Research we fund

Our study is designed to directly inform the pathways through which health insurance influences access to care at an SCC for individuals with AYA ALL using a combination of cancer registry, survey, and cost-benefit analyses. This research will contribute to knowledge of the implications of health insurance coverage on ALL cancer care in young adults and inform policy-relevant solutions, including determining whether patients are bypassing an SCC for treatment at a more distant facility, calculating estimates of insurance acceptance and access challenges at ALL treating facilities and identifying the financial implications of shifting care to SCCs with demonstrated survival improvements for this population.

Project Term: June 1, 2023 - May 31, 2026

The overall goal of this project is to understand the role of insurance design on financial toxicity and access to care among individuals with blood cancer. To understand this interplay, we will use a unique and innovative linkage of the 2012-2019 Colorado Cancer Registry (CCR) to the 2013-2021 Colorado All-Payer Claims Database and the LexisNexis and TranUnion financial and life event databases. Our specific aims are to 1) Estimate the number of individuals with blood cancer who are potentially underinsured over time relative to individuals with solid tumors or no history of cancer; 2) Examine the relationship between being underinsured and experiencing financial toxicity after diagnosis in individuals diagnosed with blood cancer relative to those with solid tumors or no history of cancer; and 3) Examine differences in access to cancer care including time to treatment, treatment intensity and survival in underinsured individuals with blood cancer versus those with more generous insurance coverage.

Project Term: June 1, 2023 - May 31, 2026

Although they represent a major therapeutic progress for blood cancers, CAR-T cells and other T-cell based therapies are subject to eventual development of resistance to many patients. Natural killer (NK) cell-based therapies are highly active against many types of blood cancer cells which are resistant to T cells, but in our CRISPR studies death receptor signaling defects emerge as a common downstream mechanism of resistance to both T- and NK-cell therapies. Building on extensive pharmacological and genomic screens, this project will specifically examine the role of SMAC mimetics and JAK/STAT inhibitors in enhancing the response of blood cancer cells (e.g., multiple myeloma, leukemias) to CAR-T or NK cell therapies. We will place emphasis of studies with patient-derived samples in vitro (Integrated Functional Immune Profiling Platform) and in vivo, including humanized bone marrow-like scaffolds, to provide a translationally-relevant simulation of the potential of these compounds to enhance the clinical activity of cell-based immunotherapies in blood cancers.

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

Our laboratory and those of others discovered highly recurring mutations in the gene MYD88 which are found in patients with various B-cell cancers including Waldenstrom’s Macroglobulinemia (95-97%), ABC Subtype of Diffuse B-cell Lymphoma (30-40%), Primary Central Nervous Lymphoma (80%), Marginal Zone Lymphoma (10%) and Chronic Lymphocytic Leukemia (5-10%). Our laboratory and those of others showed that mutated MYD88 triggers BTK, which is the target of BTK-inhibitors like ibrutinib, acalabrutinib and zanubrutinib though complete remissions are rare with these agents largely in part because other pro-survival molecules are activated by mutated MYD88 such as HCK and IRAK1. In these studies, we will develop potent and selective inhibitors to HCK and IRAK1, including PROTACs which inhibit and degrade these molecules, using lead molecules and scaffolds whose target selectivity and activity we previously validated. We will also investigate the mechanisms underlying the inactivation of the Inhibitor of BTK (IBTK) as a potential new target for development of inhibitors for use in MYD88 mutated lymphomas.

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

In up to half of patients with hematologic malignancies undergoing allogeneic stem cell transplantation, the trajectory of a smooth recovery toward cure is disrupted by acute graft-versus-host disease (aGVHD). Inspired by the role of intestinal microbial communities in aGVHD pathogenesis, we recently completed the largest fecal microbiota transplantation (FMT) trial to date in transplant recipients. We established the safety of standardized third-party FMT and characterized FMT effects on the microbiota, leading to the proposed randomized, placebo-controlled phase 2 trial of FMT to prevent aGVHD.

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

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.

Project Term: July 1, 2023 - August 31, 2026

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.

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

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.

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

Acute myeloid leukemia is life-threatening and heterogeneous, and although classification models help guide treatment, they do not use detailed phenotypic information or dynamically update with new data during a patient’s course. We will develop computational methods to extract both mutations and phenotype from the electronic health record. Machine learning models will be built that adapt to new data over time so that all clinically relevant data is used when personalizing a patient’s therapy.

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

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.

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

This work focuses on characterizing the role of FAM72A in EBV-driven B cell tumorigenesis. This protein is upregulated by EBV during the transformation of B cells and overexpressed in many hematologic cancers. Using a combination of in vitro and in vivo EBV transformation models, high-throughput drug screens, and structural analysis we aim to find small molecules inhibitors that target FAM72A and determine if these drugs can prevent or hinder EBV-associated B cell malignancies.

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

This research will investigate blood stem cell mutations associated with progression of myeloproliferative neoplasm (MPN) to secondary acute myeloid leukemia (sAML). Our preliminary data suggest that pre-leukemic cells with particular mutations may have a selective advantage in a background of certain MPN subtypes. We will confirm this by utilizing mouse models and both MPN and sAML primary patient samples. Ultimately, we will examine and test inhibition of mechanisms which drive MPN to sAML.

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