Research We Fund

We will test the efficacy of CAR T cell therapy for CMML. We will modify the tumor microenvironment to enhance their efficacy. and we will upscale CAR T cells to the next level in terms of their genetic structure.

In October 2023, LLS made an equity investment in Enterome to "support the ongoing Phase 2 SIDNEY study of EO2463 in indolent non-Hodgkin B-cell lymphoma."

Enterome is a clinical-stage biopharmaceutical company developing breakthrough immunomodulatory drugs for the treatment of cancer and immune diseases. Enterome’s pioneering approach to drug discovery is based on its unique and powerful bacterial Mimicry drug discovery platform, allowing it to analyze and uncover new biological insights from the millions of gut bacterial proteins in constant cross-talk with the human body. Its first-in-class small protein and peptide drug candidates modulate the immune system by closely mimicking the structure, effect or actions of specific antigens, hormones, or cytokines. 

EO2463 is a clinical-stage off-the-shelf OncoMimics™ peptide-based immunotherapy. It combines four microbial-derived OncoMimics™ peptides that closely mimic specific cytotoxic T cell (CD8+ T cell) epitopes in B cell Tumor-Associated Antigens CD20, CD22, CD37, and CD268 (BAFF receptor), as well as a helper CD4 peptide, UCP2. The SIDNEY trial is a multicenter, Phase 2 trial investigating EO2463 in monotherapy and in combination with standard of care - rituximab and rituximab in combination with lenalidomide – for treatment of patients with indolent NHL (NCT04669171).

T-cell leukemias and lymphomas have devastating outcomes if they recur after or don’t respond to standard treatment, with the only hope of cure being bone marrow transplant (BMT). Unfortunately, many pediatric, adolescent and young adult (AYA) patients are unable to achieve clinical remission (and thus unable to proceed to BMT) with standard salvage therapies, which are often even more toxic than upfront therapies. Available treatment options for patients with relapsed or refractory T-cell malignancies (particularly pediatric and AYA patients) are lacking, thus 3-year survival rates are <15% for these patients. This proposal aims to study a less toxic, targeted approach using patient or donor-derived T-cells engineered to target an antigen expressed on over 90% of T-cell malignancies that affect pediatric and AYA patients (CD7 Chimeric Antigen Receptor T-cells).

AML recurrence is a devastating event after allo-HCT. I hypothesize that it could be counteracted through targeting of leukemia-restricted mHAgs via TCR-like CARs. I will identify scFVs recognizing mHAg:HLA complexes using a cell-free nanobody screening platform, and test the anti-leukemia activity and safety of CAR-Ts bearing such scFVs in vitro and in vivo. Through this approach, I will build a library of CAR constructs able to provide population-scale coverage for at-risk allo-HCT patients.