Homeostatic signaling: the positive side of negative feedback

G Turrigiano - Current opinion in neurobiology, 2007 - Elsevier
Current opinion in neurobiology, 2007Elsevier
Synaptic homeostasis provides a means for neurons and circuits to maintain stable function
in the face of perturbations such as developmental or activity-dependent changes in
synapse number or strength. These forms of plasticity are thought to utilize negative
feedback signaling to sense some aspect of activity, compare this with an internal set point,
and then adjust synaptic properties to keep activity close to this set point. However, the
molecular identity of these signaling components has not been firmly established. Recent …
Synaptic homeostasis provides a means for neurons and circuits to maintain stable function in the face of perturbations such as developmental or activity-dependent changes in synapse number or strength. These forms of plasticity are thought to utilize negative feedback signaling to sense some aspect of activity, compare this with an internal set point, and then adjust synaptic properties to keep activity close to this set point. However, the molecular identity of these signaling components has not been firmly established. Recent work suggests that there are likely to be multiple forms of synaptic homeostasis, mediated by distinct signaling pathways and with distinct expression mechanisms. These include presynaptic forms that depend on retrograde signaling to presynaptic Ca2+ channels, and postsynaptic forms influenced by BDNF, TNFα and Arc signaling. Current challenges include matching signaling elements to their functions (i.e. as detectors of activity, as part of the set-point mechanism and/or as effectors of synaptic change), and fitting these molecular candidates into a unified view of the signaling pathways that underlie synaptic homeostasis.
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