At intermediate distances (10-30 μm), CF responses were still enh

At intermediate distances (10-30 μm), CF responses were still enhanced on average, but to a lower degree than at ROI-1. In both types of experiments,

local amplification of dendritic CF responses was used as a measure of excitability changes, because CF signaling provides large, widespread signals that can be recorded at multiple dendritic locations. In addition to its use as an indicator of dendritic plasticity, this location-specific amplification process is physiologically interesting, because an enhancement of the instructive CF signal and the associated calcium transient could locally affect the LTD/LTP balance at nearby PF synapses (Ohtsuki et al., 2009). It has previously been demonstrated in vivo that brief high-frequency bursts constitute Everolimus a typical granule cell response to sensory stimulation (Chadderton et al., 2004).

Thus, the PF burst pattern used (5 pulses at 50 Hz; repeated at 5 Hz for 3 s) likely provides a physiological input pattern, suggesting that the spatial Selleckchem OSI744 restriction of dendritic plasticity reported here (on average no amplification at distances of > 30 μm from the conditioned site) reflects a physiologically relevant degree of localization. It should be noted, however, that this finding does not exclude the possibility that dendritic excitability changes can be even more MycoClean Mycoplasma Removal Kit spatially restricted. In CA1 hippocampal pyramidal neurons, local changes in A-type K channels result in long-term adjustments of branch coupling strength that have been suggested to play a role in the storage of specific input patterns (Losonczy et al., 2008 and Makara et al., 2009). Another study showed that A-type K channels and SK channels

play complementary roles in limiting dendritic responses to the stimulated branch (Cai et al., 2004). However, there is a fundamental difference in the way that SK channels and voltage-gated K channels control dendritic responsiveness. SK channels are exclusively activated by calcium and, in turn, regulate the amplitude and kinetics of EPSPs and curtail spine calcium transients (Belmeguenai et al., 2010, Lin et al., 2008 and Ngo-Anh et al., 2005). Thus, SK channel activation is part of a negative feedback loop that is closely tied to calcium signaling and provides a unique brake mechanism to influence dendritic processing. Our data provide the first demonstration that the gain of this dendritic brake mechanism may be adjusted in an activity-dependent way. Moreover, we show that this form of plasticity of dendritic IE can be restricted to selectively activated compartments of the dendrite.

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