In contrast, spontaneous in vivo activity leads to elevated levels of NO, which undoubtedly contribute to nitrergic signaling and, therefore, might underlie the here-observed current potentiation following synaptic conditioning. This signaling reported here relies on phosphorylation, and inhibition of PP1 and PP2A with okadaic acid (OA; 50 nM) had no effect on Kv potentiation induced
by NO donors (Figure S5A). Interestingly, inhibition of PKC (Ro31-7549 or GF109203X) completely abolished NO-induced Kv2 potentiation CAL-101 mw (Figure S5A). Thus, the NO-mediated Kv2 enhancement requires both PKC and the classical NO pathway through activation of guanylyl cyclase and PKG (Figure S5B). So what is the ABT-199 datasheet physiological relevance of switching between delayed rectifiers? Kv3 channels have fast activation and deactivation kinetics and so turn on and off quickly. Kv2 channels have slower kinetics, allowing cumulative activation during periods of high synaptic activity and leading to enhanced membrane hyperpolarization, thereby encouraging recovery of sodium channels from inactivation (Johnston et al., 2008). This suggests functional relevance as a homeostatic gain control mechanism, where Kv2
dominance improves/maintains the dynamic range of signaling with increasing activity. To test this, we examined the ability of synaptic conditioning to modulate transmission fidelity across a range of physiological frequencies during long-lasting trains of synaptic stimulation (30 s, 100 Hz Poisson-distributed ISIs). Initial firing in the 30 s train (not shown) showed high fidelity (Hennig et al., 2008), but during such long trains the firing probability declined, so that the majority of EPSPs failed to trigger APs by the end of the train (Figure 7A, black). Following synaptic conditioning, the number of failures (Figure 7A, PC, red, black
arrowheads) was Diflunisal reduced in control CBA mice, whereas no improvement was observed in Kv2.2 KO mice (Figure 7B, PC, red). This cannot be solely explained by reduced excitability, but the observed cumulative interspike hyperpolarization of 7.9 ± 1.3 mV in WT mice (Figure 7D; p < 0.0001, one-way ANOVA with posttest) allows greater recovery of Na+ channels from inactivation (Johnston et al., 2008) and thereby increased output/input fidelity (Figure 7E). On the other hand, Kv2.2 KO and nNOS KO mice showed no hyperpolarization (Figures 7B–7D) and no improvement of fidelity (Figure 7E), indicating that Kv2.2 and nNOS signaling are required to allow reliable transmission across this synapse. Although low-frequency firing (100 Hz Poisson train) was well maintained in Kv2.2 KO and nNOS KO mice (Figures 7B and 7C) due to the lack of NO signaling and subsequent functional dominance of Kv3, high-frequency fidelity required Kv2.2 currents and NO signaling.