Calcium dependence of uni-quantal release latencies and quantal content at mouse neuromuscular junction

Uni-quantal endplate currents (EPC) were recorded at mouse diaphragm neuromuscular synapse by extracellular microelectrode during motor nerve stimulation. The probability of release expressed as quantal content m(o), and variability of synaptic latencies expressed as P90 were estimated in the presence of extracellular calcium ([Ca2+]o) varying between 0.2 and 0.6 mM in the bathing solution. At 0.2 mM ([Ca2+]o), m(o) was low (0.10) and many of long-latency EPCs were present during the late phase of the release (P90 = 2.44 ms). No change in m(o) was found when ([Ca2+]o) was 0.3 mM, but P90 decreased by 39 %. For latency shortening, saturating concentration of ([Ca2+]o) was 0.4 mM, when P90 was 1.49 ms and latencies did not further change at 0.5 and 0.6 mM ([Ca2+]o). In the latter concentrations, however, an increase of m(o) was still observed. It can be concluded that the early phase of the secretion did not significantly change when ([Ca2+]o) was raised and that only the late phase of the release depends on extracellular calcium up to 0.4 mM.     

Cyclic AMP synchronizes evoked quantal release at frog neuromuscular junctions

At frog neuromuscular junction, noradrenaline (NA) shortens the release period for evoked quantal release acting on a beta1 receptor. To test the hypothesis that this action of NA is mediated by cAMP, we measured the latencies of focally recorded uni-quantal endplate currents (EPCs) after application of dibutyryl-cAMP (db-cAMP) and adenylyl cyclase activator, forskolin. The interval between the time when responses with minimal delay appeared and the point at which 90% of all latencies had occurred (P90 parameter) was shortened in the presence of both 1 x 10(-6) mol/l db-cAMP and 1 x 10(-6) mol/l forskolin by about 30%. The cAMP-induced shortening is equal to that found after application of NA and effects of both drugs are not additive.     

Temperature Effect on Proximal to Distal Gradient of Quantal Release of Acetylcholine at Frog Endplate

The conduction velocity of the nerve terminal, mean quantal content, and release latencies of uniquantal endplate currents (EPCs) were recorded in proximal, central, and distal parts of the terminal by extracellular pipettes located 5, 50, and 100 mm from the end of myelinated nerve trunk. The spike conduction velocity, minimal latency, modal value of the latency histograms, and time interval during which 90% of EPCs released (P₉₀) at distal, central, and proximal part of the frog nerve terminal have different temperature dependency between 10° and 28°C. As shown by the size and time-course of reconstructed multiquantal EPCs, the secretion synchronization, which is greatest in distal parts, compensates at least partly for the progressive slowing of spike conduction velocity in the proximodistal direction, in particular at lower temperatures.     

Rhythmic Activity of Murine Neuromuscular Junctions upon Activation of Release of Stored Calcium in the Presence of a Calcium Buffer

Using a two-electrode voltage-clamp technique, we recorded end-plate currents (EPCs) in neuromuscular synaptic junctions of the murine diaphragm upon rhythmic stimulation of the n. phrenicus with frequencies of 7, 20, 50, 70, and 100 sec⁻¹. Parameters of EPC series were analyzed against the background of the action of a mobilizer of intracellular calcium, ryanodine (0.5 μM), after the loading of terminals by 1.2 mM BAPTA (calcium buffer with rapid dynamics of binding of calcium), and upon the action of ryanodine in the presence of BAPTA. Under the action of ryanodine, the amplitude and quantum content of EPC within the plateau phase increased by 100 to 150% (P < 0.05). Loading with BAPTA evoked sharp decreases in the quantum content of unitary EPCs, the intensity of the initial facilitation, and the level of the EPC plateau in series within the entire range of stimulation frequencies used. Against the background of the action of BAPTA, the facilitatory effect of ryanodine increased; inhibitory effects of BAPTA with respect to the amplitude of unitary EPC and the level of the initial facilitation were completely compensated, whereas the level of EPC at the plateau stage increased to levels exceeding the control values by 50 to 70%. The ability of ryanodine to facilitate the transmitter (acetylcholine) release, which was enhanced in the presence of BAPTA, was completely neutralized by a blocker of L-type calcium channels, verapamil (5 μM). In the absence of BAPTA, verapamil did not influence the effects of ryanodine. We hypothesize that in the presence of BAPTA calcium channels of L type whose activity is resistive to the buffer action of BAPTA are disinhibited. The calcium current through L-type channels, perhaps, is capable of stimulating calcium release from the stores of nerve terminals and, as a consequence, of intensifying the facilitatory effect of ryanodine on the release of acetylcholine. After verapamil-induced blockade of this current, BAPTA demonstrates the ability to prevent the facilitatory effect of ryanodine on the transmitter release. Neirofiziologiya/Neurophysiology, Vol. 37, No. 4, pp. 330–338, July–August, 2005.     

The role of calcium in modulation of the kinetics of synchronous and asynchronous quantal release at the neuromuscular junction

To elucidate the mechanisms of calcium regulation of the kinetics of the evoked neurotransmitter quantal release, we have investigated the temporal parameters of acetylcholine secretion in the mouse neuro-muscular junction at varying extracellular calcium concentration, in the presence of calcium channel blockers or intracellular calcium buffers. Acetylcholine secretion was induced by the motor nerve stimulation at a low frequency, which did not produce facilitation of the neurotransmitter release. The analysis of histograms of synaptic delays of uniquantal endplate currents recorded during 50 ms after the presynaptic action potential revealed three components of the secretion process: early and late periods of synchronous release and a delayed asynchronous release. At reduced extracellular calcium level, the relative number of quanta released during the asynchronous phase of secretion increased, while the rate of quantal release during the early synchronous period decreased. The findings support the hypothesis of participation of low- and high-affinity calcium sensors with different calcium binding kinetics in regulation of, respectively, synchronous and asynchronous release of neurotransmitter quanta.     

Endothelial progenitor cells functionally express inward rectifier potassium channels

Since the first isolation of endothelial progenitor cells (EPCs) from human peripheral blood in 1997, many researchers have conducted studies to understand the characteristics and therapeutic effects of EPCs in vascular disease models. Nevertheless, the electrophysiological properties of EPCs have yet to be clearly elucidated. The inward rectifier potassium channel (Kir) performs a major role in controlling the membrane potential and cellular events. Here, via the whole cell patch-clamp technique, we found inwardly rectifying currents in EPCs and that these currents were inhibited by Ba(2+) (100 μM) and Cs(+) (1 mM), known as Kir blockers, in a dose-dependent manner (Ba(2+), 91.2 ± 1.4% at -140 mV and Cs(+), 76.1 ± 6.9% at -140 mV, respectively). Next, using DiBAC(3), a fluorescence indicator of membrane potential, we verified that Ba(2+) induced an increase of fluorescence in EPCs (10 μM, 123 ± 2.8%), implying the depolarization of EPCs. At the mRNA and protein levels, we confirmed the existence of several Kir subtypes, including Kir2.x, 3.x, 4.x, and 6.x. In a functional experiment, we observed that, in the presence of Ba(2+), the number of tubes on Matrigel formed by EPCs was dose-dependently reduced (10 μM, 62.3 ± 6.5%). In addition, the proliferation of EPCs was increased in a dose-dependent fashion (10 μM, 157.9 ± 17.4%), and specific inhibition of Kir2.1 by small interfering RNA also increased the proliferation of EPCs (116.2 ± 2.5%). Our results demonstrate that EPCs express several types of Kir which may modulate the endothelial function and proliferation of EPCs.     

LABELLING OF ACETYLCHOLINE IN THE BRAIN OF MICE FED ON A DIET CONTAINING DEUTERIUM LABELLED CHOLINE: STUDIES UTILIZING GAS CHROMATOGRAPHY—MASS SPECTROMETRY

—A method to achieve labelling of the acetylcholine stores of the brain under ideal physiological conditions is described. To this end, mice fed on a choline free diet were supplied with deuterium labelled choline in the drinking water. Labelled and unlabelled choline in plasma and in the brain as well as labelled and unlabelled acetyicholine in the brain were measured by a gas chromatographic-mass spectrometric method. It was found that after 1–25 days on the deuterium choline diet, substantial amounts of the plasma choline and brain acetylcholine were displaced by deuterium choline and deuterium acetylcholine, respectively. Already on the first day, the mole ratio of deuterium choline/total choline in plasma was 0·22, and it approached a maximum of 0·57 on the 14th day. The mole ratios of deuterium acetylcholine/total acetylcholine in the brain were slightly but significantly lower than those of deuterium choline/total choline in plasma 1–14 days, but asymptotically approached the mole ratios of deuterium Ch/total Ch in plasma by 25 days. Intact brains submitted to incubation at room temperature for 10 min increased their total choline content by about 500 per cent. Concurrently, in brains from animals kept on a deuterium choline diet for 1–2 days, the level of deuterium choline rose only by 50 per cent after incubation. Deuterium choline levels increased, however, by 200–300 per cent in the brains from animals kept on the deuterium diet for longer time periods. On the basis of these data it is suggested that: (a) choline in plasma is partly supplied from the food and partly from endogenous sources; (b) plasma choline rapidly equilibrates (less than one day) with a pool of Ch in the brain which is responsible for biosynthesis of acetylcholine; (c) the size of this choline pool is in the order of 34–40 nmol/g.     

Light-induced proton release and proton uptake reactions in the cyanobacterial phytochrome Cph1

The P(r) to P(fr) transition of recombinant Synechocystis PCC 6803 phytochrome Cph1 and its N-terminal sensor domain Cph1Delta2 is accompanied by net acidification in unbuffered solution. The extent of this net photoreversible proton release was measured with a conventional pH electrode and increased from less than 0.1 proton released per P(fr) formed at pH 9 to between 0.6 (Cph1) and 1.1 (Cph1Delta2) H(+)/P(fr) at pH 6. The kinetics of the proton release were monitored at pH 7 and pH 8 using flash-induced transient absorption measurements with the pH indicator dye fluorescein. Proton release occurs with time constants of approximately 4 and approximately 20 ms that were also observed in parallel measurements of the photocycle (tau(3) and tau(4)). The number of transiently released protons per P(fr) formed is about one. This H(+) release phase is followed by a proton uptake phase of a smaller amplitude that has a time constant of approximately 270 ms (tau(5)) and is synchronous with the formation of P(fr). The acidification observed in the P(r) to P(fr) transition with pH electrodes is the net effect of these two sequential protonation changes. Flash-induced transient absorption measurements were carried out with Cph1 and Cph1Delta2 at pH 7 and pH 8. Global analysis indicated the presence of five kinetic components (tau(1)-tau(5): 5 and 300 micros and 3, 30, and 300 ms). Whereas the time constants were approximately pH independent, the corresponding amplitude spectra (B(1), B(3), and B(5)) showed significant pH dependence. Measurements of the P(r)/P(fr) photoequilibrium indicated that it is pH independent in the range of 6.5-9.0. Analysis of the pH dependence of the absorption spectra from 6.5 to 9.0 suggested that the phycocyanobilin chromophore deprotonates at alkaline pH in both P(r) and P(fr) with an approximate pK(a) of 9.5. The protonation state of the chromophore at neutral pH is therefore the same in both P(r) and P(fr). The light-induced deprotonation and reprotonation of Cph1 at neutral pH are thus due to pK(a) changes in the protein moiety, which are linked to conformational transitions occurring around 4 and 270 ms after photoexcitation. These transient structural changes may be relevant for signal transduction by this cyanobacterial phytochrome.     

STUDIES ON SOLUBLE PROTEINS RELEASED FROM THE SYNAPTIC VESICLES OF RAT BRAIN CORTEX

Abstract— The soluble proteins released from the synaptic vesicles of rat cerebral cortex were studied. One fraction (D₄) of these proteins was released in parallel with release of acetylcholine when synaptic vesicles were incubated at 37°C for 10 min in isotonic medium. Another fraction (Dj) was liberated from synaptic vesicles when their membranes were ruptured by mild treatment under hyposmotic conditions and freeze-thawing after release of D₁ fraction. Fractions D₁ and D₂ contained 12 and 9 per cent, respectively, of the total protein in the synaptic vesicles. Some properties of these fractions were investigated by zone electrophoresis and ultracentrifugation, and by measuring their binding capacities for [¹⁴C]acetylcholine and various enzyme activities related to acetylcholine metabolism.     

Choline increases serum insulin in rat when injected intraperitoneally and augments basal and stimulated aceylcholine release from the rat minced pancreas in vitro.

Intraperitoneal injection of choline (30-90 mg.kg-1) produced a dose-dependent increase in serum insulin, glucose and choline levels in rats. The increase in serum insulin induced by choline (90 mg.kg-1) was blocked by pretreatment with the muscarinic acetylcholine receptor antagonists, atropine (2 mg.kg-1), pirenzepine (2 mg.kg-1) and 4-diphenylacetoxy-N-methylpiperidine (2 mg.kg-1) or the ganglionic nicotinic receptor antagonist, hexamethonium (15 mg.kg-1). The effect of choline on serum insulin and glucose was enhanced by oral glucose administration (3 g.kg-1). Choline administration was associated with a significant (P < 0.001) increase in the acetylcholine content of pancreatic tissue. Choline (10-130 microm) increased basal and stimulated acetylcholine release but failed to evoke insulin release from the minced pancreas at considerably higher concentrations (0.1-10 mm). Hemicholium-3, a choline uptake inhibitor, attenuated the increase in acetylcholine release induced by choline augmentation. Choline (1-32 mm) inhibited [3H]quinuclidinyl benzilate binding to the muscarinic receptors in the pancreatic homogenates. These data show that choline, a precursor of the neurotransmitter acetylcholine, increases serum insulin by indirectly stimulating peripheral acetylcholine receptors through the enhancement of acetylcholine synthesis and release.     

Calcineurin,a Type 2B Protein Phosphatase,Modulates the Ca2+-Permeable Slow Vacuolar Ion Channel of Stomatal Guard Cells

The slowly activating vacuolar (SV) channel of plant vacuoles is gated open by cytosolic free Ca2+ and by cytosol-positive potentials. Using vacuoles isolated from broad bean guard cell protoplasts, SV-mediated currents could be measured in the whole-vacuole configuration of a patch clamp as the time-dependent increase in current at cytosol-positive voltages. Time-dependent deactivation of the SV currents when changing from activating to nonactivating voltages (tail currents) was used to calculate the selectivity of the channel to Ca2+ and Cl- with respect to K+. Changing the equilibrium potential for each permeant ion (Ca2+, Cl-, and K+) at least once for individual vacuoles allowed the relative permeabilities (P) of each of these ions to be calculated in a single experiment. The resulting Pca:Pcl:Pk ratio was close to 3:0.1:1. In accord with its characterization as a weakly selective Ca2+ channel, the SV-mediated current density decreased with increasing Ca2+ activity in the vacuole lumen. SV currents were potently modulated by the Ca2+-dependent, calmodulin-stimulated protein phosphatase 2B (calcineurin). At low concentrations ([less than or equal to]0.4 units per mL), calcineurin stimulated SV currents by ~60%, whereas at higher concentrations the phosphatase was inhibitory, reaching ~90% inhibition at 3 units per mL. Bovine calmodulin had no direct effect on SV-mediated currents, although calcineurin stimulated by exogenous calmodulin inhibited SV currents at all concentrations tested with half-maximal inhibition for calcineurin at 0.16 units per mL. The inhibitory effect of calcineurin could be blocked by the pyrethroid deltamethrin, indicating inhibition of SV channels by calcineurin via dephosphorylation. A model is discussed in which vacuolar Ca2+ release through SV channels is subject to both positive feedforward and negative feedback control through cytosolic Ca2+ and dephosphorylation, respectively.     

Inactivation of single cardiac Na+ channels in three different gating modes.

In small cell-attached patches containing one and only one Na+ channel, inactivation was studied in three different gating modes, namely, the fast-inactivating F mode and the more slowly inactivating S mode and P mode with similar inactivation kinetics. In each of these modes, ensemble-averaged currents could be fitted with a Hodgkin-Huxley-type model with a single exponential for inactivation (tauh). tauh declined from 1.0 ms at -60 mV to 0.1 ms at 0 mV in the F mode, from 4.6 ms at -40 mV to 1.1 ms at 0 mV in the S mode, and from 4.5 ms at -40 mV to 0.8 ms at +20 mV in the P mode, respectively. The probability of non-empty traces (net), the mean number of openings per non-empty trace (op/tr), and the mean open probability per trace (popen) were evaluated at 4-ms test pulses. net inclined from 30% at -60 mV to 63% at 0 mV in the F mode, from 4% at -90 mV to 90% at 0 mV in the S mode, and from 2% at -60 mV to 79% at +20 mV in the P mode. op/tr declined from 1.4 at -60 mV to 1.1 at 0 mV in the F mode, from 4.0 at -60 mV to 1.2 at 0 mV in the S mode, and from 2.9 at -40 mV to 1.6 at +20 mV in the P mode. popen was bell-shaped with a maximum of 5% at -30 mV in the F mode, 48% at -50 mV in the S mode, and 16% at 0 mV in the P mode. It is concluded that 1) a switch between F and S modes may reflect a functional change of inactivation, 2) a switch between S and P modes may reflect a functional change of activation, 3) tauh is mainly determined by the latency until the first channel opening in the F mode and by the number of reopenings in the S and P modes, 4) at least in the S and P modes, inactivation is independent of pore opening, and 5) in the S mode, mainly open channels inactivate, and in the P mode, mainly closed channels inactivate.     

Calcium channels involved in neurotransmitter release at adult,neonatal and P/Q-type deficient neuromuscular junctions (Review)

Different types of voltage-dependent calcium channels (VDCCs) have been recognized based on their molecular structure as well as their pharmacological and biophysical properties. One of these, the P/Q type, is the main channel involved in nerve evoked neurotransmitter release at neuromuscular junctions (NMJs) and many central nervous system synapses. However, under particular experimental or biological conditions, other channels can be involved. L-type VDCC presence at the NMJ has been demonstrated by the contribution to the perineural calcium currents (Ica) at adult mice Bapta-loaded NMJs. This is probably a result of a reduction in Ca(2+) inactivation. The L-type current was not coupled to neurotransmitter release, but became coupled, as demonstrated by the release of acetylcholine, after the inhibition of serine/threonine protein phosphatases with okadaic acid (OA). Thus, under these conditions, L-type channels were unmasked at Bapta- but not at Egta-loaded NMJs. This suggests that the speed, not the capacity, of the calcium chelator was decisive in preventing Ca(2+)-inactivation and facilitating the contribution to neurotransmitter release. At neonatal rat NMJs, N-type VDCCs were involved early during development whereas P/Q-type VDCCs play a main role at all stages of development. Furthermore, P/Q-type VDCCs were more efficiently coupled to neurotransmitter release than N-type VDCCs. This difference could be accounted for by a differential location of these channels at the release site. Neuromuscular transmission in P/Q-type calcium channel knock out ataxic mice jointly depends on both N-type and R-type channels and shows several altered properties including low quantal content. Thus, calcium channels may be recruited to mediate neurotransmitter release with a functional hierarchy where the P/Q channel seems to be the channel most suited to mediate exocytosis at NMJs.     

Thrombin bound to a fibrin clot confers angiogenic and haemostatic properties on endothelial progenitor cells

Recent data suggest that endothelial progenitor cells (EPCs) are involved in recanalizing venous thrombi. We examined the impact of a fibrin network, and particularly of adsorbed thrombin, on EPCs derived from cord blood CD34(+) cells. Fibrin networks generated in microplates by adding CaCl(2) to platelet-depleted plasma retained adsorbed thrombin at the average concentration of 4.2 nM per well. EPCs expressed high levels of endothelial cell protein C receptor and thrombomodulin, allowing the generation of activated protein C on the fibrin matrix in the presence of exogenous human protein C. The fibrin matrix induced significant EPC proliferation and, when placed in the lower chamber of a Boyden device, strongly enhanced EPC migration. These effects were partly inhibited by hirudin by 41% and 66%, respectively), which suggests that fibrin-adsorbed thrombin interacts with EPCs via the thrombin receptor PAR-1. Finally, spontaneous lysis of the fibrin network, studied by measuring D-dimer release into the supernatant, was inhibited by EPCs but not by control mononuclear cells. Such an effect was associated with a 10-fold increase in plasminogen activator inhibitor-1 (PAI-1) secretion by EPCs cultivated in fibrin matrix. Overall, our data show that EPCs, in addition to their angiogenic potential, have both anticoagulant and antifibrinolytic properties. Thrombin may modulate these properties and contribute to thrombus recanalization by EPCs.     

Calcium channels involved in neurotransmitter release at adult,neonatal and P/Q-type deficient neuromuscular junctions (Review)

Different types of voltage-dependent calcium channels (VDCCs) have been recognized based on their molecular structure as well as their pharmacological and biophysical properties. One of these, the P/Q type, is the main channel involved in nerve evoked neurotransmitter release at neuromuscular junctions (NMJs) and many central nervous system synapses. However, under particular experimental or biological conditions, other channels can be involved. L-type VDCC presence at the NMJ has been demonstrated by the contribution to the perineural calcium currents (I Ca ) at adult mice Bapta-loaded NMJs. This is probably a result of a reduction in Ca 2+ inactivation. The L-type current was not coupled to neurotransmitter release, but became coupled, as demonstrated by the release of acetylcholine, after the inhibition of serine/threonine protein phosphatases with okadaic acid (OA). Thus, under these conditions, L-type channels were unmasked at Bapta- but not at Egta-loaded NMJs. This suggests that the speed, not the capacity, of the calcium chelator was decisive in preventing Ca 2+ -inactivation and facilitating the contribution to neurotransmitter release. At neonatal rat NMJs, N-type VDCCs were involved early during development whereas P/Q-type VDCCs play a main role at all stages of development. Furthermore, P/Q-type VDCCs were more efficiently coupled to neurotransmitter release than N-type VDCCs. This difference could be accounted for by a differential location of these channels at the release site. Neuromuscular transmission in P/Q-type calcium channel knock out ataxic mice jointly depends on both N-type and R-type channels and shows several altered properties including low quantal content. Thus, calcium channels may be recruited to mediate neurotransmitter release with a functional hierarchy where the P/Q channel seems to be the channel most suited to mediate exocytosis at NMJs.     

Acetylcholine in the brain of rats exposed to acute irradiation

A two-fold increase in acetylcholine, that can randomly be released by brain synaptosomes, is registered 60 min following whole-body X-irradiation of rats with a dose of 0.21 C/kg; depolarization of the synaptosome membranes by potassium chloride increases the release of acetylcholine the augmentation of the release in this case being lower than that in the control. The initial rate of spontaneous neuromediator release from synaptosomes grows by 80 per cent whereas after depolarization of synaptosome membranes by potassium chloride, by 15 per cent. There is a 2.5-fold increase in the maximum rate of a highly specific uptake of choline with Km value being constant. Acetylcholine content of gray substance of irradiated rat brain is invariable.     

Production of the endocannabinoids anandamide and 2-arachidonoylglycerol by endothelial progenitor cells

Recent studies have highlighted the importance of paracrine growth factors as mediators of pro-angiogenic effects by endothelial progenitor cells (EPCs), but little is known about the release of lipid-based factors like endocannabinoids by EPCs. In the current study, the release of the endocannabinoids anandamide and 2-arachidonoylglycerol by distinct human EPC sub-types was measured using HPLC/tandem mass-spectrometry. Anandamide release was highest by adult blood colony-forming EPCs at baseline and they also demonstrated increased 2-arachidonoylglycerol release with TNF-alpha stimulation. Treatment of mature endothelial cells with endocannabinoids significantly reduced the induction of the pro-inflammatory adhesion molecule CD106 (VCAM-1) by TNF-alpha.     

THE RELEASE AND MOLECULAR STATE OF MAMMALIAN BRAIN ACETYLCHOLINESTERASE

Abstract— By incubating the particulate fraction of caudate nucleus from calf brain in ion-free media, about 90 per cent of the AChE activity was brought into solution. The effects of different salts, EDTA and tetracaine on the release were studied. The mol. wt. of the enzyme was determined by gel filtration. About 90 per cent of the activity in a fresh preparation appeared in a form with mol. wt. 80,000. During storage this form was gradually transformed into forms with higher mol. wts. The effects of changes in the ionic environment on the aggregation were investigated. Purification attempts always resulted in the transformation of the enzyme into high mol. wt. forms. If the release was performed in the presence of DEAE-Sephadex-A25, the enzyme no longer aggregated. The cytosol fraction always contained some AChE activity; the significance of the presence of AChE in this fraction is discussed.     

The functions of acetylcholine in the rabbit retina

Rabbit retinas were incubated in vitro under conditions known to maintain their physiological function. The acetylcholine stores of the cholinergic amacrine cells were labelled by incubation in the presence of [3H]choline. The tissue was then mounted in a fast-flow superfusion chamber, and the release of [3H]acetylcholine under various conditions was measured by liquid cation exchange or high-voltage electrophoresis. When the retina was stimulated by flashing light, the rate of appearance of radioactive acetylcholine in the superfusate increased, with a latency shorter than the resolution of the system. The rate of release of acetylcholine remained elevated as long as the light was flashing, and returned rapidly to baseline when the light was extinguished. A one minute stimulation with steady light caused a burst of acetylcholine release following stimulus onset and a second, smaller, burst following stimulus cessation. In the presence of 2-amino-4-phosphonobutyrate (APB), an agent known to eliminate selectively the transmission of ON responses to the proximal retina, steady light caused acetylcholine release only at stimulus cessation. Other retinas were labelled with [3H]choline, then incubated for 10-80 min in the presence of flashing light (to promote acetylcholine release) and either control medium or medium containing 100 micron APB (to prevent release from cells activated by stimulus onset). These retinas were quick-frozen, freeze-dried and radioautographed on dry emulsion. In retinas incubated under control conditions [3H]acetylcholine was initially present within two bands within the inner plexiform layer. The two bands became fainter together as the tissue's [3H]acetylcholine was released. APB selectively retarded the depletion of [3H]acetylcholine from the band nearest the ganglion cell layer. We conclude that the displaced cholinergic amacrine cells release acetylcholine at the transient when light appears, and the conventionally placed cholinergic amacrine cells release acetylcholine at the transient when light is extinguished. The retinal ganglion cells that receive a light-driven cholinergic input are distinguished from those that do not by a great sensitivity to slow stimulus motion. It is proposed that the dense plexus of cholinergic dendrites and the transient nature of acetylcholine release combine to create the local subunit that enables detection of motion within regions smaller than those ganglion cells' receptive fields.     

Reactions of OH radicals with poly(U) in deoxygenated solutions: sites of OH radical attack and the kinetics of base release

Pulse radiolysis of N2O-saturated solutions of poly(U) in the presence of tetranitromethane showed that 81 per cent of the radicals formed are reducing in nature. Using data from other sources it has been estimated that 70 per cent of the OH radicals add to the base at C(5) and 23 per cent at C(6) while only 7 per cent abstract an H-atom from the sugar moiety. To a large extent the C(5) OH adduct radicals attack the sugar moiety of poly(U) thereby inducing strand breakage and base release. G (base release) = 2.9 can be subdivided into three components: (a) immediate (20 per cent), (b) fast (50 per cent) and (c) slow (30 per cent). The immediate base release must occur either during the free-radical stage or as a result of the rapid (t1/2 less than 4 min at 0 degree C) decomposition of a diamagnetic product. The fast and the slow processes are only readily observable at elevated temperatures, e.g. at 50 degrees C the half lives are 83 min and 26 h, respectively (Ea (fast) = 68 kJ mol-1, Ea (slow) = 89 kJ mol-1, A (fast) = 1.5 X 10(7) s-1, A (slow) = 1.9 X 10(9) s-1. It is concluded that there are three different types of sugar lesions giving rise to base release, structures for which are tentatively proposed.