Research we fund

Outcomes for patients with acute myelogenous leukemia who relapse after transplantation are dismal. This SCOR brings together an international group of collaborators with deep expertise in genomics, epigenetics, antigen presentation, and immune-regulation. They will focus on mechanisms of immune evasion by leukemia cells, identifying effective T cell responses to those evasive processes, and providing critical insights into the optimal approaches to model new and promising targets for immunotherapy with a goal of eliminating leukemia recurrence.

The focus of my research is to elucidate the core molecular regulators of malignant stem cell generation in multiple myeloma. My approach addresses the tumor cell-intrinsic versus niche-dependent mechanisms of myeloma regeneration by exploring transcription factor expression and stemness profiles within single cells from primary samples and patient-derived models. The central goal of my research is to uncover novel therapeutic strategies and translate these into new myeloma treatments.

The goal of the Clinical Trial Network of South Texas is to expand access to high quality clinical trials for under-represented minority (African American and Hispanic) patients with lymphoid cancers who receives care at the UT San Antonio Mays Cancer Center (MCC) and community oncology centers in South Texas. To achieve this goal, we will leverage the existing partnership between MD Anderson Cancer Center (MDACC) and its robust clinical trial infrastructure to identify and deploy suitable clinical trials. We also will strengthen the research infrastructure at MCC and community sites, including providing equipment, clinical trial navigation support, and oversight to successfully deploy trials. By establishing MDACC/MCC as a hub for clinical trials, developing the necessary research infrastructure at community oncology centers, and allowing patients to participate in clinical trials at their local oncology centers, this IMPACT program has the potential to improve clinical outcomes.

This project is the first to explore the origin of a newly discovered type of lymphoma called “BN2-DLBCL”. Mutations in a gene called “SPEN” are a defining feature of these tumors. Strikingly, SPEN mutations are more common in females and cause more deadly disease. Our proposal will reveal for the first time how these tumors originate from the immune system, how they are intimately linked to autoimmune disorders such as Lupus, why they occur preferentially in women, and how to cure them.

Myelodysplastic syndrome (MDS) is a blood disease with poor prognosis and frequent progression to acute myeloid leukemia (AML). There are currently no effective treatments. This proposal is based on a recent discovery by my group and proposes to investigate a protein called G⍺s (alpha subunit of the stimulatory G protein), as a novel therapeutic target for MDS. If successful, this work can lead to novel therapies that can transform the treatment of MDS, AML and possibly other cancers.

This proposal explores how inherited mutations in the DNA repair gene CHEK2 lead to blood cancers. Our work employs two unique resources: patient-derived cell lines and mice engineered with an inherited Chek2 variant that accurately models how bone marrow stem cells acquire DNA changes over time leading to bone marrow cancers. Our results may lead to new approaches that slow or prevent blood cancers in people with high risk.

Although molecular targeted therapy has dramatically changed how we treat cancer, the treatment for acute myeloid leukemia (AML) remains focused on the use of cytotoxic drugs with many patients eventually relapsing with their disease. Our studies have a uncovered a new nuclear structure that is dysregulated in myeloid leukemia. This proposal studies the identity and function of this nuclear body in human AML and strives to identify novel therapeutic strategies and targets in leukemia.

Mutations in a diverse set of genes can lead to pre-cancerous expansion of blood stem cells, but the factors that mediate the growth of these mutant clones are unknown. We recently discovered that many of these mutations lead to abnormal activation of a gene called TCL1A. Consequently, TCL1A may be an attractive target for treating or preventing blood cancers, but little is known about its function. Here, we will uncover how TCL1A influences the biology of pre-cancerous blood stem cells.

City of Hope (COH) has embarked on a strategic initiative to optimize our clinical network and increase research capacity at our Community and Affiliate Network (CAN) sites in Southern California. I would like to spearhead this endeavor for the Hematology program at our new Irvine campus in Orange county, which is set to open in August 2022. We are employing a hub-and-spokes model, in which the Duarte main campus is the main research center, with 3-5 multi-disciplinary CAN sites ultimately designated as research hubs. These CAN sites (hubs) will serve geographically proximal practice sites (spokes), which will refer patients for treatment on clinical trials at either the CAN site itself or at the main Duarte campus. Following a 6-month pilot for optimizing staffing, investigational pharmacy setup, specimen and data collection in Irvine, an additional CAN site will be initiated each year over a 5-year period to allow a wider area of Southern California residents to have access to high quality and impactful clinical trials in Hematology. Our ultimate goal is to accrue 20-50 patients per year from the community, depending on the number of sites activated each year.

Most patients with acute myeloid leukemia (AML) are not cured with chemotherapy alone, and most long-term survivors of AML have undergone an allogeneic stem cell transplant (also known as bone marrow transplant). The outlook is quite grim for patients whose AML relapses after transplant. We have developed a new type of treatment for AML called chimeric antigen receptor (CAR) T cells for these patients. The goal of this project is to investigate how to improve CAR T cells for AML.

Acute myeloid leukemia (AML) is a devastating blood cancer. Most AML patients will initially respond to standard therapy; however, for many patients the disease recurs resulting in patient death. Consequently, there is an urgent need to develop new therapeutic strategies for relapsed AML patients. The objective of our proposal is to understand and target properties specific to relapsed AML cells with the overall goal of improving relapsed AML patient outcomes.

We identified that KDM5 can regulate important transcription factors in multiple myeloma (MM) and regulate the bone marrow (BM) microenvironment in providing protection toward MM, which also reduces anti-MM immunity. Thus, our study will utilize our novel potent and selective KDM5 inhibitor to fully dissect the interactions between MM cells, the BM microenvironment and the immune system in cellular and animal models to establish important mechanistic insights into MM.