Identification of a Water-Soluble Indirubin Derivative as Potent Inhibitor of Insulin-like Growth Factor 1 Receptor through Structural Modification of the Parent Natural Molecule.

Indirubins have been identified as potent ATP-competitive protein kinase inhibitors. Structural modifications in the 5- and 3'-position have been extensively investigated, but the impact of substituents in 5'-position is not equally well-studied. Here, we report the synthesis of new indirubin 3'- and 5'-derivatives in the search of water-soluble indirubins by introducing basic centers. Antiproliferative activity of all compounds in tumor cells was evaluated along with kinase inhibition of selected compounds. The results show the 3'-position to tolerate large substituents without compromising activity, whereas bulk and rigid substituents in 5'-position appear unfavorable. Screening molecular targets of water-soluble 3'-oxime ethers revealed 6ha as preferential inhibitor of insulin-like growth factor 1 receptor (IGF-1R) in a panel of 22 protein kinases and in cells. Consistently, 6ha inhibited tumor cell growth in the NCI 60 cell line panel and induced apoptosis. The results indicate that the 5'-position provides limited space for chemical modifications and identify 6ha as a potent water-soluble indirubin-based IGF-1R inhibitor.

7,7'-Diazaindirubin--a small molecule inhibitor of casein kinase 2 in vitro and in cells.

Aza- and diaza-bisindoles were synthesized by coupling of 7-azaisatin, 7-azaoxindol, 7-azaindoxyl acetate, and their non-aza counterparts, respectively. Whereas 7,7'-diazaindigo (10) and 7,7'-diazaisoindigo (11) did not show antiproliferative activity in several human tumor cell lines up to 100 µM, 7-azaindirubin (12) and 7'-azaindirubin (13) were more active than the parent molecule, indirubin, in LXFL529L cells (human large cell lung tumor xenograft), and 7,7'-diazaindirubin (14) was exhibiting substantially enhanced growth inhibitory activity in these cells. In the NCI 60 cell line panel, 14 displayed antiproliferative activity preferentially in certain melanoma and non-small cell lung cancer cells. In contrast to the potent serine/threonine/tyrosine kinase inhibition observed for indirubins, kinase inhibition profiling of 14 in 220 kinases revealed largely a loss of kinase inhibitory activity towards most kinases, with retained inhibitory activity for just a few kinases. At 1 µM concentration, especially casein kinases CK1γ3, CK2α, CK2α2, and SIK were inhibited by more than 50%. In cell-based assays, 14 markedly affected CK2-mediated signaling in various human tumor cells. In MCF7 cells, 14 induced cell cycle arrest at G1 and G2/M and apoptosis, whereas CK2-deficient MCF7 cells were resistant. These findings reveal a novel key mechanism of action for 14, suggesting primarily CK2 inhibition to be causally related to growth inhibition of human tumor cells.