Redistribution of presynaptic proteins during alpha-latrotoxin-induced release of neurotransmitter and membrane retrieval at the frog neuromuscular junction.

Calcium-dependent exocytosis at the nerve terminal involves the synaptic core (SNARE) complex composed of the t-SNAREs syntaxin 1 and synaptosome-associated protein of 25 kDa (SNAP-25), and the v-SNARE vesicle-associated membrane protein (VAMP/synaptobrevin), a stable heterotrimer which can associate with the putative calcium sensor protein, synaptotagmin. The distribution of these proteins at the frog neuromuscular junction was examined by immunofluorescent staining and confocal microscopy following exocytosis induced by alpha-latrotoxin. Experiments were performed under conditions in which synaptic vesicle recycling was either maintained in balance with exocytosis, or completely blocked, or during recovery from block of endocytosis. When endocytosis was maintained, protein distribution was essentially identical to that of unstimulated nerve terminals, in which syntaxin 1 and SNAP-25 are localized to the presynaptic active zones coincident with the postsynaptic folds that contain a high density of acetylcholine receptors (AChRs). Block of endocytosis led to complete incorporation of vesicle proteins into the plasmalemma, and t-SNARE distribution was no longer restricted to active zones. Five minutes after the onset of recovery, both synaptic vesicle proteins and t-SNARE proteins were concentrated into small spots, in a similar pattern to that obtained following endocytosis of the vital styryl dye FM1-43. These findings are consistent with a model in which following sustained exocytosis, t-SNARE trafficking involves internalization and transit via a vesicular compartment before recycling to the presynaptic plasma membrane.

Interactions between proteins implicated in exocytosis and voltage-gated calcium channels.

Neurotransmitter release from synaptic vesicles is triggered by voltage-gated calcium influx through P/Q-type or N-type calcium channels. Purification of N-type channels from rat brain synaptosomes initially suggested molecular interactions between calcium channels and two key proteins implicated in exocytosis: synaptotagmin I and syntaxin 1. Co-immunoprecipitation experiments were consistent with the hypothesis that both N- and P/Q-type calcium channels, but not L-type channels, are associated with the 7S complex containing syntaxin 1, SNAP-25, VAMP and synaptotagmin I or II. Immunofluorescence confocal microscopy at the frog neuromuscular junction confirmed that calcium channels, syntaxin 1 and SNAP-25 are co-localized at active zones of the presynaptic plasma membrane where transmitter release occurs. Experiments with recombinant proteins were performed to map synaptic protein interaction sites on the alpha 1A subunit, which forms the pore of the P/Q-type calcium channel. In vitro-translated 35S-synaptotagmin I bound to a site located on the cytoplasmic loop linking homologous domains II and III of the alpha 1A subunit. This direct link would target synaptotagmin, a putative calcium sensor for exocytosis, to a microdomain of calcium influx close to the channel mouth. Cysteine string proteins (CSPs) contain a J-domain characteristic of molecular chaperones that cooperate with Hsp70. They are located on synaptic vesicles and thought to be involved in modulating the activity of presynaptic calcium channels. CSPs were found to bind to the same domain of the calcium channel as synaptotagmin, and also to associate with VAMP. CSPs may act as molecular chaperones in association with Hsp70 to direct assembly or dissociation of multiprotein complexes at the calcium channel.

Activity-induced internalization and rapid degradation of sodium channels in cultured fetal neurons.

A regulatory mechanism for neuronal excitability consists in controlling sodium channel density at the plasma membrane. In cultured fetal neurons, activation of sodium channels by neurotoxins, e.g., veratridine and alpha-scorpion toxin (alpha-ScTx) that enhance the channel open state probability induced a rapid down-regulation of surface channels. Evidence that the initial step of activity-induced sodium channel down-regulation is mediated by internalization was provided by using 125I-alpha-ScTx as both a channel probe and activator. After its binding to surface channels, the distribution of 125I-alpha-ScTx into five subcellular compartments was quantitatively analyzed by EM autoradiography. 125I-alpha-ScTx was found to accumulate in tubulovesicular endosomes and disappear from the cell surface in a time-dependent manner. This specific distribution was prevented by addition of tetrodotoxin (TTX), a channel blocker. By using a photoreactive derivative to covalently label sodium channels at the surface of cultured neurons, we further demonstrated that they are degraded after veratridine-induced internalization. A time-dependent decrease in the amount of labeled sodium channel alpha subunit was observed after veratridine treatment. After 120 min of incubation, half of the alpha subunits were cleaved. This degradation was prevented totally by TTX addition and was accompanied by the appearance of an increasing amount of a 90-kD major proteolytic fragment that was already detected after 45-60 min of veratridine treatment. Exposure of the photoaffinity-labeled cells to amphotericin B, a sodium ionophore, gave similar results. In this case, degradation was prevented when Na+ ions were substituted by choline ions and not blocked by TTX. After veratridine- or amphotericin B-induced internalization of sodium channels, breakdown of the labeled alpha subunit was inhibited by leupeptin, while internalization was almost unaffected. Thus, cultured fetal neurons are capable of adjusting sodium channel density by an activity-dependent endocytotic process that is triggered by Na+ influx.

Co-localization of suramin and serum albumin in lysosomes of suramin-treated human colon cancer cells.

Suramin is a polysulfonated compound currently under investigation for the treatment of various types of cancer. Pharmacokinetic studies from clinical trials in humans have shown that most of the circulating drug is associated with serum albumin. The objective of the present study was to investigate the intracellular localization of suramin and serum albumin in human colon cancer cells (HT-29-D4) upon suramin treatment. For this purpose, combined gold labeling and autoradiographic methods were performed on HT-29-D4 cells grown in serum free medium containing both [3H]suramin and colloidal gold-albumin. These morphological experiments demonstrated for the first time that suramin and serum albumin were co-localized in the same cellular compartment (i.e. the lysosomal system) of the suramin-treated HT-29-D4 cells. The albumin-directed targeting of suramin in lysosomes may allow the drug to inhibit the activity of several lysosomal hydrolases, resulting in a lysosomal storage disorder.

Distribution of components of the SNARE complex in relation to transmitter release sites at the frog neuromuscular junction.

At the frog neuromuscular junction, neurotransmitter release sites are regularly spaced at 1 micron intervals along the nerve terminal, directly facing postsynaptic folds which contain a high density of acetylcholine receptors. Immunostaining and laser confocal scanning microscopy were used to compare the distribution of presynaptic proteins implicated in exocytosis with that of fluorescent alpha-bungarotoxin. Syntaxin, synaptosome-associated 25 kDa protein and calcium channels were located predominantly at release sites. Synaptobrevin (vesicle-associated membrane protein) was distributed in the cytoplasm of the nerve terminal, presumably in the packets of microvesicles associated with each active zone. N-Ethylmaleimide-sensitive fusion protein (NSF) and soluble NSF attachment proteins (alpha beta SNAP) displayed a diffuse distribution throughout the terminal cytoplasm and also colocalized in distinct concentrated zones adjacent to the presynaptic membrane.

Intracellular localisation of suramin, an anticancer drug, in human colon adenocarcinoma cells: a study by quantitative autoradiography.

Suramin is a polysulphonated naphthylurea currently investigated for the treatment of advanced malignancy. In the present study, we have analysed the uptake and the intracellular localisation of tritiated suramin in human colon adenocarcinoma cells (HT-29-D4), using quantitative autoradiographic techniques at the optical and electron microscopy levels. Our results show that the drug is able to enter both undifferentiated and differentiated HT-29-D4 cells. The process of suramin uptake is time-dependent, and significantly inhibited by the presence of the suramin-binding protein serum albumin in the culture medium of HT-29-D4 cells. Autoradiographic analysis revealed two distinct patterns of intracellular localisation of tritiated suramin labelling, according to the presence or absence of serum albumin. Indeed, in the absence of serum albumin, the labelling of free suramin was distributed over the nucleus, the Golgi apparatus and the mitochondria, while it was restricted to the lysosomal system when suramin was complexed with albumin. These data show that a serum factor, i.e. albumin, influences the biological activity of suramin by determining its intracellular localisation. The presence of suramin in a given compartment may account for specific effects of the drug including mitochondrial hypertrophy, altered gene expression and lysosomal perturbation.

Evaluation of low molecular weight heparin during and after aortic and carotid surgery: dose finding study.

Forty-four patients undergoing abdominal aortic surgery and twenty-eight patients undergoing carotid surgery were randomly treated with different anticoagulant regimens. During surgery, an unfractionated heparin (UFH) intravenous bolus of 50 IU/kg was compared with a low molecular weight heparin (LMWH) bolus of either 120 IU/kg, 80 IU/kg, 40 IU/kg or 20 IU/kg. Six hours after surgery and for 48 hours, an UFH infusion was compared with an LMWH infusion of either 10,000 IU/day or 6,000 IU/day and then, a single LMWH subcutaneous injection of 3,075 IU was administered. Heparin activity was measured by factor Xa inhibitor and by prolongation of APTT which were studied 15, 30 and 60 minutes after cross-clamping, at the end of surgery and six hours later, and on days 1, 2, 3 and 6. After a descriptive analysis of clinical and pharmacokinetic profiles of each regimen, optimal LMWH treatment is proposed.

Autoradiographic localization of tritiated suramin in polarized human colon adenocarcinoma cells.

In this report we demonstrated that [3H]suramin enters polarized human colon adenocarcinoma cells when added to the apical side of the monolayer. Using light microscopic quantitative autoradiography, we showed that suramin was accumulated in the apical cytoplasm and in the nucleus. In contrast, a weak labeling was noted in other compartments such as the basolateral cytoplasm and the intercellular space. The accumulation of suramin in the apical region of the cells is consistent with previous data showing that suramin elicited a lysosomal storage disorder in HT29-D4 cells by a mechanism of polarized endocytosis.

Autoradiographic localization of voltage-dependent sodium channels on the mouse neuromuscular junction using 125I-alpha scorpion toxin. II. Sodium distribution on postsynaptic membranes.

A radioiodinated alpha-scorpion toxin (toxin II from Androctonus australis Hector) (alpha ScTx) was used as a probe for EM autoradiography to study the distribution of voltage-dependent sodium channels (Na+ channel) on the postsynaptic side of the mouse neuromuscular junction. Silver grain distribution was analyzed by the cross-fire method to assess the relative Na+ channel density in each membrane domain measured by stereology. This analysis showed that the maximum Na+ channel density was located on the edge of the synaptic gutter, where it reached about twice the mean density in the postsynaptic fold membrane. Na+ channel densities have been calculated using ACh receptor (AChR) density in fold crests as reference. Sodium channel density on the edge of the synaptic gutter was estimated at about 5000/microns 2. Sodium channel distribution in the postsynaptic folds was compared to AChR distribution using density distribution analysis (Fertuck and Salpeter, 1976). The results confirmed that, as already observed by immunogold labeling (Flucher and Daniels, 1989), there are no Na+ channels on fold crests. Na+ channels are located in the rest of the fold membrane (bottom) and may be distributed according to two possible models. In the first, density would be uniformly high, although lower than on the gutter edge. In the second, density would decrease from the crest border, where the value was that of the gutter edge, to the fold end, where the value would be 50% lower. Based on the latter model, which was the "best-fit model," we propose that the postsynaptic membrane includes two domains. The first is the fold crest, which contains almost exclusively AChRs. This domain is devoted to reception-transduction of the chemical signal. The second includes both the fold bottom membrane and the perisynaptic membrane. Sodium channel density is highest along the crest border and decreases moving away. Its functions are the integration of postsynaptic potentials and generation-conduction of the muscle action potential.

Localization of voltage-sensitive sodium channels on the extrasynaptic membrane surface of mouse skeletal muscle by autoradiography of scorpion toxin binding sites.

Voltage-dependent sodium channels (Na+ channels) were localized by autoradiography on mouse skeletal muscle using both light and electron microscopy. 125I-scorpion toxins (ScTx) of both the alpha and beta type were used as probes. The specificity of labelling was verified by competitive inhibition with unlabelled toxin and by inhibition of alpha ScTx labelling in depolarizing conditions. Under light microscopy, the labelling of the myocyte surface appeared randomly distributed with both the alpha and beta toxins. No difference in the labelling density obtained with beta ScTx was observed between a 2 mm central segment of the fibre containing the endplate and an adjacent segment not containing the endplate. At the endplate, however, the beta ScTx binding site density was about seven fold higher at the edge of the synaptic primary clefts. This density decreased with distance from the synaptic cleft reaching the extrasynaptic value at 30-40 microns. An analysis of myocyte labelling using electron microscopy provided evidence for a specific, but very low labelling of the myocyte interior which can be attributed to the T-tubules. These results confirm a relatively high density of Na+ channels in a perijunctional zone about 50 microns in width, which could ensure the initial spread of the surface depolarization with a high safety factor, and a homogeneous distribution over the remaining surface with a low density evaluated at 5-10 per microns2. However, the very low labelling of T-tubules could be attributed mainly to a low density of tubular Na+ channels.

Autoradiographic localization of voltage-dependent sodium channels on the mouse neuromuscular junction using 125I-alpha scorpion toxin. I. Preferential labeling of glial cells on the presynaptic side.

Alpha-scorpion toxins bind specifically to the voltage-sensitive sodium channel in excitable membranes, and binding is potential-dependent (Catterall, 1984). The radioiodinated toxin II from the scorpion Androctonus australis Hector (alpha ScTx) was used to localize voltage-sensitive sodium channels on the presynaptic side of mouse neuromuscular junctions (NMJ) by autoradiography using both light and electron microscopy. Silver grain localization was analyzed by the cross-fire method. At the light-microscopic level, grain density over NMJ appeared 6-8x higher than over nonjunctional muscle membrane. The specificity of labeling was verified by competition/displacement with an excess of native alpha ScTx. Labeling was also inhibited by incubation in depolarizing conditions, showing its potential-dependence. At the electron-microscopic level, analysis showed that voltage-sensitive sodium channels labeled with alpha ScTx were almost exclusively localized on membranes, as expected. Due to washout after incubation, appreciable numbers of binding sites were not found on the postsynaptic membranes. However, on the presynaptic side, alpha ScTx-labeled voltage-sensitive sodium channels were localized on the membrane of non-myelin-forming Schwann cells covering NMJ. The axonal presynaptic membrane was not labeled. These results show that voltage-sensitive sodium channels are present on glial cells in vivo, as already demonstrated in vitro (Chiu et al., 1984; Schrager et al., 1985). It is proposed that these glial channels could be indirectly involved in the ionic homeostasis of the axonal environment.

Ultrastructural localization of voltage-sensitive sodium channels using [125I]alpha scorpion toxin.

The distribution of alpha scorpion toxin (alpha-ScTx) receptors was examined in differentiated mouse neuroblastoma cell cultures (N IE 115 clone) by electron microscope autoradiography using [125I]alpha-ScTx. This neurotoxin binds specifically to voltage-sensitive sodium channels, slowing down the inactivation of the sodium permeability. Quantitative analysis demonstrated that only plasma membranes were labelled. The alpha-ScTx receptors seemed to be randomly dispersed on both cell bodies and cell processes. Microvilli protruding from the cell bodies carried more sodium channels than other parts of the membrane. The specific binding site density for alpha-ScTx varied from 4 (cell body membrane) to 13 (cell process membrane) per square micrometer.

Ultrastructural visualization of Na+-channel associated [125I]alpha-scorpion toxin binding sites on fetal mouse nerve cells in culture.

Purified neurotoxin II from the scorpion Androctonus australis Hector (alpha-ScTx) has previously been shown to bind specifically to the voltage-sensitive Na+ channels of excitable cells. Recent studies, using high specific activity 125I-labeled alpha-ScTx, demonstrated specific binding to neuronal cells derived from fetal mouse brains. In the present study, 125I-labeled alpha-ScTx was used to localize the voltage-sensitive Na+ channels in cultured fetal mouse brain cells. By quantitative electron microscope autoradiography we demonstrate that specific alpha-ScTx binding sites are selectively located at the plasma membrane. Estimates of their density revealed that neurites at 13 days in vitro carry at least 6 X more specific alpha-ScTx sites than cell body membrane.

Voltage-sensitive Na+ channels in the neurohypophysis of the rat as demonstrated by 125I-labelled scorpion toxin.

Fresh rat neural lobe slices were incubated in the presence of [125I] alpha-scorpion toxin (ScTX), a specific marker of Na+ channels. Quantitative electron microscope autoradiography revealed preferential, irregularly spaced labeling of the axolemma of neurosecretory axons, with a significantly higher crude specific activity than any other neuronal or non-neuronal compartment. The number of specific binding sites at the neural lobe surface was calculated to be about 23 per microns2 of axolemma.

The posterior pituitary of the garden dormouse (Eliomys quercinus l.). Evidence of two types of neurosecretory axons on the basis of ultrastructural characteristics.

Ultrastructural examination of the posterior pituitary of the garden dormouse (Eliomys quercinus L) was carried out at different times in the annual cycle of this hibernating rodent. Obvious differences between experimental groups have not been observed, and the results presented here must be considered as general features of the garden dormouse posterior pituitary. Neurosecretory axons and endings can be divided into two types, according to different aspects of neurosecretory granules (NSG) and microvesicles (MV). One type contains spherical NSG with homogeneous cores and round MV. In the other type, NSG have various, often elongated, shapes. Their content shows two types of crystalline structures and most of the MV have flattened aspects. As it is very unlikely that this duality in NSG is a result of an artefact of fixation, three hypotheses are presented as explanation. The duality of NSG might be related either to their hormonal content (oxytocin or vasopressin) or to their degree of maturation. Moreover, both explanations may be valid. In the species studied, pituicytes often contain concentric lamellar structures of the endoplasmic reticulum (whorls), the significance of which remains obscure.