Functionally similar vanadate-induced 8-azidoadenosine 5'-[alpha-(32)P]Diphosphate-trapped transition state intermediates of human P-glycoprotin are generated in the absence and presence of ATP hydrolysis

P-glycoprotein (Pgp) is an ATP-dependent drug efflux pump whose overexpression confers multidrug resistance to cancer cells. Pgp exhibits a robust drug substrate-stimulable ATPase activity, and vanadate (Vi) blocks this activity effectively by trapping Pgp nucleotide in a non-covalent stable transition state conformation. In this study we compare Vi-induced [alpha-(32)P]8-azido-ADP trapping into Pgp in the presence of [alpha-(32)P]8-azido-ATP (with ATP hydrolysis) or [alpha-(32)P]8-azido-ADP (without ATP hydrolysis). Vi mimics P(i) to trap the nucleotide tenaciously in the Pgp.[alpha-(32)P]8-azido-ADP.Vi conformation in either condition. Thus, by using [alpha-(32)P]8-azido-ADP we show that the Vi-induced transition state of Pgp can be generated even in the absence of ATP hydrolysis. Furthermore, half-maximal trapping of nucleotide into Pgp in the presence of Vi occurs at similar concentrations of [alpha-(32)P]8-azido-ATP or [alpha-(32)P]8-azido-ADP. The trapped [alpha-(32)P]8-azido-ADP is almost equally distributed between the N- and the C-terminal ATP sites of Pgp in both conditions. Additionally, point mutations in the Walker B domain of either the N- (D555N) or C (D1200N)-terminal ATP sites that arrest ATP hydrolysis and Vi-induced trapping also show abrogation of [alpha-(32)P]8-azido-ADP trapping into Pgp in the absence of hydrolysis. These data suggest that both ATP sites are dependent on each other for function and that each site exhibits similar affinity for 8-azido-ATP (ATP) or 8-azido-ADP (ADP). Similarly, Pgp in the transition state conformation generated with either ADP or ATP exhibits drastically reduced affinity for the binding of analogues of drug substrate ([(125)I]iodoarylazidoprazosin) as well as nucleotide (2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate). Analyses of Arrhenius plots show that trapping of Pgp with [alpha-(32)P]8-azido-ADP (in the absence of hydrolysis) displays an approximately 2.5-fold higher energy of activation (152 kJ/mol) compared with that observed when the transition state intermediate is generated through hydrolysis of [alpha-(32)P]8-azido-ATP (62 kJ/mol). In aggregate, these results demonstrate that the Pgp.[alpha-(32)P]8-azido-ADP (or ADP).Vi transition state complexes generated either in the absence of or accompanying [alpha-(32)P]8-azido-ATP hydrolysis are functionally indistinguishable.     

Allosteric modulation bypasses the requirement for ATP hydrolysis in regenerating low affinity transition state conformation of human P-glycoprotein

ATP-dependent drug transport by human P-glycoprotein (Pgp, ABCB1) involves a coordinated communication between its drug-binding site (substrate site) and the nucleotide binding/hydrolysis domain (ATP sites). It has been demonstrated that the two ATP sites of Pgp play distinct roles within a single catalytic turnover; whereas ATP binding or/and hydrolysis by one drives substrate translocation and dissociation, the hydrolytic activity of the other resets the transporter for the subsequent cycle (Sauna, Z. E., and Ambudkar, S. V. (2000) Proc. Natl. Acad. Sci. U. S. A. 97, 2515-2520; Sauna, Z. E., and Ambudkar, S. V. (2001) J. Biol. Chem. 276, 11653-11661). Trapping of ADP (or 8-azido-ADP) and vanadate (ADP.Vi or 8-azido-ADP.Vi) at the catalytic site, following nucleotide hydrolysis, markedly reduces the affinity of Pgp for its transport substrate [125I]iodoarylazidoprazosin ([125I]IAAP), resulting in dissociation of the latter. Regeneration of the [125I]IAAP site requires an additional round of nucleotide hydrolysis. In this study, we demonstrate that certain thioxanthene-based allosteric modulators, such as cis-(Z)-flupentixol and its closely related analogs, induce regeneration of [125I]IAAP binding to vanadate-trapped (or fluoroaluminate-trapped) Pgp without any further nucleotide hydrolysis. Regeneration was facilitated by dissociation of the trapped nucleotide and vanadate. Once regenerated, the substrate site remains accessible to [125I]IAAP even after removal of the modulator from the medium, suggesting a modulator-induced relaxation of a constrained transition state conformation. Consistent with this, limited trypsin digestion of vanadate-trapped Pgp shows protection by cis-(Z)-flupentixol of two Pgp fragments (approximately 60 kDa) recognizable by a polyclonal antiserum specific for the NH2-terminal half. No regeneration was observed in the Pgp mutant F983A that is impaired in modulation by flupentixols, indicating involvement of the allosteric modulator site in the phenomenon. In summary, the data demonstrate that in the nucleotide-trapped low affinity state of Pgp, the allosteric site remains accessible and responsive to modulation by flupentixol (and its closely related analogs), which can reset the high affinity state for [125I]IAAP binding without any further nucleotide hydrolysis.     

Evidence for the vectorial nature of drug (substrate)-stimulated ATP hydrolysis by human P-glycoprotein.

P-glycoprotein (Pgp), the ATP-binding cassette multidrug transporter, exhibits a drug (substrate)-stimulatable ATPase activity, and vanadate (Vi) inhibits this activity by stably trapping the nucleoside diphosphate in the Pgp.ADP.Vi conformation. We recently demonstrated that Vi-induced 8-azido-[alpha-(32)P]ADP trapping into Pgp in the absence of substrate occurs both in the presence of 8-azido-[alpha-(32)P]ATP (following 8-azido-ATP hydrolysis) or 8-azido-[alpha-(32)P]ADP (without hydrolysis) and, the transition state intermediates generated under either condition are functionally indistinguishable. In this study, we compare the effect of substrates on Vi-induced 8-azido-[alpha-(32)P]ADP trapping into Pgp under both non-hydrolysis and hydrolysis conditions. We demonstrate that whereas substrates stimulate the Vi-induced trapping of 8-azido-[alpha-(32)P]ADP under hydrolysis conditions, they strongly inhibit Vi-induced trapping under non-hydrolysis conditions. This inhibition is concentration-dependent, follows first order kinetics, and is effected by drastically decreasing the affinity of nucleoside diphosphate for Pgp during trapping. However, substrates do not affect the binding of nucleoside diphosphate in the absence of Vi, indicating that the substrate-induced conformation exerts its effect at a step distinct from nucleoside diphosphate-binding. Our results demonstrate that during the catalytic cycle of Pgp, although the transition state, Pgp x ADP x P(i) (Vi), can be generated both via the hydrolysis of ATP or by directly providing ADP to the system, in the presence of substrate the reaction is driven in the forward direction, i.e. hydrolysis of ATP. These data suggest that substrate-stimulated ATP hydrolysis by Pgp is a vectorial process.     

Characterization of the catalytic cycle of ATP hydrolysis by human P-glycoprotein. The two ATP hydrolysis events in a single catalytic cycle are kinetically similar but affect different functional outcomes

P-glycoprotein (Pgp) is a plasma membrane protein whose overexpression confers multidrug resistance to tumor cells by extruding amphipathic natural product cytotoxic drugs using the energy of ATP. An elucidation of the catalytic cycle of Pgp would help design rational strategies to combat multidrug resistance and to further our understanding of the mechanism of ATP-binding cassette transporters. We have recently reported (Sauna, Z. E., and Ambudkar, S. V. (2000) Proc. Natl. Acad. Sci. U. S. A. 97, 2515-2520) that there are two independent ATP hydrolysis events in a single catalytic cycle of Pgp. In this study we exploit the vanadate (Vi)-induced transition state conformation of Pgp (Pgp.ADP.Vi) to address the question of what are the effects of ATP hydrolysis on the nucleotide-binding site. We find that at the end of the first hydrolysis event there is a drastic decrease in the affinity of nucleotide for Pgp coincident with decreased substrate binding. Release of occluded dinucleotide is adequate for the next hydrolysis event to occur but is not sufficient for the recovery of substrate binding. Whereas the two hydrolysis events have different functional outcomes vis à vis the substrate, they show comparable t(12) for both incorporation and release of nucleotide, and the affinities for [alpha-(32)P]8-azido-ATP during Vi-induced trapping are identical. In addition, the incorporation of [alpha-(32)P]8-azido-ADP in two ATP sites during both hydrolysis events is also similar. These data demonstrate that during individual hydrolysis events, the ATP sites are recruited in a random manner, and only one site is utilized at any given time because of the conformational change in the catalytic site that drastically reduces the affinity of the second ATP site for nucleotide binding. In aggregate, these findings provide an explanation for the alternate catalysis of ATP hydrolysis and offer a mechanistic framework to elucidate events at both the substrate- and nucleotide-binding sites in the catalytic cycle of Pgp.     

Correlation between steady-state ATP hydrolysis and vanadate-induced ADP trapping in Human P-glycoprotein. Evidence for ADP release as the rate-limiting step in the catalytic cycle and its modulation by substrates

P-glycoprotein (Pgp) is a transmembrane protein conferring multidrug resistance to cells by extruding a variety of amphipathic cytotoxic agents using energy from ATP hydrolysis. The objective of this study was to understand how substrates affect the catalytic cycle of ATP hydrolysis by Pgp. The ATPase activity of purified and reconstituted recombinant human Pgp was measured using a continuous cycling assay. Pgp hydrolyzes ATP in the absence of drug at a basal rate of 0.5 micromol x min x mg(-1) with a K(m) for ATP of 0.33 mm. This basal rate can be either increased or decreased depending on the Pgp substrate used, without an effect on the K(m) for ATP or 8-azidoATP and K(i) for ADP, suggesting that substrates do not affect nucleotide binding to Pgp. Although inhibitors of Pgp activity, cyclosporin A, its analog PSC833, and rapamycin decrease the rate of ATP hydrolysis with respect to the basal rate, they do not completely inhibit the activity. Therefore, these drugs can be classified as substrates. Vanadate (Vi)-induced trapping of [alpha-(32)P]8-azidoADP was used to probe the effect of substrates on the transition state of the ATP hydrolysis reaction. The K(m) for [alpha-(32)P]8-azidoATP (20 microm) is decreased in the presence of Vi; however, it is not changed by drugs such as verapamil or cyclosporin A. Strikingly, the extent of Vi-induced [alpha-(32)P]8-azidoADP trapping correlates directly with the fold stimulation of ATPase activity at steady state. Furthermore, P(i) exhibits very low affinity for Pgp (K(i) approximately 30 mm for Vi-induced 8-azidoADP trapping). In aggregate, these data demonstrate that the release of Vi trapped [alpha-(32)P]8-azidoADP from Pgp is the rate-limiting step in the steady-state reaction. We suggest that substrates modulate the rate of ATPase activity of Pgp by controlling the rate of dissociation of ADP following ATP hydrolysis and that ADP release is the rate-limiting step in the normal catalytic cycle of Pgp.     

Allosteric modulation of human P-glycoprotein. Inhibition of transport by preventing substrate translocation and dissociation

The human multidrug transporter P-glycoprotein (Pgp, ABCB1) contributes to the poor bioavailability of many anticancer and antimicrobial agents as well as to drug resistance at the cellular level. For rational design of effective Pgp inhibitors, a clear understanding of its mechanism of action and functional regulation is essential. In this study, we demonstrate that inhibition of Pgp-mediated drug transport by cis-(Z)-flupentixol, a thioxanthene derivative, occurs through an allosteric mechanism. Unlike competitive inhibitors, such as cyclosporin A and verapamil, cis-(Z)-flupentixol does not interfere with substrate ([(125)I]iodoarylazidoprazosin) recognition by Pgp, instead it prevents substrate translocation and dissociation, resulting in a stable but reversible Pgp-substrate complex. cis-(Z)-Flupentixol-induced complex formation requires involvement of the Pgp substrate site, because agents that either physically compete (cyclosporin A) for or indirectly occlude (vanadate) the substrate-binding site prevent formation of the complex. Allosteric modulation by cis-(Z)-flupentixol involves a conformational change in Pgp detectable by monoclonal antibody UIC2 binding to a conformation-sensitive external epitope of Pgp. The conformational change observed is distinct from that induced by Pgp substrates or competitive inhibitors. A single amino acid substitution (F983A) in TM12 of Pgp that impairs inhibition by cis-(Z)-flupentixol of Pgp-mediated drug transport also affects stabilization of the Pgp-substrate complex as well as the characteristic conformational change. Taken together, our results describe the molecular mechanism by which the Pgp modulator cis-(Z)-flupentixol allosterically inhibits drug transport.     

Both ATP sites of human P-glycoprotein are essential but not symmetric.

Human P-glycoprotein (P-gp) is a cell surface drug efflux pump that contains two nucleotide binding domains (NBDs). Mutations were made in each of the Walker B consensus motifs of the NBDs at positions D555N and D1200N, thought to be involved in Mg(2+) binding. Although the mutant and wild-type P-gps were expressed equivalently at the cell surface and bound the drug analogue [(125)I]iodoarylazidoprazosin ([(125)I]IAAP) comparably, neither of the mutant proteins was able to transport fluorescent substrates nor had detectable basal nor drug-stimulated ATPase activities. The wild-type and D1200N P-gps were labeled comparably with [alpha-(32)P]-8-azido-ATP at a subsaturating concentration of 2.5 microM, whereas labeling of the D555N mutant was severely impaired. Mild trypsin digestion, to cleave the protein into two halves, demonstrated that the N-half of the wild-type and D1200N proteins was labeled preferentially with [alpha-(32)P]-8-azido-ATP. [alpha-(32)P]-8-Azido-ATP labeling at 4 degrees C was inhibited in a concentration-dependent manner by ATP with half-maximal inhibition at approximately 10-20 microM for the P-gp-D1200N mutant and wild-type P-gp. A chimeric protein containing two N-half NBDs was found to be functional for transport and was also asymmetric with respect to [alpha-(32)P]-8-azido-ATP labeling, suggesting that the context of the ATP site rather than its exact sequence is an important determinant for ATP binding. By use of [alpha-(32)P]-8-azido-ATP and vanadate trapping, it was determined that the C-half of wild-type P-gp was labeled preferentially under hydrolysis conditions; however, the N-half was still capable of being labeled with [alpha-(32)P]-8-azido-ATP. Neither mutant was labeled under vanadate trapping conditions, indicating loss of ATP hydrolysis activity in the mutants. In confirmation of the lack of ATP hydrolysis, no inhibition of [(125)I]IAAP labeling was observed in the mutants in the presence of vanadate. Taken together, these data suggest that the two NBDs are asymmetric and intimately linked and that a conformational change in the protein may occur upon ATP hydrolysis. Furthermore, these data are consistent with a model in which binding of ATP to one site affects ATP hydrolysis at the second site.     

Evidence for modulatory sites at the lipid-protein interface of the human multidrug transporter P-glycoprotein

The human multidrug transporter P-glycoprotein (Pgp or ABCB1) sets up pharmacological barriers to many clinically important drugs, a therapeutic remedy for which has yet to be formulated. For the rational design of mechanism-based inhibitors (or modulators), it is necessary to map the potential sites for modulator interaction and understand their modes of communication with the other functional domains of Pgp. In this study, combining directed mutagenesis with homology modeling, we provide evidence of two modulator-specific sites at the lipid protein interface of Pgp. Targeting 21 variant positions in the COOH-terminal transmembrane (TM) regions, we find residues M948 (in TM11) and F983, M986, V988, and Q990 (all four in TM12) critically involved in substrate-site modulation by a thioxanthene-based allosteric modulator cis-(Z)-flupentixol. Interestingly, for ATP-site modulation by the same modulator, only two (M948 and Q990) of those four residues appear indispensable, together with two additional residues, T837 and I864 in TM9 and TM10, respectively, suggesting independent modes of communication linking the allosteric site with the substrate binding and ATPase domains. None of the seven residues identified prove to be critical for modulation of the substrate or ATP sites by Pgp modulators that are transported by the pump, such as cyclosporin A or verapamil, indicating their specificity for cis-(Z)-flupentixol. On the other hand, ATP-site modulation by verapamil proves to be highly sensitive to replacement at positions F716 (in TM7) and I765 (in TM8), and to a more moderate extent at I764 and L772 (both in TM8). Homology modeling based on the known crystal structures of the bacterial multidrug transporter SAV1866 and the mouse Pgp homologue maps the identified residues primarily at the lipid-protein interface of Pgp, in two spatially distinct modulator-specific clusters. The two modulatory sites demonstrate negative synergism in influencing ATP hydrolysis, consolidating their spatial distinctness. Because Pgp is known to recruit drug molecules directly from the lipid bilayer, identification of modulatory sites at the lipid-protein interface and at the same time outside the conventional central drug binding cavity is mechanistically revealing.     

A single amino acid residue contributes to distinct mechanisms of inhibition of the human multidrug transporter by stereoisomers of the dopamine receptor antagonist flupentixol.

Both cis and trans isomers of the dopamine receptor antagonist flupentixol inhibit drug transport and reverse drug resistance mediated by the human multidrug transporter P-glycoprotein (Pgp) with a stereoselective potency. The rate of ATP hydrolysis by Pgp and photoaffinity labeling of Pgp with the substrate analogue [125I]iodoarylazidoprazosin ([125I]IAAP) are modulated by each isomer in an opposite manner, suggesting different mechanisms for the inhibitory effect on drug transport. In this study we demonstrate that substitution of a single phenylalanine residue at position 983 (F983) with alanine (F983A) in putative transmembrane (TM) region 12 selectively affects inhibition of Pgp-mediated drug transport by both isomers of flupentixol. In F983A the stimulatory effect of cis(Z)-flupentixol and the inhibitory effect of trans(E)-flupentixol on ATP hydrolysis and [125I]IAAP labeling were significantly altered. This indicates that F983 contributes to inhibition of drug transport by both isomers of flupentixol and plays an important role in stimulation and inhibition of ATP hydrolysis and [125I]IAAP labeling by cis(Z)- and trans(E)-flupentixol, respectively. The near-wild-type level of drug transport by the F983A Pgp mutant dissociates susceptibility to inhibition by flupentixol from drug translocation, indicating the allosteric nature of the flupentixol interaction. The inhibitory effects of cyclosporin A on drug transport, drug-stimulated ATP hydrolysis, and [125I]IAAP labeling as well as the stimulatory effect of verapamil on ATP hydrolysis by Pgp were minimally affected by substitution of F983, suggesting no global alteration in the structural and functional integrity of the mutant. Taken together, our data suggest that distinct mechanisms of inhibition of Pgp-mediated drug transport by the cis and trans isomers of flupentixol are mediated through a common site of interaction.     

Multidrug resistance protein 4 (ABCC4)-mediated ATP hydrolysis: effect of transport substrates and characterization of the post-hydrolysis transition state

Multidrug resistance protein 4 (MRP4/ABCC4), transports cyclic nucleoside monophosphates, nucleoside analog drugs, chemotherapeutic agents, and prostaglandins. In this study we characterize ATP hydrolysis by human MRP4 expressed in insect cells. MRP4 hydrolyzes ATP (Km, 0.62 mm), which is inhibited by orthovanadate and beryllium fluoride. However, unlike ATPase activity of P-glycoprotein, which is equally sensitive to both inhibitors, MRP4-ATPase is more sensitive to beryllium fluoride than to orthovanadate. 8-Azido[alpha-32P]ATP binds to MRP4 (concentration for half-maximal binding approximately 3 microm) and is displaced by ATP or by its non-hydrolyzable analog AMPPNP (concentrations for half-maximal inhibition of 13.3 and 308 microm). MRP4 substrates, the prostaglandins E1 and E2, stimulate ATP hydrolysis 2- to 3-fold but do not affect the Km for ATP. Several other substrates, azidothymidine, 9-(2-phosphonylmethoxyethyl)adenine, and methotrexate do not stimulate ATP hydrolysis but inhibit prostaglandin E2-stimulated ATP hydrolysis. Although both post-hydrolysis transition states MRP4.8-azido[alpha-32P]ADP.Vi and MRP4.8-azido[alpha-32P]ADP.beryllium fluoride can be generated, nucleotide trapping is approximately 4-fold higher with beryllium fluoride. The divalent cations Mg2+ and Mn2+ support comparable levels of nucleotide binding, hydrolysis, and trapping. However, Co2+ increases 8-azido[alpha-32P]ATP binding and beryllium fluoride-induced 8-azido[alpha-32P]ADP trapping but does not support steady-state ATP hydrolysis. ADP inhibits basal and prostaglandin E2-stimulated ATP hydrolysis (concentrations for half-maximal inhibition 0.19 and 0.25 mm, respectively) and beryllium fluoride-induced 8-azido[alpha-32P]ADP trapping, whereas Pi has no effect up to 20 mm. In aggregate, our results demonstrate that MRP4 exhibits substrate-stimulated ATP hydrolysis, and we propose a kinetic scheme suggesting that ADP release from the post-hydrolysis transition state may be the rate-limiting step during the catalytic cycle.     

Comparison of the functional characteristics of the nucleotide binding domains of multidrug resistance protein 1

Multidrug Resistance Protein 1 (MRP1) transports diverse organic anionic conjugates and confers resistance to cytotoxic xenobiotics. The protein contains two nucleotide binding domains (NBDs) with features characteristic of members of the ATP-binding cassette superfamily and exhibits basal ATPase activity that can be stimulated by certain substrates. It is not known whether the two NBDs of MRP1 are functionally equivalent. To investigate this question, we have used a baculovirus dual expression vector encoding both halves of MRP1 to reconstitute an active transporter and have compared the ability of each NBD to be photoaffinity-labeled with 8-azido-[(32)P]ATP and to trap 8-azido-[(32)P]ADP in the presence of orthovanadate. We found that NBD1 was preferentially labeled with 8-azido-[(32)P]ATP, while trapping of 8-azido-[(32)P]ADP occurred predominantly at NBD2. Although trapping at NBD2 was dependent on co-expression of both halves of MRP1, binding of 8-azido-ATP by NBD1 remained detectable when the NH(2)-proximal half of MRP1 was expressed alone and when NBD1 was expressed as a soluble polypeptide. Mutation of the conserved Walker A lysine 684 or creation of an insertion mutation between Walker A and B motifs eliminated binding by NBD1 and all detectable trapping of 8-azido-ADP at NBD2. Both mutations decreased leukotriene C(4) (LTC(4)) transport by approximately 70%. Mutation of the NBD2 Walker A lysine 1333 eliminated trapping of 8-azido-ADP by NBD2 but, in contrast to the mutations in NBD1, essentially eliminated LTC(4) transport activity without affecting labeling of NBD1 with 8-azido-[(32)P]ATP.     

Importance of the conserved Walker B glutamate residues, 556 and 1201, for the completion of the catalytic cycle of ATP hydrolysis by human P-glycoprotein (ABCB1)

The human MDR1 (ABCB1) gene product, P-glycoprotein (Pgp), functions as an ATP-dependent efflux pump for a variety of chemotherapeutic drugs. In this study, we assessed the role of conserved glutamate residues in the Walker B domain of the two ATP sites (E556 and E1201, respectively) during the catalytic cycle of human Pgp. The mutant Pgps (E556Q, E556A, E1201Q, E1201A, E556/1201Q, and E556/1201A) were characterized using a vaccinia virus based expression system. Although steady-state ATP hydrolysis and drug transport activities were abrogated in both E556Q and E1201Q mutant Pgps, [alpha-(32)P]-8-azidoADP was trapped in the presence of vanadate (Vi), and the release of trapped [alpha-(32)P]-8-azidoADP occurred to a similar extent as in wild-type Pgp. This indicates that these mutations do not affect either the first hydrolysis event or the ADP release step. Similar results were also obtained when Glu residues were replaced with Ala (E556A and E1201A). Following the first hydrolysis event and release of [alpha-(32)P]-8-azidoADP, both E556Q and E1201Q mutant Pgps failed to undergo another cycle of Vi-induced [alpha-(32)P]-8-azidoADP trapping. Interestingly, the double mutants E556/1201Q and E556/1201A trapped [alpha-(32)P]-8-azidoADP even in the absence of Vi, and the occluded nucleotide was not released after incubation at 37 degrees C for an extended period. In addition, the properties of transition state conformation of the double mutants generated in the absence of Vi were found to be similar to that of the wild-type protein trapped in the presence of Vi (Pgp x [alpha-(32)P]-8-azidoADP xVi). Thus, in contrast to the single mutants, the double mutants appear to be defective in the ADP release step. In aggregate, these data suggest that E556 and E1201 residues in the Walker B domains may not be critical as catalytic carboxylates for the cleavage of the bond between the gamma-P and the beta-P of ATP during hydrolysis but are essential for the second ATP hydrolysis step and completion of the catalytic cycle.     

Photoaffinity labeling of the recBCD enzyme of Escherichia coli with 8-azidoadenosine 5'-triphosphate

The recB and recD subunits of the recBCD enzyme (exonuclease V) from Escherichia coli were covalently photolabeled with the ATP photoaffinity analogue [alpha-32P]8-azido-ATP. The labeling was specific for ATP binding sites by the following criteria. Saturation occurs at high 8-azido-ATP concentrations with dissociation constants of 30 and 120 microM for the recD and recB subunits, respectively; ATP strongly inhibits the photolabeling; 8-azido-ATP is hydrolyzed by the recBCD enzyme and supports its double-stranded DNA exonuclease activity; and the label is largely confined to two peptides obtained by tryptic digestion of the photolabeled holoenzyme; one is derived from the recB subunit and the other from the recD subunit.     

Nonequivalent nucleotide trapping in the two nucleotide binding folds of the human multidrug resistance protein MRP1

Multidrug resistance protein 1 (MRP1) and P-glycoprotein, which are ATP-dependent multidrug efflux pumps and involved in multidrug resistance of tumor cells, are members of the ATP binding cassette proteins and contain two nucleotide-binding folds (NBFs). P-glycoprotein hydrolyzes ATP at both NBFs, and vanadate-induced nucleotide trapping occurs at both NBFs. We examined vanadate-induced nucleotide trapping in MRP1 stably expressed in KB cell membrane by using 8-azido-[alpha-(32)P]ATP. Vanadate-induced nucleotide trapping in MRP1 was found to be stimulated by reduced glutathione, glutathione disulfide, and etoposide and to be synergistically stimulated by the presence of etoposide and either glutathione. These results suggest that glutathione and etoposide interact with MRP1 at different sites and that those bindings cooperatively stimulate the nucleotide trapping. Mild trypsin digestion of MRP1 revealed that vanadate-induced nucleotide trapping mainly occurs at NBF2. Our results suggest that the two NBFs of MRP1 might be functionally nonequivalent.     

Binding and hydrolysis of 2-azido-ATP and 8-azido-ATP by isolated mitochondrial F1: characterisation of high-affinity binding sites

The kinetic parameters for the hydrolysis by F1 of the photoreactive nucleotide analogue 2-azido-ATP were determined (Vmax, 105 U/mg F1; Km, 250 microM, in the presence of 1.0 mM SO2-3). In the absence of an activating anion, a non-linear relationship in a Lineweaver-Burk plot was found for the hydrolysis of 2-azido-ATP. The 2-azido-analogues of ATP and ADP proved to be good photoaffinity labels causing notable inactivation of the F1-ATPase activity upon irradiation at 360 nm. This inhibition was also used to demonstrate high-affinity binding of these analogues to a catalytic binding site on the F1. High-affinity binding proved to be an Mg2+-requiring process, occurring with both 2-azido-ATP and 2-azido-ADP but hardly or not occurring with 8-azido-AT(D)P. Covalent binding of 2-nitreno-ATP upon irradiation of F1 containing tightly bound [beta-32P]2-azido-ATP results in a proportional inhibition of ATPase activity, extrapolating to 0.92 mol of covalently bound label per mol of F1 needed for the complete inactivation of the enzyme. When the F1 was irradiated in the presence of excess [beta-32P]2-azido-AT(D)P, 3-4 mol of label were bound when the enzyme was fully inactivated. In all cases, all or most of the radioactivity was found on the beta subunits.     

Localization of the high-affinity binding site for ATP on the membrane-bound chloroplast ATP synthase

The photoaffinity analog 2-azido-ADP has been used to investigate the high-affinity binding site(s) for ATP on the chloroplast thylakoid membrane. Photophosphorylation of 2-azido-ADP results in the rapid formation of 2-azido-ATP, which remains tightly bound to the membranes after extensive washing. The kinetic parameters of the tight binding of ATP and of 2-azido-ATP are similar (apparent Km = 1-2 microM; maximum extent = 0.2-0.4 nmol/mg of chlorophyll). Ultraviolet irradiation of washed thylakoid membranes containing tightly bound 2-azido-[gamma-32P]ATP induces covalent incorporation of the label exclusively into the beta subunit of the chloroplast coupling factor one. Previous results have shown that the tight binding site for ADP is also located on the beta subunit of the ATP synthase (Czarnecki, J. J., Abbott, M. S., and Selman, B. R. (1983) Eur. J. Biochem. 136, 19-24). To further characterize the tight binding sites for ADP and ATP, the membrane-bound coupling factor has been covalently modified with either tightly bound 2-azido-[gamma-32P]ATP or tightly bound 2-azido-[beta-32P]ADP. The photolabeled beta subunits have been isolated and subjected to partial proteolytic digestion and SDS-gel electrophoresis. The results of these experiments demonstrate that the tight binding sites for ADP and ATP are located on identical portions of beta subunit polypeptide.     

Nucleotide binding and nucleotide hydrolysis properties of the ABC transporter MRP6 (ABCC6)

Mutations in the MRP gene family member MRP6 cause pseudoxanthoma elasticum (PXE) in humans, a disease affecting elasticity of connective tissues. The normal function of MRP6, including its physiological substrate(s), remains unknown. To address these issues, recombinant rat Mrp6 (rMrp6) was expressed in the methylotrophic yeast Pichia pastoris. The protein was expressed in the membrane fraction as a stable 170 kDa protein. Its nucleotide binding and hydrolysis properties were investigated using the photoactive ATP analogue 8-azido-[alpha-(32)P]ATP and compared to those of the drug efflux pump MRP1. rMrp6 can bind 8-azido-[alpha-(32)P]ATP in a Mg(2+)-dependent and EDTA-sensitive fashion. Co(2+), Mn(2+), and Ni(2+) can also support 8-azido-[alpha-(32)P]ATP binding by rMrp6 while Ca(2+), Cd(2+), and Zn(2+) cannot. Under hydrolysis conditions (at 37 degrees C), the phosphate analogue beryllium fluoride (BeF(x)()) can stimulate trapping of the 8-azido-[alpha-(32)P]adenosine nucleotide in rMrp6 (and in MRP1) in a divalent cation-dependent and temperature-sensitive fashion. This suggests active ATPase activity, followed by trapping and photo-cross-linking of the 8-azido-[alpha-(32)P]ADP to the protein. By contrast to MRP1, orthovanadate-stimulated nucleotide trapping in rMrp6 does not occur in the presence of Mg(2+) but can be detected with Ni(2+) ions, suggesting structural and/or functional differences between the two proteins. The rMrp6 protein can be specifically photolabeled by a fluorescent photoactive drug analogue, [(125)I]-IAARh123, with characteristics similar to those previously reported for MRP1 (1), and this photolabeling of rMrp6 can be modulated by several structurally unrelated compounds. The P. pastoris expression system has allowed demonstration of ATP binding and ATP hydrolysis by rMrp6. In addition to providing large amounts of active protein for detailed biochemical studies, this system should also prove useful to identify potential rMrp6 substrates in [(125)I]-IAARh123 photolabeling competition studies, as well as to study the molecular basis of PXE mutations, which are most often found in the NBD2 of MRP6.     

Nucleotide-induced conformational changes in P-glycoprotein and in nucleotide binding site mutants monitored by trypsin sensitivity

Limited trypsin digestion was used to monitor nucleotide-induced conformational changes in wild-type P-glycoprotein (Pgp) as well as in nucleotide binding domain (NBD) Pgp mutants. Purified and reconstituted wild-type or mutant mouse Mdr3 Pgps were preincubated with different hydrolyzable or nonhydrolyzable nucleotides, followed by limited proteolytic cleavage at different trypsin:protein ratios. The Pgp tryptic digestion products were separated by SDS-PAGE followed by immunodetection with the mouse monoclonal anti-Pgp antibody C219, which recognizes a conserved epitope (VVQE/AALD) in each half of the protein. Different trypsin digestion patterns were observed for wild-type Pgp incubated with MgCl(2) alone, MgADP, MgAMP.PNP, MgATP, and MgATP + vanadate. A unique trypsin digestion profile suggestive of enhanced resistance to trypsin was observed under conditions of vanadate-induced trapping of nucleotides (MgATP + vanadate). The trypsin sensitivity profiles of Pgp mutants bearing either single or double mutations in Walker A (K429R, K1072R) and Walker B (D551N, D1196N) sequence signatures of NBD1 and NBD2 were analyzed under conditions of vanadate-induced trapping of nucleotides. The proteolytic cleavage pattern observed for the double mutants K429R/K1072R and D551N/D1196N, and for the single mutants K429R, K1072R, and D1196N were similar and clearly distinct from wild-type Pgp under the same conditions. This is consistent with the absence of ATP hydrolysis and of vanadate-induced trapping of 8-azido-ADP previously reported for these mutants [Urbatsch et al. (1998) Biochemistry 37, 4592-4602]. Interestingly, the trypsin digestion profiles observed under vanadate-induced trapping for the D551N and D1196N mutants were quite different, with the D551N mutant showing a profile resembling that seen for wild-type Pgp. The different sensitivity profiles of Pgp mutants bearing mutations at the homologous residue in NBD1 (D551N) and NBD2 (D1196N) suggest possible structural and functional differences between the two sites.     

Demonstration of an Mg2+-induced conformational change by photoaffinity labelling of the high-affinity ATP-binding site of (Na+ + K+)-ATPase with 8-azido-ATP

8-Azido-ATP (8-N3ATP) is a substrate of (Na+ + K+)-ATPase from pork kidney and photoinactivates it by binding to the Mr = 100 000 alpha-subunit. The photoinactivation requires the presence of Mg2+ even though 8-azido-ATP is recognized by the high-affinity ATP binding site (Kd = 3.1 microM). K+ ions protect the enzyme against photoinactivation as does excess ATP. To see whether the Mg2+-requirement of the photoinactivation is due to the action of free Mg2+ or to the existence of an Mg X 8-azido-ATP complex, the action of the stable Mg X ATP complex analogue, chromium X 8-N3ATP (Cr X 8-N3ATP), was studied. Cr X 8-N3ATP photoinactivates (Na+ + K+)-ATPase in the absence of Mg2+, but the photoinactivation is enhanced by Mg2+, indicating that the formation of a Mg X ATP complex is an absolute requirement for photoinactivation. However, the interaction of Mg2+ with a low-affinity site also enhances the photoinactivation. It is therefore concluded that interactions with MgATP and free Mg induce conformational changes in the purine subsite of the high-affinity ATP binding site. Controlled trypsinolysis of the [alpha-32P]8-N3ATP-photolabelled enzyme in the presence of K+ results in the formation of an Mr = 56 000 radioactive peptide, whereas trypsinolysis of a [gamma-32P]Cr X ATP-labelled enzyme under identical conditions forms an Mr = 41 000 radioactive peptide. Extensive trypsinolysis of the [alpha-32P] 8-N3ATP-photolabelled alpha-subunit leads to the formation of a radioactive peptide of Mr = 1800.     

Covalent modification of the non-catalytic sites of the H(+)-ATPase from chloroplasts with 2-azido-[alpha-(32)P]ATP and its effect on ATP synthesis and ATP hydrolysis

Incubation of the isolated H(+)-ATPase from chloroplasts, CF(0)F(1), with 2-azido-[alpha-(32)P]ATP leads to the binding of this nucleotide to different sites. These sites were identified after removal of free nucleotides, UV-irradiation and trypsin treatment by separation of the tryptic peptides by ion exchange chromatography. The nitreno-AMP, nitreno-ADP and nitreno-ATP peptides were further separated on a reversed phase column, the main fractions were subjected to amino acid sequence analysis and the derivatized tyrosines were used to distinguish between catalytic (beta-Tyr362) and non-catalytic (beta-Tyr385) sites. Several incubation procedures were developed which allow a selective occupation of each of the three non-catalytic sites. The non-catalytic site with the highest dissociation constant (site 6) becomes half maximally filled at 50 microM 2-azido-[alpha-(32)P]ATP, that with the intermediate dissociation constant (site 5) at 2 microM. The ATP at the site with the lowest dissociation constant had to be hydrolyzed first to ADP before a replacement by 2-azido-[alpha-(32)P]ATP was possible. CF(0)F(1) with non-covalently bound 2-azido-[alpha-(32)P]ATP and after covalent derivatization was reconstituted into liposomes and the rates of ATP synthesis as well as ATP hydrolysis were measured after energization of the proteoliposomes by Delta pH/Delta phi. Non-covalent binding of 2-azido-ATP to any of the three non-catalytic sites does not influence ATP synthesis and ATP hydrolysis, whereas covalent derivatization of any of the three sites inhibits both, the degree being proportional to the degree of derivatization. Extrapolation to complete inhibition indicates that derivatization of one site (either 4 or 5 or 6) is sufficient to block completely multi-site catalysis. The rates of ATP synthesis and ATP hydrolysis were measured as a function of the ADP and ATP concentration from uni-site to multi-site conditions with covalently derivatized and non-derivatized CF(0)F(1). Uni-site ATP synthesis and ATP hydrolysis were not inhibited by covalent derivatization of any of the non-catalytic sites, whereas multi-site catalysis is inhibited. These results indicate that multi-site catalysis requires some flexibility between beta- and alpha-subunits which is abolished by covalent derivatization of beta-Tyr385 with a 2-nitreno-adenine nucleotide. Conformational changes connected with energy transduction between the F(0)-part and the F(1)-part are either not required for uni-site ATP synthesis or they are not impaired by the derivatization of any of the three beta-Tyr385.