Distinct modulation of I h by synaptic potentiation in excitatory and inhibitory neurons
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Selective modifications in the expression or function of dendritic ion channels regulate the propagation of synaptic inputs and determine the intrinsic excitability of a neuron. Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels open upon membrane hyperpolarization and conduct a depolarizing inward current (I h ). HCN channels are enriched in the dendrites of hippocampal pyramidal neurons where they regulate the integration of synaptic inputs. Synaptic plasticity can bidirectionally modify dendritic HCN channels in excitatory neurons depending on the strength of synaptic potentiation. In inhibitory neurons, however, the dendritic expression and modulation of HCN channels is largely unknown. In this study, we systematically compared the modulation of I h by synaptic potentiation in hippocampal CA1 pyramidal neurons and stratum Radiatum (sRad) interneurons. I h properties were similar in inhibitory and excitatory neurons and contributed to resting membrane potential and action potential firing. We found that in sRad interneurons, HCN channels were downregulated after synaptic plasticity, irrespective of the strength of synaptic potentiation. This suggest differential regulation of I h in excitatory and inhibitory neurons, possibly signifying their distinct role in network activity.
Significance statement
Learning reflects a change in the way information is processed in neuronal circuits. This occurs via changes in synaptic connections and via alterations of intrinsic excitability of neurons. Here we examined how synaptic changes affect properties of HCN channels, which are important ion channels for intrinsic excitability. We found that strong synaptic potentiation leads to opposite changes in HCN channels in CA1 pyramidal neurons and sRad interneurons. We speculate that this reflects their differential role in the CA1 network. An upregulation of HCN channels in pyramidal neurons results in a decrease in their excitability, which limits overall network excitation. In contrast, sRad interneurons show downregulation of I h , and therefore an increased excitability after strong synaptic activation, which will strengthen feedforward inhibition and sharpen activity patterns.
