Showing papers by "Victor P. Whittaker published in 1974"

Adenosine triphosphate. A constituent of cholinergic synaptic vesicles.

Abstract: 1. Synaptic vesicles separated by density-gradient centrifugation from extracts of the cholinergic nerve terminals of the electric organ of Torpedo marmorata were found to contain appreciable amounts of ATP as well as acetylcholine. 2. Vesicular ATP was stable in the presence of concentrations of apyrase and myokinase that rapidly destroyed equivalent amounts of endogenous or added free ATP; pre-treatment of cytoplasmic extracts of electric tissue with these enzymes destroyed endogenous free ATP, but did not affect the vesicular ATP. 3. When [U-14C]ATP was added to electric tissue at the time of comminution and extraction of the vesicles, all the radioactivity was associated with soluble components in the subsequent fractionation: none was associated with vesicles or membrane fragments; thus it is unlikely that vesicular ATP can be accounted for by the sequestration of endogenous free ATP within any vesicles formed during comminution and extraction of the tissue. 4. When synaptic vesicles were passed through iso-osmotic columns of Bio-Gel A-5m, which separates vesicles from soluble proteins and small molecules, all the recovered ATP and acetylcholine passed through together in the void volume. 5. Regression analysis showed that vesicular ATP content was highly correlated with vesicular acetylcholine content in different experiments, the molar ratio acetylcholine/ATP being 5.32±(s.e.m.) 0.45 (21 expts.) for the peak density-gradient fraction. The ratio varied, however, somewhat across the density-gradient peak suggesting some degree of chemical heterogeneity in the vesicle population.

Effect of electrical stimulation on the yield and composition of synaptic vesicles from the cholinergic synapses of the electric organ of Torpedo: a combined biochemical, electrophysiological and morphological study.

Abstract: — The effect of stimulating the electric organ of Torpedo marmorata, anaesthetized with 0.01% Tricaine methane sulphonate, by means of electrical stimulation (5/s) administered via an electrode placed on the electric lobe has been studied electrophysiologically, biochemically and morphologically. The response of the organ declined to about 50 per cent of its initial value after about 500 stimuli, by a further 10 per cent after another 500 stimuli and then to about 12 per cent of the initial value after a further 1000 stimuli. Thereafter the response fell off progressively. However, even when the response was less than 1 per cent of its initial value, the organ had considerable powers of recuperation during a 30-s rest period, to 30–50 per cent of its initial value. The fall in response was accompanied by a reduction in vesicle size and number, an increase in the area of the presynaptic membrane and a fall in the protein, total nucleotide, ATP and acetylcholine content of the vesicle fraction isolated from the stimulated tissue. However, whereas vesicle numbers and the protein and total nucleotide content of the vesicle fraction fell by only about 50 per cent, vesicular ATP and acetylcholine levels were reduced to about 10 per cent. An analysis of the covariance of vesicular ATP and acetylcholine showed an initial loss of an acetylcholine-rich (relative to ATP) population of vesicles. The early loss of vesicular protein and nucleotide and vesicle numbers as well as the morphological changes seen would be consistent with a loss of vesicles due to fusion with the external membrane. The preferential loss of acetylcholine and ATP from the vesicle fraction indicates that the vesicles surviving the stimulation procedure have been utilized in a number of cycles causing the progressive fall in vesicle volume, and acetylcholine and ATP content.

Different recovery rates of the electrophysiological, biochemical and morphological parameters in the cholinergic synapses of the Torpedo electric organ after stimulation.

Abstract: —During stimulation there occurred a decay in electrical response, vesicular acetylcholine, ATP and nucleotide as well as a loss of vesicle number and a decrease in vesicle diameter in the electric organ of Torpedo. These alterations were re-established during a subsequent recovery period. The different parameters recovered at different rates. Firstly, electrical response to single pulses recovered to prestimulation values within about 5 h. Vesicle number and diameter as well as bouton size were found to be re-established fully after 24 h. The newly formed vesicles appeared to be empty as vesicular acetylcholine, ATP and total nucleotide recovered much more slowly and were back to control values after about three days. Acetylcholine reappeared more quickly in the vesicles than ATP. Only after recovery of the vesicular pool of transmitter and ATP did the electric organ regain full stability of the electric discharge pattern on restimulation.

Immunological approach to the characterization of cholinergic vesicular protein

Abstract: — Rabbit antisera have been prepared against whole cholinergic vesicles purified from the electric organ of Torpedo marmorata. The sera contain two major and two minor precipitating systems against membranous proteins, as revealed by Ouchterlony diffusion. No immunoprecipitation could be detected against the soluble vesicle protein constituent ‘vesiculin’. Fractions from cephalopod, amphibian and mammalian neural tissue were shown to exhibit no immunochemical homology with Torpedo cholinergic vesicle proteins.

Membranes in Synaptic Function

Abstract: Many significant details have emerged from studies of the membranes involved in neural transmission. It has been found that acetylcholine—and perhaps other neurohumors—is bound in tiny membranous vesicles concentrated at the terminals of nerve cells. These vesicles release their contents in discrete quanta by a mechanism that appears to be akin to the emptying of intracellular vacuoles.