Prepronociceptin-Expressing Neurons in the Bed Nucleus of the Stria Terminalis Signal Escape Behavior

IF 4 Q2 NEUROSCIENCES

Biological psychiatry global open science Pub Date : 2025-05-22 DOI:10.1016/j.bpsgos.2025.100538

Maria M. Ortiz-Juza , Randall L. Ung , Sophia M. Hegel , Ayden L. Ring , Noah W. Miller , Ruben A. Garcia-Reyes , Hiroshi Nomura , Hiroyuki K. Kato , Nicolas C. Pégard , Jose Rodriguez-Romaguera

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Abstract

Background

Dysregulation in neural circuits that encode arousal responses to aversive stimuli is thought to contribute to changes in motivated behaviors associated with neuropsychiatric disorders. However, the relationship between arousal and motivation remains poorly understood. We previously identified that prepronociceptin-expressing neurons in the bed nucleus of the stria terminalis (Pnoc^BNST neurons) modulate rapid physiological arousal responses to a motivationally salient aversive odor. However, whether Pnoc^BNST neurons also signal behavioral actions triggered by an aversive odor is still unknown.

Methods

In this study, we investigated the role of Pnoc^BNST neurons in signaling behavioral responses to an aversive odor. We leveraged miniaturized head-mounted microscopes to monitor the calcium activity of Pnoc^BNST neurons in vivo while freely behaving mice performed an odor preference test.

Results

We found that the bulk activity of Pnoc^BNST neurons increased as mice approached an aversive odor. Single-cell analyses revealed heterogeneity in response dynamics within the Pnoc^BNST neuronal population upon initial exposure to the odor. Subsequent analysis revealed that the response dynamics of Pnoc^BNST neurons that showed excitation when mice were in close proximity to the aversive odor were due to the initiation of darting away from the odor.

Conclusions

These results highlight a novel role of Pnoc^BNST neurons to signal escape behavior in response to an aversive stimulus. This, in combination with our previous findings that Pnoc^BNST neurons encode arousal responses, supports a neurobiological relationship of arousal and motivation within extended amygdala circuits.

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终纹床核中表达pronocceptin的神经元信号逃逸行为

对厌恶刺激的唤醒反应进行编码的神经回路的失调被认为有助于与神经精神疾病相关的动机行为的改变。然而，唤起和动机之间的关系仍然知之甚少。我们之前发现，在终纹床核中表达pronociceptin的神经元（pnobnst神经元）可以调节对动机显著的厌恶气味的快速生理唤醒反应。然而，pnobnst神经元是否也会发出由厌恶气味触发的行为信号仍然未知。方法在这项研究中，我们研究了pnobnst神经元在对厌恶气味的行为反应信号传导中的作用。我们利用微型头戴显微镜来监测pnobnst神经元的钙活性，同时自由行为的小鼠进行气味偏好测试。结果我们发现，当小鼠接近厌恶气味时，pnobnst神经元的总体活性增加。单细胞分析揭示了pnobnst神经元群体在初次接触气味时反应动力学的异质性。随后的分析表明，当小鼠靠近令人厌恶的气味时，pnobnst神经元表现出兴奋的反应动力学是由于开始远离气味而引起的。这些结果突出了pnobnst神经元在对厌恶刺激发出逃避行为信号方面的新作用。这与我们之前关于pnobnst神经元编码唤醒反应的发现相结合，支持了在扩展的杏仁核回路中唤醒和动机的神经生物学关系。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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