A clinically relevant mouse model to understand how IMiDs modulate the host-tumor immunolandscape in multiple myeloma

Multiple myeloma (MM) is a predominantly incurable form of plasma cell cancer. Although immunomodulatory imide drugs (IMiDs) such as thalidomide, lenalidomide, and pomalidomide constitute the backbone of most MM therapies, little is understood about how these drugs function to alter the tumor/microenvironment in vivo . Recently, it was demonstrated that IMiDs bind to the substrate receptor protein cereblon (CRBN) leading to the ubiquitination and degradation of multiple neoantigen protein targets, often DNA-binding zinc finger regulatory proteins such as ZFP91, IKZF1 and IKZF3. Interestingly, CRBN differs in amino acid sequence between mice and humans rendering mice non-responsive to IMiDs’ effects. This difference has made it difficult to study the complex pleotropic actions of IMiDs in vivo . Consequently, our lab has generated an immunocompetent transgenic mouse that expresses full-length human CRBN under the control of its endogenous regulatory elements (hCRBN+). We crossed this mouse with our well-established Vk*MYC mouse to generate a novel humanized Vk*MYC hCRBN+ strain that develops human-like multiple myeloma disease, is sensitive to IMiD therapy, and maintains a fully competent immune system. The purpose of generating our Vk*MYC hCRBN+ mouse is to determine the mechanism of action of IMiDs on the tumor only, the host only, and to understand the cross-talk between tumor and microenvironment in a clinically relevant in vivo model of MM. We find that hCRBN+ mice are sensitive to IMiD treatment in vivo by displaying degradation of known target proteins such as Ikzf1/Ikzf3 in splenocytes. We also show that non-tumor immune cells such as T and NK cells respond to IMiD treatment by increased proliferation and expression of effector molecules such as IL-2 and IFN-γ. Furthermore, by engrafting IMiD-sensitive Vk*MYC hCRBN+ MM cells into an IMiD-insensitive WT host we establish that IMiDs have tumor-intrinsic effects in vivo that are independent of the host’s immune system. These tumor-intrinsic IMiD effects synergize not only with dexamethasone, which has been shown clinically, but also with enhancer-targeting BET or p300/CBP inhibitors. Conversely, when engrafting IMiD-insensitive Vk*MYC MM cells into an IMiD-sensitive hCRBN+ host we were unable to demonstrate significant IMiD-induced host immune activation or tumor suppression. We conclude, based on our preliminary data, that IMiD activity is predominantly tumor-intrinsic. Moving forward, we are currently utilizing single-cell RNA sequencing to map the cellular and transcriptional changes across time in both tumor cells and the immune microenvironment during IMiD treatment. Ultimately, our goal is to gain mechanistic understanding in order to optimize clinical practice. Citation Format: Seth J. Welsh, Meaghen E. Sharik, Victoria M. Garbitt, Link R. Taylor, Daniel L. Riggs, Caleb Stein, Grady Day, Courtney J. Hillukka, Zach J. Hammond, P Leif Bergsagel, Marta Chesi. A clinically relevant mouse model to understand how IMiDs modulate the host-tumor immunolandscape in multiple myeloma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 4628.