Contribution of the nucleoside transport system to doxorubicin transport in HL60 cells but not in mononuclear cells

Effect of linalool as a component of Humulus lupulus on doxorubicin-induced antitumor activity

As malignant neoplasm is a major public health problem, there is a need for the development of a novel modulator that enhances antitumor activity and reduces adverse reactions to antitumor agents. In this study, the effects of some volatile oil components in Humulus lupulus on doxorubicin (DOX) permeability in tumor cells and DOX-induced antitumor activity were examined. In vitro, DOX levels in tumor cells by combined linalool as its component significantly increased in the DOX influx system, and the increased effect by linalool on DOX cytotoxicity was shown. In vivo, the combination of DOX with linalool significantly decreased tumor weight compared with that of DOX alone treated group. The promotion of DOX influx level by combined linalool did not depend on energy, whereas it was suppressed by the absence of Na(+). This promoting effect was suppressed by the presence of S-(4-nitrobenzyl)-6-thioinosine and inhibited dependently on phlorizin concentration. It is considered that linalool promoted DOX influx in tumor cells because of its action on DOX transport through concentrative Na(+)-dependent nucleoside transporter 3, which increased DOX concentration in tumor cells and thus enhanced the antitumor activity of DOX. Therefore, linalool as a food component is anticipated to be an effective DOX modulator.

Increased effects of MPDAX, a novel xanthine derivative, on antitumor activity of doxorubicin

To clarify the effect of 1-methyl-3-propyl-7-N,N-dimethylpropylamide-xanthine (MPDAX) on doxorubicin (DOX) transport, we examined the efficacy of MPDAX as an amplifier of the antitumor activity of DOX in mice bearing tumors with different properties as to DOX transport across cell membranes. MPDAX significantly enhanced the DOX-induced antitumor activity on DOX-sensitive tumors. It is expected that the increase in antitumor activity caused by MPDAX contributes to the increased DOX concentration in tumors due to the MPDAX-induced change in DOX transport via the transporter expressed in sensitive tumor cells. In contrast, in M5076, a lower sensitive to DOX, MPDAX decreased the tumor weight by half at an otherwise ineffective dose of DOX. Furthermore, in P388/DOX, DOX has no effect, but MPDAX caused an elevation of the DOX-induced antitumor activity with an increase in the DOX concentration in the tumors. The results suggested that MPDAX is a novel amplifier for antitumor agents as it significantly increased the antitumor activity toward tumors with different properties. The DOX concentrations in the MPDAX + DOX group for all tumor lines were about two-fold those in the DOX alone group. Furthermore, MPDAX and DOX exhibited significant inhibitory effects on uridine and thymidine uptake. It is known that nucleoside transporters increase the membrane permeability of DOX. We speculated that MPDAX inhibits the cell membrane transport of uridine and thymidine via nucleoside transporters. MPDAX, acting via nucleoside transporters, increases the DOX-induced antitumor activity toward many tumor types and is an useful biochemical modulator.

Synthetic 1,4-anthracenediones, which block nucleoside transport and induce DNA fragmentation, retain their cytotoxic efficacy in daunorubicin-resistant HL-60 cell lines

Anthracene-1,4-dione and 6,7-dichloro-1,4-anthracenedione (code names AQ1 and AQ4, respectively) are cytostatic (IC50: 53 and 110 nM, respectively) and cytotoxic (IC50: 100 and 175 nM, respectively) in wild-type drug-sensitive HL-60-S tumor cells at day 4 in vitro. Therefore, the antitumor effects of these drugs were assessed and compared to those of daunorubicin (DAU) in HL-60-RV and HL-60-R8 tumor cells, which are, respectively, P-glycoprotein-positive and -negative multidrug-resistant (MDR) sublines. In contrast to DAU, which loses its cytostatic [resistance factors (RFs): 30.3-31.8] and cytotoxic (RFs: 48.8-58.1) activities in MDR sublines, AQ1 inhibits cell proliferation (RFs: 0.9-1.3) and cell viability (RFs: 1.4-1.6) as effectively in HL-60-RV and HL-60-R8 as in HL-60-S cells. Similarly, DAU decreases the rate of DNA synthesis less effectively in MDR sublines (RFs: 8.0-13.3) but AQ1 inhibits the incorporation of [3H]thymidine into DNA to the same degree in HL-60-S as in HL-60-RV and HL-60-R8 cells (RFs: 0.9-1.1). In contrast to DAU, which is ineffective, the advantage of AQ1 is its ability to block the cellular transport of purine and pyrimidine nucleosides in HL-60-S cells, an effect which persists in the MDR sublines (RFs: 1.1). AQ4, which mimics to a lesser degree all the antitumor effects of AQ1, except the inhibition of adenosine transport, also retains its effectiveness in MDR sublines (RFs: 1.1-3.1). The peaks of DNA cleavage caused by DAU and AQ1 in HL-60-S cells shift to lower concentrations with increasing times of drug exposure but DAU loses most of its ability to induce DNA fragmentation in MDR sublines, whereas the levels of AQ1-induced DNA cleavage at 16 and 24 h are nearly equivalent in HL-60-S, HL-60-RV and HL-60-R8 cells. Because they not only mimic the antitumor effects of DAU in the nM range but also block nucleoside transport and remain effective in tumor cells that have developed different mechanisms of MDR, AQ1 and AQ4 analogs might be valuable to develop new means of polychemotherapy.

Inhibition of glutamate transporter by theanine enhances the therapeutic efficacy of doxorubicin

Theanine, a major amino acid existing in green tea, enhanced the antitumor activity of doxorubicin (DOX) due to inhibition of DOX efflux from tumor cells. In order to clarify the mechanism, we have investigated the contribution of glutamate transporters to the action of theanine, because theanine is a glutamate analogue. In M5076 ovarian sarcoma cells, glutamate transport inhibitors reduced the efflux of DOX, as well as theanine. Incidentally, theanine significantly inhibited the glutamate uptake by M5076 cells in a concentration-dependent manner similar to specific inhibitors. These results suggested that the inhibition of DOX efflux was induced by the inhibition of glutamate transport by theanine. In addition, RT-PCR and Western blot analysis revealed the expression of GLAST and GLT-1, astrocytic high-affinity glutamate transporters, in M5076 cells. Thus, theanine was shown to competitively inhibit the glutamate uptake by acting on these glutamate transporters. This action suggested the contribution of glutamate transporters to the inhibition of DOX efflux by theanine. We revealed the novel mechanism of enhancement of the antitumor efficacy of DOX via the inhibition of glutamate transporters by theanine.

Effects of 1-methyl-3-propyl-7-butylxanthine (MPBX) on idarubicin-induced antitumor activity and bone marrow suppression

The effects of 1-methyl-3-propyl-7-butylxanthine (MPBX), a xanthine derivative, on idarubicin (IDA)-induced antitumor activity against P388 leukemia cells (P388) and bone marrow suppression were examined. In P388 tumor-bearing mice, the combination of MPBX with IDA increased the antitumor activity of IDA. The IDA concentration in the tumors in the MPBX combination group increased by 2.0-fold compared to the level in the IDA-alone group. On the other hand, as regards IDA-induced bone marrow suppression, the combination of MPBX with IDA reduced the decrease in the bone marrow cell number by 30% compared to that in the IDA-alone group. In addition, the IDA concentration in the bone marrow cells was decreased by the combination of MPBX with IDA. An in vitro experiment showed that MPBX facilitated IDA influx and suppressed IDA efflux in P388 cells. In conclusion, the combination of MPBX with IDA increased the antitumor activity and decreased the bone marrow suppression. Therefore, we expect that the combination of MPBX with IDA will be useful for leukemia chemotherapy.