Purification of breast cancer resistance protein ABCG2 and role of arginine-482

Human ABCG2 was efficiently overexpressed in insect cell membranes, solubilized with 3-[(3-cholamidopropyl)dimethyl ammonio]-1-propanesulfonate, and purified through N-terminal hexahistidine tag. Its functionality was assessed by high vanadate-sensitive ATPase activity, and nucleotide-binding capacity. Interestingly, the R482T point mutation increased both maximal hydrolysis rate and affinity for MgATP, and lowered sensitivity to vanadate inhibition. Direct nucleotide binding, as monitored by quenching of intrinsic fluorescence, indicated a mutation-related preference for ATP over ADP. The R482T mutation only produced a limited change, if any, on the binding of drug substrates, indicating that methotrexate, on the one hand, and rhodamine 123 or doxorubicin, on the other hand, bound similarly to wild-type and mutant transporters whether or not they were subject to cellular transport. In addition, the characteristic inhibitors GF120918 and 6-prenylchrysin, which alter mitoxantrone efflux much better for wild-type than mutant ABCG2, bound similarly to purified ABCG2, while the highly-potent Ko143 bound in the nanomolar range also effective in inhibition of drug transport. All results indicate that the role of the arginine-482 mutation on substrate drug transport and inhibitor efficiency is not mediated by changes in drug binding. Received 10 April 2006; received after revision 22 May 2006; accepted 12 June 2006 A. Pozza and J. M. Perez-Victoria contributed equally to this work     

RU49953: a non-hormonal steroid derivative that potently inhibits P-glycoprotein and reverts cellular multidrug resistance

Progesterone and the antiprogestin RU38486 have been reported as non-transported modulators of P-glycoprotein-mediated drug efflux. However, their hormonal properties limit their potential for clinical trials. The present work shows that some derivatives from either progesterone/RU38486 or estradiol, displaying differential interaction with hormone receptors, bind to P-glycoprotein and chemosensitize the growth of MDR1-transfected cells to vinblastine more strongly than does RU38486. Structure comparison of the compounds indicates that the highly hydrophobic estradiol derivative RU49953, which does not interact with any hormone receptor, inhibits P-glycoprotein-mediated drug efflux very efficiently, as monitored by flow cytometry, and prevents drug site photoaffinity labeling by azidopine. It induces a much higher chemosensitization than the well-known P-glycoprotein modulator verapamil, which is itself more efficient than RU38486. RU49953 therefore constitutes a promising new lead for steroid-type modulators of multidrug resistance.