Cell-type specific induction of cyclo-oxygenase-2 in layer II/III prefrontal cortical neurons mediates stress-induced anxiety phenotypes in mice

The ability of the medial prefrontal cortex (mPFC) to exert top-down control of behavior is affected by stress. The molecular response of mPFC to stress is incompletely understood, however, in part because of the region’s cellular heterogeneity. Here we used single nucleus RNA sequencing (snRNAseq) to map specific molecular cell types within the mPFC and to detect cell-type specific transcriptional changes to foot-shock stress. We identified Ptgs2, encoding cyclo-oxygenase 2, as an important candidate that is upregulated in layer II/III excitatory neurons after stress. Specifically, Ptgs2 was transiently upregulated with shock-induced fear learning and fear expression, along with Bdnf, Nptx2, and Lingo1, in a layer II/III neuronal population marked by the neuronal excitatory gene Slc17a7 and cell-type specific neuropeptide Penk. These dynamic cell-type specific expression patterns identified with snRNAseq were validated with quantitative fluorescent in situ hybridization. Using a pharmacological approach, we found that systemic lumiracoxib, a selective Ptgs2-inhibitor, led to a significant reduction in fear expression. Furthermore, genetic ablation of Ptgs2 in excitatory Camk2a-expressing neurons led to reduced stress-induced anxiety-like behaviors. Together these findings suggest that Ptgs2 is expressed in a dynamic, cell-type specific way in Layer II/III Penk+ neurons in mPFC, and that its role in prostaglandin and /or endocannabinoid regulation within these neurons may be an important mediator of stress-related behavior.

Role of Amygdala-Infralimbic Cortex Circuitry in Glucocorticoid-Induced Facilitation of Auditory Fear Memory Extinction

Purpose: The basolateral amygdala (BLA) and infralimbic area (IL) of medial prefrontal cortex (mPFC) are two inter-connected brain structures that mediate both fear memory expression and extinction. Besides the well-known role of the BLA in the acquisition and expression of fear memory, projections from IL to BLA inhibit fear expression and have a critical role in fear extinction. However, the details of IL-BLA interaction remain unclear. Here, we aimed to investigate the role of functional reciprocal interactions between BLA and IL in mediating fear memory extinction. Methods: Using lidocaine (LID), male rats underwent unilateral or bilateral inactivation of the BLA and then unilateral intra-IL infusion of CORT, prior to extinction training of auditory fear conditioning paradigm. Freezing behavior was reported as an index for the measurement of conditioned fear. Infusions were performed before the extinction training, allowing to examine the effects on fear expression and also further extinction memory. Experiments 1-3 investigated the effects of left or right infusion of CORT into IL, and LID unilaterally into BLA on fear memory extinction. Results: Results showed that intra-IL infusion of CORT in the right hemisphere reduced freezing behavior when administrated before the extinction training. Auditory fear memory extinction was impaired by asymmetric inactivation of BLA and CORT infusion in the right IL; however, the same effect was not observed with symmetric inactivation of BLA. Conclusion: It is concluded that that the IL-BLA neural circuit may provide additional evidence to contribution of this circuit in auditory fear extinction. This study demonstrate dissociable roles for right or left BLA in subserving the auditory fear extinction. Our finding also raise the possibility that left BLA-IL circuitry may contribute in mediating auditory fear memory extinction via underlying mechanisms, however further research is required.

Prefrontal GABAergic Interneurons Gate Long-Range Afferents to Regulate Prefrontal Cortex-Associated Complex Behaviors

Prefrontal cortical GABAergic interneurons (INs) and their innervations are essential for the execution of complex behaviors such as working memory, social behavior, and fear expression. These behavior regulations are highly dependent on primary long-range afferents originating from the subcortical structures such as mediodorsal thalamus (MD), ventral hippocampus (vHPC), and basolateral amygdala (BLA). In turn, the regulatory effects of these inputs are mediated by activation of parvalbumin-expressing (PV) and/or somatostatin expressing (SST) INs within the prefrontal cortex (PFC). Here we review how each of these long-range afferents from the MD, vHPC, or BLA recruits a subset of the prefrontal interneuron population to exert precise control of specific PFC-dependent behaviors. Specifically, we first summarize the anatomical connections of different long-range inputs formed on prefrontal GABAergic INs, focusing on PV versus SST cells. Next, we elaborate on the role of prefrontal PV- and SST- INs in regulating MD afferents-mediated cognitive behaviors. We also examine how prefrontal PV- and SST- INs gate vHPC afferents in spatial working memory and fear expression. Finally, we discuss the possibility that prefrontal PV-INs mediate fear conditioning, predominantly driven by the BLA-mPFC pathway. This review will provide a broad view of how multiple long-range inputs converge on prefrontal interneurons to regulate complex behaviors and novel future directions to understand how PFC controls different behaviors.

Neuromodulation-induced burst firing in parvalbumin interneurons of the basolateral amygdala mediates transition between fear-associated network and behavioral states

Network orchestration of behavioral states involves coordinated oscillations within and between brain regions. The network communication between the basolateral amygdala (BLA) and the medial prefrontal cortex (PFC) plays a critical role in fear expression. Neuromodulatory systems play an essential role in regulating changes between behavioral states, however, a mechanistic understanding of how amygdalar circuits mediate transitions between brain and behavioral states remains largely unknown. Here, we examine the role of Gq-mediated neuromodulation of parvalbumin (PV)-expressing interneurons in the BLA in coordinating network and behavioral states using combined chemogenetics, patch clamp and field potential recordings. We demonstrate that Gq-signaling via hM3D designer receptor and α1 adrenoreceptor activation shifts the pattern of activity of the PV interneurons from tonic to phasic by stimulating a previously unknown, highly stereotyped bursting pattern of activity. This, in turn, generates bursts of inhibitory postsynaptic currents (IPSCs) and phasic firing in BLA principal neurons. The Gq-induced transition from tonic to phasic firing in BLA PV interneurons suppressed amygdalo-frontal gamma oscillations in vivo, consistent with the critical role of tonic PV neuron activity in gamma generation. The suppression of gamma oscillations by hM3D and α1 receptor activation in BLA PV interneurons also facilitated fear memory recall, in line with the inhibitory effect of gamma on fear expression. Thus, our data reveal a BLA parvalbumin neuron-specific neuromodulatory mechanism that mediates the transition to a fear-associated brain network state via regulation of amygdalo-frontal gamma oscillations.