Steps in the formation of neurites and synapses studied in cultured leech neurons

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Abstract

Leech neurons in culture have provided novel insights into the steps in the formation of neurite outgrowth patterns, target recognition and synapse formation. Identified adult neurons from the central nervous system of the leech can be removed individually and plated in culture under well-controlled conditions, where they retain their characteristic physiological properties, grow neurites and form specific chemical or electrical synapses. Different identified neurons develop distinctive outgrowth patterns that depend on their identities and on the molecular composition of the substrate. On native substrates, the patterns displayed by these neurons reproduce characteristics from the adult or the developing neurons. In addition, the substrate may induce selective directed growth between pairs of neurons that normally make contact in the ganglion. Upon contact, pairs of cultured leech neurons form chemical or electrical synapses, or both types depending on the neuronal identities. Anterograde and retrograde signals during membrane contact and synapse formation modify the distribution of synaptic terminals, calcium currents, and responses to 5-hydroxytryptamine.

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In vivo regulation of axon extension and pathfinding by growth-cone calcium transients.

N Spitzer, T Gomez (1999)

Growth cones at the tips of extending neurites migrate through complex environments in the developing nervous system and guide axons to appropriate target regions using local cues. The intracellular calcium concentration ([Ca2+]i) of growth cones correlates with motility in vitro, but the physiological links between environmental cues and axon growth in vivo are unknown. Here we report that growth cones generate transient elevations of [Ca2+]i as they migrate within the embryonic spinal cord and that the rate of axon outgrowth is inversely proportional to the frequency of transients. Suppressing Ca2+ transients by photorelease of a Ca2+ chelator accelerates axon extension, whereas mimicking transients with photorelease of Ca2+ slows otherwise rapid axonal growth. The frequency of Ca2+ transients is cell-type specific and depends on the position of growth cones along their pathway. Furthermore, growth-cone stalling and axon retraction, which are two important aspects of pathfinding, are associated with high frequencies of Ca2+ transients. Our results indicate that environmentally regulated growth-cone Ca2+ transients control axon growth in the developing spinal cord.