DESCRIPTION (provided by applicant): B cell lineage acute lymphoblastic leukemia (ALL) represents the most frequent malignancy in children and is also common in adults. Compared to patients with other malignancies, cure rates for patients with ALL are in general higher. The ALL subset with the so-called Philadelphia chromosome (Ph) encoding the oncogenic BCR- ABL1 kinase, however, has a particularly poor prognosis. Ph+ ALL is typically treated with BCR-ABL1 kinase inhibitors such as Imatinib. The treatment response to Imatinib, however, is not durable and after a latency of only a few months, Ph+ ALL cells become drug-resistant and ALL relapses. Of note, the oncogenic BCR-ABL1 kinase is not only expressed in Ph+ ALL (mainly p190 BCR-ABL1) but also in >95% of cases of chronic myeloid leukemia (CML; mainly p210 BCR-ABL1). In contrast to Ph+ ALL, long-term treatment of CML with Imatinib is effective and resistance develops only rarely. In a subgroup of patients with CML, however, the disease progresses into B lymphoid blast crisis (CML-LBC), in which treatment responses are as short-lived as in Ph+ ALL. In most cases, acquired resistance to Imatinib in Ph+ ALL and CML-LBC can be attributed to somatic mutations within the BCR-ABL1 kinase domain, which compromise the efficacy of Imatinib. In preliminary experiments for this proposal, we show that AID is specifically expressed in B cell lineage + clones of BCR-ABL1-driven leukemia (Ph ALL and CML-LBC). In these cells, AID functions as a mutator and thereby contributes to the drug-resistance typically observed in Ph+ ALL and CML-LBC. Based on these findings, our proposal addresses the question of + (1) how AID contributes to genetic instability and drug-resistance in Ph ALL (e.g. AID-specific deletions; Aim 1), (2) to which extent AID contributes to the progression of chronic phase CML to CML-LBC (outgrowth of B lymphoid subclones that carry advantageous mutations; Aim 2), (3) which factors cause aberrant expression of AID in Ph+ ALL and CML-LBC (Aim 3), + (4) and whether AID-expressing clones in Ph ALL and CML-LBC can be specifically targeted in a prodrug- based approach that takes advantage of the enzymatic activity of AID (Aim 4). + Together, these four Aims will help to elucidate mechanisms of drug-resistance in Ph ALL and CML-LBC and + propose a novel concept of targeted treatment Ph ALL and CML-LBC for pre-clinical evaluation. Aim 1: Contribution of AID to genetic instability in Ph+ ALL: We have generated BCR-ABL1-transformed B cell lineage leukemia cells with three levels of AID expression based on their genotype, namely Aid-/-, endogenous AID and forced AID-overexpression. We have injected these leukemia cells into congenic mouse recipients and will compare the developing leukemia clones by comparative genomic hybridization (CGH) analysis to identify AID-specific deletions. Deletion breakpoints will be verified by FISH analysis and mapped to AID-related somatic hypermutation hot spots. We will compare development of Imatinib-resistance in Aid-/- and Aid-wildtype leukemias developing in BCR-ABL1 p190-transgenic mice. Aim 2: Contribution of AID-induced mutations to progression of CML into lymphoid blast crisis: To clarify to which extent AID contributes to the progression of CML into lymphoid blast crisis, we will take two approaches. (1) Transformation of hematopoietic stem cells (HSC) by p210 BCR-ABL1 induces CML-like leukemia with subsequent progression into B lymphoid blast crisis. Studying transgenic mice expressing p210 BCR-ABL1 under control of the HSC-specific Scl-promoter on an Aid-/- background, we will investigate whether Aid-function is required for the outgrowth of B lymphoid blast crisis clones. Second, we will cross Scl-BCR-ABL1 p210 transgenic mice with an Aid-Cre reporter strain that carries YFP preceded by a loxP-flanked Stop cassette. Expression of Aid in these cells will lead to permanent genetic labeling with YFP. Based on YFP-labeling, this mouse model wil |