The possible role of cyclic nucleotides as second messengers mediating growth cone turning was studied by producing an asymmetric distribution of cyclic nucleotides across the growth cone. A repetitive pulse application method was developed to produce microscopic chemical gradients near the growth cone of embryonic Xenopus neurons in cell culture. When picoliters of a solution containing 20 mM dibutyryl cAMP (dB-cAMP), a membrane-permeable analog of cAMP, were repetitively ejected from a micropipette near the growth cone, neurite growth was consistently directed toward the pipette. Theoretical analysis of the diffusion gradient showed that the neurite is capable of detecting a 10% difference in dB-cAMP concentration across the growth cone. Similar responses were also observed using gradients of the phosphodiesterase inhibitor isobutylmethylxanthine, or of forskolin, which activates adenylate cyclase. Dibutyryl cGMP, however, produced no significant turning. These results suggest that a cytoplasmic gradient of cAMP across the growth cone is sufficient to initiate its turning response, and that cAMP in the growth cone could serve as a second messenger in mediating the action of extracellular guidance cues.
Extracellularly applied steady electric fields of 0.1 to 10 V/cm were found to have marked effects on the neurite growth of single dissociated Xenopus neurons in culture: (1) neurites facing the cathode showed accelerated growth, while the growth of those facing the anode was reduced. Neurites growing relatively perpendicular to the field axis were prompted to curve toward the cathode. (2) More neurites appeared to be initiate from the cathodal side of the cell. (3) The number of neurite-bearing neurons per culture and the average neurite length were increased. These effects are absent in cultures treated with electric fields of similar strength but alternating polarity and cannot be attributed either to a gradient of extracellular diffusible substances or to the flow of culture medium produced by the field. The field effects are reversible: (1) removal of the electric field resulted in the loss of neurite orientation in a few hours and (2) reversal of the polarity of the electric field led to a rapid reversal in the neurite orientation. To determine the cellular loci of these field effects, we treated the neurons with a number of pharmacological agents or altered their ionic environments. Incubation with concanavalin A (Con A) was found to abolish these filed effects completely. Since the binding of Con A to the neuronal surface was shown to prevent field-induced accumulation of the Con A receptors toward the cathodal side of these neurons, our finding is accumulation of the Con A receptors toward the cathodal side of these neurons, our finding is consistent with the notion that cathodal accumulation of growth-controlling surface glycoproteins by the field is the underlying mechanism of the field-induced orientation of neurite growth toward the cathode.
We have studied the spontaneous and nerve-evoked synaptic currents during the initial period of nerve-muscle contact in Xenopus cell cultures. The precise timing of the contact was achieved by physically manipulating embryonic muscle cells into contact with co-cultured spinal neurons. Previous studies have shown that physical contact of the muscle membrane induces pulsatile release of acetylcholine (ACh) from the growth cone of these neurons, resulting in spontaneous synaptic currents (SSCs) in the muscle cell within seconds following the contact. In the present work, we first showed that these SSCs at the manipulated nerve-muscle contacts are similar to those observed at naturally occurring synapses. We then examined the possible cellular mechanisms responsible for the marked variation in SSC amplitude and showed that it most likely results from differences in either the amount of ACh contained in each release event or the extent of close membrane apposition near the release sites. During the first 20 min following the nerve-muscle contact, there was an increase in the frequency and mean amplitude of the SSCs. During a similar period, the evoked synaptic currents (ESCs), which were induced by suprathreshold electrical stimulation of the neuronal soma, also showed an increase in the mean amplitude and a reduction in the delay of onset following the stimulus. These postcontact changes in the efficacy of synaptic transmission may be related to an increase in the total area of close membrane apposition between the nerve and muscle cells. This was suggested by the finding that neurite-muscle adhesion increases over a similar postcontact period. The transition from low- to high-efficacy transmission during the early phase of contact may reflect the process of selective adhesion between the cells, and thus signify the formation of specific synapse. Analysis of the fluctuation in the ESC amplitude at the early nerve-muscle contact suggests that evoked release of ACh occurs as multiples of a quantal unit. However, this unit is apparently related to only a small subpopulation of SSCs of relatively high amplitudes.(ABSTRACT TRUNCATED AT 400 WORDS)
Dissociated neurons from normal and mutant Drosophila larval central nervous system in cell culture
A primary dissociated cell culture of Drosophila larval central nervous system is reported. Divisions of neuroblasts and vigorous outgrowth of neurites could be observed in culture. Within 24 hr cultured cells exhibited characteristic neuronal morphology and unimpaired ability to synthesize and accumulate acetylcholine. This cell culture system renders easy access to experimental analysis of normal neuronal properties and the altered mechanisms in neurological mutants. Single-channel currents induced by acetylcholine and regenerative action potentials were studied in the somata of the dissociated neurons. The appearance of Na channels in these cultured neurons was demonstrated by the cell lethality induced by veratridine and inhibition of the effect by tetrodotoxin. Dissociated neurons from a temperature-sensitive paralytic mutant napts, in which nerve conduction fails at high temperature, were studied in culture. Neuronal growth was not affected by this mutation, nor by tetrodotoxin. However, napts neurons showed greatly reduced sensitivity to veratridine even at 21 degrees C, a temperature at which napts individuals behave normally. This finding indicates expression of the napts phenotype at a level of isolated single cells and provides independent evidence that napts affects Na channel function.
We have studied the fine structure of nerve-muscle contacts during the first few hours of synaptogenesis in embryonic Xenopus cell cultures. The precise timing of contact was achieved by manipulating isolated spherical myocytes (myoballs) into contact with growth cones or neurites of co-cultured spinal neurons. The contacts were shown to be functional by whole-cell voltage-clamp recording of nerve-evoked synaptic currents in the muscle cell. The ultrastructure of these functional contacts was examined by thin-section electron microscopy. In total, 20 nerve-muscle pairs were studied with contact periods ranging from 20 min to 12 hr, during which time a substantial increase in the amplitude of synaptic currents occurred. The structure of noncontacting cells and of nerve-muscle contacts formed between the cells by natural encounters in 1-d-old cultures were also examined in order to identify the features and the time course of morphological differentiation of early functional contacts. Prominent features of the contact area during the first few hours included: close apposition of the nerve and muscle membranes, greater frequency of coated pits and vesicles, and thickening of postsynaptic muscle membrane. Occasionally, clusters of clear vesicles occurred near presynaptic membrane, but no further sign of active zone differentiation was observed. In comparison, definitive active zone structure, well-formed extracellular basal lamina, and widened cleft were seen in natural contacts less than 24 hr old. This study of the identified functional contacts may help us to understand the structural basis for early nerve-muscle interaction and the functional significance of various synaptic specializations.
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