An endocannabinoid-regulated basolateral amygdala–nucleus accumbens circuit modulates sociability
Oakleigh M. Folkes, … , Brad A. Grueter, Sachin Patel
Oakleigh M. Folkes, … , Brad A. Grueter, Sachin Patel
Published December 24, 2019
Citation Information: J Clin Invest. 2020;130(4):1728-1742. https://doi.org/10.1172/JCI131752.
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An endocannabinoid-regulated basolateral amygdala–nucleus accumbens circuit modulates sociability

Abstract

Deficits in social interaction (SI) are a core symptom of autism spectrum disorders (ASDs); however, treatments for social deficits are notably lacking. Elucidating brain circuits and neuromodulatory signaling systems that regulate sociability could facilitate a deeper understanding of ASD pathophysiology and reveal novel treatments for ASDs. Here we found that in vivo optogenetic activation of the basolateral amygdala–nucleus accumbens (BLA-NAc) glutamatergic circuit reduced SI and increased social avoidance in mice. Furthermore, we found that 2-arachidonoylglycerol (2-AG) endocannabinoid signaling reduced BLA-NAc glutamatergic activity and that pharmacological 2-AG augmentation via administration of JZL184, a monoacylglycerol lipase inhibitor, blocked SI deficits associated with in vivo BLA-NAc stimulation. Additionally, optogenetic inhibition of the BLA-NAc circuit markedly increased SI in the Shank3B–/– mouse, an ASD model with substantial SI impairment, without affecting SI in WT mice. Finally, we demonstrated that JZL184 delivered systemically or directly to the NAc also normalized SI deficits in Shank3B–/– mice, while ex vivo JZL184 application corrected aberrant NAc excitatory and inhibitory neurotransmission and reduced BLA-NAc–elicited feed-forward inhibition of NAc neurons in Shank3B–/– mice. These data reveal circuit-level and neuromodulatory mechanisms regulating social function relevant to ASDs and suggest 2-AG augmentation could reduce social deficits via modulation of excitatory and inhibitory neurotransmission in the NAc.

Authors

Oakleigh M. Folkes, Rita Báldi, Veronika Kondev, David J. Marcus, Nolan D. Hartley, Brandon D. Turner, Jade K. Ayers, Jordan J. Baechle, Maya P. Misra, Megan Altemus, Carrie A. Grueter, Brad A. Grueter, Sachin Patel

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Figure 4

CB1 receptors and 2-AG augmentation regulate BLA-NAc synapses.

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CB1 receptors and 2-AG augmentation regulate BLA-NAc synapses. (A) The c...
(A) The cannabinoid receptor agonist CP55940 decreased oEPSC amplitude in the NAc; N = 3. (B) JZL184 reduced aEPSC frequency in D1 receptor+ (D1R+; *P = 0.0171) and D1 receptor (D1R) cells (#P = 0.0197) (C) but did not affect aEPSC amplitude after BLA-NAc optogenetic stimulation; D1+ n = 3, and D1 n = 3 (B, C). aEPSC, asynchronous excitatory postsynaptic current; BL, baseline. (D) WIN55212-2 (Win55), a cannabinoid receptor agonist, uniformly decreased oEPSC amplitude in D1+ and D1 NAc cell types; D1+ n = 4, and D1 n = 4. (E) DSE was present in both D1+ and D1 NAc cells, (F) although DSE magnitude was increased in D1+ compared with D1 cells (*P = 0.0450); D1+ n = 4, and D1 n = 5 (E, F). (G) sEPSC frequency in NAc recordings were unaffected by JZL184, (H) but there was a significant effect of JZL184 on sIPSC frequency (*P = 0.0400). (I) There were no effects of JZL184 on sIPSC amplitude; D1+ n = 4, D1 n = 4. Data analyzed via 2-way mixed-effects ANOVA followed by Holm-Šídák multiple-comparisons test (B, C, GI) or unpaired, 2-tailed t test (F). P and F values for drug effect shown in B, C, and GI.