Fast voltage-sensitive dye imaging of excitatory and inhibitory synaptic transmission in the rat granular retrosplenial cortex.

Rodent granular retrosplenial cortex (GRS) has dense connections between the anterior thalamic nuclei (ATN) and hippocampal formation. GRS superficial pyramidal neurons exhibit distinctive late spiking (LS) firing property and form patchy clusters with prominent apical dendritic bundles. The aim of this study was to investigate spatiotemporal dynamics of signal transduction in the GRS induced by ATN afferent stimulation by using fast voltage-sensitive dye imaging in rat brain slices. In coronal slices, layer 1a stimulation, which presumably activated thalamic fibers, evoked propagation of excitatory synaptic signals from layers 2-4 to layers 5-6 in a direction perpendicular to the layer axis, followed by transverse signal propagation within each layer. In the presence of ionotropic glutamate receptor antagonists, inhibitory responses were observed in superficial layers, induced by direct activation of inhibitory interneurons in layer 1. In horizontal slices, excitatory signals in deep layers propagated transversely mainly from posterior to anterior via superficial layers. Cortical inhibitory responses upon layer 1a stimulation in horizontal slices were weaker than those in the coronal slices. Observed differences between coronal and horizontal planes suggest anisotropy of the intracortical circuitry. In conclusion, ATN inputs are processed differently in coronal and horizontal planes of the GRS and then conveyed to other cortical areas. In both planes, GRS superficial layers play an important role in signal propagation, which suggests that superficial neuronal cascade is crucial in the integration of multiple information sources.NEW & NOTEWORTHY Superficial neurons in the rat granular retrosplenial cortex (GRS) show distinctive late-spiking (LS) firing property. However, little is known about spatiotemporal dynamics of signal transduction in the GRS. We demonstrated LS neuron network relaying thalamic inputs to deep layers and anisotropic distribution of inhibition between coronal and horizontal planes. Since deep layers of the GRS receive inputs from the subiculum, GRS circuits may work as an integrator of multiple sources such as sensory and memory information.

Current source-density analysis of intracortical circuit in the granular retrosplenial cortex of rats: a possible role in stimulus time buffering.

The rodent granular retrosplenial cortex (GRS) has dense connections with the hippocampal formation and anterior thalamic nuclei. However, functional connectivity within the GRS has not been examined. The aim of this study is to investigate the intracortical circuit of the GRS, including late-spiking (LS) neurons in layers 2 and 3. We conducted extracellular recordings of field potentials from slice preparations of the rat GRS following stimulations of layer 1a and white matter (WM). Current source-density analysis demonstrated that layer 1a stimulation first evoked synaptic current sinks in layer 1 followed by sinks in layers 2-4. These sinks were extinguished by glutamate antagonists. WM stimulation induced long latency synaptic current sinks in layers 2-4 and 6. Thus, signal inputs from the thalamus to layer 1a might be transmitted to layer 5, presumably delayed by LS neurons in layers 2 and 3. According to previous anatomical studies, current sinks in layers 2-4 following WM stimulation were attributed to the horizontal connections of LS neurons. Based on these results we suggest that GRS microcircuitry possibly enables layer 5 neurons to integrate time-delayed thalamic inputs with direct inputs from other brain regions.