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Functional organization of a cortical-medullary neural circuit mediating organismal adaptation to stress

Abstract

Hindbrain regions responsible for epinephrine and norepinephrine production are critical for orchestrating stress responses, maintaining physiological equilibrium and integrating afferent information. The nuclei central to hindbrain epinephrine and norepinephrine production, create a neural network that interfaces with forebrain and spinal cord regions, facilitating the integration of neuroendocrine and autonomic functions. Despite significant strides in our comprehension of stress response systems, questions concerning the roles of sex, stress history, and circuit mechanisms endure. In this study, we unveil and characterize a prefrontal-medullary circuit crucial for the suppression of stress responses. First, anterograde and retrograde tract-tracing studies demonstrated a stress-reactive vmPFC-RVLM circuit. Activation of this vmPFC-RVLM circuit mitigates glucocorticoid stress reactivity in both males and females, by targeting non-catecholaminergic neurons. Therefore, vmPFC-RVLM circuit activation may utilize local inhibitory neurons to limit catecholaminergic activation. To better understand how chronic stress affects the medulla, we explored the impact of chronic stress on signaling machinery and revealed elevated tyrosine hydroxylase (TH) levels in both male and female rats following chronic variable stress (CVS). To understand how CVS interacts with the vmPFC-RVLM circuit, we used an intersectional TeLC (Tetanus toxin - light chain) approach to disrupt the circuit and evaluate multiple stress response systems. In males, circuit disruption and CVS largely left behavioral and cardiovascular stress reactivity unaltered, however, some neuroendocrine endpoints were affected. Conversely, females exposed to circuit disruption and chronic stress exhibited heightened stress reactivity in glycemic, corticosterone, and arterial pressure responses, coupled with avoidant-like behaviors. These findings underscore the sex-specific necessity of the vmPFC-RVLM circuit in countering chronic stress-related outcomes, emphasizing a greater protective role in females relative to males. To gain deeper insights into the role of vmPFC inputs to the RVLM in females, we once again utilized a circuit-based TeLC approach, employing in situ hybridization (ISH) coupled with immunohistochemistry (IHC) to assess TH and phenylethanolamine N-methyltransferase (PNMT) transcript density across various VLM subregions. Notably, the TeLC-induced elevation of PNMT expression in females suggests that disrupting this circuit could potentially enhance epinephrine production by RVLM neurons, potentially intensifying stress reactivity post-CVS. This comprehensive study demonstrated the critical role of the vmPFC-RVLM circuit in modulating stress responses and revealing female-specific effects in mitigating physiological, behavioral, and transcriptional outcomes after chronic stress. These findings emphasize the significance of the vmPFC-RVLM circuit in managing stress reactivity in the context of chronic stress and identify the circuit as a potential candidate for reducing stress responding.

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