Loss of ASIC1A-dependent inhibitory neuron activity in basolateral amygdala is associated with increased CO 2 -evoked jumping

  1. Rebecca J Taugher-Hebl
  2. Aubrey C Chan
  3. Collin J Kreple
  4. Ali Ghobbeh
  5. Grace Z Wang
  6. Gail I S Harmata
  7. Mackenzie M Conlon
  8. Subhash C Gupta
  9. Rong Fan
  10. Ramkumar Kuruba
  11. Margaret P Price
  12. Jeffrey D Long
  13. Youngcho Kim
  14. Brian J Dlouhy
  15. Nandakumar S Narayanan
  16. John A Wemmie
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Abstract

Background

Responding appropriately to threats is critical for survival. Dysregulated defensive responses are core features of psychiatric illnesses including panic disorder and post-traumatic stress disorder. Carbon dioxide (CO 2 ) inhalation evokes defensive behaviors in both humans and mice. Here we investigated the role of acid-sensing ion channels (ASICs) in CO 2 -evoked jumping in mice.

Methods

Defensive behaviors (jumping and freezing) were assessed in response to CO 2 inhalation and basolateral amygdala (BLA) acidification. We tested the role of ASICs using global knockout mice and Asic1a loxP/loxP mice transduced with AAV-CMV-Cre or AAV-CaMKII-Cre in the BLA. Effects of CO 2 on single neuron firing and local field potentials were studied via BLA microwire arrays.

Results

ASIC1A disruption increased CO 2 -evoked jumping while reducing freezing, paralleled by increased BLA c-Fos induction. Acidification of the BLA recapitulated these effects. Virus-mediated ASIC1A disruption in BLA did not resolve the locus of ASIC1A action in jumping. CO 2 inhalation suppressed firing in most BLA neurons, though a small number increased firing. ASIC1A disruption enhanced CO 2 -induced suppression of narrow waveform neurons (putative interneurons), and facilitated excitation of wide waveform neurons (putative principal neurons). Additionally, CO 2 produced concentration-dependent broadband power suppression with selective theta enhancement, effects that were augmented by ASIC1A disruption.

Conclusions

Together, these findings suggest that ASIC1A promotes interneuron activity during acidosis and that its loss may reduce inhibition of principal neuron output, shifting defensive responses from freezing toward jumping. These results advance our understanding of how brain pH and ASICs regulate defensive behavior, with potential implications for understanding dysregulated defensive responses.

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  1. Version published to 10.64898/2026.05.18.725939 on bioRxiv