Inactivation of a T cell receptor-associated GTP-binding protein by antibody-induced modulation of the T cell receptor/CD3 complex.

TCR modulation induced by anti-TCR or anti-CD3 mAbs leads to a transient state of refractoriness of the T cell to all signals given via cell surface structures. To investigate the underlying mechanisms, we have used human CTL permeabilized with the alpha toxin of S. aureus. This method of permeabilization allows manipulation of the interior milieu of the cell, but maintains its functional and structural integrity. Introduction of the G protein activator GTP gamma S into permeabilized CTL leads to triggering of granule exocytosis. The G protein inactivator GDP beta S inhibited exocytosis induced by TCR triggering but not that induced by activation of protein kinase C. This indicates that the G protein that triggers exocytosis is localized after CD3 triggering but before formation of the polyphosphoinositol breakdown product diacylglycerol. In TCR-modulated CTL, GTP gamma S is no longer able to activate exocytosis. Such CTL, however, still respond to PKC activators. This demonstrates that a TCR-associated G protein has been functionally inactivated by TCR modulation.

Embryonic and postnatal development of the serotonergic raphe system and its target regions in 5-HT1A receptor deletion or overexpressing mouse mutants.

The neurotransmitter 5-HT regulates early developmental processes in the CNS. In the present study we followed the embryonic and postnatal development of serotonergic raphe neurons and catecholaminergic target systems in the brain of 5-HT1A receptor knockout (KO) and overexpressing (OE) in comparison with wild-type (WT) mice from embryonic day (E) 12.5 to postnatal day (P) 15.5. Up to P15.5 no differences were apparent in the differentiation and distribution of serotonergic neurons in the raphe area as revealed by the equal number of serotonergic neurons in the dorsal raphe in all three genotypes. However, the establishment of serotonergic projections to the mesencephalic tegmentum and hypothalamus was delayed at E12.5 in KO and OE animals and projections to the cerebral cortex between E16.5 and E18.5 were delayed in OE mice. This delay was only transient and did not occur in other brain areas including septum, hippocampus and striatum. Moreover, OE mice caught up with WT and KO animals postnatally such that at P1.5 serotonergic innervation of the cortex was more extensive in the OE than in KO and WT mice. Tissue levels of 5-HT and of its main metabolite 5-hydroxyindoleacetic acid as well as 5-HT turnover were considerably higher in brains of OE mice and slightly elevated in KO mice in comparison with the WT, starting at E16.5 through P15.5. The initial differentiation of dopaminergic neurons and fibers in the substantia nigra at E12.5 was transiently delayed in KO and OE mice as compared with WT mice, but no abnormalities in noradrenergic development were apparent in later stages. The present data indicate that 5-HT1A receptor deficiency or overexpression is associated with increased 5-HT synthesis and turnover in the early postnatal period. However, they also show that effects of 5-HT1A KO or OE on the structural development of the serotonergic system are at best subtle and transient. They may nonetheless contribute to the establishment of increased or reduced anxiety-like behavior, respectively, in adult mice.

Regulation of vesicular neurotransmitter transporters.

Neurotransmitters are key molecules of neurotransmission. They are concentrated first in the cytosol and then in small synaptic vesicles of presynaptic terminals by the activity of specific neurotransmitter transporters of the plasma and the vesicular membrane, respectively. It has been shown that postsynaptic responses to single neurotransmitter packets vary over a wide range, which may be due to a regulation of vesicular neurotransmitter filling. Vesicular filling depends on the availability of transmitter molecules in the cytoplasm and the active transport into secretory vesicles relying on a proton gradient. In addition, it is modulated by vesicle-associated heterotrimeric G proteins, Galphao2 and Galphaq, which regulate VMAT activities in brain and platelets, respectively, and may also be involved in the regulation of VGLUTs. It appears that the vesicular content activates the G protein, suggesting a signal transduction form the luminal site which might be mediated by a vesicular G-protein coupled receptor or, as an alternative, possibly by the transporter itself. These novel functions of G proteins in the control of transmitter storage may link regulation of the vesicular content to intracellular signal cascades.

Regulation of vesicular monoamine and glutamate transporters by vesicle-associated trimeric G proteins: new jobs for long-known signal transduction molecules.

Neurotransmitters of neurons and neuroendocrine cells are concentrated first in the cytosol and then in either small synaptic vesicles ofpresynaptic terminals or in secretory vesicles by the activity of specific transporters of the plasma and the vesicular membrane, respectively. In the central nervous system the postsynaptic response depends--amongst other parameters-on the amount of neurotransmitter stored in a given vesicle. Neurotransmitter packets (quanta) vary over a wide range which may be also due to a regulation of vesicular neurotransmitter filling. Vesicular filling is regulated by the availability of transmitter molecules in the cytoplasm, the amount of transporter molecules and an electrochemical proton-mediated gradient over the vesicular membrane. In addition, it is modulated by vesicle-associated heterotrimeric G proteins, Galphao2 and Galphaq. Galphao2 and Galphaq regulate vesicular monoamine transporter (VMAT) activities in brain and platelets, respectively. Galphao2 also regulates vesicular glutamate transporter (VGLUT) activity by changing its chloride dependence. It appears that the vesicular content activates the G protein, suggesting a signal transduction from the luminal site which might be mediated by a vesicular G protein-coupled receptor or as an alternative possibility by the transporter itself. Thus, G proteins control transmitter storage and thereby probablylink the regulation of the vesicular content to intracellular signal cascades.

Molecular aspects of tetanus and botulinum neurotoxin poisoning.

Clostridial neurotoxins, tetanus and the botulinum toxins A-G, are high molecular weight proteins consisting of a heavy chain which is responsible for the internalisation and a light chain possessing a zinc-dependent proteolytic activity. They exclusively proteolyse either the vesicle membrane protein, synaptobrevin or two integral plasma membrane proteins, SNAP 25 and syntaxin. Together with cytosolic proteins these proteins form the SNARE complex involved in vesicle exocytosis, and their cleavage blocks the latter process. Clostridial neurotoxins have now become powerful tools to investigate the final events occurring during secretion in neuronal, endocrine, and non-neuronal cells. They are applied to dissect the specific interactions of the SNARE protein complex with cytosolic fusogens and other modulators of exocytosis. Whereas exocytosis is not essential for the survival of cells, the organism as a whole will fall victim to a few nanograms since interneuronal and neuromuscular transmission is vital to muscular control, especially in respiration. Although all clostridial neurotoxins by their light chains attack proteins of the SNARE complex, tetanus toxin and the various botulinum toxins differ dramatically in their clinical symptoms. The biological information for this difference resides on the respective heavy chains which select different transport routes carrying the light chain from the place of entrance to the final compartment of action. So far the different transport vesicles used either by the various botulinum neurotoxins or by tetanus toxin are not yet defined. Nevertheless at least one of the botulinum toxins serves as a beneficial drug in the treatment of severe neuromuscular spasms.

Expression of Kv1 potassium channels in mouse hippocampal primary cultures: development and activity-dependent regulation.

Excitability and discharge behavior of neurons depends on the highly variable expression pattern of voltage-dependent potassium (Kv) channels throughout the nervous system. To learn more about distribution, development, and activity-dependent regulation of Kv channel subunit expression in the rodent hippocampus, we studied the protein expression of members of the Kv1 subfamily in mouse hippocampus in situ and in primary cultures. In adult hippocampus, Kv1 (1-6) channel alpha-subunits were present, whereas at postnatal day 2, none of these proteins could be detected in CA1-CA3 and dentate gyrus. Kv1.1 was the first channel to be observed at postnatal day 6. The delayed postnatal expression and most of the subcellular distribution observed in hippocampal sections were mimicked by cultured hippocampal neurons in which Kv channels appeared only after 10 days in vitro. This developmental upregulation was paralleled by a dramatic increase in total K(+) current, as well as an elevated GABA release in the presence of 4-aminopyridine. Thus, the developmental profile, subcellular localization, and functionality of Kv1 channels in primary culture of hippocampus closely resembles the in situ situation. Impairing secretion by clostridial neurotoxins or blocking activity by tetrodotoxin inhibited the expression of Kv1.1, Kv1.2, and Kv1.4, whereas the other Kv1 channels still appeared. This activity-dependent depression was only observed before the initial appearance of the respective channels and lost after they had been expressed. Our data show that hippocampal neurons in culture are a convenient model to study the developmental expression and regulation of Kv1 channels. The ontogenetic regulation and the activity-dependent expression of Kv1.1, Kv1.2, and Kv1.4 indicate that neuronal activity plays a crucial role for the development of the mature Kv channel pattern in hippocampal neurons.

The neuronal monoamine transporter VMAT2 is regulated by the trimeric GTPase Go(2).

Monoamines such as noradrenaline and serotonin are stored in secretory vesicles and released by exocytosis. Two related monoamine transporters, VMAT1 and VMAT2, mediate vesicular transmitter uptake. Previously we have reported that in the rat pheochromocytoma cell line PC 12 VMAT1, localized to peptide-containing secretory granules, is controlled by the heterotrimeric G-protein Go(2). We now show that in BON cells, a human serotonergic neuroendocrine cell line derived from a pancreatic tumor expressing both transporters on large, dense-core vesicles, VMAT2 is even more sensitive to G-protein regulation than VMAT1. The activity of both transporters is only downregulated by Galphao(2), whereas comparable concentrations of Galphao(1) are without effect. In serotonergic raphe neurons in primary culture VMAT2 is also downregulated by pertussis toxin-sensitive Go(2). By electron microscopic analysis from prefrontal cortex we show that VMAT2 and Galphao(2) associate preferentially to locally recycling small synaptic vesicles in serotonergic terminals. In addition, Go(2)-dependent modulation of VMAT2 also works when using a crude synaptic vesicle preparation from this brain area. We conclude that regulation of monoamine uptake by the heterotrimeric G proteins is a general feature of monoaminergic neurons that controls the content of both large, dense-core and small synaptic vesicles.

Changes in erythrocyte permeability due to palytoxin as compared to amphotericin B.

Palytoxin causes within minutes a temperature-dependent K+ loss from human and rat erythrocytes which is followed within hours by haemolysis. It decreases the osmotic resistance in a concentration-dependent manner, so that osmotic influences are negligible for K+ release but considerable in haemolysis. External K+ inhibits the haemoglobin release and Rb+ inhibits the release of K+ and haemoglobin. Ca2+ (over 20 microM) and borate (over 5 microM) enhance the loss of K+ and haemoglobin. With both Ca2+ and borate present, the efficacy of palytoxin is raised about 10 000-fold. Under these conditions, about 15 palytoxin molecules per human cell trigger a 50% K+ loss over a wide range of cell concentrations. The palytoxin effect is reversible. After depletion from K+ by low concentrations of palytoxin, human cells can be refilled with K+ and resealed. The pores formed by palytoxin are small. They allow the entrance of Na+ and choline, whereas inositol is largely excluded and Ca2+, as well as sucrose and inulin, are completely excluded. Amphotericin B resembles palytoxin in its ability to cause a considerable prelytic K+ loss and to form small pores. However, it is about 1000-times weaker than palytoxin, is not inhibited by K+ or Rb+, is not activated by Ca2+ or borate, and has a negative temperature dependence. Thus palytoxin represents a novel type of cytolysin.

Delayed haemolytic action of palytoxin. General characteristics.

1. Palytoxin is a haemolysin. The erythrocytes from various species can be classified into a sensitive and a hardly sensitive group. The former contain potassium as their main inside cation and are arranged according to their sensitivity as hog greater than or equal to rat, mouse greater than rabbit greater than guinea-pig greater than man. The latter, comprising those from sheep and cattle, have sodium as their main inside cation. In addition, chicken erythrocytes are relatively insensitive. 2. Haemolysis of rat erythrocytes is preceded by a lag period of 1--2 h. With increasing temperature the haemolysis proceeds more quickly but reaches the same final range between 25 and 42 degrees C. The pH optimum in Britton-Robinson buffer supplemented with saline is between 7 and 8. Washing off palytoxin during the prelytic period reduces the haemolytic power. 3. The sensitivity of rat erythrocytes decreases with increase of osmolarity between 235 and 415 mosM. Accordingly, their osmotic resistance is lowered by palytoxin in a concentration-dependent manner. 4. With both rat and sheep erythrocytes, potassium loss by far precedes the haemolysis due to palytoxin. Potassium loss is measurable already after 1 min and increases with time. After 2 hours the quotient between the ED50 of haemolysis and that of potassium loss is around 200. Thus palytoxin is an unusually strong but slow haemolysin of the osmotic type. The extreme prelytic potassium loss and the correlation between susceptibility and potassium content of erythrocytes points towards the relevance of ionic fluxes.

Differentiation of pluripotent embryonic stem cells into the neuronal lineage in vitro gives rise to mature inhibitory and excitatory neurons.

Embryonic stem (ES) cells represent a suitable model to analyze cell differentiation processes in vitro. Here, we report that pluripotent ES cells of the line BLC 6 differentiate in vitro into neuronal cells possessing the complex electrophysiological and immunocytochemical properties of postmitotic nerve cells. In the course of differentiation BLC 6-derived neurons differentially express voltage-dependent (K+, Na+, Ca2+) and receptor-operated (GABAA, glycine, AMPA, NMDA receptors) ionic channels. They generate fast Na(+)-driven action potentials and are functionally coupled by inhibitory (GABAergic) and excitatory (glutamatergic) synapses as revealed by measurements of postsynaptic currents. Moreover, BLC 6-derived neurons express neuron-specific cytoskeletal, cell adhesion and synaptic vesicle proteins and exhibit a Ca(2+)-dependent GABA secretion. Thus, the ES cell model enables the investigation of cell lineage determination and signaling mechanisms in the developing nervous system from a pluripotential stem cell to a differentiated postmitotic neuron. The in vitro differentiation of neurons from ES cells may be an excellent approach to study by targeted gene disruption a variety of neuronal functions.

Molecular and cell biological aspects of neuroendocrine tumors of the gastroenteropancreatic system.

Neurons and neuroendocrine cells share a variety of common characteristics. Cell and molecular biological studies in recent years have improved our understanding of physiological and pathophysiological processes such as cellular growth, adhesion, and secretion of neuroendocrine cells. Here we review current findings from the area of basic research and from current clinical research relevant to improving the diagnosis and therapy of neuroendocrine tumors of the gastroenteropancreatic system.

The synaptophysin-synaptobrevin complex is developmentally upregulated in cultivated neurons but is absent in neuroendocrine cells.

Regulated secretion requires the formation of a fusion complex consisting of synaptobrevin, syntaxin and SNAP 25. One of these key proteins, synaptobrevin, also complexes with the vesicle protein synaptophysin. The fusion complex and the synaptophysin-synaptobrevin complex are mutually exclusive. Using a combination of immunoprecipitation and crosslinking experiments we report here that the synaptophysin-synaptobrevin interaction in mouse whole brain and defined brain areas is upregulated during neuronal development as previously reported for rat brain. Furthermore the synaptophysin-synaptobrevin complex is also upregulated within 10-12 days of cultivation in mouse hippocampal neurons in primary culture. Besides being constituents of small synaptic vesicles in neurons synaptophysin and synaptobrevin also occur on small synaptic vesicle analogues of neuroendocrine cells. However, the synaptophysin-synaptobrevin complex was not found in neuroendocrine cell lines and more importantly it was also absent in the adrenal gland, the adenohypophysis and the neurohypophysis although the individual proteins could be clearly detected. In the rat pheochromocytoma cell line PC 12 complex formation between synaptophysin and synaptobrevin could be initiated by adult rat brain cytosol. In conclusion, the synaptophysin-synaptobrevin complex is upregulated in neurons in primary culture but is absent in the neuroendocrine cell lines and tissues tested. The complex may provide a reserve pool of synaptobrevin during periods of high synaptic activity. Such a reserve pool probably is less important for more slowly secreting neuroendocrine cells and neurons. The synaptophysin on small synaptic vesicle analogues in these cells appears to resemble the synaptophysin of embryonic synaptic vesicles since complex formation can be induced by adult brain cytosol.

Synaptobrevin is essential for secretion but not for the development of synaptic processes.

The formation of small synaptic vesicles represents a hallmark during synaptogenesis. The small synaptic vesicle protein synaptophysin is considered as a marker protein for synapses during neuronal development. Another small synaptic vesicle protein, synaptobrevin, is now well accepted to play an important role for the function of synapses in being a key component of exocytosis. Its role during synaptogenesis is not known. Tetanus toxin which exclusively proteolysis synaptobrevin thereby inhibiting secretion from all types of neurons was used to investigate consequences of inactivating synaptobrevin for the formation of small synaptic vesicles and synaptic contacts. In primary cultures of mouse hypothalamic and cerebellar neurons cultivated for 3 to 4 days, synaptobrevin appears earlier on small synaptic vesicles and in synaptic contacts than synaptophysin. Upon longer cultivation up to 12 to 14 days in vitro both proteins associated equally with small synaptic vesicles. Interestingly, GABA secretion stimulated by 50 mM potassium or 500 PM alpha-latrotoxin, did not vary during cultivation time. Tetanus toxin added to neuronal cultures at day 2 in vitro cleaved synaptobrevin and inhibited regulated GABA secretion during the whole cultivation time. Despite the impaired function of synaptobrevin other synaptic proteins such as synaptophysin, synaptotagmin, rab 3A, protein SV2, SNAP-25 and syntaxin were found in processes and synaptic contacts comparable to untreated cultures. The expression of various synaptic proteins was also followed in vivo. In mouse brains taken at different embryonic days, synaptobrevin, synaptotagmin, rab 6 and the membrane protein SNAP-25 were expressed earlier than synaptophysin and protein SV2. We conclude that synaptobrevin represents a marker for early events in synaptogenesis. Its proteolysis by tetanus toxin, however, does not interfere with the formation of synaptic contacts and neuronal differentiation.

Detection of G-protein heterotrimers on large dense core and small synaptic vesicles of neuroendocrine and neuronal cells.

Heterotrimeric G proteins, initially believed to be exclusively present in the plasma membrane, have also been found to be associated with intracellular membrane compartments. There they are involved in various membrane trafficking processes including regulated secretion (reviewed in Bomsel, M., K. Mostov, Mol. Biol. Cell 3, 1317-1328 (1992)). Vesicles of two distinct types enter the regulated secretory pathway, i.e. large dense core vesicles and small synaptic vesicles, which differ in their membrane composition and content. Little is known about an association of heterotrimeric G proteins with regulated secretory vesicles, that would explain some aspects of the role heterotrimeric G proteins have during secretion. By immunofluorescence microscopy and immunoreplica analysis, we provide the first demonstration of the presence of complete sets of heterotrimeric G proteins, consisting of alpha-, beta-, and gamma-subunits, on large dense core vesicles from bovine adrenal medulla (chromaffin granules) and small synaptic vesicles from rodent and bovine brain. Each of the two types of secretory vesicles contains beta-subunits (at least beta 1 and beta 2), as well as gamma-subunits (at least gamma 2 or gamma 3). Interestingly, they differ in their composition of alpha-subunits. On small synaptic vesicles, we found two G(o) alpha-subunits (alpha o1 and alpha o2) and two Gi alpha-subunits (alpha i1 and alpha i2). In contrast, on chromaffin granules so far only one alpha o-subunit but no alpha i-subunits could be detected. Functional properties such as transmitter storage and/or exocytotic membrane fusion may be modulated by the various G-protein subunits associated with chromaffin granules and small synaptic vesicles.

Differential distribution of G-protein beta-subunits in brain: an immunocytochemical analysis.

Heterotrimeric G proteins play central roles in signal transduction of neurons and other cells. The variety of their alpha-, beta-, and gamma-subunits allows numerous combinations thereby confering specificity to receptor-G-protein-effector interactions. Using antisera against individual G-protein beta-subunits we here present a regional and subcellular distribution of Gbeta1, Gbeta2, and Gbeta5 in rat brain. Immunocytochemical specificity of the subtype-specific antisera is revealed in Sf9 cells infected with various G-protein beta-subunits. Since Gbeta-subunits together with a G-protein gamma-subunit affect signal cascades we include a distribution of the neuron-specific Ggamma2- and Ggamma3-subunits in selected brain areas. Gbeta1, Gbeta2, and Gbeta5 are preferentially distributed in the neuropil of hippocampus, cerebellum and spinal cord. Gbeta2 is highly concentrated in the mossy fibres of dentate gyrus neurons ending in the stratum lucidum of hippocampal CA3-area. High amounts of Gbeta2 also occur in interneurons innervating spinal cord alpha-motoneurons. Gbeta5 is differentially distributed in all brain areas studied. It is found in the pyramidal cells of hippocampal CA1-CA3 as well as in the granule cell layer of dentate gyrus and in some interneurons. In the spinal cord Gbeta5 in contrast to Gbeta2 concentrates around alpha-motoneurons. In cultivated mouse hippocampal and hypothalamic neurons Gbeta2 and Gbeta5 are found in different subcellular compartments. Whereas Gbeta5 is restricted to the perikarya, Gbeta2 is also found in processes and synaptic contacts where it partially colocalizes with the synaptic vesicle protein synaptobrevin. An antiserum recognizing Ggamma2 and Ggamma3 reveals that these subunits are less expressed in hippocampus and cerebellum. Presumably this antiserum specifically recognizes Ggamma2 and Ggamma3 in combinations with certain G alphas and/or Gbetas. The widespread but regionally and cellularly rather different distribution of Gbeta- and Ggamma2/3-subunits suggests that region-specific combinations of G-protein subunits mediate signal transduction in the central nervous system. The different subcellular distribution of Gbeta-subunits in cultivated neurons reflects that observed in tissue where Gbeta5 and Gbeta2 associate preferentially with the perikarya and the neuropil, respectively, and suggests an additional association of Gbeta2 with secretory vesicles.

SNARE proteins and rab3A contribute to canalicular formation in parietal cells.

SNARE proteins - rab3A - parietal cells - H+/K+-ATPase When stimulated by histamine, acetylcholine, or gastrin the luminal compartments of oxyntic parietal cells display conspicuous morphological changes. The luminal plasma membrane surface becomes greatly expanded, while the cytoplasmic tubulovesicles are decreased in parallel. Due to these membrane rearrangements the H+/K(+)-ATPase obtains access to the luminal surface, where proton secretion occurs. The stimulation-induced translocation of H+/K(+)-ATPase involves a fusion process. Exocytotic membrane fusion in neurons is achieved by the highly regulated interaction of mainly three proteins, the vesicle protein synaptobrevin and the plasma membrane proteins syntaxin and SNAP25 (synaptosomal-associated protein of 25 kDa), also referred to as SNARE proteins. Using immunofluorescence microscopy we analysed the subcellular distribution of neuronal synaptic proteins and rab3A in resting and stimulated parietal cells from pig and rat. In resting cells all synaptic proteins colocalized with the H+/ K(+)-ATPase trapped in the tubulovesicular compartment. After stimulation, translocated H+/K(+)-ATPase showed a typical canalicular distribution. Syntaxin, synaptobrevin, SNAP25 and rab3A underwent a similar redistribution in stimulated cells and consequently localized to the canalicular compartment. Using immunoprecipitation we found that the SNARE complex consisting of synaptobrevin, syntaxin and SNAP25, which is a prerequisite for membrane fusion in neurons, is also assembled in parietal cells. In addition the parietal cell-derived synaptobrevin could be proteolytically cleaved by tetanus toxin light chain. These data may provide evidence that SNARE proteins and rab3A are functionally involved in the stimulation-induced translocation of the H+/K(+)-ATPase.

Activity-dependent changes of the presynaptic synaptophysin-synaptobrevin complex in adult rat brain.

The vesicular protein synaptobrevin contributes to two mutually exclusive complexes in mature synapses. Synaptobrevin tightly interacts with the plasma membrane proteins syntaxin and SNAP 25 forming the SNARE complex as a prerequisite for exocytotic membrane fusion. Alternatively, synaptobrevin binds to the vesicular protein synaptophysin. It is unclear whether SNARE complex formation is diminished or facilitated when synaptobrevin is bound to synaptophysin. Here we show that the synaptophysin-synaptobrevin complex is increased in adult rat brain after repeated synaptic hyperactivity in the kindling model of epilepsy. Two days after the last kindling-induced stage V seizure the relative amount of synaptophysin-synaptobrevin complex obtained by co-immunoprecipitation from cortical and hippocampal membranes was increased twofold compared to controls. By contrast the relative amounts of various synaptic proteins as well as that of the SNARE complex did not change in membrane preparations from kindled rats compared to controls. The increased amount of synaptophysin-synaptobrevin complex in kindled rats supports the idea that this complex represents a reserve pool for synaptobrevin enabling synaptic vesicles to adjust to an increased demand for synaptic efficiency. We conclude that the synaptophysin-synaptobrevin interaction is involved in activity-dependent plastic changes in adult rat brain.

Potential roles of heterotrimeric G proteins of the endomembrane system.

Heterotrimeric G proteins are recognized as versatile switches linking cell surface receptors to cellular effectors. Beside their location at the plasma membrane G proteins are found on intracellular membranes. Studies with modulators of G protein activity suggest that G proteins associated with organelle membranes are involved in various steps of secretion and vesicular function. In contrast to hormonal responses involving G proteins little is currently known about possible receptors or activators and effectors interacting with intracellular G proteins. This short review focuses on recent developments elucidating the role of organelle-associated G proteins.

The amphicrine pancreatic cell line, AR42J, secretes GABA and amylase by separate regulated pathways.

Treatment of AR42J cells with dexamethasone leads to an enhanced formation of amylase-containing granules and facilitates their regulated secretion. Besides the exocrine properties, AR42J cells possess a specific uptake system for [3H]GABA. The stored GABA can be released upon potassium depolarisation in a Ca(2+)-dependent manner. After treatment with dexamethasone, potassium depolarisation fails to release GABA, but instead causes a Ca(2+)-dependent secretion of amylase. Since vesicles similar to small synaptic vesicles of neurons have been identified in AR42J cells, we suggest that the regulated GABA release is mediated by this vesicle type. It is tentatively speculated that other epithelial cells, which also contain small synaptic vesicles and amino acid neurotransmitters, may release them in a similar fashion.

Reductive chain separation of botulinum A toxin--a prerequisite to its inhibitory action on exocytosis in chromaffin cells.

Cleavage of the disulfide bond linking the heavy and the light chains of tetanus toxin is necessary for its inhibitory action on exocytotic release of catecholamines from permeabilized chromaffin cells [(1989) FEBS Lett. 242, 245-248; (1989) J. Neurochem., in press]. The related botulinum A toxin also consists of a heavy and a light chain linked by a disulfide bond. The actions of both neurotoxins on exocytosis were presently compared using streptolysin O-permeabilized bovine adrenal chromaffin cells. Botulinum A toxin inhibited Ca2+-stimulated catecholamine release from these cells. Addition of dithiothreitol lowered the effective doses to values below 5 nM. Under the same conditions, the effective doses of tetanus toxin were decreased by a factor of five. This indicates that the interchain S-S bond of botulinum A toxin must also be split before the neurotoxin can exert its effect on exocytosis.