Jordi Marsal

Control of neurotransmitter release by an internal gel matrix in synaptic vesicles

Neurotransmitters are stored in synaptic vesicles, where they have been assumed to be in free solution. Here we report that in Torpedo synaptic vesicles, only 5% of the total acetylcholine (ACh) or ATP content is free, and that the rest is adsorbed to an intravesicular proteoglycan matrix. This matrix, which controls ACh and ATP release by an ion-exchange mechanism, behaves like a smart gel. That is, it releases neurotransmitter and changes its volume when challenged with small ionic concentration change. Immunodetection analysis revealed that the synaptic vesicle proteoglycan SV2 is the core of the intravesicular matrix and is responsible for immobilization and release of ACh and ATP. We suggest that in the early steps of vesicle fusion, this internal matrix regulates the availability of free diffusible ACh and ATP, and thus serves to modulate the quantity of transmitter released.

Nitric oxide synthase in rat neuromuscular junctions and in nerve terminals of torpedo electric organ: Its role as regulator of acetylcholine release

The distribution of nitric oxide synthase on peripheral motor system was studied using a specific antibody against the neuronal isoform of nitric oxide synthase (nNOS). The immunoreactivity for nNOS was detected on the sarcolemmal surface of muscle cells, in intramuscular axons and in neuromuscular synapses. At the neuromuscular junctions, ultrastructural immunolabeling demonstrated that nNOS immunoreactivity was localized mainly into the presynaptic nerve terminals as well as adjacent postsynaptic muscle membrane. Similar immunostaining pattern was present in frog muscles and Torpedo electric organs. After chronic muscle denervation, nNOS immunoreactity at endplate level decreased during the first week but it was upregulated after 30 days of denervation. In denervated endplates, nNOS immunoreactivity was localized in the terminal Schwann cells covering the degenerated neuromuscular junctions whereas nNOS was not detected in Schwann cells under normal conditions. In Torpedo synaptosomes, acetylcholine (ACh) release elicited by potassium depolarization was inhibited by NO donors such as sodium nitroprusside. In contrast, application of inhibitors of NOS activity, aminoguanidine (AMG) and Nω‐Nitro‐L‐arginine methyl esther (L‐NAME) increased acetylcholine release. These results indicate that nNOS is present at the motor nerve terminals in a variety of vertebrates and that it may be involved in the physiological modulation of ACh release and in the regulation of muscle response to nerve injury.

Differential Distribution of Syntaxin Isoforms 1A and 1B in the Rat Central Nervous System

Syntaxin 1 binds to several proteins of the synaptic terminal and is a central component in the pathway of protein–protein interactions that underlies docking and fusion of synaptic vesicles. Molecular studies revealed the occurrence of two isoforms, syntaxin 1A and syntaxin 1B, which coexpress in neural tissues. However, they display differential expression patterns in endocrine cell types. We generated isoform‐specific antibodies that were used in Western blotting and immunocytochemical studies. First, we confirmed the sole presence of syntaxin 1A in endocrine pituitary cells. Second, we found distinctive immunolabelling patterns of each isoform in the rat olfactory system, hippocampus, striatum, thalamus and spinal cord. In addition, the principal white matter commissures displayed distinct immunoreactivity for each isoform. This report shows, for the first time, major differences between the distributions of syntaxin 1A and syntaxin 1B isoforms in the rat central nervous system.

ATP Crossing the Cell Plasma Membrane Generates an Ionic Current in Xenopus Oocytes

The presence of ATP within cells is well established. However, ATP also operates as an intercellular signal via specific purinoceptors. Furthermore, nonsecretory cells can release ATP under certain experimental conditions. To measure ATP release and membrane currents from a single cell simultaneously, we usedXenopus oocytes. We simultaneously recorded membrane currents and luminescence. Here, we show that ATP release can be triggered in Xenopus oocytes by hyperpolarizing pulses. ATP release (3.2 ± 0.3 pmol/oocyte) generated a slow inward current (2.3 ± 0.1 μA). During hyperpolarizing pulses, the permeability for ATP4– was more than 4000 times higher than that for Cl–. The sensitivity to GdCl3 (0.2 mm) of hyperpolarization-induced ionic current, ATP release and E-ATPase activity suggests their dependence on stretch-activated ion channels. The pharmacological profile of the current inhibition coincides with the inhibition of ecto-ATPase activity. This enzyme is highly conserved among species, and in humans, it has been cloned and characterized as CD39. The translation, in Xenopus oocytes, of human CD39 mRNA encoding enhances the ATP-supported current, indicating that CD39 is directly or indirectly responsible for the electrodiffusion of ATP.

Effect of opioids on acetylcholine release evoked by K+ or glutamic acid from rat neostriatal slices

Endogenous acetylcholine (ACh) release from rat striatal slices was measured by a chemiluminescent method. Several opiate agents were tested for their ability to modulate ACh release evoked by potassium ions (K+) or glutamic acid (GLU). Morphine, [D-Ala2,Gly(0l)5]-enkephalin (DAGO), [D-Ala2,D-Leu5]-enkephalin (DADLE) and [D-Pen2-D-Pen5]-enkephalin (DPDPE) were found to have an inhibitory effect on K(+)- or GLU-evoked ACh release. This effect was completely blocked by naloxone, but this antagonist by itself had no effect on ACh release. The action of mu-opiate agonists (morphine and DAGO) on ACh release evoked by K+ was sensitive to tetrodotoxin (TTX), but that of delta-opiate agonists (DADLE and DPDPE) was insensitive. The release evoked by GLU was abolished in the presence of TTX. The activation of kappa-opiate receptor by dynorphin-(1-13) had no effect on K(+)- or GLU-evoked ACh release. It is concluded that mu- and delta-opiate agonists, but not kappa, exert an inhibitory control on striatal cholinergic interneurons, but with a different mechanism of action of localization of the receptors. Corticostriatal glutamatergic neurons have an important role in the interaction of the ACh-opioid systems.

Syntaxin 1A and 1B display distinct distribution patterns in the rat peripheral nervous system

Syntaxin 1 has been shown to play an outstanding role in synaptic vesicle exocytosis. Two isoforms of this protein are expressed in neurons, syntaxin 1A and 1B. However, the physiological significance of the occurrence of such closely related isoforms is not still understood. Here, by means of isoform-specific immunocytochemistry, we show that syntaxin 1A and 1B display different patterns of expression in the rat peripheral nervous system. Nerve terminals of sensory neurons reaching the spinal cord were clearly enriched in immunoreactive syntaxin 1A. Both isoforms were detected in cell bodies of sensory neurons at the dorsal root ganglia, although specific immunolabelling displayed very different patterns at the cellular level. Motor endplates and muscle spindles were only immunostained for syntaxin 1B. Syntaxin 1A was mainly associated with nerve fibres reaching small blood vessels. In addition, nerve plexuses of the enteric nervous system showed immunostaining for both syntaxin isoforms. The different distribution pattern of the two neuronal syntaxin isoforms in the rat peripheral nervous system could be related to isoform-specific biochemical properties involved in the exocytotic process.

Botulinum toxin inhibits quantal acetylcholine release and energy metabolism in the Torpedo electric organ.

1. Type A Botulinum toxin (BoTX) blocked nerve‐electroplaque transmission in small fragments of Torpedo marmorata electric organ incubated in vitro. The effect was observed either with the crystalline toxin complex (associated with haemagglutinin) or with the purified neurotoxin (molecular weight approximately 150,000). 2. The quantal content of the evoked post‐synaptic response was reduced by BoTX but the quantum size remained unchanged till complete blockade of the evoked response. 3. Spontaneous electroplaque potentials were composed of two populations: one with a bell‐shaped amplitude distribution (miniature potentials or quanta) and a population of small events with a skewed distribution (subminiatures). In BoTX‐poisoned tissue, the bell‐distributed miniatures progressively disappeared, but the subminiatures kept on occurring. Occasionally, larger spontaneous potentials with a slow time course were recorded; they were also BoTX resistant. 4. A biochemical assay showed that evoked acetylcholine (ACh) release was impaired by BoTX. During the period when evoked transmission was blocked, spontaneous ACh release transiently increased. 5. At the time of transmission blockade, there was no significant change of ACh content, of ACh turnover, of ACh repartition in the vesicle‐bound and free compartments, or of the number of synaptic vesicles. 6. The amount of ATP was reduced to 50% by BoTX, and that of creatine phosphate (CrP) to less than 20%. The ATP‐CrP‐converting enzyme, creatine kinase, was inhibited in BoTX‐poisoned tissue. 7. Thus, the electrophysiological effects of BoTX are very similar at the nerve‐electroplaque and the neuromuscular junctions. The present work suggests in addition that suppression of quantal release by BoTX is related to marked alterations of the energy metabolism in the tissue.

Endogenous hemichannels play a role in the release of ATP from Xenopus oocytes

ATP is an electrically charged molecule that functions both in the supply of energy necessary for cellular activity and as an intercellular signaling molecule. Although controlled ATP secretion occurs via exocytosis of granules and vesicles, in some cells, and under certain conditions, other mechanisms control ATP release. Gap junctions, intercellular channels formed by connexins that link the cytoplasm of two adjacent cells, control the passage of ions and molecules up to 1 kDa. The channel is formed by two moieties called hemichannels, or connexons, and it has been suggested that these may represent an alternative pathway for ATP release. We have investigated the release of ATP through hemichannels from Xenopus oocytes that are formed by Connexin 38 (Cx38), an endogenous, specific type of connexin. These hemichannels generate an inward current that is reversibly activated by calcium‐free solution and inhibited by octanol and flufenamic acid. This calcium‐sensitive current depends on Cx38 expression: it is decreased in oocytes injected with an antisense oligonucleotide against Cx38 mRNA (ASCx38) and is increased in oocytes overexpressing Cx38. Moreover, the activation of these endogenous connexons also allows transfer of Lucifer Yellow. We have found that the release of ATP is coincident with the opening of hemichannels: it is calcium‐sensitive, is inhibited by octanol and flufenamic acid, is inhibited in ASCx38 injected oocytes, and is increased by overexpression of Cx38. Taken together, our results suggest that ATP is released through activated hemichannels in Xenopus oocytes.

Energy metabolism and quantal acetylcholine release: effects of botulinum toxin, 1-fluoro-2,4-dinitrobenzene, and diamide in the Torpedo electric organ

In the Torpedo electric organ, a modified nervemuscle system, type A botulinum toxin blocked the release of acetylcholine (ACh) quanta, both neurally evoked and spontaneous. At the same time, the toxin increased the release of a class of small miniature potentials (the subminiature potentials), reduced the ATP and more the creatine phosphate content of the tissue, and impaired the activity of creatine kinase (CK). Thus, we compared this pattern of changes with those provoked by l‐fluoro‐2,4‐dinitrobenzene (FDNB), an efficient inhibitor of CK. As expected, FDNB rapidly inactivated CK, which resulted in a profound depletion of ATP whereas the stores of creatine phosphate were preserved. In addition, FDNB caused conspicuous morphological alterations of nerve endings and ACh depletion. This agent also suppressed evoked and spontaneous quantal release whereas the occurrence of subminiature potentials was markedly increased. Diamide, a penetrating thiol oxidizing substance, provoked first a transient rise in quantal ACh release and then blockade of transmission with, again, production of a large number of subminiature potentials. Creatine phosphate was depleted in the tissue by diamide, the ATP content reduced, and CK activity partly inhibited. The morphology of nerve terminals did not show obvious changes with either diamide or botulinum toxin at the stage of transmission failure. Although the three poisons acted by different mechanisms, this resulted in a rather similar pattern of physiological changes: failure of quantal release and enhancement of subquantal release. These results and experiments on synaptosomes indicated that CK inhibition was probably a crucial mechanism for FDNB but not for diamide or botulinum intoxication. On the other hand, similarities between the effect of the clostridial toxin and those of diamide may suggest that the effects of botulinum toxin in nerve terminals result from a general oxidation of thiols. in parallel damaging energy‐providing enzymes (including creatine kinase) and components responsible for the quantal mode of ACh release.

Depolarization-induced release of ATP from cholinergic synaptosomes is not blocked by botulinum toxin type A.

We report here the effects of Botulinum Toxin type A on the release of ATP and Acetylcholine from Torpedo electric organ synaptosomes. Our results show that Botulinum Toxin type A inhibits specifically the K(+)-induced release of Acetylcholine from synaptosomes without affecting the release of ATP. Membrane potential and calcium uptake into cholinergic nerve terminals are not modified after Botulinum Toxin poisoning. It is suggested that either most of the ATP released during the depolarization of the cholinergic synaptosomes does not originate from cholinergic synaptic vesicles or that there are two populations of synaptic vesicles, Acetylcholine-enriched synaptic vesicles and ATP-enriched synaptic vesicles. However, the possibility that the ACh and ATP released could come from different intrasynaptosomal compartments cannot be excluded.