Prefrontal cortical synaptic plasticity induced by stimulation of the rat mediodorsal thalamus in vivo: effects of cholinergic muscarinic and nicotinic modulation

The mediodorsal thalamic nucleus (MD) and the prefrontal cortex (PFC) communicate with each other, constituting a circuit involved in executive functions and psychiatric disorders. Executive functions are subject to arousal levels driven& by the thalamocortical oscillatory activity, which in turn is controlled by the cholinergic neurotransmission. Possibly, the MD-PFC synaptic plasticity is susceptible to both the oscillatory patterns within the MD-PFC circuit and the cholinergic modulation. However, this likelihood is still untested, as well as the specific roles of muscarinic and nicotinic receptors. Thus, our aim was to evaluate whether and how the MD-PFC plasticity is modulated under cholinergic system-dependent oscillatory states of the forebrain, and if such modulation varies with the subtypes of activated cholinergic receptors. For that, we anesthetized rats with urethane to implant a stimulating electrode into the MD, a recording electrode into the PFC, and a microinjection cannula above the ventricle. We applied 90 monophasic square pulses into the MD (0.05 Hz) for recording of basal field postsynaptic potentials (fPSPs) in the PFC for 30 min. Then, we did an intraventricular injection of either the muscarinic agonist pilocarpine (PILO), the nicotinic agonist nicotine (NIC), or a control vehicle (Veh). The drug effects on local field potentials (electroencephalogram) were monitored through the same electrodes. PILO and NIC induced an increase in theta, beta and gamma oscillations (4-80 Hz) with proportional reduction of urethane-driven delta waves (0.5-4 Hz), and these effects survived approximately 10-15 min according to pilot-experiments on PILO and NIC concentrations. During this period, we applied either high-frequency (HFS) or low-frequency stimulation (LFS) for induction of respectively long-term potentiation (LTP) or depression (LTD), which are well-known synaptic plasticity models. In control groups, the injection of PILO, NIC or Veh was not followed by the HFS/LFS. Lastly, we resumed the evoking of fPSP at 0.05 Hz for an additional 240 min. The results showed that the HFS did not affect the fPSPs when applied after the Veh. However, in PILO and NIC rats the fPSP had their amplitudes increased from 150 min after HFS, indicating that the cholinergic pre-activation was required for the induction of a late-phase LTP. On the other hand, when the LFS was applied after the Veh, the fPSP amplitudes were stably decreased for 240 min, which did not occur when the LFS was applied after PILO and NIC, suggesting that the cholinergic modulation suppressed the LTD. In the control groups, PILO, NIC, and Veh by themselves did not change fPSPs in the long term, reinforcing that the LTP and LTD were due to an interaction between the cholinergic pre-activation and synaptic mechanisms triggered by the HFS/LFS. Therefore, the rapid oscillations induced by the cholinergic transmission favor LTP in the MD-PFC loop, while occlude its LTD. Moreover, the muscarinic and nicotinic effects on long-term plasticity were equal, although their quite distinct cell mechanisms. Our findings might help clarify the regulation of thalamic signals on the PFC both under physiological (attention and rapid-eye-movement sleep) and dysfunctional (schizophrenia symptoms and Alzheimer\'s) cholinergic drive. (AU)