Multidrug resistance protein (MRP) and P-glycoprotein (Pgp) are both members of the superfamily of ATP binding cassette plasma membrane drug transport proteins, which may be partly responsible for multidrug resistance of tumor cells. Although MRP has been identified as an organic anion transporter and Pgp as a transporter of certain positively charged compounds, there is considerable overlap in resistance spectrum, suggesting that both proteins transport important anticancer agents such as doxorubicin, etoposide, and vincristine. To obtain more insight in the handling of drugs by both proteins, we performed a detailed kinetic analysis of the efflux of calcein-acetoxymethyl ester (CAL-AM), a common neutral substrate for both proteins and compared it with the kinetics of efflux of calcein (CAL) which is only effluxed by MRP. CAL, the hydrolysis product of the nonfluorescent CAL-AM, is negatively charged and highly fluorescent. For this purpose Pgp+ K562/ADR and MRP+ GLC4/ADR tumor cells were incubated with CAL-AM in ATP-rich or ATP-depleted buffer, and the calcein formation was followed in time by fluorescence development. The intracellular CAL could be distinguished from effluxed (extracellular) CAL by addition to the medium of Co2+, which completely quenched the extracellular CAL fluorescence. The results showed that the Vmax for efflux of CAL-AM and CAL by MRP were very similar (1.0-1.2 x 10(5) molecules/cell/s) but that the Km for CAL-AM was much lower (0.05 microM) than for CAL (268 microM). The latter therefore is much less efficiently transported by MRP than CAL-AM. The Km for CAL-AM transport by Pgp (0.12 microM) was similar to that for MRP. Compared to previously published data for anthracyclines, the kinetic data for MRP-mediated CAL-AM pumping are most similar to those for the neutral hydroxydaunorubicin. These data give a quantitative account of transport properties of MRP for two related but differently charged compounds.
Fe(III) complexes of two anthracyclines, adriamycin and daunorubicin, have been studied. Using potentiometric and spectroscopic measurements, we have shown that adriamycin and daunorubicin form two well-defined species with Fe(III), which can be formulated as respectively Fe(HAd)3 and Fe(HDr)3. In these formulas, HAd and HDr stand for adriamycin and daunorubicin in which the 1,4-dihydroxy-anthraquinone moiety is half-deprotonated. Both complexes are six-membered chelates. The stability constant is beta = (2.5 +/- 0.5) X 10(28) for both complexes. Interaction with DNA has been studied showing that, despite strong coordination to Fe(III), anthracyclines are able to intercalate between DNA bases pairs, releasing the metal. These complexes display antitumor activity against P 388 leukemia that compares with that of the free drug. Fe(HAd)3, unlike adriamycin, does not catalyze the flow of electrons from NADH to molecular oxygen through NADH dehydrogenase. Moreover, it is shown that the triferric adriamycin compound so called "quelamycin" is in fact a mixture of Fe(HAd)3 and polymeric ferric hydroxide.
Doxorubicin, daunorubicin and other anthracycline antibiotics constitute one of the most important groups of drugs used today in cancer chemotherapy. The details of the drug interactions with membranes are of particular importance in the understanding of their kinetics of passive diffusion through the membrane which is itself basic in the context of multidrug resistance (MDR) of cancer cells. Anthracyclines are amphiphilic molecules possessing dihydroxyanthraquinone ring system which is neutral under the physiological conditions. Their lipophilicity depends on the substituents. The amino sugar moiety bears the positive electrostatic charge localised at the protonated amino nitrogen. The four anthracyclines used in this study doxorubicin, daunorubicin, idarubicin and idarubicinol (an idarubicin metabolite readily formed inside the cells) have the same amino sugar moiety, daunosamine, with pKa of 8.4. Thus, all drugs studied will exhibit very similar electrostatic interactions with membranes, while the major differences in overall drug-membrane behaviour will result from their hydrophobic features. Circular dichroism (CD) spectroscopy was used to understand more precisely the conformational aspects of the drug-membrane systems. Large unilamellar vesicles (LUV) consisting of phosphatidylcholine, phosphatidic acid (PA) and cholesterol, were used. The anthracycline-LUV interactions depend on the molar ratio of phospholipids per drug. At low molar ratios drug:PA, these interactions depend also on the anthracycline lipophilicity. Thus, both doxorubicin and daunorubicin bind to membranes as monomers and their CD signal in the visible is positive. However, doxorubicin with its very low lipophilicity binds to the LUV through electrostatic interactions, with the dihydroxyanthraquinone moiety being in the aqueous phase, while daunorubicin, which is more lipophilic is unable to bind only through electrostatic interactions and actually the hydrophobic interactions are the only detected. The highly hydrophobic idarubicin, forms within the bilayer a rather complex entity involving 2-3 molecules of idarubicin associated in the right-handed conformation, one cholesterol molecule and also molecule(s) of phosphatidic acid, as this special oligomeric species is not detected in the absence of negatively-charged phospholipids. Idarubicinol differs from idarubicin with CH(13)-OH instead of C(13)=O and its interactions with LUV are distinctly different. Its CD signal in the visible becomes negative and no self associations of the molecule within the bilayer could be detected. The variation of the sign of the Cotton effect (positive to negative) may derive from the changes in the C(6a)-C(7)-O(7)-C(1') dihedral angle. It is noteworthy that C(13)-OH group, which strongly favours formation of the dimeric species in aqueous solutions when compared to idarubicin prevent association inside the LUV bilayer. At high ratios of phospholipids per drug all of them are embedded within the bilayer as monomer.
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