Increased Excitability of Pyramidal Neurons in the Secondary Motor Cortex Enhances Cocaine-Seeking

Abstract

Cocaine addiction is a brain disorder characterized by chronic relapse. Although drug-seeking behaviors have been recognized to be associated with relapse, the role of the motor cortex, including the primary (M1) and secondary (M2) motor cortex, which are functionally important mediators of complex behaviors remains unclear in addiction. Here we use a rat cocaine intravenous self-administration (IVSA) model to investigate the intrinsic excitability of pyramidal neurons in the medial prefrontal cortices and motor cortices during withdrawal. Cocaine IVSA-trained rats performed a cocaine-seeking test on withdrawal day (WD) 1 or WD 45. Relative to WD 1 an increase in cocaineseeking was detected on WD 45. Whole-cell patch clamp recordings revealed an increase in intrinsic excitability in pyramidal neurons in Layer 2 of the secondary motor cortex (M2-L2) in cocaine trained rats on WD 45. Using a pharmacological approach, bath application of GABAA receptor agonist, muscimol, dosedependently (0.1 mM, 0.3 mM, and 1.0 mM) decreased the excitability of M2-L2 pyramidal neurons in cocaine IVSA-trained rats on WD 45. Pharmacological inactivation of M2-L2 by bilateral intra-M2 injection of muscimol (324 ng/1.0 μl) attenuated cocaine-seeking on WD 45. A chemogenetic approach was used to validate that M2-L2 pyramidal neurons play a contributing role in the increase in cocaine-seeking, a microinjection of rAAV5-CaMKIIa-hM4di-mCherry was performed to express Gi-DREADD receptors on M2-L2 pyramidal neurons. Activating Gi-DREADD with an intraperitoneal injection of compound 21 on WD 45 attenuated cocaine-seeking. To elucidate the mechanism that contributes to the increased excitability of M2-L2 pyramidal neurons, an analysis of the action potential kinetics revealed that calcium-activated small conductance potassium (SK) channel-mediated medium afterhyperpolarization amplitude decreased in cocaine vs. saline IVSA-trained rats on WD 45. SK channel activation by 1-EBIO (300 μm) increased the medium afterhyperpolarization amplitude and decreased the excitability of M2-L2 pyramidal neurons in cocaine IVSA-trained rats. Furthermore, intra-M2 injection of 1-EBIO on WD 45 attenuated cocaine-seeking. These experiments suggest that cocaine IVSA-training-induced persistent changes in M2-L2 pyramidal neurons' intrinsic excitability contributes to enhanced cocaine-seeking. Our results provide evidence targeting the SK channels in the superficial layer for M2 could be an important therapeutic approach for preventing cocaine relapse.