The herpesvirus Epstein-Barr Virus (EBV) targets B-cells and epithelial cells. The virus is transmitted by saliva and commonly associated with infectious mononucleosis. After initial infection, the virus enters a latent stage. The first oncogenic virus identified in humans, it contributes to 1.5% of all cases of human cancers worldwide, specifically cancers of B-cells and epithelial cells, and roughly 140,000 deaths/year. Currently, no treatment is available for EBV-related cancers. Due to the widespread impact of EBV on populations, including a drainage of resources in parts of the world where EBV-associated cancer rates are disproportionately high, an effective treatment will be greatly beneficial. The gH/gL complex and gB, glycoproteins necessary for virus fusion to the host cell, are conserved among herpesviruses, including EBV. Recently isolated, the monoclonal antibodies AMMO1 and AMMO5 inhibit EBV infection by preventing fusion to the host cell. AMMO1 binds to the gH/gL complex and interferes with both epithelial and B-cell infection, while AMMO5 binds to gB and can prevent epithelial cell infection. Emerging evidence suggests certain tumors express these glycoproteins, thus they may be readily targeted for immunotherapy. In this project I created Jurkat leukemic cell line T-cells which express chimeric express chimeric antigen receptors (CARs) using AMMO1 and AMMO5. This CAR should target EBV viral antigens on tumors. First, I used mutagenesis to insert DNA encoding for the AMMO1 or AMMO5 scFV, into a CAR expression plasmid and verify integration by Sanger sequencing. I then used lentiviral delivery to transduce CAR constructs into Jurkat T-cell genomic DNA. Flow cytometry was used to confirm transduction of the T-cells. Future directions with this project include increasing transduction efficiency and transducing the constructs into cytotoxic T-cell so T-cell killing assays can be used to determine the efficacy of the AMMO1 and AMMO5 CAR-T cells.