Research We Fund

Our proposal aims to develop a novel strategy to improve therapeutic efficacy for patients with multiple myeloma by remodeling obesity-induced inflammatory microenvironment. We hypothesize that acetyl-CoA synthetase 2, which is stimulated by obesity, enhances inflammatory cytokine production from myeloma cells, leading to an inflammatory niche where anti-tumor function of CD8+ T cells is dampened, and tumor growth is promoted. Our study will be the first to explore a novel insight for how obesity impacts the interaction between myeloma cells and microenvironment. In preparation of using the inhibitor of acetyl-CoA synthetase 2 in the clinical setting, we will establish its potential as a single agent or in combination of other chemo- or immuno- drugs to treat myeloma.

The b-catenin/BCL9 transcriptional complex, is a novel dependency in multiple myeloma (MM). Disruption of this complex inhibits MM cell growth in culture and in MM xenograft models. Development of potent selective b-catenin/BCL9 inhibitors will provide valuable tools to further investigate their mechanism of MM inhibition. We have established a chemistry, structural biology, and molecular pathology platform to facilitate novel inhibitor development, and explore its translational potential in MM.

This proposal is to conduct a phase I (early phase) clinical trial to test whether the combination of the approved targeted therapy venetoclax with memory-like Natural Killer (NK) cells is safe and active in patients with acute myeloid leukemia (AML). Based on laboratory research at Dana-Farber Cancer Institute, we believe that the addition of memory-like NK cells obtained from an haploidentical (‘half matched’) donor will be able to eradicate residual leukemia cells left over after prior venetoclax treatment and hence prevent a future relapse of the disease. A total of 10 patients will be treated with two different doses of NK cells and a constant dose of venetoclax. We also plan scientific studies on patient samples to learn more about the function of NK cells when combined with venetoclax, evaluate for clearance of residual leukemia cells with this combination therapy and explore potential resistance mechanisms.

We will develop a novel T cell therapy strategy for multiple myeloma (MM) that will combine existing chimeric antigen receptors (CARs) with a novel designed biosensor responding to soluble factors abundantly present in the MM bone marrow environment in patients. The biosensor will be expressed as novel type of chimeric receptor in T cells concomitantly with the CAR and signal the T cells to persist longer and keep eliminating cancer cells from the body. We will deeply characterize the effects of our novel biosensor in CAR T cells to precisely understand how the treatment works. If successful, we expect that CAR T cell therapy for MM can be made more efficient, and the same strategy could potentially also be applied to other cancer types.