Research we fund

p>SIRT5 is a master regulator of central energy metabolism. The survival and growth of Acute Myeloid Leukemia (AML) cells depend on SIRT5. I will employ genetic SIRT5 disruption and small molecule inhibitors to target SIRT5 in Acute Lymphoblastic Leukemia (ALL) cells and primary samples. This study aims to 1) determine the effects of SIRT5 inhibition on ALL in vitro and in vivo, and 2) identify SIRT5-regulated pathways and mechanisms underlying SIRT5 dependency in T-ALL. 

Project Term: July 1, 2024 - June 30, 2026

AML risk stratification established by previous studies do not reflect survival outcomes observed in Black patients. Exome sequencing of 100 Black AML patients revealed the novel variants previously not affiliated with AML, including PHIP. Using multiomic patient sample captures and GEMMs, we will functionalize variants in PHIP and assess if they drive leukemogenesis and/or therapy resistance. The overall goal of this work is to implement inclusive genetic assessment tools for AML diagnosis.

Project Term: July 1, 2024 - June 30, 2027

In June 2022, LLS made an equity investment in Faron Pharmaceuticals to "Support Clinical Development of the Bexmarilimab Program for Leukemia Indications."Faron is a clinical stage biopharmaceutical company developing novel treatments for medical conditions with significant unmet needs caused by dysfunction of our immune system. The Company currently has a pipeline based on the receptors involved in regulation of immune response in oncology, organ damage and bone marrow regeneration. Bexmarilimab, a novel anti-Clever-1 humanized antibody, is its investigative precision immunotherapy with the potential to provide permanent immune stimulation for difficult-to-treat cancers through targeting myeloid function. A Phase 2 study (BEXMAB) of bexmarilimab in combination with azacitidine is currently enrolling high-risk MDS patients in the US and Finland (NCT05428969).

Project Term: June 30, 2022 - TBD

In March 2021, LLS made an equity investment in Immune-Onc Therapeutics to support the "Phase 1 Clinical Development of IO-202, An Antibody Targeting LILRB4, for the Treatment of AML with Monocytic Differentiation and CMML."Immune-Onc is a private, clinical-stage cancer immunotherapy company dedicated to the discovery and development of novel myeloid checkpoint inhibitors for cancer patients. The company aims to translate unique scientific insights in myeloid cell biology and immune inhibitory receptors to discover and develop first-in-class biotherapeutics that reverse immune suppression in the tumor microenvironment. Immune-Onc has a differentiated pipeline with a current focus on targeting the Leukocyte Immunoglobulin-Like Receptor subfamily B (LILRB) of myeloid checkpoints. The company’s work builds on early research by Chengcheng (Alec) Zhang, Ph.D. at the University of Texas Southwestern Medical Center that was also funded by LLS grants.IO-202 is a first-in-class antibody targeting the LILRB4 and has entered a phase 1 cohort expansion clinical trial (NCT0437243) for the treatment of AML (IO-202 in combination with azacitidine) and CMML (IO-202 in combination with azacitidine). 

Project Term: March 5, 2021 - TBD

Tmdshe 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.

Project Term: February 1, 2024 - January 29, 2029

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.

Project Term: July 1, 2024 - June 30, 2027

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.

Project Term: July 1, 2024 - June 30, 2027

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.

Project Term: July 1, 2024 - June 30, 2027

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.

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

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.

Project Term: July 1, 2024 - June 30, 2027

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.

Project Term: July 1, 2024 - June 30, 2027

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.

Project Term: July 1, 2024 - June 30, 2027