Research we fund

In order to develop a novel immunotherapy approach to treating AML, we propose targeting B7-H3 (CD276), a promising immune checkpoint that has been reported to inhibit NK cell activation. We have generated a novel anti–B7-H3 monoclonal antibody (T-1A5) to block B7-H3 function, showing the best in vitro and in vivo activity against AML cells. We will test the hypothesis that combination strategies such as targeting B7-H3 along with BCL2 inhibition (venetoclax) or IL-15r agonist (NKTR-255) result in synergistic inhibition of AML growth.

Project Term: July 1, 2023 - June 1, 2026

Acute myeloid leukemia (AML) is the most fatal type of leukemia and has a high rate of relapse following current therapies. We have recently uncovered that RSPO3-LGR4 pathway is a key regulator of leukemia-initiating cell activity and is exclusively activated in relapsed and refractory AML. Our project aims to investigate the mechanistic link between the pathway activation and therapy resistance, and design combination therapies that would overcome resistance and improve the treatment of relapsed leukemia.

Project Term: July 1, 2023 - June 30, 2026

Cellular immunotherapies such CAR-T cells are now firmly established as major pillars of anti-cancer therapy particularly in B-cell malignancies. However, despite their remarkable success in mediating an objective clinical response in up to 90% of patients, long-term durable remissions remain confined to only a minority of patients. It is now increasingly apparent that genetic evolution through the acquisition of new mutations cannot solely explain the molecular basis for therapeutic resistance. Therefore, to meet our ambition of precision medicine we need a better understanding of both the genetic and non-genetic mechanisms of malignant clonal dominance and therapeutic adaptation. To address this important challenge, we have developed new ex vivo and in vivo (mouse models) of resistance to CAR-T therapy. These will be coupled to a synthetic clone tracing strategy termed SPLINTR (Single-cell Profiling and LINeage Tracing) using expressed barcodes. In this proposal we will use SPLINTR in our models to uncover the clone intrinsic properties of cancer cells that enable them to evade these pioneering cellular immunotherapies. This research will deliver a blueprint around which future clinical trial strategies could be enabled to improve outcomes with these ground-breaking therapies.

Project Term: July 1, 2023 - June 30, 2026

RAS/MAPK mutations are the key drivers in MM, which occurs in 50% of newly diagnosed and higher in relapsed MM patients. However, RAS remains undruggable in MM. We found that RAS mutation MM growth is highly dependent on germinal center kinase(GCK). The goal of this project is to develop small molecule inhibitors against GCK with the expected outcome to provide novel treatments for relapsed/refractory and especially multi-drug resistant MM with RAS mutation, as well as other B-cell malignancies.

Project Term: July 1, 2023 - June 30, 2026

Patients with CLL that have progressed on BTK inhibitors have high risk disease with few clinical options. Here we propose a novel, selective inhibitor of PKCβ, MS-553, as a strategy for these patients. Our project will evaluate this drug alone and in combination with venetoclax preclinically and will perform correlative studies from an ongoing phase 1/2 trial of this drug alone and in combination with venetoclax.

Project Term: July 1, 2023 - June 30, 2026

In this project, we will test an innovative therapy called CAR T-cell therapy for children with a type of cancer called AML. In the laboratory, we have identified and developed a powerful CAR T-cell therapy that targets a protein called CD70 on AML cells. We propose to now develop a clinical trial in which we will study the effects of this CD70.CAR T-cell therapy in children with AML.

Project Term: July 1, 2023 - June 30, 2026

Double-hit lymphoma (DHL) is an aggressive form of diffuse large B-cell lymphoma (DLBCL) defined by co-occuring MYC and BCL2 rearrangements. DHL has been linked to very poor outcomes when treated with R-CHOP chemotherapy. Effective treatments to prevent treatment failure remain a critical unmet need. This proposal will develop novel, mechanism-based therapeutic regimens for DHL that overcome chemotherapy resistance and defective immune surveillance to improve outcomes.

Project Term: July 1, 2023 - June 30, 2026

This project aims to develop targeted therapies against peripheral T cell lymphoma (PTCL), a diverse group of aggressive blood cancers with poor clinical outcomes. This project is tightly relevant to cancer control and treatment, promising to advance our understanding on how blood cancers initiate and progress, and lead to new therapeutics for the treatment of peripheral T cell lymphoma (PTCL). We will develop targeted therapeutics to engage an oncogenic RHOA GTPase mutant to treat PTCL and other types of tumors with similar genetic backgrounds.

Project Term: July 1, 2023 - June 30, 2026

We observed that patients with many hematologic cancers expressed high levels of DKK1 and generated novel human DKK1-A2 CAR-T cells that can kill cancer cells from HLA-A2+ patients with myeloma, lymphoma, or leukemia. We also found that Th9-polarized T cells have enhanced antitumor effects in vivo. In this proposal, we will determine 1) whether and how Th9-polarized DKK1-A2 CAR-T cells are promising effector T cells for immunotherapy of human patients, and 2) whether Th9-polarized DKK1-A2 CAR-T cells are associated with reduced on- and off-target toxicities. Completing these studies are critical for developing new and effective CAR-T therapy for patients with hematologic malignancies who are still dying from the disease.

Project Term: July 1, 2023 - June 30, 2026

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.

Project Term: July 1, 2023 - June 30, 2026

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.

Project Term: July 1, 2023 - June 30, 2026

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.

Project Term: July 1, 2023 - June 30, 2026