Abstract
Theta oscillations are considered crucial mechanisms in neuronal communication across brain areas, required for consolidation and retrieval of fear memories. One form of inhibitory learning allowing adaptive control of fear memory is extinction, a deficit of which leads to maladaptive fear expression potentially leading to anxiety disorders. Behavioral responses after extinction training are thought to reflect a balance of recall from extinction memory and initial fear memory traces. Therefore, we hypothesized that the initial fear memory circuits impact behavioral fear after extinction, and more specifically, that the dynamics of theta synchrony in these pathways signal the individual fear response. Simultaneous multi-channel local field and unit recordings were obtained from the infralimbic prefrontal cortex, the hippocampal CA1 and the lateral amygdala in mice. Data revealed that the pattern of theta coherence and directionality within and across regions correlated with individual behavioral responses. Upon conditioned freezing, units were phase-locked to synchronized theta oscillations in these pathways, characterizing states of fear memory retrieval. When the conditioned stimulus evoked no fear during extinction recall, theta interactions were directional with prefrontal cortical spike firing leading hippocampal and amygdalar theta oscillations. These results indicate that the directional dynamics of theta-entrained activity across these areas guide changes in appraisal of threatening stimuli during fear memory and extinction retrieval. Given that exposure therapy involves procedures and pathways similar to those during extinction of conditioned fear, one therapeutical extension might be useful that imposes artificial theta activity to prefrontal cortical-amygdalo-hippocampal pathways that mimics the directionality signaling successful extinction recall.
Highlights
Timed neuronal activity is crucial for communication within synaptic networks across brain areas, as required for instance for cognitive tasks and integrative behavioral responses [1,2,3]
We have focused on the first conditioned stimulus (CS)+ presentation, in line with previous studies related to theta oscillations [5,6,7,21,25,26,27]
One-way ANOVA revealed a significant effect of session (R1, R6 and E) on first CS+ elicited freezing (F2,36 = 16.03, p,0.001), and post-hoc multiple comparison (Tukey’s) showed that freezing in R6 and E was significantly decreased compared to revealed that 11.3963.85% (R1) (R1, 62.5663.36%; R6 21.366.21%, p,0.001; E, 31.6565.98%, p,0.001; Figure 2)
Summary
Timed neuronal activity is crucial for communication within synaptic networks across brain areas, as required for instance for cognitive tasks and integrative behavioral responses [1,2,3]. One example is the synchronization at theta frequencies between amygdala and hippocampus during consolidation of fear memories [4,5]. Ventral hippocampal inputs influence anxiety-related activity in mPFC neurons, and synchronization at theta frequencies is involved in this interaction [9,10]. From this data it has been inferred that synchronized theta oscillations selectively recruit neurons to form a fear memory trace, by providing spatiotemporal codes for temporal compression from the rather long time scale of learned behavior down to the milliseconds timescale required for synaptic plasticity and orchestra molecular cascades of memory stabilization [4,11,12,13]
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