The gallium complex KP46 sensitizes resistant leukemia cells and overcomes Bcl-2-induced multidrug resistance in lymphoma cells via upregulation of Harakiri and downregulation of XIAP in vitro.

Tris-(8-quinolinolato)gallium(III) (KP46, AP-002) is an orally administered investigational anticancer and bone-protective drug currently being evaluated in patients with advanced solid tumors with bone involvement. Despite the clinical efficacy of other gallium compounds in non-Hodgkin's lymphoma, effects of KP46 in hematological tumor settings have not been studied systematically before. We report here intriguing activities in various human cell lines, including such with multidrug resistance (MDR): In Nalm-6 lymphoblastic leukemia cell sublines, KP46 was capable of overcoming P-gp-related as well as P-gp-unrelated MDR. Apoptosis induction by KP46 was unaffected by bcl2-mediated vincristine-induced MDR in a BJAB lymphoma cell subline and even enhanced in a K562 leukemia subline with daunorubicin-induced MDR, which could be re-sensitized to daunorubicin by KP46. As the latter resistance is associated with lowered Harakiri (HRK) protein levels, a modulating effect of KP46 on HRK expression is suggested. This is consistent with the significant high upregulation of HRK on RNA and protein levels observed in KP46-treated parental BJAB cells according to qPCR and Western blot analysis, respectively. Furthermore, KP46 significantly reduces the protein level of X-linked inhibitor of apoptosis (XIAP) in BJAB cells, the most potent known inhibitor of apoptosis. Overall, these results indicate both a higher potential of HRK and XIAP as cellular targets for cancer therapy and a broader therapeutic potential of KP46 than hitherto envisaged.

Dihydroxyquingdainone Induces Apoptosis in Leukaemia and Lymphoma Cells via the Mitochondrial Pathway in a Bcl-2- and Caspase-3-Dependent Manner and Overcomes Resistance to Cytostatic Drugs In Vitro.

Isatis tinctoria and its indigo dyes have already provided highly active anti-leukaemic lead compounds, with the focus mainly being on indirubin, whereas indigo itself is inactive. There are many more indigoids to find in this plant extract, for example, quingdainone, an indigoid derived from tryptanthrin. We present here a new synthesis of hitherto neglected substituted quingdainones, which is very necessary due to their poor solubility behaviour, and a structure-dependent anti-leukaemic activity study of a number of compounds. Substituted α-phenylaminoacrylic acid was synthesised by hydrogen sulfide extrusion from an analogue mercaptoacetic acid, available from the condensation of rhodanin and a substituted tryptanthrin. It is shown that just improving water solubility does not increase anti-leukaemic activity, since a quingdainone carboxylic acid is inactive compared to dihydroxyquingdainone. The most effective compound, dihydroxyquingdainone with an AC50 of 7.5 µmole, is further characterised, revealing its ability to overcome multidrug resistance in leukaemia cells (Nalm-6/BeKa) with p-glycoprotein expression.

The homeodomain protein Cux1 interacts with Grg4 to repress p27 kip1 expression during kidney development.

The homeodomain protein Cux1 is highly expressed in the nephrogenic zone of the developing kidney where it functions to regulate cell proliferation. Here we show that Cux1 directly interacts with the co-repressor Grg4 (Groucho 4), a known effector of Notch signaling. Promoter reporter based luciferase assays revealed enhanced repression of p27(kip1) promoter activity by Cux1 in the presence of Grg4. Chromatin immunoprecipitation (ChIP) assays demonstrated the direct interaction of Cux1 with p27(kip1) in newborn kidney tissue in vivo. ChIP assays also identified interactions of Cux1, Grg4, HDAC1, and HDAC3 with p27(kip1) at two separate sites in the p27(kip1) promoter. DNAse1 footprinting experiments revealed that Cux1 binds to the p27(kip1) promoter on the sequence containing two Sp1 sites and a CCAAT box approximately 500 bp from the transcriptional start site, and to an AT rich sequence approximately 1.5 kb from the transcriptional start site. Taken together, these results identify Grg4 as an interacting partner for Cux1 and suggest a mechanism of p27(kip1) repression by Cux1 during kidney development.