- Ferguson, Ian D;
- Patiño-Escobar, Bonell;
- Tuomivaara, Sami T;
- Lin, Yu-Hsiu T;
- Nix, Matthew A;
- Leung, Kevin K;
- Kasap, Corynn;
- Ramos, Emilio;
- Nieves Vasquez, Wilson;
- Talbot, Alexis;
- Hale, Martina;
- Naik, Akul;
- Kishishita, Audrey;
- Choudhry, Priya;
- Lopez-Girona, Antonia;
- Miao, Weili;
- Wong, Sandy W;
- Wolf, Jeffrey L;
- Martin, Thomas G;
- Shah, Nina;
- Vandenberg, Scott;
- Prakash, Sonam;
- Besse, Lenka;
- Driessen, Christoph;
- Posey, Avery D;
- Mullins, R Dyche;
- Eyquem, Justin;
- Wells, James A;
- Wiita, Arun P
The myeloma surface proteome (surfaceome) determines tumor interaction with the microenvironment and serves as an emerging arena for therapeutic development. Here, we use glycoprotein capture proteomics to define the myeloma surfaceome at baseline, in drug resistance, and in response to acute drug treatment. We provide a scoring system for surface antigens and identify CCR10 as a promising target in this disease expressed widely on malignant plasma cells. We engineer proof-of-principle chimeric antigen receptor (CAR) T-cells targeting CCR10 using its natural ligand CCL27. In myeloma models we identify proteins that could serve as markers of resistance to bortezomib and lenalidomide, including CD53, CD10, EVI2B, and CD33. We find that acute lenalidomide treatment increases activity of MUC1-targeting CAR-T cells through antigen upregulation. Finally, we develop a miniaturized surface proteomic protocol for profiling primary plasma cell samples with low inputs. These approaches and datasets may contribute to the biological, therapeutic, and diagnostic understanding of myeloma.