or the increased activity of existing ones. The present experiments attempt to clarify the mechanism by which choline transport is regulated by testing if the preexposure of synaptosomes to choline mustard aziridinium ion prevents the stimulation-induced appearance of hemicholinium-3 binding sites and/or choline transport activity. Choline mustard inhibited irreversibly most of the “ground-state” (basal) high-affinity choline transport but only 50% of “ground-state” hemicholinium-3 binding sites. Exposure of both striatal and hippocampal synaptosomes to the mustard, before stimulation, inhibited K⁺-stimulated increases in choline transport and of [³H]hemicholinium-3 binding. We conclude that the mechanism by which choline transport is regulated involves the increased activity of a pool of transport sites that are occluded to hemicholinium-3 but are available to choline mustard aziridinium ion, and presumably to choline, before stimulation. However, the concentration of mustard needed to inhibit the stimulation-induced increase of [³H]hemicholinium-3 binding and choline transport was lower for striatal synaptosomes than for hippocampal synaptosomes. In the absence of extracellular Ca²⁺ or presence of high Mg²⁺ levels, the choline mustard did not prevent the appearance of extra striatal hemicholinium-3 binding sites. Also, high Mg²⁺ levels removed the ability of the mustard to inhibit K⁺-stimulated increases of either [³H]hemicholinium-3 binding or choline transport by hippocampal synaptosomes. In contrast, the preexposure of hippocampal synaptosomes to the mustard in the presence of a calcium ionophore (A23187) reduced the concentration of inhibitor needed to prevent the activation of [³H]hemicholinium-3 binding and choline uptake. Thus, we conclude that the ability of the choline mustard to alkylate the pool of choline transporters that are activated by stimulation appears dependent on the entry of extracellular Ca²⁺.     

Choline acetyltransferase-like activity bound to neuronal plasma membranes

A form of CAT-like activity was found bound present in rat brain synaptosomal membranes which could be recovered in the Triton X-114 phase. The enzyme activity was slightly activated by NaCl, had a pH maximum around 8 and showed a temperature dependence with a Q₁₀ of 2.28. It was inhibited 100% by 10^–6 M naphthyl vinyl pyridinium but not by 10^–5 M diisopropyl phosphofluoridate. The kinetics of this bound form of CAT were similar to the soluble form of the enzyme. TheK _m was 405±58 M for choline and 62±8 M for AcCoA. Five isoelectric forms were found with pH's of 4.55, 6.05, 7.06, 7.36, and 8.00 which is in contrast to the three isoelectric forms found of the soluble enzyme in rat brain. The presence of a CAT-like activity in the plasma membrane was confirmed with experiments performed using intact synaptosomes and intact cells in culture. Acetylcholine, synthesized from radioactive AcCoA by intact rat brain synaptosomes, was recovered in the incubation medium and only in the presence of exogenous choline or when the production of choline was stimulated by oleate via the activation of phospholipase D. This was also seen in experiments with intact pheochromocytoma cell cultures (PC 12) which synthesize acetylcholine that was recoverved in the incubation medium. Acetylcholine formation in the presence of choline and AcCoA was stimulated in cells that had been grown in the presence of nerve growth factor (NGF). The localization of 1% of CAT activity in a transbilayer position in the plasma membrane, could suggest a possible role of this enzymatic form in the regulation of acetylcholine synthesis.     

Choline mustard: an irreversible ligand for use in studies of choline transport mechanisms at the cholinergic nerve terminal

It has been shown in our laboratory that choline mustard aziridinium ion is a potent and irreversible inhibitor of choline transport into rat brain synaptosomes; this compound showed selectivity for the sodium-dependent, high affinity carrier in that it was 30 times more potent as an inhibitor when compared with the effect on sodium-independent, low affinity choline uptake. In the present study, this mustard analogue did not inhibit synaptosomal uptake of 5-hydroxytryptamine, noradrenaline, or gamma-aminobutyric acid, thereby confirming further the specificity of this compound for the choline carrier. Studies of the effect of depolarization of the nerve terminals on the inactivation of choline carriers by choline mustard were performed. It was determined that alkylation of the carrier was significantly increased in nerve endings previously depolarized. The enhancing effect of depolarization on choline transport velocity and on the alkylation of choline carriers by choline mustard was dependent upon the presence of sodium in the external medium. Possible mechanisms for the enhanced inactivation of choline carriers by choline mustard aziridinium ion are proposed, and kinetic interactions of choline mustard with the high affinity choline carrier and with choline acetyltransferase are reviewed and discussed.     

Acetylation of Homocholine by Rat Brain: Subcellular Distribution of Acetylhomocholine and Studies on the Ability of Homocholine to Serve as Substrate for Choline Acetyltransferase In Situ and In Vitro

Abstract: In situ acetylation of homocholine by slices of rat cerebral cortex was about 34% of the in situ acetylation of choline. Acetylhomocholine synthesized by the cerebral cortical slices was distributed in the same subcellular fractions as was acetylcholine (ACh), although the relative distribution of acetylhomocholine and ACh between nerve-ending-free and nerve-ending-bound stores was different. Cerebellar slices acetylated homocholine <10% as well as did cerebral cortical slices. In vitro , choline acetyltransferase (ChAT; EC 2.3.1.1.6) either partially purified from whole rat brain, solubilized from lysed synaptosomes, or in a synaptosomal membrane-associated form, did not acetylate homocholine at an appreciable rate. Under conditions of alkaline pH, an appreciable in vitro rate of homocholine acetylation by preparations of lysed synaptosomes was detected. However, analysis of this acetylation showed it not to be the result of ChAT catalysis and unlikely to occur by the same mechanism as that responsible for acetylation of homocholine in situ : the acetylation was not inhibited by ChAT inhibitors and occurred equally in the presence of preparations of lysed cerebral cortical or cerebellar synaptosomes. It is concluded that in situ acetylation of homocholine is probably catalyzed by ChAT and that acetylhomocholine is subsequently stored in the same subcellular sites as is ACh; the inability to detect ChAT-catalyzed acetylation of homocholine in vitro might arise as an artefact of the procedures employed in isolation of the enzyme.     

Homocholine and Short-Chain N-Alkyl Choline Analogues as Substrates for Torpedo Choline Acetyltransferase

Abstract: The kinetic parameters, K_m and V_max, for the acetylation of choline and several close analogues were determined by using (a) purified choline acetyltransferase and (b) a hypotonically lysed synaptosomal extract prepared from the electric organ of Torpedo marmorata. Whereas the K_m for choline was similar in both cases (0.51 and 0.42 m m ), the crude enzyme showed a three- to fivefold greater affinity for its analogues than the purified enzyme, the activity decreasing rapidly with increased N -alkyl substitution. Homocholine was a poor substrate, but was clearly acetylated by both preparations. The effect of salt on analogue acetylation by the crude enzyme was studied by increasing NaCl concentration from zero to 150 m m . There was an increase in both K_m and V_max for all substrates; choline, N,N,N -dimethylmonoethylaminoethanol, -monomethyldiethylaminoethanol and -dimethylmonobutylaminoethanol showed the greatest changes, whilst N,N,N -triethylaminoethanol and -dimethylmonopropylaminoethanol and homocholine were much less affected. However, in all cases, the kinetic parameter V_max / K_m remained unchanged. The maximal velocities of the different substrates varied more under conditions of high than of low salt. Sodium chloride up to 300 m m had no effect on the amount of enzyme which was bound to membranes in the synaptosomal extract. It is concluded that choline acetyltransferase has a high degree of substrate specificity, which is slightly altered by purification. The effects of salt cannot be explained as a consequence of nonspecific ionic association with membranes.     

Effect of Phospholipase C from Bacillus cereus on the Release of Membrane-Bound Choline-O-Acetyltransferase from Rat Hippocampal Tissue

Some of the enzyme choline-O-acetyltransferase (ChAT) associated with central cholinergic nerve terminals appears to be non-ionically associated with membranes. In the present study, we tested the possibility that some membrane-bound ChAT might be anchored to membranes by a phosphatidylinositol linkage by incubating rat hippocampal tissue with phospholipase C (PLC) from Bacillus cereus. The PLC selectively augmented the release of ChAT; also, the glycosylphosphatidylinositol-PLC inhibitor, zinc, blocked this increase in release. When control and PLC-treated hippocampal tissues were subjected to Triton X-114 phase separation, a procedure that separates amphiphilic from hydrophilic proteins, the detergent-soluble, membrane-bound fraction of tissue ChAT appeared to be the source of the ChAT released by PLC into the incubation medium. Zinc also blocked the temperature-dependent release of ChAT, but not lactic dehydrogenase, from hippocampal tissue. Extracellular membrane-bound ChAT appeared to be the source of the ChAT released by a low exogenous concentration of PLC, as well as that released by a temperature-dependent process during tissue incubation. Phosphatidylinositol-specific PLC from Bacillus thuringiensis released ChAT, but not lactic dehydrogenase, from a crude synaptosomal fraction prepared from rat hippocampal tissue. These results suggest that some of the membrane-bound ChAT in rat hippocampal tissue may be extracellular and anchored to the membrane by phosphatidylinositol, and also that an endogenous factor in hippocampal tissue may function to remove this extracellular ChAT from the membrane.     

AF64A: An Active Site Directed Irreversible Inhibitor of Choline Acetyltransferase

Ethylcholine mustard aziridinium ion (AF64A, MEChMAz) has been proposed as a cholinergic neuron-specific neurotoxin. We report that in further studies on its mechanism of action incubation of the cholinergic neuroblastoma X glioma cell line, NG-108-15, with 100 microM AF64A resulted in a rapid decrease in cellular choline acetyltransferase (ChAT) activity which preceded cytotoxicity. Thus, a 60-85% decrease in ChAT activity was measured within 5 h of AF64A exposure, whereas cell lysis (measured as the release of the cytosolic enzyme lactate dehydrogenase into the medium) did not become apparent until 18 h of AF64A exposure. This led us to examine the effects of AF64A on partially purified ChAT. We report a concentration- and time-dependent inhibition of partially purified ChAT by AF64A that could not be reversed by dialysis but could be prevented by coincubation of the enzyme and AF64A with choline but not with acetyl-coenzyme A. We present kinetic evidence that choline and AF64A compete for the same site on the enzyme. In addition, thiosulfate, which inactivates the aziridinium ion, eliminated AF64A's capacity to inhibit the enzyme. AF64A also irreversibly inhibited partially purified choline kinase and acetylcholinesterase but not lactate dehydrogenase, alcohol dehydrogenase, carboxypeptidase A, or chymotrypsinogen, enzymes that do not use choline as a substrate or product. Thus, the data suggest that AF64A acts as an irreversible active site directed inhibitor of ChAT and possibly other enzymes recognizing choline.     

Characterization of the Irreversible Inhibition of High-Affinity Choline Transport Produced by Hemicholinium Mustard

The inhibition of high-affinity choline transport by hemicholinium mustard (HCM), an alkylating analogue of hemicholinium-3, was examined in rat brain synaptosomes and guinea pig myenteric plexus. In synaptosomes, 50% high-affinity choline transport inhibition occurs with an HCM concentration of 104 nM (4-min incubation). A 10-min preincubation with 10 microM HCM results in essentially complete (greater than 95%) inactivation that persists after washing. Low-affinity choline transport in synaptosomes is unaffected by HCM inhibition at all concentrations examined (1-50 microM). Time course experiments indicate that the maximum irreversible inhibition (58%) seen after a 1-min preincubation with 500 nM HCM decreases to 46% inhibition after a 15-min preincubation; however, analysis of variance reveals that this difference is not significant. HCM inhibition of acetylcholine release from myenteric plexus-longitudinal muscle preparations persists for at least 2 h after removal of drug from the incubation bath; this inactivation can be prevented by coincubation with a high choline concentration during treatment with the mustard. In contrast, inhibition produced by the parent compound hemicholinium-3 is largely reversed by washing in both preparations examined. The observed potency and selectivity of HCM suggest its usefulness as a covalent probe for high-affinity choline transport.     

A Monoclonal Antibody Raised Against Plasma Membrane of Cholinergic Nerve Terminals of the Torpedo Inhibits Choline Acetyltransferase Activity and Acetylcholine Release

Monoclonal antibodies were raised against the synaptosomal plasma membranes (SPMs) purified from the electric organ of the Torpedo. One antibody that reacts preferentially with SPMs rather than with other membrane fractions isolated from this tissue was previously found to inhibit hydrophilic and amphiphilic choline-O-acetyltransferase (ChAT) activity. On immunoblots of SPMs, this antibody recognizes two polypeptides of 135 and 66 kilodaltons that are related; the 66-kilodalton polypeptide appears to exist as a monomer and as a dimer in SPMs. The antibody was also able to inhibit the calcium-dependent release of acetylcholine in Torpedo synaptosomes without affecting the total neurotransmitter content. This inhibition was dependent on the antibody concentration and was observed when the release was elicited by either KCl depolarization or the calcium ionophore A23187; this suggests that inhibition was not mediated by a blockage of the depolarization-activated calcium influx. The inhibition could not be prevented by atropine, a result indicating that the antibody does not block release by mimicking the action of acetylcholine on presynaptic muscarinic autoreceptors. Thus, the antigen recognized by this antibody appeared to be involved in acetylcholine release; this antigen could be membrane-bound ChAT, another protein of the SPMs, or both.     

Synaptosomal Phospholipase D Potential Role in Providing Choline for Acetylcholine Synthesis

The phospholipase D of the rat brain synaptic membrane possesses the highest activity of this enzyme of any mammalian tissue examined. The synaptic phospholipase D activity is latent and barely detectable in the absence of 4 mM sodium oleate. Several other fatty acids were either less effective or ineffective as stimulators of activity compared to this monounsaturated fatty acid. The activity was decreased by hemicholinium-3, an inhibitor of choline uptake and slightly activated by neostigmine, an acetylcholinesterase inhibitor. Incubation of synaptosomes in the presence of sodium oleate and acetyl-coenzyme A resulted in the formation of a product chromatographing with acetylcholine. Acetylcholine formation was nearly undetectable in the absence of sodium oleate or acetyl-coenzyme A. These results implicate synaptosomal phospholipase D in releasing choline from phosphatidylcholine for acetylcholine formation.     

Acetylation of Choline and Homocholine by Membrane-Bound Choline-O-Acetyltransferase in Mouse Forebrain Nerve Endings

Abstract: The choline analog homocholine is not acetylated in vitro by choline- O -acetyltransferase (ChAT, EC 2.3.1.6), which is solubilized by 100 mM-sodium phosphate buffer washes of a crude vesicular fraction of mouse forebrain. However, both homocholine and choline are acetylated by a form of ChAT which is nonionically associated with a subcellular fraction of mouse forebrain containing membrane-associated organelles and occluded acetylcho-line (P₄). Acetylation of homocholine by membrane-associated ChAT is saturable. 4-(1-Naphthylvinyl)pyridine (NVP) inhibits the acetylation of both choline (60%) and homocholine (40%) by membrane-associated ChAT but reduces the acetylation of choline alone by soluble ChAT (76%). Choline and homocholine serve as competitive alternative substrates for the same membrane-associated ChAT, whereas homocholine acts only as a competitive inhibitor of choline acetylation by soluble ChAT. Acetylhomocholine competitively inhibits the acetylation of choline by both soluble and membrane-associated ChAT more dramatically than does the natural end product, acetylcholine.     

Differential Effects of Nerve Growth Factor on Expression of Choline Acetyltransferase and Sodium-Coupled Choline Transport in Basal Forebrain Cholinergic Neurons in Culture

Abstract: Nerve growth factor (NGF) treatment of primary cultures of embryonic day 17 rat basal forebrain differentially altered activity of choline acetyltransferase (ChAT) and high-affinity choline transport; ChAT specific activity was increased by threefold in neurons grown in the presence of NGF for between 4 and 8 days, whereas high-affinity choline transport activity was not changed relative to control. Dose-response studies revealed that enhancement of neuronal ChAT activity occurred at low concentrations of NGF with an EC₅₀ of 7 ng/ml, with no enhancement of high-affinity choline transport observed at NGF concentrations up to 100 ng/ml. In addition, synthesis of acetylcholine (ACh) and ACh content in neurons grown in the presence of NGF for up to 6 days was increased significantly compared with controls. These results suggest that regulation of ACh synthesis in primary cultures of basal forebrain neurons is not limited by provision of choline by the high-affinity choline transport system and that increased ChAT activity in the presence of NGF without a concomitant increase in high-affinity choline transport is sufficient to increase ACh synthesis. This further suggests that intracellular pools of choline, which do not normally serve as substrate for ACh synthesis, may be made available for ACh synthesis in the presence of NGF.     

Evidence for Membrane-Associated Choline Kinase Activity in Rat Striatum

The distribution of choline kinase (EC 2.7.1.32) activity was investigated in subcellular fractions of rat striatum. Enzyme activity in the crude mitochondrial fraction, determined after dissolution in Triton X-100, was 5.90 mumol/g initial wet weight/h. When a crude mitochondrial preparation was hypoosmotically shocked and fractionated, followed by the addition of Triton X-100, choline kinase activity in the soluble and particulate fractions was 4.58 and 1.40 mumol/g initial wet weight/h, respectively. Enzyme activity in the particulate fraction was not detected in the absence of Triton X-100 or in the presence of NaCl (up to 1.5 M). Subcellular enzyme markers indicated that the membrane-associated activity was not attributable to mitochondrial or microsomal contamination. Kinetic analysis of the activity of soluble and membrane-solubilized choline kinase indicated Km values of 0.74 mM and 0.68 mM, respectively. Results indicate that choline kinase activity may be measured in both the soluble and the particulate fractions of rat striatum, the latter most likely involving enzyme associated with membrane through hydrophobic or covalent interactions. The specific function of the membrane-associated enzyme has not yet been determined.