Afferent-specific modulation of excitatory synaptic transmission by acetylcholine and serotonin in the prelimbic cortex

Abstract Acetylcholine (ACh) and serotonin (5-hydroxytryptamine, or 5-HT) differentially regulate the excitability of pyramidal neurons in the mouse prelimbic (PL) cortex according to their long-distance projections. Here we tested for afferent- and/or target-specific modulation of glutamate release by ACh and 5-HT in two long-distance excitatory projections to the PL cortex: commissural (COM) afferents from the contralateral cortex and projections from the mediodorsal nucleus (MDN) of the thalamus. Using ex-vivo optogenetic approaches, we mapped the connectivity and neuromodulation of COM and MDN afferents in layer 5 intratelencephalic (IT) and extratelencephalic (ET) projection neurons. Dual whole-cell recordings in pairs of IT and ET neurons revealed that COM afferents target both neuron subtypes, but that MDN afferents selectively target IT neurons. Both afferents exhibited similar target-independent short-term synaptic plasticity (paired-pulse facilitation) across a range of frequencies, but were differentially modulated by ACh and 5-HT. In both control conditions and after isolating monosynaptic connections with tetrodotoxin and 4-aminopyridine, COM transmission was suppressed strongly by ACh and moderately by 5-HT, while MDN transmission was largely unaffected by either neuromodulator. Suppression o,f COM transmission by ACh or 5-HT was concentration dependent and mediated by M4 muscarinic or 5-HT1B receptors, respectively. Chemogenetic inhibition of hM4Di-expressing COM terminals mimicked the suppressive effects of ACh and 5-HT on synaptic transmission. Our results demonstrate that ACh and 5-HT preferentially regulate COM synaptic transmission, albeit to different degrees, and suggest that, through their combined pre- and postsynaptic neuromodulation, ACh and 5-HT may differentially regulate cortico-striatal-thalamic loops to influence cognition and behavior. Competing Interest Statement The authors have declared no competing interest. Footnotes This work was supported by National Institute for Mental Health grants R01MH099054 (ATG), R01MH124934 (ATG), and F31MH116570 (ALB). We thank Saiko Ikeda for technical assistance with intracranial virus injections and data analysis, and Dartmouth undergraduate Ethan Liu for conducting experiments contributing to Figures 8 and 10. The authors declare no competing financial interests. The introduction has been rewritten for clarity and minor edits have been made throughout the manuscript. The manuscript has been formatted for readability.