Active transport of conjugated and unconjugated electrophiles out of cells is essential for cellular homeostasis. We have previously identified in human tissues a transporter, DNP-SG [S-(2, 4-dinitrophenyl)glutathione] ATPase, capable of carrying out this function [Awasthi et al. (1998) Biochemistry 37, 5231-5238, 5239-5248]. We now report the cloning of DNP-SG ATPase. The sequence of the cDNA clone was identical to that of human RLIP76, a known Ral-binding protein. RLIP76 expressed in E. coli was purified by DNP-SG affinity chromatography. Purified recombinant RLIP76: (1) had ATPase activity stimulated by DNP-SG or doxorubicin (DOX), and the K(m) values of RLIP76 for ATP, DOX, and DNP-SG were similar to those reported for DNP-SG ATPase; (2) upon reconstitution with asolectin as well as with defined lipids, catalyzed ATP-dependent transport of DNP-SG and DOX with kinetic parameters similar to those of DNP-SG ATPase; (3) when transfected into K562 cells, resulted in increased resistance to DOX, and increased ATP-dependent transport of DNP-SG and DOX by inside-out membrane vesicles from transfected cells; (4) direct uptake of purified RLIP76 protein into mammalian cells from donor proteoliposomes confers DOX resistance. These results indicate that RLIP76, in addition to its role in signal transduction, can catalyze transport of glutathione conjugates and xenobiotics, and may contribute to the multidrug resistance phenomenon.
We have recently shown that RLIP76, a Ral-binding, GTPase-activating protein, is an ATP-dependent transporter of doxorubicin (DOX) as well as glutathione conjugates [Awasthi, S., et al. (2000) Biochemistry 39, 9327-9334]. RLIP76 overexpressed in human cells or transformed E. coli undergoes proteolysis to yield several fragments, including two prominent peptides, N-RLIP76(1-367) and C-RLIP76(410-655), from the N- and C-terminal domains, respectively. To investigate whether the fragmentation of RLIP76 has any relevance to its transport function, we have studied the characteristics of these two peptide fragments. Recombinant N-RLIP76(1-367) and C-RLIP76(410-655) were purified from overexpressing transformed E. coli. While N-RLIP76(1-367) readily underwent proteolysis, showing SDS-gel patterns similar to those of RLIP76, C-RLIP76(410-655) was resistant to such degradation. Both N-RLIP76(1-367) and C-RLIP76(410-655) had ATPase activity (K(m) for ATP, 2.5 and 2.0 mM, respectively) which was stimulated by DNP-SG, DOX, and colchicine (COL). ATP binding to both peptides was confirmed by photoaffinity labeling with 8-azido-ATP that was increased in the presence of compounds that stimulated their ATPase activity. Photoaffinity labeling was also increased in the presence of vanadate, indicating trapping of a reaction intermediate in the ATP binding site. The ATP binding sites in N-RLIP76(1-367) and C-RLIP76(410-655) were identified to be (69)GKKKGK(74) and (418)GGIKDLSK(425), respectively. Mutation of K(74) and K(425) to M residues, in N-RLIP76(1-367) and C-RLIP76(410-655), respectively, abrogated their ATPase activity as well as azido-ATP labeling. Proteoliposomes reconstituted with either N-RLIP76(1-367) or C-RLIP76(410-655) alone did not catalyze ATP-dependent transport of DOX or COL. However, proteoliposomes reconstituted with a mixture of N-RLIP76(1-367) and C-RLIP76(410-655) mediated such transport. Proteoliposomes reconstituted with the mixture of mutant peptides lacking ATPase activity did not exhibit transport activity. Present studies have identified the ATP binding sites in RLIP76, and show that DOX and COL transport can be reconstituted by two fragments of RLIP76.
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