The Behavioral Role of Mu Opioid Receptors in Glutamatergic Neurons
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Abstract
Mu opioid receptors (MORs) mediate the analgesic and rewarding effects of opioids. Most research has focused on MORs in GABAergic neurons; however, MORs are also in glutamatergic neurons and their role in opioid-related behaviors was unclear. Our lab previously showed that MORs inhibit glutamate transmission from vesicular glutamate transporter 2 (vGluT2)-expressing thalamostriatal synapses. The behavioral relevance of MORs in vGluT2-expressing neurons was unknown; therefore, I utilized a conditional MOR knockout mouse with MORs deleted in vGluT2-expressing neurons (MORflox-vGluT2cre). MORflox-vGluT2cre mice have disrupted opioid reward, locomotor stimulation, and withdrawal, compared to cre-recombinase negative littermate controls. However, other MOR-mediated behaviors, including opioid-induced antinociception, alcohol reward, and palatable substance consumption are intact. MORs are expressed in vGluT2 neurons in several reward-related brain regions, including the thalamus and lateral habenula (LHb). To determine whether MORs in these brain regions modulate opioid-related behaviors, an adeno-associated viral (AAV) vector encoding cre-recombinase was stereotaxically injected into the thalamus or LHb of MORflox mice to specifically delete MORs in these brain regions. Opioid reward and locomotor stimulation remained intact in both thalamic and LHb MOR knockout mice; however, basal locomotor activity was increased in LHb MOR knockout mice. Sucrose consumption was also intact in LHb MOR knockout mice. Interestingly, in LHb MOR KO mice opioid withdrawal-induced paw shakes were increased, while withdrawal-induced jumping was completely ablated. Our lab previously showed that MORs inhibit glutamate transmission from the anterior insular cortex (AIC), which is disrupted by in vivo alcohol exposure. To determine the role of AIC MORs, AIC MORs were deleted with AAV vectors. AIC MOR knockout mice had intact opioid, sucrose, and alcohol reward, but had increased basal locomotor activity. MORs in glutamatergic neurons are critical mediators of opioid reward; however, the specific glutamatergic neurons mediating the rewarding effects of opioids remains to be determined.