Three novel patient-derived BCR/ABL mutants show different sensitivity to second and third generation tyrosine kinase inhibitors.

BCR/ABL (Breakpoint Cluster Region protein/Abelson tyrosine-protein kinase 1) kinase domain (KD) mutations represent the most frequently described mechanism of resistance to the treatment with tyrosine kinase inhibitors (TKI) in patients with chronic myeloid leukemia (CML). Mutations may impair TKI activity by directly or indirectly impairing the drug binding to the protein. We report the discovery of three new BCR/ABL mutations, L248R, T315V, and F317R identified in two patients with CML (L248R and T315V) and in one patient with Ph+ acute lymphoblastic leukemia (ALL) (F317R). Mutations were screened against second-generation (bosutinib, nilotinib, and dasatinib), as well as third-generation TKIs (ponatinib/AP-24534 and DCC-2036). Furthermore, the activity profile of ponatinib and DCC-2036 against a panel of 24 clinically relevant BCR/ABL mutants is presented and compared to the other TKIs. The IC50 values for each TKI against the mutants and the IC50 increase over wild type BCR/ABL (relative resistance, RR) were calculated to define four resistance levels: sensitive (RR ≤ 2), moderately resistant (2 < RR ≤ 4), resistant (4 < RR ≤ 10), or highly resistant (RR > 10). L248R and T315V showed high resistance to imatinib, bosutinib, dasatinib, and nilotinib, intermediate resistance to ponatinib, but were sensitive to DCC-2036. Interestingly, F317R showed a moderate resistance to imatinib and nilotinib, but is resistant/highly resistant to dasatinib, bosutinib, ponatinib, and DCC-2036. The availability of drugs activity profiles may become a useful tool for clinicians dealing with the treatment of drug-resistant CML patients.

Synthesis, structure-activity relationship and crystallographic studies of 3-substituted indolin-2-one RET inhibitors.

The synthesis, structure-activity relationships (SAR) and structural data of a series of indolin-2-one inhibitors of RET tyrosine kinase are described. These compounds were designed to explore the available space around the indolinone scaffold within RET active site. Several substitutions at different positions were tested and biochemical data were used to draw a molecular model of steric and electrostatic interactions, which can be applied to design more potent and selective RET inhibitors. The crystal structures of RET kinase domain in complex with three inhibitors were solved. All three compounds bound in the ATP pocket and formed two hydrogen bonds with the kinase hinge region. Crystallographic analysis confirmed predictions from molecular modelling and helped refine SAR results. These data provide important information for the development of indolinone inhibitors for the treatment of RET-driven cancers.

Inhibition of RET tyrosine kinase by SU5416.

Thyroid neoplasia is frequently associated with rearranged during transfection (RET) proto-oncogene mutations that cause hyperactivation of RET kinase activity. Selective inhibition of RET-mediated signaling should lead to an efficacious therapy. SU5416 is a potent inhibitor of vascular endothelial cell growth factor receptor, c-Kit, and FLT-3 receptor tyrosine kinases presently used in clinical trials. We found that SU5416 inhibits RET with similar potency, both in cell-free assays and in cells, thus causing proliferation arrest in oncogenic RET-transfected cells and in papillary thyroid carcinoma (PTC) cells expressing the RET/PTC1 oncogene, but not in RET-negative control cells. SU5416 inhibited RET-mediated signaling through the extracellular signal regulated kinase (ERK) and JNK pathways. In addition, we show that a naturally occurring MEN2 mutation at codon 804 confers resistance to SU5416, but not to the related compound SU4984. We provide a possible explanation to these results by using molecular docking. Finally, SU5416 was also assessed against an array of 52 tyrosine and serine/threonine kinases.

Molecular mechanisms of resistance to imatinib in Philadelphia-chromosome-positive leukaemias.

Imatinib (STI571 or CGP57148B) is an innovative treatment for tumours with a constitutively activated form of c-ABL, c-KIT, or PDGFR. Such tumours include Philadelphia-chromosome-positive (Ph-positive) leukaemias, gastrointestinal stromal tumours, and PDGFR-positive leukaemias. Diseases such as primary hypereosinophilia and dermatofibrosarcoma protuberans also seem to respond to imatinib. Clinical trials assessing the therapeutic effects of imatinib have shown that the drug is highly effective with few associated side-effects, achieving durable cytogenetic responses in many patients with chronic-phase BCR-ABL-positive leukaemias. However, the emergence of resistance, particularly in patients with acute leukaemias, has prompted intense research, and many are concerned about the future prospects for imatinib. The resistance has been found in patients with acute-phase disease, but may also occur in patients with chronic-phase disease. Two cellular mechanisms for resistance to imatinib have been identified: amplification of BCR-ABL gene and mutations in the catalytic domain of the protein. In addition, suboptimum inhibition of BCR-ABL in vivo could contribute to the selection of resistant cells. We have summarised all currently available data on resistance to imatinib, both published and unpublished, including the mechanisms of resistance identified so far, and their clinical relevance to the different forms of Ph-positive leukaemias is discussed. Furthermore, we discuss strategies to overcome or prevent the development of resistance.