Cancer is one of the deadliest ailments in the United States, killing hundreds of thousands of people per year. One group of proteins that have been implicated in human cancers are the Phosphatase of Regenerating Livers, or PRLs. PRL-1 has been shown to have differing effects on cancer. Some research has found this protein to be an oncogene while others have found it to be a tumor suppressor. In our lab, past research has shown that for dPRL-1 to function as a tumor suppressor, it must localize to the adherens junction. The adherens junction helps glue epithelial cells together; malfunctioning adherens junctions, found in some cancers, no longer glue cells together thereby allowing them to metastasize. To better understand how dPRL-1 can function as a tumor suppressor, I performed a co-immunoprecipitation on the homolog, dPRL-1 in Drosophila melanogaster to discover the proteins that dPRL-1 interacts with in vivo at the adherens junction. To do this, I overexpressed dPRL-1 in the developing wing epithelium of the organisms and used an antibody to dPRL-1 for co-immunoprecipitation. This approach is an unbiased way to identify proteins that dPRL-1 interacts with while functioning as a tumor suppressor. My initial attempts at co-immunoprecipitation revealed one unknown protein of possible significance, but I have been unable to identify it yet. I am also testing my protocol to see if E-cadherin, a protein component of the adherens junction that contributes to cell adhesion, and dPRL-1 co-immunoprecipitate. We expect this interaction since our lab found that the two proteins colocalize via fluorescence microscopy. The proteins that dPRL-1 interacts with when functioning as a tumor suppressor could be mutated or missing in cancer cells thereby preventing dPRL-1 from functioning as a tumor suppressor. Hopefully, this knowledge will help clinicians make more effective chemotherapies to target cancers affected by PRLs.