Isolated dystonia can be caused by loss-of-function mutations in the GNAL gene (DYT-GNAL). This gene encodes the olf heterotrimeric G protein subunit, which, together with {beta}2{gamma}7 subunits, mediates the stimulatory coupling of dopamine D1 and adenosine A2A receptors to adenylyl-cyclase. These receptors are expressed in distinct striatal projection neurons (SPNs) with complementary functions on motor behavior. To dissect the specific roles of Golf in each subpopulation of SPNs, we generated and characterized mouse models in which Gnal was conditionally deleted in neurons expressing either D1 receptors (D1-SPNs) or A2A receptors (A2A-SPNs). Our results confirmed the critical role of Golf in regulating adenylyl-cyclase 5 and its coupling with D1 and A2A receptors. Mice with a selective loss of Golf in D1-SPNs showed nocturnal hyperactivity, deficits in motor performances, but no overt abnormal movements or generalized motor disability. Our experiments also revealed that Golf in D1-SPNs is not systematically required for locomotor responses induced by D1 agonists or psychostimulants. Selective loss of Golf in A2A-SPNs did not affect motor abilities nor learning. However, this loss strikingly increased spontaneous locomotor activity that was not further enhanced by psychostimulant drugs (cocaine, D-amphetamine, methylphenidate) or a selective A2 agonist, KW6002, and was paradoxically reduced by caffeine Our study identified specific roles of Golf downstream of D1 and A2A receptors in the control of motor behavior and drug responses, highlighting their respective individual contribution in diseases associated with dysfunctional striatal signaling, including dystonia.