Abstract
Dopamine is a neurotransmitter that plays a critical role in movement, motivation, and reward. Dopamine neurotransmission is regulated by the dopamine transporter (DAT), which translocates dopamine from the extracellular space to the presynaptic neuron. DAT is a target for psychostimulants such as cocaine, giving DAT a key role in psychostimulant‐use disorders. DAT cell‐surface expression regulated by trafficking to and from the plasma membrane is an important mechanism for controlling DAT function. Two signaling pathways that contribute to DAT trafficking are the protein kinase C (PKC) and mitogen activated protein kinases (MAPKs), including the extracellular signal‐regulated kinase (ERK1/2) and p38 MAPK. ERK1/2 is inactivated by the MAP kinase phosphatase MKP3, which dephosphorylates and inactivates ERK1/2. Previous data from the lab demonstrated that activation of PKC by administration of phorbol 12‐myristate 13‐acetate (PMA) in an in vitro system results in decreased DAT cell‐surface expression, and overexpression of MKP3 attenuates this effect. Furthermore, other studies have shown that ERK1/2 activation, downstream of PKC activation, may lead to phosphorylation of DAT on residue threonine 53 (Thr53), however the significance of this phosphorylation is not completely understood. In order to characterize the contributions of MKP3 and ERK1/2 to DAT phosphorylation and trafficking in vivo, we have developed two viral constructs based on adeno‐associated viral (AAV) vectors that enable cre recombinase (cre)‐dependent expression. One vector cre‐dependently expresses MKP3. The other vector is based on a genetic tool named OptoSOS. This vector enables cre‐dependent, blue‐light induced activation of ERK1/2, and as a result, can spatiotemporally activate intracellular ERK1/2 signaling. Both viral vectors are employed with transgenic rats that express cre in tyrosine hydroxylase‐positive cells (TH‐Cre rats) to drive expression in dopaminergic neurons. From these studies, we find that MKP3 overexpression and resulting ERK1/2 inactivation increases DAT surface expression by blocking the internalization and degradation of the transporter leading to an accumulation of DAT on the cell‐surface. Interestingly, MKP3 overexpression also decreases phosphorylation at Thr53. While we have shown that ERK inactivation results in increased DAT cell‐surface expression, we have employed the OptoSOS system to activate ERK1/2 and assess resulting changes in DAT trafficking. We have confirmed that ERK1/2 is activated by blue‐light in a cre‐dependent manner, and similar to what we observe with MKP3 overexpression, ERK1/2 activation results in changes in DAT cell‐surface expression and phosphorylation. Taken together, our results indicate that MKP3 and ERK1/2 serve critical physiological roles in DAT regulation and can be utilized to investigate the mechanistic relationship between DAT trafficking, phosphorylation, and transporter activity.
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