Research We Fund

In recent work of our collaborating labs, the protein acetyltransferases P300 and CBP emerged as potent and preferential dependencies for multiple myeloma (MM) based on genetic depletion, catalytic inhibition or chemical degradation studies. Our current project will define distinct vs. redundant molecular and biological functions of P300/CBP in MM, identify the mechanisms of resistance to their inhibition/degradation and exploit these findings to develop new therapeutic modalities to treat MM.

Despite the promise of CAR-T cell immunotherapy for patients with lymphoma and multiple myeloma, a significant proportion of patients fail to respond or relapse following treatment. This project will focus on the clinical translation of a new treatment designed to improve durable response rates by combining CAR-T cell therapy with a new class of anticancer drugs called SMAC-mimetics. The results will provide the evidence base to drive a first-in-human clinical trial of this combination strategy.

Evolving insights into the B cell-restricted FCRL1 surface protein reveal that it integrates with critical signaling pathways and is a promising immunotherapeutic target in CLL. Based on preclinical evaluation of novel FCRL1 monoclonal antibodies, we propose developing chimeric antigen receptor (CAR) T cells for targeting in unique mouse models and patient-derived cells. The results will form the basis for strategic drug development and clinical testing in CLL and related B cell malignancies.

The proposed studies will identify alterations in hematopoietic regulation that predict for risk for therapy-related myeloid neoplasm (TMN) and improve understanding of disease evolution to guide strategies to prevent TMN in patients receiving autologous hematopoietic cell transplantation (aHCT) for lymphoma. They will investigate alterations in hematopoietic function in peripheral blood stem cell used for aHCT, and serial evolution of hematopoietic defects leading to development of TMN.