The ligand binding relationship between the acetylcholine transporter (AcChT) and the vesamicol receptor (VR) and the kinetics of active transport were studied in synaptic vesicles purified from the Torpedo electric organ using analogues of AcCh and vesamicol. Methoxyvesamicol, which should exhibit better equilibration properties for kinetics measurements than the more potent parent, inhibits active transport in a nonlinear noncompetitive manner. AcCh analogues competitively inhibit binding of [3H]vesamicol with higher affinity in hyposmotically lysed vesicle ghosts than in intact vesicles, apparently due to removal of a competing internal, osmotically active factor. AcCh and actively transported analogues of AcCh that are up to 57% larger in van der Waals volume exhibit up to a 200-fold ratio for the dissociation constant measured by inhibition of vesamicol binding to ghosts (KIAg) compared to the Michaelis constant for transport (KM) or the IC50 value for inhibition of [3H]AcCh active transport. In contrast, two AcCh analogues that are about 120% larger and that almost surely are not transported exhibit a KIAg/IC50 ratio of about 1. The data demonstrate that the vesamicol family of compounds binds to an allosteric site in the AcChT. Initiation of active transport has no apparent effect on the affinities of vesamicol and AcCh analogues, which suggests that most of the AcChT-VR in purified vesicles is transport incompetent. Vesicle ghosts actively transport [3H]AcCh nearly as well as intact vesicles, which suggests that internal factor does not affect transport-competent AcChT-VR. A kinetics model is proposed that predicts that AcCh analogues exhibiting a KIAg/IC50 ratio significantly greater than 1 are actively transported. Some of the microscopic constants in the model are estimated. The AcChT binds AcCh very weakly with a dissociation constant of about 20-50 mM, but it transports substrates rapidly in a process exhibiting remarkably little selectivity for the detailed shape and volume of the transported ion.
Cholinergic synaptic vesicles obtained from Torpedo electric organ have an active transport system for acetylcholine (ACh). Linked to ACh transport is a cytoplasmically oriented receptor for the inhibitory drug (-)-trans-2-(4-phenylpiperidino)cyclohexanol (vesamicol, formerly AH5183). Storage of freshly isolated vesicles for several days leads to more vesamicol binding. This can be induced immediately by hyposmotic lysis of the vesicles, which reseal to form right-side-out ghosts. The increased drug binding was due to a twofold increase in the affinity and a 20% increase in the amount of the receptor expressed, probably as a result of the release of an endogenous factor. Binding of vesamicol to ghosts was specifically inhibited by exogenous ACh acting with a dissociation constant of 18 mM. This suggests that the vesamicol binding site probably is linked to a low-affinity ACh binding site that is different from the higher affinity transport binding site. Equilibrium and kinetic attempts to determine whether exogenous ACh acts on the outside or the inside of the ghost membrane to inhibit vesamicol binding failed because of rapid equilibration of exogenous ACh across the ghost membrane. It is argued that the endogenous factor released by hyposmotic lysis might be ACh. Potential roles for such a transmembrane signal regulating the vesamicol receptor are discussed.
[3H]Palmitic acid and [14C]arachidonic acid were injected together into the cerebral ventricle of 4-month and 24-month-old rats. At different time intervals from the injection, the distribution of these fatty acids in the lipids from different brain areas was examined. The fatty acids were rapidly incorporated into the lipids through different mechanisms. The time-specific activity relationship indicate that the utilization of the fatty acid differs according to the different areas and aging decreases the utilization of both the fatty acids. The decline of arachidonic acid incorporation into phospholipids is particularly evident, indicating that aging affects mainly the utilization of polyunsaturated fatty acids.
The relationship of the acetylcholine transporter-vesamicol receptor (AcChT-VR) to proteoglycan in Torpedo electric organ synaptic vesicles was investigated. The cholate-solubilized VR was immunoprecipitated by a monoclonal antibody directed against the SV1 epitope located in the glycosaminoglycan portion of the proteoglycan. AcChT that was photoaffinity-labeled with a tritiated high-affinity analogue of AcCh [cyclohexylmethyl cis-N-(4-azidophenacyl)-N-methylisonipecotate] and then denatured in sodium dodecyl sulfate also immunoprecipitated. The labeled AcChT exhibited a M(r) range of 100,000-200,000. Proteoglycan did not engage in detectable nonspecific reversible aggregation that might mask the presence of another subunit during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In vesicles permeabilized with cholate, the enzymes keratanase and testicular hyaluronidase inactivated binding of vesamicol and destroyed the SV1 epitope without detectable proteolysis. Other glycosaminoglycan-degrading enzymes were without effect. The results demonstrate that the AcChT-VR and proteoglycan are very strongly linked and that glycosaminoglycan-like polysaccharide controls the conformation of the VR. The unexpected linkage to proteoglycan suggests that AcChT-VR in intact terminals might communicate with extracellular matrix and participate in stabilization and operation of the synapse.
The effects of cerebral ischemia, induced for 10 min by bilateral common carotid ligation in the Mongolian gerbil, on the brain and synaptosomal content of phospholipids and free fatty acids were measured. Moreover, the incorporation of arachidonic acid and oleoyl-CoA into phospholipids, as well as the respiration and the accumulation of 45Ca, norepinephrine, dopamine, choline, glutamate, and gamma-aminobutyrate in the ischemic brain synaptosomal fraction were studied. Analyses of lipids showed a drop in phospholipids content with concomitant increase of lysocompounds and free fatty acids in ischemic cerebral cortex. Disturbances in lipid metabolism including rapid phospholipids hydrolysis and changes in the incorporation of arachidonic acid into inositol and choline phosphoglycerides were also shown in the synaptosomal fraction of ischemic brain. The uptake of neurotransmitter substances, expressed as a percent of control value, was reduced 21% for norepinephrine, 40% for dopamine, 20% for choline, 24% for glutamate and 13% for gamma-aminobutyrate in ischemic synaptosomes. There was no significant effect of ischemia on synaptosomal respiration and 45Ca uptake in both control and high potassium media. The inhibition of neurotransmitter uptake in ischemic brain synaptosomes may be caused by the disturbance of fatty acid metabolism.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.