Diversity Supplement for R37 Grant

Summary/Abstract This proposal is for a Diversity Supplement to R37CA273232 to support a graduate student Benjamin Kroger. Below is the abstract for the parent award, and as part of this diversity supplement, Mr. Kroger will be contributing to studies performing ribosome profiling to identify key LSC regulators selectively translated in the context of regulated protein

synthesis. Leukemia stem cells (LSCs) promote therapeutic resistance and poor clinical outcomes in acute myeloid leukemia (AML). Central to the function of LSCs is a capacity for aberrant self-renewal, but the mechanisms underlying this activity are not well understood. The long-term goal is to identify these mechanisms to develop new therapies that can eradicate

LSCs to improve clinical outcomes. The overall objectives in this application are to (i) determine if LSCs from specific genetic subtypes of AML are dependent on regulation of protein synthesis, (ii) determine whether LSCs in high-risk hematopoietic stem cell (HSC)- like AMLs are more dependent on regulated protein synthesis, and (iii) test a novel

therapeutic strategy inhibiting protein synthesis in LSCs. The central hypothesis is that LSCs aberrantly self-renew by adopting from normal HSCs a dependence on tightly regulated protein synthesis. The rationale for this project is based on the finding that the cell surface marker CD99 is selectively overexpressed on LSCs and serves to regulate

protein synthesis to promote LSC function. This offers a strong scientific framework by which new strategies to deplete LSCs can be developed. The central hypothesis will be tested by pursuing three specific aims: 1) Determining the role of regulated protein synthesis in promoting LSC function; 2) Determining if the cell-of-origin of AML influences

the dependence of LSCs on regulated protein synthesis; and 3) Determining if inhibition of protein synthesis can deplete LSCs in high-risk AML. In the first aim, genetically engineered mice will be used to generate models of AML lacking CD99, to test if this leads to dysregulated protein synthesis that impairs LSC self-renewal. LSCs from these models will

be evaluated to determine if they require low protein synthesis rates to prevent induction of tumor suppressors, the unfolded protein response, and the integrated stress response. Ribosome profiling will be performed to identify key LSC regulators selectively translated in the context of regulated protein synthesis. In the second aim, we will generate a mouse

model of HSC-like AML which mimics high-risk human AML. We will assess if LSCs in HSC- like AML exhibit heightened sensitivity to dysregulated protein synthesis. These studies will be complemented with an evaluation of protein synthesis in HSC-like human LSCs to determine if they also require maintenance of low levels of protein synthesis. The third aim

will test if the combination of a ribosome biogenesis-inhibitor with a BCL2-inhibitor currently used to treat AML can eradicate LSCs in high-risk HSC-like AML. The proposal is innovative, in the applicant’s opinion, because it aims to leverage a novel LSC-specific cell surface marker to establish a new paradigm for understanding mechanisms underlying

LSC self-renewal. The proposed research is significant because it is expected to provide a strong scientific justification for the development of therapies inhibiting protein synthesis to overcome therapeutic resistance in patients with high-risk AML. Ultimately, the knowledge gained from these studies may offer insights into the mechanisms that promote

the function of cancer stem cells in general, opening up opportunities for the development of new strategies to treat cancer.