Mechanisms of α-latrotoxin action

The major component of black widow spider venom, alpha-latrotoxin, triggers massive exocytosis in a variety of neurosecretory cells. An important trigger for exocytosis is the calcium influx via alpha-latrotoxin-induced channels in biological membranes. However, this mechanism fails to explain exocytosis which occurred in the complete absence of extracellular calcium. Recently, sophisticated biochemical and molecular techniques have led to the discovery of novel alpha latrotoxin-binding membrane receptors: neurexins and latrophilin/CIRL (calcium-independent receptor for alpha-latrotoxin). Neurexins are single transmembrane proteins which bind to alpha-latrotoxin in a calcium-dependent manner and also interact with the synaptic vesicle protein, synaptotagmin. On the other hand, latrophilin is a seven-transmembrane protein and belongs to the family of G-protein-coupled receptors. The multitude of effects of alpha-latrotoxin on exocytosis in different cell systems and the nature of its membrane targets are discussed in this article. The molecular details of how alpha-latrotoxin binding is transduced eventually to exocytosis remain to be elucidated.     

Characterization of the epitope for 4C4.1 mAb on alpha-latrotoxin using phage display-peptide libraries: prevention of toxin-dependent 45Ca(2+) uptake in non-neuronal human embryonic cells transiently expressing latrophilin

alpha-Latrotoxin, a protein toxin present in the venom of black widow spider, interacts with membrane receptors of neurons and other secretory cells to stimulate exocytosis. Two types of receptors have been identified and cloned. Our attention has been focused on the calcium independent receptor, a G-protein coupled receptor, named latrophilin to see whether alpha-latrotoxin interaction was capable to produce an ionotropic effect, in alternative to the metabotropic hypothesis. Expression of latrophilin receptor is sufficient for the alpha-latrotoxin effect to become manifest. By inducing the transient expression of latrophilin receptor in non-neuronal human embryonic cells, we made them susceptible to toxin action as demonstrated by the increase in 45Ca(2+) accumulation detected after toxin treatment. Since the presence of a monoclonal antibody against alpha-latrotoxin (4C4.1 mAb) was able to obliterate toxin-dependent effects, we further investigated the nature of toxin-antibody interaction by characterization of the binding epitope using phage display-peptide libraries. A conformational epitope was recognized and partially localized on a region of the peptide toxin whereby a tetrameric structure is formed and inserted into the membrane of target cells where it functions as a pore.     

Latrophilin, neurexin, and their signaling-deficient mutants facilitate alpha -latrotoxin insertion into membranes but are not involved in pore formation

Pure alpha-latrotoxin is very inefficient at forming channels/pores in artificial lipid bilayers or in the plasma membrane of non-secretory cells. However, the toxin induces pores efficiently in COS-7 cells transfected with the heptahelical receptor latrophilin or the monotopic receptor neurexin. Signaling-deficient (truncated) mutants of latrophilin and latrophilin-neurexin hybrids also facilitate pore induction, which correlates with toxin binding irrespective of receptor structure. This rules out the involvement of signaling in pore formation. With any receptor, the alpha-latrotoxin pores are permeable to Ca(2+) and small molecules including fluorescein isothiocyanate and norepinephrine. Bound alpha-latrotoxin remains on the cell surface without penetrating completely into the cytosol. Higher temperatures facilitate insertion of the toxin into the plasma membrane, where it co-localizes with latrophilin (under all conditions) and with neurexin (in the presence of Ca(2+)). Interestingly, on subsequent removal of Ca(2+), alpha-latrotoxin dissociates from neurexin but remains in the membrane and continues to form pores. These receptor-independent pores are inhibited by anti-alpha-latrotoxin antibodies. Our results indicate that (i) alpha-latrotoxin is a pore-forming toxin, (ii) receptors that bind alpha-latrotoxin facilitate its insertion into the membrane, (iii) the receptors are not physically involved in the pore structure, (iv) alpha-latrotoxin pores may be independent of the receptors, and (v) pore formation does not require alpha-latrotoxin interaction with other neuronal proteins.     

Effect of synaptosomal cytosolic [3H]GABA pool depletion on secretory ability of alpha-latrotoxin

alpha-Latrotoxin, a presynaptic neurotoxin from the venom of Latrodectus mactans tredecimguttatus, induces massive [3H]GABA release from rat brain synaptosomes as a result of interaction with either Ca(2+)-dependent (neurexin 1 alpha or Ca(2+)-independent (latrophilin) membrane receptor. The main aim of the study was to elucidate whether the binding of alpha-latrotoxin to different types of receptors led to [3H]GABA secretion from one pool or in each case the source of neurotransmitter differs: in the presence of Ca2+ exocytosis is induced, while in the absence of Ca(2+)--outflow by mobile membrane GABA transporter from cytoplasm. We examined the effect of the depletion of cytosolic [3H]GABA pool by competitive inhibitors of the GABA transporter (nipecotic acid and 2,4-diaminobutyric acid) on the alpha-latrotoxin-stimulated neurotransmitter release. We also compared the influence of these agents on neurosecretion, evoked by depolarization with that evoked by alpha-latrotoxin. Depolarization was stimulated by 4-aminopyridine in the Ca(2+)-containing saline and high KCl in Ca(2+)-free medium. In synaptosomes treated with nipecotic acid unstimulated [3H]GABA release was significantly augmented and high KCl-evoked Ca(2+)-independent [3H]GABA release was essentially inhibited. But under the same conditions neurosecretion stimulated by alpha-latrotoxin greatly raised with respect to the control response. The similar results were obtained with the synaptosomes treated with 2,4-diaminobutyric acid. Another way to determine which of GABA pool is the target of alpha-latrotoxin action lay in analysis of the toxin effects on the preliminary depolarized synaptosomes. alpha-Latrotoxin influence was diminished by the preceding depolarization by 4-aminopyridine in Ca2+ presence. But after the high KCl stimulation effect of alpha-latrotoxin didn't change. These data suggest that alpha-latrotoxin triggers neurotransmitter release from synaptic vesicles via exocytosis. We suppose that the type of membrane receptor does not determine the mechanism of GABA release evoked by the toxin.     

Protein-tyrosine phosphatase-sigma is a novel member of the functional family of alpha-latrotoxin receptors

Receptor-like protein-tyrosine phosphatase sigma (PTPvarsigma) is essential for neuronal development and function. Here we report that PTPvarsigma is a target of alpha-latrotoxin, a strong stimulator of neuronal exocytosis. alpha-Latrotoxin binds to the cell adhesion-like extracellular region of PTPvarsigma. This binding results in the stimulation of exocytosis. The toxin-binding site is located in the C-terminal part of the PTPvarsigma ectodomain and includes two fibronectin type III repeats. The intracellular catalytic domains of PTPvarsigma are not required for the alpha-latrotoxin binding and secretory response triggered by the toxin in chromaffin cells. These features of PTPvarsigma resemble two other previously described alpha-latrotoxin receptors, neurexin and CIRL. Thus, alpha-latrotoxin represents an unusual example of the neurotoxin that has three independent, equally potent, and yet structurally distinct targets. The known structural and functional characteristics of PTPvarsigma, neurexin, and CIRL suggest that they define a functional family of neuronal membrane receptors with complementary or converging roles in presynaptic function via a mechanism that involves cell-to-cell and cell-to-matrix interaction.     

A novel ubiquitously expressed alpha-latrotoxin receptor is a member of the CIRL family of G-protein-coupled receptors

Poisoning with alpha-latrotoxin, a neurotoxic protein from black widow spider venom, results in a robust increase of spontaneous synaptic transmission and subsequent degeneration of affected nerve terminals. The neurotoxic action of alpha-latrotoxin involves extracellular binding to its high affinity receptors as a first step. One of these proteins, CIRL, is a neuronal G-protein-coupled receptor implicated in the regulation of secretion. We now demonstrate that CIRL has two close homologs with a similar domain structure and high degree of overall identity. These novel receptors, which we propose to name CIRL-2 and CIRL-3, together with CIRL (CIRL-1) belong to a recently identified subfamily of large orphan receptors with structural features typical of both G-protein-coupled receptors and cell adhesion proteins. Northern blotting experiments indicate that CIRL-2 is expressed ubiquitously with highest concentrations found in placenta, kidney, spleen, ovary, heart, and lung, whereas CIRL-3 is expressed predominantly in brain similarly to CIRL-1. It appears that CIRL-2 can also bind alpha-latrotoxin, although its affinity to the toxin is about 14 times less than that of CIRL-1. When overexpressed in chromaffin cells, CIRL-2 increases their sensitivity to alpha-latrotoxin stimulation but also inhibits Ca2+-regulated secretion. Thus, CIRL-2 is a functionally competent receptor of alpha-latrotoxin. Our findings suggest that although the nervous system is the primary target of low doses of alpha-latrotoxin, cells of other tissues are also susceptible to the toxic effects of alpha-latrotoxin because of the presence of CIRL-2, a low affinity receptor of the toxin.     

Does extracellular calcium determine what pool of GABA is the target for alpha-latrotoxin?

Presynaptic neurotoxin alpha-latrotoxin, from the venom of Latrodectus mactans tredecimguttatus, causes massive [(3)H]GABA release from rat brain synaptosomes, irrespective of calcium presence in the extracellular medium. Whether the binding of alpha-latrotoxin to Ca(2+)-dependent (neurexin 1 alpha) or to Ca(2+)-independent (latrophilin) receptor triggers [(3)H]GABA release by the same mechanisms or different ones, inducing either exocytotic process or outflow by mobile membrane GABA transporter, is unknown. We examined alpha-latrotoxin-evoked [(3)H]GABA release from synaptosomes which cytosolic [(3)H]GABA pool was depleted either by applying competitive inhibitors of the GABA transporter, nipecotic acid and 2,4-diaminobutyric acid, or by permeation with digitonin. We also compared the effect of the GABA transporter inhibitors on depolarisation-evoked and alpha-latrotoxin-evoked [(3)H]GABA release using as depolarising agents 4-aminopyridine and high KCl in the Ca(2+)-containing and in Ca(2+)-free medium, respectively. Incubation of synaptosomes with nipecotic acid induced the essential acceleration of unstimulated [(3)H]GABA release and deep inhibition of high KCl-evoked Ca(2+)-independent [(3)H]GABA release. In contrast, at the similar conditions the effect of alpha-latrotoxin was greatly augmented with respect to the control response. Another way to assay what GABA pool was involved in alpha-latrotoxin-induced release lays in an analysis of the effects of depolarisation and alpha-latrotoxin in consecutive order. The preliminary 4-aminopyridine-stimulated [(3)H]GABA release attenuated the toxin effect. But when depolarisation occurred in Ca(2+)-free medium, no influence on alpha-latrotoxin effect was revealed. Employing digitonin-permeated synaptosomes, we have shown that alpha-latrotoxin could stimulate [3H]GABA release in the medium with 1mM EGTA, this effect of the toxin was blocked by concanavalin A and was ATP-dependent. The latter suggests that alpha-latrotoxin-released neurotransmitter has the vesicular nature. We assume that the type of the toxin membrane receptor does not determine the mechanisms of [(3)H]GABA release evoked by alpha-latrotoxin.     

A high level of cytoplasmic calcium inactivates ion channels, formed by alpha-latrotoxin in the rat brain synaptosomes

Effect of alpha-latrotoxin on the concentration level of free calcium [( Ca2+]in) in the rat brain synaptosomes and dependence of the activity of "latrotoxin" channels on [Ca2+]in were studied using fluorescent calcium probe quin-2. It is shown that alpha-latrotoxin exerts effect on calcium permeability of plasmalemma and does not induce calcium ejection from the intracellular compartments. A lag-period is characteristic of alpha-latrotoxin action. A degree of the [Ca2+]in increase in synaptosomes depends on the toxin concentration. When [Ca2+]in increases as a result of preliminary potassium depolarization of plasmalemma of synaptosomes, the amount of incoming calcium ions followed by the toxin effect as well as the calcium input rate considerably decrease. Inactivation of calcium-transferring channels induced by alpha-latrotoxin is not a result of a change in the potential on the membrane, as during the blockage of potential-depending calcium channels by D-600, an increase of KCl in the incubation medium does not influence the alpha-latrotoxin action. Differences in the properties of alpha-latrotoxin channels are discussed in synaptosomes and BLM.     

Binding of latrotoxin to synaptosomes and synaptic membranes of the rat brain

The binding of [125I] alpha-latrotoxin to synaptosomes from the rat brain is studied. It is shown that the constant rate of toxin association with the synaptosome receptor at 37 degrees C is equal to 8.2 +/- 1.3 x 10(7) M-1.s-1, while that of synaptosomal membrane -7.6 +/- 2.7 x 10(6) M-1 s-1. Depolarization of the synaptosome membrane induced by 55 mM KCl decreases the binding rate of toxin to the receptor, the rate constant being equal to 3.9 +/- 1.5 x 10(7) m-1 s-1. The pattern of the dissociation process of the toxin-receptor complex of synaptosomes and of synaptosomal membrane is different. In the first case dissociation follows two stages with the rate constants 3.6 x 10(-3) s-1 and 1.2/10(-4) s-1, in the second case it follows one stage with the constant equalled 2.0 x 10(-5) s-1. The quantity of the toxin binding sites on synaptosomes may vary under the action of agents modifying the activity of calcium fluxes which are induced by alpha-latrotoxin. It is supposed that a decrease in the ATP level in synaptosomes as well as deenergy of the surface membrane leads to a change in the state of the alpha-latrotoxin receptor.     

Alpha-latrotoxin induces exocytosis by inhibition of voltage-dependent K+ channels and by stimulation of L-type Ca2+ channels via latrophilin in beta-cells

The spider venom alpha-latrotoxin (alpha-LTX) induces massive exocytosis after binding to surface receptors, and its mechanism is not fully understood. We have investigated its action using toxin-sensitive MIN6 beta-cells, which express endogenously the alpha-LTX receptor latrophilin (LPH), and toxin-insensitive HIT-T15 beta-cells, which lack endogenous LPH. alpha-LTX evoked insulin exocytosis in HIT-T15 cells only upon expression of full-length LPH but not of LPH truncated after the first transmembrane domain (LPH-TD1). In HIT-T15 cells expressing full-length LPH and in native MIN6 cells, alpha-LTX first induced membrane depolarization by inhibition of repolarizing K(+) channels followed by the appearance of Ca(2+) transients. In a second phase, the toxin induced a large inward current and a prominent increase in intracellular calcium ([Ca(2+)](i)) reflecting pore formation. Upon expression of LPH-TD1 in HIT-T15 cells just this second phase was observed. Moreover, the mutated toxin LTX(N4C), which is devoid of pore formation, only evoked oscillations of membrane potential by reversible inhibition of iberiotoxin-sensitive K(+) channels via phospholipase C, activated L-type Ca(2+) channels independently from its effect on membrane potential, and induced an inositol 1,4,5-trisphosphate receptor-dependent release of intracellular calcium in MIN6 cells. The combined effects evoked transient increases in [Ca(2+)](i) in these cells, which were sensitive to inhibitors of phospholipase C, protein kinase C, or L-type Ca(2+) channels. The latter agents also reduced toxin-induced insulin exocytosis. In conclusion, alpha-LTX induces signaling distinct from pore formation via full-length LPH and phospholipase C to regulate physiologically important K(+) and Ca(2+) channels as novel targets of its secretory activity.     

alpha-latrotoxin action probed with recombinant toxin: receptors recruit alpha-latrotoxin but do not transduce an exocytotic signal.

alpha-Latrotoxin stimulates neurotransmitter release probably by binding to two receptors, CIRL/latrophilin 1 (CL1) and neurexin Ialpha. We have now produced recombinant alpha-latrotoxin (LtxWT) that is as active as native alpha-latrotoxin in triggering synaptic release of glutamate, GABA and norepinephrine. We have also generated three alpha-latrotoxin mutants with substitutions in conserved cysteine residues, and a fourth mutant with a four-residue insertion. All four alpha-latrotoxin mutants were found to be unable to trigger release. Interestingly, the insertion mutant LtxN4C exhibited receptor-binding affinities identical to wild-type LtxWT, bound to CL1 and neurexin Ialpha as well as LtxWT, and similarly stimulated synaptic hydrolysis of phosphatidylinositolphosphates. Therefore, receptor binding by alpha-latrotoxin and stimulation of phospholipase C are insufficient to trigger exocytosis. This conclusion was confirmed in experiments with La3+ and Cd2+. La3+ blocked release triggered by LtxWT, whereas Cd2+ enhanced it. Both cations, however, had no effect on the stimulation by LtxWT of phosphatidylinositolphosphate hydrolysis. Our data show that receptor binding by alpha-latrotoxin and activation of phospholipase C do not by themselves trigger exocytosis. Thus receptors recruit alpha-latrotoxin to its point of action without activating exocytosis. Exocytosis probably requires an additional receptor-independent activity of alpha-latrotoxin that is selectively inhibited by the LtxN4C mutation and by La3+.     

Reconstitution of the purified alpha-latrotoxin receptor in liposomes and planar lipid membranes. Clues to the mechanism of toxin action.

The receptor of alpha-latrotoxin (the major toxin of the black widow spider venom), purified from bovine synaptosomal membranes, was reconstituted into small unilamellar liposomes. These (but not control) liposomes exhibited high-affinity, specific binding of [125I]alpha-latrotoxin. In the receptor-bearing liposomes alpha-latrotoxin induced depolarization and stimulated 45Ca efflux. These responses to alpha-latrotoxin, that were observed only in the presence of external divalent cations, resembled those previously demonstrated in mammalian brain synaptosomes. The alpha-latrotoxin-activated ion fluxes are therefore, at least in part, the result of the direct interaction of the toxin with its receptor. When control and receptor-bearing liposomes were pre-incubated with alpha-latrotoxin and then added to a solution bathing a planar lipid bilayer membrane, single channel cationic conductances were observed. In the presence of the receptor, the conductances induced by alpha-latrotoxin were markedly different from those observed without the receptor, but not identical to those observed without the receptor, but not identical to those recently characterized by patch clamping in the cells of a line (PC12) sensitive to alpha-latrotoxin. These results demonstrate that the reconstituted receptor is functional, and suggest that the cationic channel activated by the toxin-receptor interaction is modulated by additional component(s) in the membrane of synapses and cells.     

The reconstruction of ion channels created by protein neurotoxins in bilayer lipid membranes as a research tool for exocytosis processes

The direct transport of inorganic ions and much highly organized biomolecules across native membranes by the specific membrane proteins--ionic channels provides the functioning of a number of important biochemical processes like depolarization, Ca(2+)-release and exocytosis in nerve or muscle cells at the synaptic transmission. Therefore, the investigation of the structure and ion-conducting properties for neurotoxin channels and different factors affecting channels themselves and neuro-muscular transmission plays an important role in the research of pathologies that appear in intoxicated nerve tissues. As the massive release of neurotransmitters resulting from toxin-induced increase in Ca(2+)-permeability of the nerve endings occurs after the interaction of pore-forming neurotoxins alpha-latrotoxin, alpha- and delta-latroinsectotoxin from black widow spider venom with the specific receptors located on plasma membrane of the vertebrate or invertebrate nerve cells most attention in the review is paid to the reconstitution of above toxins channels. The part the pore-forming proteins reconstruction research takes to determine the exocytosis regulation endogenous cell proteins may participate has been observed on the example of latrotoxin-like L-protein from bovine brain nerve cells cytoplasm capable of binding with antibodies against alpha-latrotoxin.     

Tetanus toxin-mediated cleavage of cellubrevin impairs exocytosis of transferrin receptor-containing vesicles in CHO cells

Cellubrevin is a member of the synaptobrevin/VAMP family of SNAREs, which has a broad tissue distribution. In fibroblastic cells it is concentrated in the vesicles which recycle transferrin receptors but its role in membrane trafficking and fusion remains to be demonstrated. Cellubrevin, like the synaptic vesicle proteins synaptobrevins I and II, can be cleaved by tetanus toxin, a metallo-endoprotease which blocks neurotransmitter release. However, nonneuronal cells are unaffected by the toxin due to lack of cell surface receptors for its heavy chain. To determine whether cellubrevin cleavage impairs exocytosis of recycling vesicles, we tested the effect of tetanus toxin light chain on the release of preinternalized transferrin from streptolysin-O-perforated CHO cells. The release was found to be temperature and ATP dependent as well as NEM sensitive. Addition of tetanus toxin light chain, but not of a proteolytically inactive form of the toxin, resulted in a partial inhibition of transferrin release which correlated with the toxin-mediated cleavage of cellubrevin. The residual release of transferrin occurring after complete cellubrevin degradation was still ATP dependent. Our results indicate that cellubrevin plays an important role in the constitutive exocytosis of vesicles which recycle plasmalemma receptors. The incomplete inhibition of transferrin release produced by the toxin suggests the existence of a cellubrevin-independent exocytotic mechanism, which may involve tetanus toxin-insensitive proteins of the synaptobrevin/VAMP family.     

Neurexins are functional alpha-latrotoxin receptors

Alpha-latrotoxin is a potent neurotoxin that triggers synaptic exocytosis. Surprisingly, two distinct neuronal receptors for alpha-latrotoxin have been described: CIRL/latrophilin 1 (CL1) and neurexin-1alpha. Alpha-latrotoxin is thought to trigger exocytosis by binding to CL1, while the role of neurexin 1alpha is uncertain. Using PC12 cells, we now demonstrate that neurexins indeed function as alpha-latrotoxin receptors that are at least as potent as CL1. Both alpha- and beta-neurexins represent autonomous alpha-latrotoxin receptors that are regulated by alternative splicing. Similar to CL1, truncated neurexins without intracellular sequences are fully active; therefore, neurexins and CL1 recruit alpha-latrotoxin but are not themselves involved in exocytosis. Thus, alpha-latrotoxin is unique among neurotoxins, because it utilizes two unrelated receptors, probably to amplify recruitment of alpha-latrotoxin to active sites.     

alpha-latrotoxin triggers transmitter release via direct insertion into the presynaptic plasma membrane

alpha-latrotoxin, a component of black widow spider venom, binds to presynaptic nerve terminals and stimulates massive neurotransmitter release. Previous studies have demonstrated that alpha-latrotoxin first binds to two high-affinity receptors on nerve terminals, neurexins and CLs (CIRLs and latrophilins), and then executes a critical, second step of unknown nature that stimulates neurotransmitter release. We now demonstrate that incubation of alpha-latrotoxin with synaptosomes at 0 degrees C results in its peripheral membrane association. Incubation at 37 degrees C, however, converts the toxin into an operationally integral membrane protein, and induces generation of a protease-resistant fragment that consists of the entire N-terminal domain of alpha-latrotoxin and becomes protease sensitive after lysis of synaptosomes. Our data suggest that alpha-latrotoxin inserts into the presynaptic plasma membrane after receptor binding, resulting in an intracellular location of the N-terminal sequences. Membrane insertion of the N-terminal domain of alpha-latrotoxin occurs spontaneously, independently of membrane recycling or transmembrane ion gradients. We postulate that alpha-latrotoxin acts intracellularly in triggering release, and propose that non-selective cation channels induced by alpha-latrotoxin may be a by-product of membrane insertion.     

Study of the receptor for black widow spider neurotoxin. I. Characteristics of membrane-bound and solubilized receptors from the bovine brain

Iodine-125 labelled alpha-latrotoxin from the venom of Central Asia black widow spider Latrodectus mactans tredecimguttatus binds specifically to the bovine brain membrane receptor producing a stable slowly dissociating complex with Kd = 1.6 x 10(-10) M and Bmax = 0.5 pmol/mg protein. Treatment of the complex with alkaline high-salt buffer induces reversible dissociation of the bound toxin. The antitoxin polyclonal antibody does not increase the dissociation rate of the bound toxin. Wheat germ lectin as well as concanavalin A inhibit the toxin binding to the membrane receptor. The receptor is solubilized with ionic and non-ionic detergents, and methods of latrotoxin binding assay are developed. The solubilized receptor is shown to retain high affinity to toxin, its binding activity being stable but critically dependent on the presence of calcium ions. Chromatographic properties of the receptor suggest its glycoprotein nature.     

Intracellular Calcium Homeostasis in a Human Neuroblastoma Cell Line: Modulation by Depolarization, Cholinergic Receptors, and α-Latrotoxin

Intracellular calcium homeostasis and its modulation by different agents was studied in control and differentiated IMR32 human neuroblastoma cells by using the Ca2+-sensitive fluorescent dye quin2. The results obtained demonstrate the existence in IMR32 cells of (a) voltage-dependent, verapamil sensitive, Ca2+ channels, which are expressed before differentiation; (b) muscarinic receptors whose activation triggers both Ca2+ influx and Ca2+ redistribution from intracellular stores, whereas nicotinic receptors and alpha-bungarotoxin binding sites do not; and (c) receptors for alpha-latrotoxin (the major toxin of the black widow spider venom), which are well-known markers of the neuronal presynaptic membrane. Up to now, no cell lines of human origin sensitive to this toxin have been identified. These results confirm that IMR32 cells are very convenient model cells for studying specific aspects of the neurochemistry and neurobiology of the human neuron at the molecular and cellular levels.     

The synaptophysin/synaptobrevin complex dissociates independently of neuroexocytosis

Synaptophysin is one of the most abundant membrane proteins of small synaptic vesicles. In mature nerve terminals it forms a complex with the vesicular membrane protein synaptobrevin, which appears to modulate synaptobrevin's interaction with the plasma membrane-associated proteins syntaxin and SNAP25 to form the SNARE complex as a prerequisite for membrane fusion. Here we show that synaptobrevin is preferentially cleaved by tetanus toxin while bound to synaptophysin or when existing as a homodimer. The synaptophysin/synaptobrevin complex is, however, not affected when neuronal secretion is blocked by botulinum A toxin which cleaves SNAP25. Excessive stimulation with alpha-latrotoxin or Ca(2+)-ionophores dissociates the synaptophysin/synaptobrevin complex and increases the interaction of the other SNARE proteins. The stimulation-induced dissociation of the synaptophysin/synaptobrevin complex is not inhibited by pre-incubating neurones with botulinum A toxin, but depends on extracellular calcium. However, the synaptophysin/synaptobrevin complex cannot be directly dissociated by calcium alone or in combination with magnesium. The dissociation of synaptobrevin from synaptophysin appears to precede its interaction with the other SNARE proteins and does not depend on the final fusion event. This finding further supports the modulatory role the synaptophysin/synaptobrevin complex may play in mature neurones.     

Synaptogyrins regulate Ca2+-dependent exocytosis in PC12 cells.

Synaptogyrins constitute a family of synaptic vesicle proteins of unknown function. With the full-length structure of a new brain synaptogyrin isoform, we now show that the synaptogyrin family in vertebrates includes two neuronal and one ubiquitous isoform. All of these synaptogyrins are composed of a short conserved N-terminal cytoplasmic sequence, four homologous transmembrane regions, and a variable cytoplasmic C-terminal tail that is tyrosine-phosphorylated. The localization, abundance, and conservation of synaptogyrins suggest a function in exocytosis. To test this, we employed a secretion assay in PC12 cells expressing transfected human growth hormone (hGH) as a reporter protein. When Ca2+-dependent hGH secretion from PC12 cells was triggered by high K+ or alpha-latrotoxin, co-transfection of all synaptogyrins with hGH inhibited hGH exocytosis as strongly as co-transfection of tetanus toxin light chain. Synaptophysin I, which is distantly related to synaptogyrins, was also inhibitory but less active. Inhibition was independent of the amount of hGH expressed but correlated with the amount of synaptogyrin transfected. Inhibition of exocytosis was not observed with several other synaptic proteins, suggesting specificity. Analysis of the regions of synaptogyrin required for inhibition revealed that the conserved N-terminal domain of synaptogyrin is essential for inhibition, whereas the long C-terminal cytoplasmic tail is largely dispensable. Our results suggest that synaptogyrins are conserved components of the exocytotic apparatus, which function as regulators of Ca2+-dependent exocytosis.