Research We Fund

CD19 targeting chimeric antigen receptor (CAR) T cell therapies (CAR19) are effective treatments for patients with non-Hodgkin Lymphoma (NHL), however, the majority of these patients will relapse. We have now evaluated a CD22 targeting CAR T cell therapy (CAR22) in patients who have large B cell lymphoma who have relapsed after CAR19 therapy and found that this therapy is both safe and effective resulting in a high rate of durable complete responses. We will now test this promising CAR22 for the first time in patients with other non-Hodgkin Lymphoma subtypes including mantle cell lymphoma, follicular lymphoma, and other CD22-expressing lymphomas.

Inhibition of a tumor-triggered immune exhaustion pathway, termed PD-1 blockade, enables immune effector cells to attack cancers. In classic Hodgkin Lymphoma (cHL), PD-1 blockade is now a standard treatment for relapsed disease and a component of experimental frontline therapy. We have identified a major population of monocyte/macrophages in patients with cHL that inhibit tumor cell killing and limit the efficacy of PD-1 blockade. Our goal is to fully characterize these tumor-specific monocytes/macrophages and target their immunosuppressive and tumorigenic program for therapeutic benefit in patients with cHL and other lymphoid malignancies.

Innovations in gene engineering have made it possible to reprogram immune cells to attack specific targets on cancer cells, allowing the first adoptive cellular immunotherapies, known as CAR T cells, to be approved by the FDA for the treatment B lymphoblastic leukemia. A similar approach is currently under development for AML, but in contrast to B-ALL, there is no leukemia-specific target which would be amenable to targeting by immune cells without incurring severe adverse effects. Here, we aim to modify normal bone marrow stem cells used for allogeneic transplantation to make them resistant to CAR-T cells, thus enabling targeting proteins essential for tumor survival without the risk of severe toxicity on the healthy tissue counterpart.

DNMT3A is a critical tumor suppressor in hematologic malignancies; DNMT3A protein levels affect both tumor latency and type. DNMT3A is regulated in part by protein stability, but the mechanisms remain incompletely understood. Here, I will dissect the mechanisms that regulate DNMT3A protein turnover using CRISPR screening and genetically engineered mouse leukemia models. This work will reveal whether its stabilization could contribute to a new therapeutic approach for hematologic malignancies.