Although feed-forward inhibition onto Purkinje cells was first documented forty years ago, we still understand little of how inhibitory interneurons contribute to cerebellar function in behaving animals. Using a mouse line (PC-Δγ2) in which GABAA receptor-mediated synaptic inhibition was selectively removed from Purkinje cells, we examined how feed-forward inhibition from molecular layer interneurons regulates adaptation of the vestibulo-ocular reflex. Whereas impairment of baseline motor performance was relatively mild, the ability to adapt the phase of the vestibulo-ocular reflex and to consolidate gain adaptations, was strongly compromised. Purkinje cells showed abnormal patterns of simple spikes, both during and in the absence of evoked compensatory eye movements. Based on modeling of the experimental data, we propose that feed-forward inhibition, by controlling the fine scale patterns of Purkinje cell activity, enables the induction of plasticity in neurons of the cerebellar and vestibular nuclei.
Neuronal plasticity is an important process for learning, memory and complex behaviour. Rapid remodelling of the actin cytoskeleton in the postsynaptic compartment is thought to have an important function for synaptic plasticity. However, the actin-binding proteins involved and the molecular mechanisms that in vivo link actin dynamics to postsynaptic physiology are not well understood. Here, we show that the actin filament depolymerizing protein n-cofilin is controlling dendritic spine morphology and postsynaptic parameters such as late long-term potentiation and long-term depression. Loss of n-cofilin-mediated synaptic actin dynamics in the forebrain specifically leads to impairment of all types of associative learning, whereas exploratory learning is not affected. We provide evidence for a novel function of n-cofilin function in synaptic plasticity and in the control of extrasynaptic excitatory AMPA receptors diffusion. These results suggest a critical function of actin dynamics in associative learning and postsynaptic receptor availability.
Glycine receptors (GlyRs) and their role in retinal circuitry were analyzed immunocytochemically in the rat retina. Specific antibodies against the alpha 1 subunit of the GlyR and against the GlyR-associated protein gephyrin, respectively, were used. In the inner plexiform layer (IPL), both antibodies produced a punctate label that was shown by electron microscopy to occur at synapses. Gephyrin-like immunoreactivity (-LI) was more widely distributed, indicating that gephyrin might also occur at nonglycinergic synapses. At the ultrastructural level, gephyrin-LI was found at the cytoplasmic face of postsynaptic membranes of amacrine and ganglion cells, but was never detected in bipolar cell axons. Immunoreactivity for the alpha 1 subunit was concentrated in the cleft of conventional synapses made by amacrine cell processes onto ganglion cell dendrites and cone bipolar axons. The latter synapses differ from other glycinergic synapses since they are not labeled by the antibody against gephyrin used in this study. In order to identify the type of bipolar cell involved in these synapses, the distribution of the alpha 1 subunit was compared with that of recoverin-immunoreactive cone bipolar cells and with that of parvalbumin-immunoreactive All-amacrine cells. Double-label immunofluorescence showed that, in the outer part of the IPL, 75% of the alpha 1-immunoreactive puncta were colocalized with recoverin-positive bipolar cell axons and 71% of the alpha 1-immunoreactive puncta were colocalized with parvalbumin-positive All-amacrine processes. Hence, the alpha 1 subunit of the GlyR is present at the chemical synapses established by All-amacrine cells with OFF-cone bipolar cells and OFF-ganglion cells. These synapses play a key role in the transmission of scotopic signals through the OFF-channel of the rod pathway.
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