Neural correlates of state transitions elicited by a chemosensory danger cue

S. Jesuthasan, Seetha Krishnan, R. Cheng, A. Mathuru
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引用次数: 15

Abstract

Background Detection of predator cues changes the brain state in prey species and helps them avoid danger. Dysfunctionality in changing the central state appropriately in stressful situations is proposed to be an underlying cause of multiple psychiatric disorders in humans. Methods Here, we investigate the dynamics of neural circuits mediating response to a threat, to characterize these states and to identify potential control networks. We use resonant scanning 2-photon microscopy for in vivo brain-wide imaging and custom designed behavioral assays for the study. Results We first show that 5-7 day old zebrafish larvae react to an alarm pheromone (Schreckstoff) with reduced mobility. They subsequently display heightened vigilance, as evidenced by increased dark avoidance. Calcium imaging indicates that exposure to Schreckstoff elicits stimulus-locked activity in olfactory sensory neurons innervating a lateral glomerulus and in telencephalic regions including the putative medial amygdala and entopeduncular nucleus. Sustained activity outlasting the stimulus delivery was detected in regions regulating neuromodulator release, including the lateral habenula, posterior tuberculum, superior raphe, and locus coeruleus. Conclusion We propose that these latter regions contribute to the network that defines the “threatened” state, while neurons with transient activity serve as the trigger. Our study highlights the utility of the zebrafish larval alarm response system to examine neural circuits during stress dependent brain state transitions and to discover potential therapeutic agents when such transitions are disrupted.
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由化学感觉危险提示引起的状态转换的神经关联
探测到捕食者的线索会改变猎物的大脑状态,帮助它们躲避危险。在压力情况下改变中枢状态的功能障碍被认为是人类多种精神疾病的潜在原因。在这里,我们研究了神经回路对威胁反应的动力学,表征这些状态并识别潜在的控制网络。我们使用共振扫描双光子显微镜进行体内全脑成像和定制设计的行为分析。我们首先发现,5-7日龄的斑马鱼幼虫对报警信息素(Schreckstoff)有反应,行动能力降低。随后,他们表现出更高的警惕性,这可以从他们对黑暗的回避程度增加中得到证明。钙成像显示,暴露于Schreckstoff会引起支配外侧肾小球和远端脑区的嗅觉感觉神经元的刺激锁定活动,包括假定的内侧杏仁核和核束内核。在调节神经调节剂释放的区域,包括外侧链、后结节、中缝上和蓝斑,检测到持续活动超过刺激递送。我们认为,后两个区域参与了定义“受威胁”状态的网络,而具有短暂活动的神经元则充当了触发机制。我们的研究强调了斑马鱼幼虫报警反应系统在压力依赖的大脑状态转换期间检查神经回路的效用,并在这种转换被破坏时发现潜在的治疗药物。
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