Research we fund

The majority of myeloid cancers remain incurable. We previously showed that individuals at risk can be identified years in advance, indicating that prevention may be a viable alternative to treatment. Here, we propose a program of work to establish a clinical platform for myeloid cancer prevention. This includes development of a screening strategy, improved understanding of myeloid cancer evolution, identification of treatment targets and establishment of a specialized clinic to deliver therapy.

Chimeric antigen receptor (CAR) T cell therapy is a form of immune-based therapy where a patient’s own immune cells are genetically engineered to recognize and kill the tumor cells. This therapy has revolutionized the treatment of certain blood cancers and excitingly, two CAR T cell products were recently approved for the treatment of multiple myeloma.

Despite impressive initial clinical data showing responses in 73-98% of patients, most patients still relapse after CAR-T cell therapy within 3 years. Therefore, there is a significant unmet need to further enhance the effectiveness of CAR T cell therapy in this disease. In this project we will investigate whether an approach we have shown to make CAR T cells “fitter” and more effective in solid tumors is also effective in the context of multiple myeloma.

As a lymphoma develops it expresses genes that are normally silenced to convey a survival advantage. When these genes are on the X or Y (sex chromosomes) they may present a gender-specific therapeutic target. We have identified a gene (DDX3X in females or DDX3Y in males) that is reactivated in lymphomas such that the lymphomas cannot survive if this gene is removed. This project will develop new ways to inhibit DDX3X and Y as a novel treatment for poor-risk and aggressive lymphoma.

Myelodysplastic neoplasms are malignant disorders driven by expansion of diseased hematopoietic stem cells and progression to leukemia. Our investigations have identified the important role of the transporter of amino acid glutamine SLC38A1 in sustaining metabolic demands of rapidly growing malignant stem cells. The goal of this project is to genetically target this transporter to understand its role on tumorigenesis and progression; and to develop SLC38A1 inhibitors as novel therapeutic tools.

In the Cancer Immunology field, the “aging” variable has not been investigated profoundly yet, even though aging is the first factor associated to cancer. This represents a major limitation on the significance of the experimental results and their translation to the clinic. We believe that with our proposal we can shade light on important biological processes which drive immunotherapy failure. We have shown that T cell function is dependent not only on the differentiation state but also on their biological age. Thus, taking in consideration aging and the age-driven metabolic defects in T cells will help to better understand their biology and develop better strategies to boost immunotherapy.

We have observed that non-glycosylated CST6 proteins suppress osteoclast differentiation and function without causing immunosuppression. We aim to determine whether BCMA-CAR-T cells which are engineered to secret CST6 proteins kill myeloma cells and suppress bone lytic lesions without immune suppressive effects in myeloma. Our ultimate goal is to develop a CAR-T-cell based immune therapy to prevent bone loss and disease progression in myeloma patients.

TP53-Y220C is a recurrent hotspot TP53 mutation observed predominantly in AML and MDS among hematological malignancies. This study aims to investigate the mechanism of action and therapeutic activity of PC14586, a compound designed to bind p53-Y220C protein and stabilize it in the wild-type conformation and to develop mechanism-based combinations that improve its efficacy in TP53-Y220C mutant AML.

Follicular lymphoma is a common form of blood cancer, affecting 15,000 new patients annually in the United States, but it remains incurable with conventional treatments. Bispecific antibodies represent a new class of therapies that engage the immune system to attack lymphoma cells and have shown promising effectiveness in inducing remissions in patients with this disease, but even they are unlikely to be curative. Researchers from the Dana-Farber Cancer Institute here propose to analyze lymphoma cells from patients undergoing treatment with bispecific antibodies on several complementary clinical trials to determine how these cells evade the immune system and develop resistance. It is believed that such mechanisms of resistance may reveal vulnerabilities within the lymphoma cells that novel treatments can overcome in combination with bispecific antibodies to cure patients with follicular lymphoma.

Despite remarkable progress in the last 20 years, multiple myeloma remains an incurable disease. In recent years, 2 CAR T cell products that target BCMA on the myeloma cell have been approved. These products result in remarkable initial responses however the duration of these responses has been disappointing. In this proposal, we will take a novel approach to isolate and characterize myeloma cells that interact with CAR T cells but are not killed by them as a potential resistance mechanism.

Mantle cell lymphoma (MCL) is an aggressive B-cell lymphoma characterized by resistance to standard treatments and short survival. For the 2023 LLS MCLII Synergistic Team Award, we have assembled a team of leaders in basic, translational, and clinical research in MCL to tackle the current significant obstacles in understanding and treating MCL. In the last decade, we investigated the therapy resistance mechanism of MCL, and pioneered clinical trials for targeted therapies (ibrutinib, lenalidomide) and chimeric antigen receptor T-cell (CAR-T) therapy. However, despite these dramatic advancements, resistance to these newer therapies, including targeted therapy and CAR-T cells, is seen in over 50% of patients. Thus, it remains an unmet need to better define the mechanisms of resistance and then develop rationally designed strategies to overcome resistance. The overall goal of this Synergistic Team Award is to develop improved curative therapies for patients with MCL at relapse. The goals will be addressed in three highly focused, independent but highly integrated projects that utilize state-of-the-art genomic technologies, patient-derived xenograft models, clinical data and primary MCL samples. With the joint effort of our laboratories, highly interactive and accomplished scientists, and physician researchers from multiple institutions with expertise in MCL and therapy, we are uniquely poised to develop improved next-generation of combination therapy for relapsed MCL patients.