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Cancer is one of the leading causes of death across all countries and its diagnosis still yields fear for the affected patient. Although treatment of cancer has made marvelous progress compared to the agents available thirty years ago, a cure for cancer, however, is still a distant prospect. Modern therapy still is a burden for many patients due to heavy side effects. With the development of agents targeting specific molecular targets on cancer cells, a new field of cancer therapy was opened and a small success story in the history of cancer began.
Aurora kinases represent a relatively new target in cancer therapy. The kinase is a essential part of mitosis and cell cycle progression and its overexpression has been shown to be related to many kinds of malignancies. Allosteric inhibition of a kinase is an increasing pre-clinical approach not yet established in the treatment of patients. In this thesis, we combine allostery with another innovative approach that is drug repurposing. If repurposed, a drug can be permitted to fast track drug admission to clinical trials.
I set up a screening of 1280 FDA approved drugs to identify small molecule compounds that affect the binding of Aurora kinase A and its main physiologic binding partner, TPX2. Further, I characterized the positive hits in vitro for their capabilities to displace TPX2 from Aurora A, to inhibit Aurora kinase activity, to thermally stabilize the protein and performed assays to determine their dissociation constant. Last but not least, I tested the compounds in cells for their effect on the cell viability and cell cycle via flow cytometry. Comparing the hit-compounds with controls I found that ATP-competitive AurA inhibitor MLN 8237 strongly displaces the interaction of Aurora A with TPX2.
Summarized, we identified eight hit compounds allosterically affecting Aurora A, but no compound proved to be active in all assays. Just one compound, PS 731, identified in another screening performed by our group and further characterized in this thesis remains interesting, especially when put in context with recent publications released in the time between the start of experiments for this thesis and its finalization.
Background: Chronic myelogenous leukemia (CML) and Philadelphia chromosome-positive (Ph+) acute lymphatic leukemia (Ph + ALL) are caused by the t(9;22), which fuses BCR to ABL resulting in deregulated ABL-tyrosine kinase activity. The constitutively activated BCR/ABL-kinase "escapes" the auto-inhibition mechanisms of c-ABL, such as allosteric inhibition. The ABL-kinase inhibitors (AKIs) Imatinib, Nilotinib or Dasatinib, which target the ATP-binding site, are effective in Ph + leukemia. Another molecular therapy approach targeting BCR/ABL restores allosteric inhibition. Given the fact that all AKIs fail to inhibit BCR/ABL harboring the 'gatekeeper' mutation T315I, we investigated the effects of AKIs in combination with the allosteric inhibitor GNF2 in Ph + leukemia.
Methods: The efficacy of this approach on the leukemogenic potential of BCR/ABL was studied in Ba/F3 cells, primary murine bone marrow cells, and untransformed Rat-1 fibroblasts expressing BCR/ABL or BCR/ABL-T315I as well as in patient-derived long-term cultures (PDLTC) from Ph + ALL-patients.
Results: Here, we show that GNF-2 increased the effects of AKIs on unmutated BCR/ABL. Interestingly, the combination of Dasatinib and GNF-2 overcame resistance of BCR/ABL-T315I in all models used in a synergistic manner.
Conclusions: Our observations establish a new approach for the molecular targeting of BCR/ABL and its resistant mutants using a combination of AKIs and allosteric inhibitors.