Evidence that noradrenergic transmitter release is regulated by presynaptic receptors

A review is provided of the evidence in support of the existence of prejunctional alpha adrenoceptors on noradrenergic nerve terminals as well as the evidence for their physiological importance. The use of alpha-adrenoceptor agonists and antagonists has provided convincing data in support of the presynaptic receptor hypothesis. Moreover, there is ample evidence for the location of alpha adrenoceptors on nerve terminals. This evidence has often been forgotten in arguments opposing the presynaptic alpha-adrenoceptor hypothesis. The precise physiological role of presynaptic alpha adrenoceptors is still an open question, but there is support from a wide range of experiments in favor of a physiological role. Although it is not known which of these functions is most important, presynaptic alpha adrenoceptors may: regulate the pulse-to-pulse regulation of norepinephrine release during nerve stimulation, prevent noise, and protect the neuroeffector cell from excessive activation by transmitter during periods of rest or as physiological antagonists to the facilitation of transmitter release. In summary, evidence reviewed here strongly supports the existence of presynaptic alpha adrenoceptors. These receptors are clearly important pharmacologically and may play a physiological role in noradrenergic transmission. The exact physiological function must await further experimentation.     

钙调蛋白及其结合蛋白对神经递质释放的调控作用

钙离子（Ca2+）是调节突触前神经递质的胞吐释放的关键离子信号.作为胞内最普遍存在的钙离子感受器的钙调蛋白（CaM）被发现能通过与多种蛋白的相互作用,调控着突触小泡的生发、运输及再填充,从而传递胞内Ca2+浓度变化的信号,对神经递质的释放及突触电生理活动起到至关重要的调控作用.本文综述了CaM及其结合蛋白是如何参与对突触小泡的胞吐释放和胞吞恢复的调控,并探讨了其中可能的分子机制.     

Presynaptic mechanisms of zinc effects on the neuromuscular transmission]

The effect of zinc ions on presynaptic currents and transmitter release was studied at the neuromuscular junction of the frog cutaneous pectoris muscle preparation with using an extracellular microelectrode. It has been shown that zinc (100 mkM) amplified MEPP frequency at first, but suppressed it later. Zinc affected the presynaptic spike waveform and transmitter release in a concentration-dependent manner. Depending on concentration and time of exposure zinc increased or suppressed transmitter release. Increase of transmitter release was shown to be resulted by blockade voltage gated and calcium activated potassium channels in nerve ending, leading to broad of both presynaptic spike and action potential. Strong change of presynaptic spike waveform after high concentration zinc treatment supposed that under this condition zinc depressed voltage gated calcium and sodium channel leading to decrease of transmitter release. It was concluded that the final and irreversible depression of acetylcholine release by zinc was due to alteration of whole ion conductances in nerve ending and to change of configuration of proteins included in structure of ion channels. It is discussed possible mechanisms of various effects of zinc ions at the neuromuscular synapse.     

Regulation of chemoreceptor sensitivity in the carotid body: the role of presynaptic sensory nerves

Several neural and vascular mechanisms regulate the sensitivity of carotid body chemoreceptors to hypoxia, hypercapnia, and acidosis. Factors that control blood flow and oxygen delivery in the carotid body along with those that augment or diminish catecholamine release from glomus cells can have major effects on chemoreceptor function. In addition, the sensory nerves themselves may participate in the regulation of chemoreceptor sensitivity. A portion of the carotid body's sensory nerves are presynaptic to glomus cells. In response to stimulation, the sensory nerve terminals exhibit ultrastructural changes that resemble changes associated with increased release of transmitter from motor nerves: 1) the number of small (synaptic) vesicles decreases; and 2) coated vesicles and coated regions of cisternal membrane increase in number during stimulation. If sensory nerves of the carotid body release a neurotransmitters, sensory nerve activity could influence glomus cell secretion of catecholamines or other substances tha modify chemoreceptor sensitivity. Such an effect could be produced in the carotid body by hypoxia and other conditions that stimulate the sensory nerves or it could result from antidromic activity evoked in the sensory nerves by primary afferent depolarization of their terminals in the CNS.     

Ion channels in nerve ending

The modern data about the structure and function of the nerve ending ion channels are generalized and systematized. Ion channels of nerve endings provide the forming of the rest membrane potential, excitability, generation of action potential, regulate the intracellular concentration of calcium ions, take part in exocytosis of synaptic vesicules, participate in short-term and long-term synaptic plasticity, ensure the modulation of presynaptic functions. Methods of investigation of ion channels and data about their localization in central and peripheral nerve systems are represented. The review gives the functional characteristics, molecular structure and mechanisms of regulation of the known voltage- and ligand-dependent ion channels, the role of the certain types of ion channels in the machinery of transmitter release.     

Components of astrocytic intercellular calcium signaling

It has become evident that astrocytes play major roles in central nervous system (CNS) function. Because they are endowed with ion channels, transport pathways, and enzymatic intermediates optimized for ionic uptake, degradation of metabolic products, and inactivation of numerous substances, they are able to sense and correct for changes in neural microenvironment. Besides this housekeeping role, astrocytes modulate neuronal activity either by direct communication through gap junctions or through the release of neurotransmitters and/or nucleotides affecting nearby receptors. One prominent mode by which astrocytes regulate their own activity and influence neuronal behavior is via Ca²⁺ signals, which may be restricted within one cell or be transmitted throughout the interconnected syncytium through the propagation of intercellular calcium waves. This review aims to outline the most recent advances regarding the active communication of astrocytes that is encoded by intracellular calcium variation.     

The role of presynaptic ryanodine receptors in regulation of the kinetics of the acetylcholine quantal release in the mouse neuromuscular junction

To determine the role of presynaptic ryanodine receptors in the regulation of the kinetics of neurotransmitter quantum secretion caused by a nerve impulse in the experiments on the mouse neuromuscular junction, temporal parameters of phase synchronous and asynchronous delayed release of acetylcholine under the conditions of ryanodine receptors block and rhythmic stimulation were examined. The analysis of histograms of synaptic delays of the uni-quantal end-plate currents registered within 50 ms after the onset of the presynaptic action potential showed that ryanodine receptor blockers ryanodine, TMB-8 and dantrolene reduced the intensity of both phase synchronous and delayed asynchronous release of the mediator. The proportion of quanta released synchronously increased at the expense of the reduction of quantum numbers forming the delayed asynchronous release, i.e., there was a redistribution of quanta between synchronous and asynchronous phases of secretion. A block of ryanodine receptors also reduced the fluorescence intensity of the specific fluorescent calcium-sensitive dye Fluo-3 AM, which indicates a decrease in the intracellular calcium ion concentration. Thus, the presynaptic ryanodine receptors control the intracellular content of calcium ions under repetitive stimulation of the nerve endings and contribute to the modulation of the time parameters of the evoked release of the neurotransmitter quanta by increasing the intensity of the delayed asynchronous release of neurotransmitters.     

Receptor-mediated regulation of calcium channels and neurotransmitter release

Ca2+ influx into the nerve terminal is normally the trigger for the release of neurotransmitters. Many neurons possess presynaptic receptors whose activation results in changes in the quantity of neurotransmitter released by an action potential. This paper reviews studies that show that presynaptic receptors can regulate the activity of Ca2+ channels in the nerve terminal, resulting in changes in the influx of Ca2+ and in neurotransmitter release. Neurons possess several different types of voltage-sensitive Ca2+ channels. Ca2+ influx through N-type channels appears to trigger transmitter release in many instances. In other cases Ca2+ influx through L channels can influence transmitter release. Neurotransmitters can inhibit N channels through a G protein-mediated transduction mechanism. The G proteins are frequently pertussis toxin substrates. Inhibition of N channels appears to involve changes in their voltage dependence. Neurotransmitters can also regulate neuronal K+ channels. Activation of these K+ channels can lead to a reduction in Ca2+ influx and neurotransmitter release; these effects are also mediated by G proteins. Thus neurotransmitters may often regulate both presynaptic Ca2+ and K+ channels. These two effects may be synergistic mechanisms for the regulation of Ca2+ influx and neurotransmitter release.     

Presynaptic calcium stores and synaptic transmission

Following the gradual recognition of the importance of intracellular calcium stores for somatodendritic signaling in the mammalian brain, recent reports have also indicated a significant role of presynaptic calcium stores. Ryanodine-sensitive stores generate local, random calcium signals that shape spontaneous transmitter release. They amplify spike-driven calcium signals in presynaptic terminals, and consequently enhance the efficacy of transmitter release. They appear to be recruited by an association with certain types of calcium-permeant ion channels, and they induce specific forms of synaptic plasticity. Recent research also indicates a role of inositoltrisphosphate-sensitive presynaptic calcium stores in synaptic plasticity.     

Receptor regulation of ion transport in the intestinal epithelium

The active transport of ions by the intestinal epithelium is regulated by a number of enteric neurotransmitters, hormones and other substances. Our knowledge of the receptors mediating the actions of these substances is generally fragmentary. This review summarizes current knowledge on the location and functional characteristics of transmitter receptors regulating transport function in the small intestine, highlighting recent research on cholinergic and bradykinin receptors.     

Role of ion channels during cell division

Ion channels are transmembrane proteins whose canonical function is the transport of ions across the plasma membrane to regulate cell membrane potential and play an essential role in neural communication, nerve conduction, and muscle contraction. However, over the last few years, non-canonical functions have been identified for many channels, having active roles in phagocytosis, invasiveness, proliferation, among others. The participation of some channels in cell proliferation has raised the question of whether they may play an active role in mitosis. There are several reports showing the participation of channels during interphase, however, the direct participation of ion channels in mitosis has received less attention. In this article, we summarize the current evidence on the participation of ion channels in mitosis. We also summarize some tools that would allow the study of ion channels and cell cycle regulatory molecules in individual cells during mitosis.     

Solubilization and Partial Purification of a Presynaptic Membrane Protein Ensuring Calcium-Dependent Acetylcholine Release from Proteoliposomes

In previous work, it was shown that cytoplasmic acetylcholine decreased on stimulation of Torpedo electric organ or synaptosomes in a strictly calcium-dependent manner. This led to the hypothesis that the presynaptic membrane contained an element translocating acetylcholine when activated by calcium. To test this hypothesis, the presynaptic membrane constituents were incorporated into the membranes of liposomes filled with acetylcholine. The proteoliposomes thus obtained released the transmitter in response to a calcium influx. The kinetics and calcium dependency of acetylcholine release were comparable for proteoliposomes and synaptosomes. The presynaptic membrane element ensuring calcium-dependent acetylcholine release is most probably a protein, since it was susceptible to Pronase, but only when the protease had access to the intracellular face of the presynaptic membrane. Postsynaptic membrane fractions contained very low amounts of this protein. It was extracted from the presynaptic membrane under alkaline conditions in the form of a protein-lipid complex of large size and low density which was partially purified. The specificity of the calcium-dependent release for acetylcholine was tested with proteoliposomes filled with equal amounts of acetylcholine and choline or acetylcholine and ATP. In both cases, acetylcholine was released preferentially. After cholate solubilization and gel filtration, the protein ensuring the calcium-dependent acetylcholine release was recovered at a high apparent molecular weight (between 600,000 and 200,000 daltons), its apparent sedimentation coefficient being 17S after cholate elimination. This protein is probably an essential coin of the transmitter release mechanism. We propose to name it mediatophore.     

BCL-xL regulates synaptic plasticity

Mitochondria are the predominant organelle within many presynaptic terminals. During times of high synaptic activity, they affect intracellular calcium homeostasis and provide the energy needed for synaptic vesicle recycling and for the continued operation of membrane ion pumps. Recent discoveries have altered our ideas about the role of mitochondria in the synapse. Mitochondrial localization, morphology, and docking at synaptic sites may indeed alter the kinetics of transmitter release and calcium homeostasis in the presynaptic terminal. In addition, the mitochondrial ion channel BCL-xL, known as a protector against programmed cell death, regulates mitochondrial membrane conductance and bioenergetics in the synapse and can thereby alter synaptic transmitter release and the recycling of pools of synaptic vesicles. BCL-xL, therefore, not only affects the life and death of the cell soma, but its actions in the synapse may underlie the regulation of basic synaptic processes that subtend learning, memory and synaptic development.     

Long-term potentiation in the piriform cortex is blocked by lead

Summary 1. Long-term potentiation (LTP) is a prolonged increase in synaptic efficacy that is triggered by a brief tetanic stimulation at certain central synapses. LTP is one of the best available model systems available to the neurophysiologist of neuronal plasticity such as that underlying learning and memory.2. We have studied the susceptibility of LTP to blockade by lead as a test of the hypothesis that the negative effect of lead on intelligence in children may result from interference with this process. LTP was studied in slices of rat piriform cortex. At this site, as in many other central synapses, LTP requires activation of postsynapticN-methyl-d-aspartate (NMDA) receptors, and we investigated whether lead actions, if any, were mediated via effects on NMDA-activation ion channels or, alternatively, at voltage-activated calcium channels.3. We find that lead blocks LTP at low micromolar concentrations. However, concentrations of lead that totally block LTP had no apparent effect on either NMDA-activated responses or presynaptic calcium channels, as monitored by transmitter release from presynaptic terminals.4. While the mechanism of lead blockade of LTP remains to be determined, these observations are consistent with the hypothesis that the cognitive effects of lead neurotoxicity may result from effects on LTP.     

Time course of transmitter release calculated from simulations of a calcium diffusion model.

A three-dimensional presynaptic calcium diffusion model developed to account for characteristics of transmitter release was modified to provide for binding of calcium to a receptor and subsequent triggering of exocytosis. When low affinity (20 microM) and rapid kinetics were assumed for the calcium receptor triggering exocytosis, and stimulus parameters were selected to match those of experiments, the simulations predicted a virtual invariance of the time course of transmitter release to paired stimulation, stimulation with pulses of different amplitude, and stimulation in different calcium solutions. The large temperature sensitivity of experimental release time course was explained by a temperature sensitivity of the model's final rate limiting exocytotic process. Inclusion of calcium tail currents and a saturable buffer with finite binding kinetics resulted in high peak calcium transients near release sites, exceeding 100 microM. Models with a single class of calcium binding site to the secretory trigger molecule failed to produce sufficient synaptic facilitation under this condition. When at least one calcium ion binds to a different site having higher affinity and slow kinetics, facilitation again reaches levels similar to those seen experimentally. It is possible that the neurosecretory trigger molecule reacts with calcium at more than one class of binding site.     

Can presynaptic depolarization release transmitter without calcium influx?

Recent experimental evidence suggesting that presynaptic depolarization can evoke transmitter release without calcium influx has been re-examined. The presynaptic terminal of the squid giant synapse can be depolarized by variable amounts while recording presynaptic calcium current under voltage clamp and postsynaptic responses. Small depolarizations open few calcium channels with large single channel currents. Large depolarizations approaching the calcium equilibrium potential open many channels with small single channel currents. When responses to small and large depolarizations eliciting similar total macroscopic calcium currents are compared, the large pulses evoke more transmitter release. This apparent voltage-dependence of transmitter release may be explained by the greater overlap of calcium concentration domains surrounding single open calcium channels when many closely apposed channels open at large depolarizations. This channel domain overlap leads to higher calcium concentrations at transmitter release sites and more release for large depolarizations than for small depolarizations which open few widely dispersed channels. At neuromuscular junctions, a subthreshold depolarizing pulse to motor nerve terminals may release over a thousand times as much transmitter if it follows a brief train of presynaptic action potentials than if it occurs in isolation. This huge synaptic facilitation has been taken as indicative of a direct effect of voltage which is manifest only when prior activity raises presynaptic resting calcium levels. This large facilitation is actually due to a post-tetanic supernormal excitability in motor nerve terminals, causing the previously subthreshold test pulse to become suprathreshold and elicit a presynaptic action potential. When motor nerve terminals are depolarized by two pulses, as the first pulse increases above a certain level it evokes more transmitter release but less facilitation of the response to the second pulse.(ABSTRACT TRUNCATED AT 250 WORDS)     

The actin cytoskeleton and neurotransmitter release: an overview

Here we review evidence that actin and its binding partners are involved in the release of neurotransmitters at synapses. The spatial and temporal characteristics of neurotransmitter release are determined by the distribution of synaptic vesicles at the active zones, presynaptic sites of secretion. Synaptic vesicles accumulate near active zones in a readily releasable pool that is docked at the plasma membrane and ready to fuse in response to calcium entry and a secondary, reserve pool that is in the interior of the presynaptic terminal. A network of actin filaments associated with synaptic vesicles might play an important role in maintaining synaptic vesicles within the reserve pool. Actin and myosin also have been implicated in the translocation of vesicles from the reserve pool to the presynaptic plasma membrane. Refilling of the readily releasable vesicle pool during intense stimulation of neurotransmitter release also implicates synapsins as reversible links between synaptic vesicles and actin filaments. The diversity of actin binding partners in nerve terminals suggests that actin might have presynaptic functions beyond synaptic vesicle tethering or movement. Because most of these actin-binding proteins are regulated by calcium, actin might be a pivotal participant in calcium signaling inside presynaptic nerve terminals. However, there is no evidence that actin participates in fusion of synaptic vesicles.     

Limitations of presynaptic theory: no support for feedback control of autonomic effectors

Only limited evidence, much of it repetitious, has supported the hypothesis that transmitter release is regulated by negative and positive feedback. It is shown here that the theory fails to satisfactorily predict the outcome of experimental tests that examine transmitter efflux critically, over an array of test conditions in several effector organs. Experimentally established inadequacies relate to: the observed effects of agonists and antagonists on stimulation-induced efflux; presynaptic site specificity; per pulse output of transmitter in the absence and presence of drugs; single-pulse stimulation; synaptic dimensions and efflux; lack of coincidence between enhancement of efflux and blockade of amine-induced inhibition and between effector response size and efflux alterations. Theoretical considerations about negative and positive feedback that render their routine operation unlikely are also discussed. It is concluded that, despite repeated observations that norepinephrine and some antagonists exert presynaptic actions to decrease and enhance transmitter output, the unitary hypothesis that assigns these effects to interactions with functional autoinhibitory and excitatory systems mediated by alpha- and beta-adrenergic receptors is probably not correct.     

The calcium hypothesis and modulation of transmitter release by hyperpolarizing pulses.

Small presynaptic conditioning hyperpolarizing pulses reduce transmitter release to a depolarizing stimulus by a substantial amount, with little effect on release by a subsequent depolarization. This result, obtained at neuromuscular junctions and the squid giant synapse, has been offered as a disproof of the calcium hypothesis of transmitter release or the residual calcium hypothesis of synaptic facilitation. However, calculations based on several formulations of these hypotheses are shown to be consistent with the experimental results, and no fundamental modification of the hypotheses is necessary.     

Calcium channel regulation and presynaptic plasticity

Voltage-gated calcium (Ca(2+)) channels initiate release of neurotransmitters at synapses, and regulation of presynaptic Ca(2+) channels has a powerful influence on synaptic strength. Presynaptic Ca(2+) channels form a large signaling complex, which targets synaptic vesicles to Ca(2+) channels for efficient release and mediates Ca(2+) channel regulation. Presynaptic plasticity regulates synaptic function on the timescale of milliseconds to minutes in response to neurotransmitters and the frequency of action potentials. This article reviews the regulation of presynaptic Ca(2+) channels by effectors and regulators of Ca(2+) signaling and describes the emerging evidence for a critical role of Ca(2+) channel regulation in control of neurotransmission and in presynaptic plasticity. Failure of function and regulation of presynaptic Ca(2+) channels leads to migraine, ataxia, and potentially other forms of neurological disease. We propose that presynaptic Ca(2+) channels serve as the regulatory node in a dynamic, multilayered signaling network that exerts short-term control of neurotransmission in response to synaptic activity.