1. Reliable methods for establishing fetal mouse spinal cord (SC) and dorsal root ganglion (DRG) cells in long term (greater than 1 mo) dissociated cell cultures are described. These cells have been studied by morphologic and intracellular electrophysiologic techniques. 2. Cells studied electrophysiologically can be relocated after preparation for electron microscopy and examined in thin sections. The electron microscope shows that the surface membranes of these cells were directly accessible to the culture medium. The surfaces of SC cells were studded with synaptic boutons, whereas the DRG cell surfaces generally had none. 3. Current-voltage relationships and linear electrotonic properties of the neurons are described. Delayed and anomalous rectification were seen in both cell types. The length of SC cell dendrites was about one characteristic electrotonic length, while little or no contribution of the relatively sparse DRG cell processes was seen in the transient responses of the DRG cells. 4. Postspike and posttetanic hyperpolarizations in DRG cells were due to a surface membrane conductance increase; this was probably primarily an increase in K+ conductance. Post-activation hyperpolarization in SC cells was primarily due to activation of an electrogenic Na+ pump.
Botulinum neurotoxins (BoNTs) act within the synaptic terminal to block neurotransmitter release. The toxin enters the neuron by binding to neuronal membrane receptor(s), being taken up into an endosome-like compartment, and penetrating the endosome membrane via a pH-dependent translocation process. Once within the synaptic cytoplasm, BoNT serotypes A and E cleave separate sites on the C-terminus of the neuronal protein SNAP-25, one of the SNARE proteins required for synaptic vesicle fusion. In this study, we measured the effect of brief toxin exposure on SNAP-25 proteolysis in neuronal cell cultures as an indicator of toxin translocation. The results indicate that (1) uptake of both BoNT-A and -E is enhanced with synaptic activity induced by K+ depolarization in the presence of Ca2+ and (2) translocation of BoNT-A from the acidic endosomal compartment is slow relative to that of BoNT-E. Polyclonal antisera against each toxin protect cells when applied with the toxin during stimulation but has no effect when added immediately after toxin exposure, indicating that toxin endocytosis occurs with synaptic activity. Both serotypes cleave SNAP-25 at concentrations between 50 pM and 4 nM. IC50 values for SNAP-25 cleavage are approximately 0.5 nM for both serotypes. Inhibition of the pH-dependent translocation process by pretreating cultures with concanamycin A (Con A) prevents cleavage of SNAP-25 with IC50 values of approximately 25 nM. Addition of Con A at times up to 15 min after toxin exposure abrogated BoNT-A action; however, addition of Con A after 40 min was no longer protective. In contrast, Con A inhibited, but did not prevent, translocation of BoNT-E even when added immediately after toxin exposure, indicating that pH-dependent translocation of BoNT-E is rapid relative to that of BoNT-A. This study demonstrates that uptake of both BoNT-A and -E is enhanced with synaptic activity and that translocation of the toxin catalytic moiety into the cytosol occurs at different rates for these two serotypes.
Primary dissociated fetal mouse spinal cord cultures were used to study the mechanisms underlying the differences in persistence of botulinum neurotoxin A (BoNT/A) and botulinum neurotoxin/E (BoNT/E) activities. Spinal cord cultures were exposed to BoNT/A (0.4 pM) for 2^3 days, which converted approximately half of the SNAP-25 to an altered form lacking the final nine C-terminal residues. The distribution of toxindamaged to control SNAP-25 remained relatively unchanged for up to 80 days thereafter. Application of a high concentration of BoNT/E (250 pM) either 25 or 60 days following initial intoxication with BoNT/A converted both normal and BoNT/ A-truncated SNAP-25 into a single population lacking the final 26 C-terminal residues. Excess BoNT/E was removed by washout, and recovery of intact SNAP-25 was monitored by Western blot analysis. The BoNT/E-truncated species gradually diminished during the ensuing 18 days, accompanied by the reappearance of both normal and BoNT/A-truncated SNAP-25. Return of BoNT/A-truncated SNAP-25 was observed in spite of the absence of BoNT/A in the culture medium during all but the first 3 days of exposure. These results indicate that proteolytic activity associated with the BoNT/A light chain persists inside cells for s 11 weeks, while recovery from BoNT/E is complete in 6 3 weeks. This longer duration of enzymatic activity appears to account for the persistence of serotype A action.z 1999 Federation of European Biochemical Societies.
A fundamental difference between short-term and long-term forms of synaptic plasticity is the dependence on transcription and translation of new genes. Using organotypic cultures of hippocampal slices, we have investigated whether the modulation of synapses by brain-derived neurotrophic factor (BDNF) also requires protein synthesis. Long-term treatment of hippocampal slice cultures with BDNF increased the number of docked vesicles, but not that of reserve pool vesicles, at CA1 excitatory synapses. BDNF also increased the levels of the vesicle proteins synaptophysin, synaptobrevin, and synaptotagmin, without affecting the presynaptic membrane proteins syntaxin and SNAP-25, or the vesicle-binding protein synapsin-I. The increase in synaptophysin and synaptobrevin expression was moderate (2-fold) and occurred within 6 h after BDNF application. In contrast, synaptotagmin expression took 24 h to reach maximum levels (5-fold). The delayed increase in synaptotagmin was blocked by protein synthesis inhibitors, while the early increase in synaptophysin and synaptobrevin was not. Moreover, the BDNF-induced increase of synaptotagmin was blocked by inhibiting the cAMP/ protein kinase A (PKA) pathway. However, BDNF did not activate PKA, and application of a PKA activator did not mimic the BDNF effect. Taken together, these results suggest a novel, protein synthesis-dependent form of BDNF modulation that requires cAMP gating.As the cellular basis for learning and memory, two forms of synaptic plasticity have been subjects of intensive study: shortterm changes in synaptic strength within minutes and hours, and long-term modulation of the structure and function of synapses over the course of days. In the mammalian hippocampus, a single high-frequency stimulation of afferent fibers elicits an early phase of long-term potentiation (E-LTP) 1 lasting for 2-3 h, while repeated (3-4 times) high-frequency stimulation results in long-lasting, late phase LTP (L-LTP) that lasts as long as the recordings can be maintained (1). Similar shortand long-term forms of synaptic plasticity have been observed in the sea slug Aplysia (2) and the fruit fly Drosophila (3, 4). A single application of the neuromodulator serotonin facilitates synaptic transmission at these synapses for a few hours. In contrast, 4 -5 repeated applications of serotonin elicit a longterm facilitation that lasts for days. These forms of short-and long-term facilitation of synaptic transmission are thought to underlie short-and long-term sensitization, a simple form of learning and memory (2). Similarly, brief training of the fruit fly Drosophila results in short-term memory, while repeated, spaced training leads to long-term memory formation (3, 4). A unique feature sets long-term modulation apart from shortterm plasticity: its dependence on protein synthesis (1-3). It has been proposed that repeated stimulation leads to a cAMPdependent, sustained phosphorylation of the transcription factor CREB (cAMP response element binding protein), which in turn triggers the expression ...
A noninvasive method of electric stimulation was used in cell culture preparations to determine the effects of patterned electrical activity on the morphology and motility of mammalian central nervous system growth cones. Neurites from dorsal root ganglion (DRG) neurons of fetal mice were allowed to grow under the barrier of an insert placed in culture dishes. The insert confined the cell bodies within separate experimental and control compartments, and provided a means of exciting action potentials in the growing neurites by extracellular current pulses delivered across the barrier. A phasic pattern of stimulation caused immediate retraction of the filopodia and lamellipodium. Further outgrowth was halted and in many cases retraction of the neurite ensued. No changes in morphology or growth cone motility were evoked by electric stimulation when action potentials were blocked with 1 microM tetrodotoxin (TTX). These effects depended on the rate, pattern, and duration of stimulation. Phasic stimulation was more effective than stimulation with the same number of impulses delivered at a constant frequency. An important new observation was that cultures exposed to phasic stimulation for several hours contained actively growing neurites with normal growth cones which were insensitive to the stimulus. This apparent accommodation in neurites exposed to chronic stimulation may involve processes that regulate calcium conductance or buffering. Cessation of neurite outgrowth by action potentials could represent one mechanism linking morphological and functional characteristics in the developing CNS of mammals, by stabilizing the outgrowth of neurites forming appropriate synaptic contacts and leading to the retraction of growth cones from collaterals that have not formed appropriate contacts at the time the neuron enters into a functionally active circuit.
Clostridial neurotoxins are zinc endopeptidases that block neurotransmission and have been shown to cleave, in vitro, specific proteins involved in synaptic vesicle docking and/or fusion. We have used immunohistochemistry and immunoblotting to demonstrate alterations in toxin substrates in intact neurons under conditions of toxin-induced blockade of neurotransmitter release. Vesicle-associated membrane protein, which colocalizes with synaptophysin, is not detectable in tetanus toxin-blocked cultures. Syntaxin, also concentrated in synaptic sites, is cleaved by botulinum neurotoxin C. Similarly, the carboxyl terminus of the synaptosomal-associated protein of 25 kDa (SNAP-25) is not detectable in botulinum neurotoxin A-treated cultures. Unexpectedly, tetanus toxin exposure causes an increase in SNAP-25 immunofluorescence, reflecting increased accessibility of antibodies to antigenic sites rather than increased expression of the protein. Furthermore, botulinum neurotoxin C causes a marked loss of the carboxyl terminus of SNAP-25 when the toxin is added to living cultures, whereas it has no action on SNAP-25 in vitro preparations. This study is the first to demonstrate in functioning neurons that the physiologic response to these toxins is correlated with the proteolysis of their respective substrates. Furthermore, the data demonstrate that botulinum neurotoxin C, in addition to cleaving syntaxin, exerts a secondary effect on SNAP-25.
Abstract. The developmental regulation of neuronal survival by vasoactive intestinal peptide (VIP) was investigated in dissociated spinal cord-dorsal root ganglion (SC-DRG) cultures. Previous studies demonstrated that VIP increased neuronal survival in SC-DRG cultures when synaptic transmission was blocked with tetrodotoxin (TTX). This effect was further investigated to determine if VIP acted directly on neurons or via nonneuronal cells. For these studies, SC-DRG cells were cultured under conditions designed to provide preparations enriched for a particular cell type: astrocyte-enriched background cell (BG) cultures, meningeal fibroblast cultures, standard mixed neuron-nonneuron (STD) cultures, and neuronenriched (N) cultures. Addition of 0.1 nM VIP to TTX-treated STD cultures for 5 d prevented the TTXmediated death and the death that occurred naturally during development in culture, whereas the same treatment on N cultures did not prevent neuronal cell death. Conditioned medium from VIP-stimulated BG cultures prevented neuronal cell death when added to the medium (10 % of total volume) of N cultures treated with TTX. The same amount of conditioned medium from BG cultures that were not treated with VIP had no protective action on N cultures. Conditioned medium from N or meningeal fibroblast cultures, either with or without VIP treatment, did not prevent TTX-mediated cell death in N test cultures. These data indicate that VIP increases the availability of neurotrophic survival-promoting substances derived from nonneuronal cultures, the most likely source being astroglial cells. This study suggests that VIP has a role in mediating a neuron-glia-neuron interaction that influences the trophic regulation of neuronal survival.N 'EtJRO~AL cell death is characteristic of most developing neural systems in vertebrates. The extent (30-80%) of neuronal death that occurs during development indicates that the regulation of this process is of fundamental importance to the determination of nervous system structure (see Berg, 1982). Although a great deal of descriptive data has been reported concerning the magnitude and ubiquity of this neuronal cell loss, little is known of the mechanism that regulates the process during development. It is clear that electrical activity plays an important role in determining neuronal survival during this regressive phase of development. For example, blockage of electrical activity with ~t-bungarotoxin attenuates the naturally occuring cell death in spinal motorneurons (Pittman and Oppenheim, 1978) and in trochlear nucleus in vivo (Creazzo and Sohal, 1979).Studies with cultured spinal cord-dorsal root ganglion (SC-DRG) ~ neurons have shown that during development in 1. Abbreviations used in this paper: BG, astrocyte-enriched background; GFAP, glial fibrillary acidic protein; N, neuronal; NF, neurofilament protein; NSE, neuron-specific enolase; SC-DRG, spinal cord-dorsal root ganglion; STD, standard cultures composed of neurons and nonneuronal cells; TTX, tetrodotoxin; VIP, vasoactive intestinal ...
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