Research We Fund

The mitogen-activated protein kinase (MAPK) pathway is activated in high-risk leukemia and is a hallmark of resistance to therapies. This project uses patient-derived xenograft models of relapsed pediatric ALL and AML with activated RAS/MAPK to test whether clinically relevant MAPK mutations activate the VAV3/RAC pathway and if pharmacological inhibition of that pathway by a small molecule we developed synergizes with a MAPK-inhibitor to provide a new treatment strategy for RAS-driven leukemia.

The B-cell kinase SYK and its T-cell homolog ZAP70 have almost identical functions but are strictly segregated to B- and T-cells. We recently discovered that B-cell malignancies frequently coexpress ZAP70 and that only SYK but not ZAP70 can trigger negative B-cell selection and cell death. Here we test the hypothesis that ZAP70 enables malignant B-cell transformation, test pharmacological SYK-hyperactivation and validate ZAP70 as biomarker of patients who benefit from this approach.

Leukemia often results from aberrant gene expression caused by epigenetic alterations. Previously we discovered a novel histone acetylation reader domain in the ENL protein and demonstrated that this domain is essential for the survival of a wide range of acute leukemias, making it an attractive therapeutic target. We will develop specific inhibitors of ENL activity in acute leukemias and will use mouse models to define the role of ENL mutations identified in patients in leukemogenesis.

Our research program aims to gain a deeper understanding of the pathobiology of T-ALL and HSTL.

To this end, we will use novel mouse models, cutting-edge techniques and comprehensive genetic, pharmacological and metabolic interventions. In addition, we will perform unbiased experiments to identify novel therapeutic targets.

Our goal is to uncover new tools and targets for the treatment of T-ALL and HSTL, which could be used for the benefit of patients in the short/mid-term.