Abstract
In humans, prefrontal cortical areas are known to support executive functions. In mice, these functions are mediated by homologous regions in the medial prefrontal cortex (mPFC). Executive processes are critically dependent on optimal levels of dopamine (DA), but the cellular mechanisms of DA modulation are incompletely understood. Stable patterns of neuronal activity may be sensitive to frequency‐dependent changes in synaptic transmission. We characterized the effects of D2 receptor (D2R) activation on short‐term excitatory postsynaptic potential (EPSP) dynamics evoked at varying frequencies in the two subtypes of layer V pyramidal neurons in mouse mPFC. We isolated NMDA receptor and non‐NMDA receptor‐mediated components of EPSP trains evoked by stimulating fibers within layer V or layer I. All significant effects of D2 receptor activation were confined to type I (corticopontine) cells. First, we found that with layer I stimulation, D2R activation reduces the amplitude of NMDAR‐mediated EPSPs, with no effect on facilitation or depression of these responses at lower frequencies, but leading to facilitation with high frequency stimulation. Further, the non‐NMDA component also underwent synaptic depression at low frequencies. Second, with layer V stimulation, D2R activation had no effect on NMDA or non‐NMDA receptor‐mediated EPSP components. Overall, our results suggest that D2R activation may modulate memory functions by inhibiting ‘top‐down’ influences from apical tuft inputs activated at low frequencies, while promoting ‘top‐down’ influences from inputs activated at higher frequencies. These data provide further insight into mechanisms of dopamine's modulation of executive functions.
Highlights
In humans, prefrontal cortical (PFC) areas are known to support goal-directed behaviors, mediating a variety of functions that render behavior more flexible in the face of changing environmental demands
Considered in the context of a circuit with recurrent connections, here we explore phenomena relevant to the hypothesis that layer-specific, frequency-dependent short-term synaptic dynamics and their modulation by dopamine play a significant role in generating persistent activity observed in prefrontal cortical networks during memory-related tasks
We studied the effects of D2 receptor activation on isolated NMDA receptor (NMDAR) and non-NMDAR-mediated components of excitatory postsynaptic potential (EPSP) evoked over a range of frequencies that mimic high frequency bursting, in layer V pyramidal cell subtypes
Summary
Prefrontal cortical (PFC) areas are known to support goal-directed behaviors, mediating a variety of functions that render behavior more flexible in the face of changing environmental demands. They hypothesize that D2-receptors, located only on type I cells, may play a critical role in enhancing outputs to subcortical brain regions This differential expression pattern of dopaminergic receptors on layer V pyramidal subtypes suggests that dopamine has the ability to differentially regulate these pyramidal cell subtypes. The intent of this study was to describe the overall effects of quinpirole on non-NMDA and NMDA receptor-mediated, frequency-dependent synaptic dynamics in the two major dendritic compartments of mPFC layer V pyramids, without addressing subcellular mechanisms of D2 receptor modulation. Some of these results have been presented previously in abstract form (Leyrer-Jackson and Thomas 2016)
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