Vesicles slide on a synaptic body
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《细胞学杂志》
Roberts/Elsevier
In vision and hearing, all-or-nothing action potentials are insufficient because they cannot transmit small changes in intensity. Thus, neurons in these areas use the synaptic body (SB), an unusual presynaptic organelle that is specialized for continuous transmitter release. This requires a lasting supply of synaptic vesicles. A new article by David Lenzi, William Roberts (University of Oregon, Eugene, Oregon), and colleagues suggests that the SB is a source of these vesicles.
The distribution of vesicles on the SB changes sharply in response to stimulation, as seen in electron tomography maps of inhibited versus strongly stimulated synapses. Vesicles near the plasma membrane side of the SB were released most rapidly. This generated a gradient of vesicles, most of which remained on the cytoplasmic face of the SB. "The redistribution is what you expect if vesicles bind to the synaptic body and then move along to reach the release site," says Roberts.
After stimulation, fewer vesicles were found at the plasma membrane just below the SB than in a surrounding ring. Thus, stimulation establishes vesicle gradients on both the SB and the plasma membrane that may be sources for ongoing release. Roberts hopes to determine whether the movement of vesicles down the SB is passive or is powered by a transporter. So far, only three SB components are known, which limits the number of proteins that could be tested for transporter activity.
Reference:
Lenzi, D., et al. 2002. Neuron. 36:649–659.(A gradient of synaptic vesicles (yellow))
In vision and hearing, all-or-nothing action potentials are insufficient because they cannot transmit small changes in intensity. Thus, neurons in these areas use the synaptic body (SB), an unusual presynaptic organelle that is specialized for continuous transmitter release. This requires a lasting supply of synaptic vesicles. A new article by David Lenzi, William Roberts (University of Oregon, Eugene, Oregon), and colleagues suggests that the SB is a source of these vesicles.
The distribution of vesicles on the SB changes sharply in response to stimulation, as seen in electron tomography maps of inhibited versus strongly stimulated synapses. Vesicles near the plasma membrane side of the SB were released most rapidly. This generated a gradient of vesicles, most of which remained on the cytoplasmic face of the SB. "The redistribution is what you expect if vesicles bind to the synaptic body and then move along to reach the release site," says Roberts.
After stimulation, fewer vesicles were found at the plasma membrane just below the SB than in a surrounding ring. Thus, stimulation establishes vesicle gradients on both the SB and the plasma membrane that may be sources for ongoing release. Roberts hopes to determine whether the movement of vesicles down the SB is passive or is powered by a transporter. So far, only three SB components are known, which limits the number of proteins that could be tested for transporter activity.
Reference:
Lenzi, D., et al. 2002. Neuron. 36:649–659.(A gradient of synaptic vesicles (yellow))