BTN3A1 governs antitumor responses by coordinating αβ and γδ T cells.
Kyle K PayneJessica A MineSubir BiswasRicardo A ChaurioAlfredo Perales-PuchaltCarmen M AnadonTara Lee CostichCarly M HarroJennifer WalrathQianqian MingEvgenii N TcyganovAndrea L BurasKristen E RigolizzoGunjan MandalJason LajoieMichael J OphirJulia TchouDouglas MarchionVincent C LucaPiotr BobrowiczBrooke McLaughlinUgur EskiocakMichael SchmidtJuan R Cubillos-RuizPaulo C RodriguezDmitry I GabrilovichJosé R Conejo-GarciaPublished in: Science (New York, N.Y.) (2020)
Gamma delta (γδ) T cells infiltrate most human tumors, but current immunotherapies fail to exploit their in situ major histocompatibility complex-independent tumoricidal potential. Activation of γδ T cells can be elicited by butyrophilin and butyrophilin-like molecules that are structurally similar to the immunosuppressive B7 family members, yet how they regulate and coordinate αβ and γδ T cell responses remains unknown. Here, we report that the butyrophilin BTN3A1 inhibits tumor-reactive αβ T cell receptor activation by preventing segregation of N-glycosylated CD45 from the immune synapse. Notably, CD277-specific antibodies elicit coordinated restoration of αβ T cell effector activity and BTN2A1-dependent γδ lymphocyte cytotoxicity against BTN3A1+ cancer cells, abrogating malignant progression. Targeting BTN3A1 therefore orchestrates cooperative killing of established tumors by αβ and γδ T cells and may present a treatment strategy for tumors resistant to existing immunotherapies.