The nematode Caenorhabditis elegans is well known for its ability to support forward genetic screens to identify molecules involved in neuronal viability and signaling. The proteins involved in C. elegans dopamine (DA) regulation are highly conserved across evolution, with prior work demonstrating that the model can serve as an efficient platform to identify novel genes involved in disease‐associated processes. To identify novel players in DA signaling, we took advantage of a recently developed library of pre‐sequenced mutant nematodes arising from the million mutation project (MMP) to identify strains that display the DA‐dependent swimming‐induced‐paralysis phenotype (Swip). Our screen identified novel mutations in the dopamine transporter encoding gene dat‐1, whose loss was previously used to identify the Swip phenotype, as well as multiple genes with previously unknown connections to DA signaling. Here, we present our isolation and characterization of one of these genes, bbs‐1, previously linked to the function of primary cilia in worms and higher organisms, including humans, and where loss‐of‐function mutations result in a human disorder known as Bardet–Biedl syndrome. Our studies of C. elegans BBS‐1 protein, as well as other proteins that are known to be assembled into a higher order complex (the BBSome) reveal that functional or structural disruption of this complex leads to exaggerated C. elegans DA signaling to produce Swip via a cell‐autonomous mechanism. We provide evidence that not only does the proper function of cilia in C. elegans DA neurons support normal swimming behavior, but also that bbs‐1 maintains normal levels of DAT‐1 trafficking or function via a RHO‐1 and SWIP‐13/MAPK‐15 dependent pathway where mutants may contribute to Swip independent of altered ciliary function. Together, these studies demonstrate novel contributors to DA neuron function in the worm and demonstrate the utility and efficiency of forward genetic screens using the MMP library.image