Do drug substrates enter the common drug-binding pocket of P-glycoprotein through "gates"?

Overexpression of P-glycoprotein (P-gp; ABCB1) can cause multidrug resistance during cancer and AIDS chemotherapy because of its ability to transport a broad range of structurally unrelated compounds from the cell. P-gp is a member of the ABC family of proteins. It is a single polypeptide containing four domains—two transmembrane (TM) domains each of which contains six TM segments and two nucleotide-binding domains. Chemical modification and cross-linking studies of cysteine mutants of P-gp indicate that the common drug-binding pocket is at the interface between the TM domains. It has been postulated that drug substrates enter the lipid bilayer, are extracted by P-gp and transported to the extracellular medium. It is not clear how drug substrates enter the drug-binding pocket. Here, we propose that drug-substrates diffuse from the lipid bilayer into the drug-binding pocket through “gates” formed by TM segments at either end of the drug-binding pocket.     

The ATPase Activity of the P-glycoprotein Drug Pump Is Highly Activated When the N-terminal and Central Regions of the Nucleotide-binding Domains Are Linked Closely Together

The P-glycoprotein (P-gp, ABCB1) drug pump protects us from toxic compounds and confers multidrug resistance. Each of the homologous halves of P-gp is composed of a transmembrane domain (TMD) with 6 TM segments followed by a nucleotide-binding domain (NBD). The predicted drug- and ATP-binding sites reside at the interface between the TMDs and NBDs, respectively. Crystal structures and EM projection images suggest that the two halves of P-gp are separated by a central cavity that closes upon binding of nucleotide. Binding of drug substrates may induce further structural rearrangements because they stimulate ATPase activity. Here, we used disulfide cross-linking with short (8 Å) or long (22 Å) cross-linkers to identify domain-domain interactions that activate ATPase activity. It was found that cross-linking of cysteines that lie close to the LSGGQ (P517C) and Walker A (I1050C) sites of NBD1 and NBD2, respectively, as well as the cytoplasmic extensions of TM segments 3 (D177C or L175C) and 9 (N820C) with a short cross-linker activated ATPase activity over 10-fold. A pyrylium compound that inhibits ATPase activity blocked cross-linking at these sites. Cross-linking between the NBDs was not inhibited by tariquidar, a drug transport inhibitor that stimulates P-gp ATPase activity but is not transported. Cross-linking between extracellular cysteines (T333C/L975C) predicted to lock P-gp into a conformation that prevents close NBD association inhibited ATPase activity. The results suggest that trapping P-gp in a conformation in which the NBDs are closely associated likely mimics the structural rearrangements caused by binding of drug substrates that stimulate ATPase activity.     

Translocation mechanism of P-glycoprotein and conformational changes occurring at drug-binding site: Insights from multi-targeted molecular dynamics

P-glycoprotein (P-gp) is well known for multidrug resistance in drug therapy. Its over-expression results into the increased efflux of therapeutic agents rendering them inefficacious. A clear understanding of P-gp efflux mechanism and substrate/inhibitor interactions during the course of efflux cycle will be crucial for designing effective P-gp inhibitors, and therapeutic agents that are non-substrate to P-gp. In the present work, we have modeled P-gp in three different catalytic states. These models were utilized for elucidation of P-gp translocation mechanism using multi-targeted molecular dynamics (MTMD). The gradual changes occurring in P-gp structure from inward open to outward open conformation were sampled out. A detailed investigation of conformational changes occurring in trans-membrane domains (TMDs) during the course of catalytic cycle was carried out. Movements of each TM helices in response to pronounced twisting and translatory motion of NBDs were measured quantitatively. The role of intracellular coupling helices (ICHs) during the structural transition of P-gp was studied, and observed as vital links for structural transition. A close observation of displacements and conformational changes in the residues lining drug-binding pocket was also carried out. Further, we have analyzed the molecular interactions of P-gp substrates/inhibitors during the P-gp translocation to find out how stable binding interactions of a compound at drug-binding site(s) in open conformation, becomes highly destabilized in closed conformation. The study revealed striking differences between the molecular interactions of substrate and inhibitor; inhibitors showed a tendency to maintain stable binding interactions during the catalytic transition cycle.     

Identification of the Distance between the Homologous Halves of P-glycoprotein That Triggers the High/Low ATPase Activity Switch

P-glycoprotein (P-gp, ABCB1) is an ATP-binding cassette drug pump that protects us from toxic compounds and confers multidrug resistance. Each homologous half contains a transmembrane domain with six transmembrane segments followed by a nucleotide-binding domain (NBD). The drug- and ATP-binding sites reside at the interface between the transmembrane domain and NBDs, respectively. Drug binding activates ATPase activity by an unknown mechanism. There is no high resolution structure of human P-gp, but homology models based on the crystal structures of bacterial, mouse, and Caenorhabditis elegans ATP-binding cassette drug pumps yield both open (NBDs apart) and closed (NBDs together) conformations. Molecular dynamics simulations predict that the NBDs can be separated over a range of distances (over 20 Å). To determine the distance that show high or low ATPase activity, we cross-linked reporter cysteines L175C (N-half) and N820C (C-half) with cross-linkers of various lengths that separated the halves between 6 and 30 Å (α-carbons). We observed that ATPase activity increased over 10-fold when the cysteines were cross-linked at distances between 6 and 19 Å, although cross-linking at distances greater than 20 Å yielded basal levels of activity. The results suggest that the ATPase activation switch appears to be turned on or off when L175C/N820 are clamped at distances less than or greater than 20 Å, respectively. We predict that the high/low ATPase activity switch may occur at a distance where the NBDs are predicted in molecular dynamic simulations to undergo pronounced twisting as they approach each other (Wise, J. G. (2012) Biochemistry 51, 5125–5141).     

Simultaneous binding of two different drugs in the binding pocket of the human multidrug resistance P-glycoprotein

The human multidrug resistance P-glycoprotein (P-gp, ABCB1) transports a wide variety of structurally diverse compounds out of the cell. The drug-binding pocket of P-gp is located in the transmembrane domains. Although occupation of the drug-binding pocket by one molecule is sufficient to activate the ATPase activity of P-gp, the drug-binding pocket may be large enough to accommodate two different substrates at the same time. In this study, we used cysteine-scanning mutagenesis to test whether P-gp could simultaneously interact with the thiol-reactive drug substrate, Tris-(2-maleimidoethyl)amine (TMEA) and a second drug substrate. TMEA is a cross-linker substrate of P-gp that allowed us to test for stimulation of cross-linking by a second substrate such as calcein-acetoxymethyl ester, colchicine, demecolcine, cyclosporin A, rhodamine B, progesterone, and verapamil. We report that verapamil induced TMEA cross-linking of mutant F343C(TM6)/V982C(TM12). By contrast, no cross-linked product was detected in mutants F343C(TM6), V982C(TM12), or F343C(TM6)/V982C(TM12) in the presence of TMEA alone. The verapamil-stimulated ATPase activity of mutant F343C(TM6)/V982C(TM12) in the presence of TMEA decreased with increased cross-linking of the mutant protein. These results show that binding of verapamil must induce changes in the drug-binding pocket (induced-fit mechanism) resulting in exposure of residues F343C(TM6)/V982C(TM12) to TMEA. The results also indicate that the common drug-binding pocket in P-gp is large enough to accommodate both verapamil and TMEA simultaneously and suggests that the substrates must occupy different regions in the common drug-binding pocket.     

Transmembrane segment 7 of human P-glycoprotein forms part of the drug-binding pocket

P-gp (P-glycoprotein; ABCB1) protects us by transporting a broad range of structurally unrelated compounds out of the cell. Identifying the regions of P-gp that make up the drug-binding pocket is important for understanding the mechanism of transport. The common drug-binding pocket is at the interface between the transmembrane domains of the two homologous halves of P-gp. It has been shown in a previous study [Loo, Bartlett and Clarke (2006) Biochem. J. 396, 537-545] that the first transmembrane segment (TM1) contributed to the drug-binding pocket. In the present study, we used cysteine-scanning mutagenesis, reaction with an MTS (methanethiosulfonate) thiol-reactive analogue of verapamil (termed MTS-verapamil) and cross-linking analysis to test whether the equivalent transmembrane segment (TM7) in the C-terminal-half of P-gp also contributed to drug binding. Mutation of Phe728 to cysteine caused a 4-fold decrease in apparent affinity for the drug substrate verapamil. Mutant F728C also showed elevated ATPase activity (11.5-fold higher than untreated controls) after covalent modification with MTS-verapamil. The activity returned to basal levels after treatment with dithiothreitol. The substrates, verapamil and cyclosporin A, protected the mutant from labelling with MTS-verapamil. Mutant F728C could be cross-linked with a homobifunctional thiol-reactive cross-linker to cysteines I306C(TM5) and F343C(TM6) that are predicted to line the drug-binding pocket. Disulfide cross-linking was inhibited by some drug substrates such as Rhodamine B, calcein acetoxymethyl ester, cyclosporin, verapamil and vinblastine or by vanadate trapping of nucleotides. These results indicate that TM7 forms part of the drug-binding pocket of P-gp.     

Cysteines Introduced into Extracellular Loops 1 and 4 of Human P-Glycoprotein That Are Close Only in the Open Conformation Spontaneously Form a Disulfide Bond That Inhibits Drug Efflux and ATPase Activity

P-glycoprotein (P-gp) is an ATP-binding cassette drug pump that protects us from toxic compounds and confers multidrug resistance. The protein is organized into two halves. The halves contain a transmembrane domain (TMD) with six transmembrane segments and a nucleotide-binding domain (NBD). The drug- and ATP-binding sites reside at the TMD1/TMD2 and NBD1/NBD2 interfaces, respectively. ATP-dependent drug efflux involves changes between the open inward-facing (NBDs apart, extracellular loops (ECLs) close together) and the closed outward-facing (NBDs close together, ECLs apart) conformations. It is controversial, however, whether the open conformation only exists transiently in intact cells because of the presence of high levels of ATP. To test for the presence of an open conformation in intact cells, reporter cysteines were placed in extracellular loops 1 (A80C, N half) and 4 (R741C, C half). The rationale was that cysteines A80C/R741C would only come close enough to form a disulfide bond in an open conformation (6.9 Å apart) because they are separated widely (30.4 Å apart) in the closed conformation. It was observed that the mutant A80C/R741C cross-linked spontaneously (>90%) when expressed in cells. In contrast to previous reports showing that trapping P-gp in a closed conformation highly activated ATPase activity, here we show that A80C/R741C cross-linking inhibited ATPase activity and drug efflux. Both activities were restored when the cross-linked mutant was treated with a thiol-reducing agent. The results show that an open conformation can be readily detected in cells and that cross-linking of cysteines placed in ECLs 1 and 4 inhibits activity.     

Val133 and Cys137 in transmembrane segment 2 are close to Arg935 and Gly939 in transmembrane segment 11 of human P-glycoprotein

P-glycoprotein (P-gp; ABCB1) transports a wide variety of structurally diverse compounds out of the cell. The protein has two homologous halves joined by a linker region. Each half consists of a transmembrane (TM) domain with six TM segments and a nucleotide-binding domain. The drug substrate-binding pocket is at the interface between the TM segments in each half of the protein. Preliminary studies suggested that the arrangement of the two halves of P-gp shows rotational symmetry (i.e. "head-to-tail" arrangement). Here, we tested this model by determining whether the cytoplasmic ends of TM2 and TM3 in the N-terminal half are in close contact with TM11 in the C-terminal half. Mutants containing a pair of cysteines in TM2/TM11 or TM3/TM11 were subjected to oxidative cross-linking with copper phenanthroline. Two of the 110 TM2/TM11 mutants, V133C(TM2)/G939C(TM11) and C137C(TM2)/A935C (TM11), were cross-linked at 4 degrees C, when thermal motion is reduced. Cross-linking was specific since no cross-linked product was detected in the 100 double Cys TM3/TM11 mutants. Vanadate trapping of nucleotide or the presence of some drug substrates inhibited cross-linking of mutants V133C(TM2)/G939C(TM11) and C137C(TM2)/A935C(TM11). Cross-linking of TM2 and TM11 also blocked drug-stimulated ATPase activity. The close proximity of TM2/TM11 and TM5/TM8 (Loo, T. W., Bartlett, M. C., and Clarke, D. M. (2004) J. Biol. Chem. 279, 7692-7697) indicates that these regions between the two halves must enclose the drug-binding pocket at the cytoplasmic side of P-gp. They may form the "hinges" required for conformational changes during the transport cycle.     

ATP hydrolysis promotes interactions between the extracellular ends of transmembrane segments 1 and 11 of human multidrug resistance P-glycoprotein

P-glycoprotein (P-gp, ABCB1) actively pumps a broad range of structurally unrelated cytotoxic compounds out of the cell. It has two homologous halves that are joined by a linker region. Each half has a transmembrane (TM) domain containing six TM segments and a nucleotide-binding domain (NBD). Cross-linking studies have shown that the drug-binding pocket is at the interface between the TM domains. The two NBDs interact to form the ATP-binding sites. Coupling of ATP hydrolysis to drug efflux has been postulated to occur by conversion of the binding pocket from a high-affinity to a low-affinity state through alterations in the packing of the TM segments. TM 11 has also been reported to be important for drug binding. Here, we used cysteine-scanning mutagenesis and oxidative cross-linking to test for changes in the packing of TM 11 during ATP hydrolysis. We generated 350 double cysteine mutants that contained one cysteine at the extracellular end of TM11 and another cysteine at the extracellular ends of TMs 1, 3, 4, 5, or 6. The mutants were expressed in HEK293 cells and treated with oxidant in the absence or presence of ATP. Cross-linked product was not detected in SDS-PAGE gels in the absence of ATP. By contrast, cross-linked product was detected in mutants M68C(TM1)/Y950C(TM11), M68C(TM1)/Y953C(TM11), M68C(TM1)/A954C(TM11), M69C(TM1)/A954C(TM11), and M69C(TM1)/ F957C(TM11) in the presence of ATP but not with ADP or AMP.PNP. These results indicate that rearrangement of TM11 may contribute to the release of drug substrate during ATP hydrolysis.     

Locking Intracellular Helices 2 and 3 Together Inactivates Human P-glycoprotein

The P-glycoprotein (P-gp) drug pump (ABCB1) has two transmembrane domains and two nucleotide-binding domains (NBDs). Coupling of the drug-binding sites in the transmembrane domains to the NBDs occurs through interaction of the intracellular helices (IHs) with residues in the NBDs (IH1/IH4/NBD1 and IH2/IH3/NBD2). We showed previously that cross-linking of cysteines in IH3 and IH1 with a short cross-linker mimicked drug binding as it activated P-gp ATPase activity. Here we show that residue A259C(IH2) could be directly cross-linked to W803C(IH3). Cross-linking was inhibited by the presence of ATP and adenosine 5′-(β,γ-imino)triphosphate but not by ADP. Cross-linking of mutant A259C/W803C inhibited its verapamil-stimulated ATPase activity mutant, but activity was restored after addition of dithiothreitol. Because these residues are close to the ball-and-socket joint A266C(IH2)/Phe¹⁰⁸⁶(NBD2), we mutated the adjacent Tyr¹⁰⁸⁷(NBD2) close to IH3. Mutants Y1087A and Y1087L, but not Y1087F, were misprocessed, and all inhibited ATPase activity. Mutation of hydrophobic residues (F793A, L797A, L814A, and L818A) flanking IH3 also inhibited maturation. The results suggest that these residues, together with Trp⁸⁰³ and Phe⁸⁰⁴, form a large hydrophobic pocket. The results show that there is an important hydrophobic network at the IH2/IH3/NBD2 transmission interface that is critical for folding and activity of P-gp.     

The drug-binding pocket of the human multidrug resistance P-glycoprotein is accessible to the aqueous medium

P-Glycoprotein (P-gp) is an ATP-dependent drug pump that transports a broad range of compounds out of the cell. Cross-linking studies have shown that the drug-binding pocket is at the interface between the transmembrane (TM) domains and can simultaneously bind two different drug substrates. Here, we determined whether cysteine residues within the drug-binding pocket were accessible to the aqueous medium. Cysteine mutants were tested for their reactivity with the charged thiol-reactive compounds sodium (2-sulfonatoethyl)methanethiosulfonate (MTSES) and [2-(trimethylammonium)ethyl)]methanethiosulfonate (MTSET). Residue Ile-306(TM5) is close to the verapamil-binding site. It was changed to cysteine, reacted with MTSES or MTSET, and assayed for verapamil-stimulated ATPase activity. Reaction of mutant I306C(TM5) with either compound reduced its affinity for verapamil. We confirmed that the reduced affinity for verapamil was indeed due to introduction of a charge at position 306 by demonstrating that similar effects were observed when Ile-306 was replaced with arginine or glutamic acid. Mutant I306R showed a 50-fold reduction in affinity for verapamil and very little change in the affinity for rhodamine B or colchicine. MTSES or MTSET modification also affected the cross-linking pattern between pairs of cysteines in the drug-binding pocket. For example, both MTSES and MTSET inhibited cross-linking between I306C(TM5) and I868C(TM10). Inhibition was enhanced by ATP hydrolysis. By contrast, cross-linking of cysteine residues located outside the drug-binding pocket (such as G300C(TM5)/F770C(TM8)) was not affected by MTSES or MTSET. These results indicate that the drug-binding pocket is accessible to water.     

The packing of the transmembrane segments of human multidrug resistance P-glycoprotein is revealed by disulfide cross-linking analysis

Residues from several transmembrane (TM) segments of P-glycoprotein (P-gp) likely form the drug-binding site(s). To determine the organization of the TM segments, pairs of cysteine residues were introduced into the predicted TM segments of a Cys-less P-gp, and the mutant protein was subjected to oxidative cross-linking. In SDS gels, the cross-linked product migrated with a slower mobility than the native protein. The cross-linked products were not detected in the presence of dithiothreitol. Cross-linking was observed in 12 of 125 mutants. The pattern of cross-linking suggested that TM6 is close to TMs 10, 11, and 12, while TM12 is close to TMs 4, 5, and 6. In some mutants the presence of drug substrate colchicine, verapamil, cyclosporin A, or vinblastine either enhanced or inhibited cross-linking. Cross-linking was inhibited in the presence of ATP plus vanadate. These results suggest that the TM segments critical for drug binding must be close to each other and exhibit different conformational changes in response to binding of drug substrate or vanadate trapping of nucleotide. Based on these results, we propose a model for the arrangement of the TM segments.     

Mapping the Binding Site of the Inhibitor Tariquidar That Stabilizes the First Transmembrane Domain of P-glycoprotein

ABC (ATP-binding cassette) transporters are clinically important because drug pumps like P-glycoprotein (P-gp, ABCB1) confer multidrug resistance and mutant ABC proteins are responsible for many protein-folding diseases such as cystic fibrosis. Identification of the tariquidar-binding site has been the subject of intensive molecular modeling studies because it is the most potent inhibitor and corrector of P-gp. Tariquidar is a unique P-gp inhibitor because it locks the pump in a conformation that blocks drug efflux but activates ATPase activity. In silico docking studies have identified several potential tariquidar-binding sites. Here, we show through cross-linking studies that tariquidar most likely binds to sites within the transmembrane (TM) segments located in one wing or at the interface between the two wings (12 TM segments form 2 divergent wings). We then introduced arginine residues at all positions in the 12 TM segments (223 mutants) of P-gp. The rationale was that a charged residue in the drug-binding pocket would disrupt hydrophobic interaction with tariquidar and inhibit its ability to rescue processing mutants or stimulate ATPase activity. Arginines introduced at 30 positions significantly inhibited tariquidar rescue of a processing mutant and activation of ATPase activity. The results suggest that tariquidar binds to a site within the drug-binding pocket at the interface between the TM segments of both structural wings. Tariquidar differed from other drug substrates, however, as it stabilized the first TM domain. Stabilization of the first TM domain appears to be a key mechanism for high efficiency rescue of ABC processing mutants that cause disease.     

Insight into Pleiotropic Drug Resistance ATP-binding Cassette Pump Drug Transport through Mutagenesis of Cdr1p Transmembrane Domains

The fungal ATP-binding cassette (ABC) transporter Cdr1 protein (Cdr1p), responsible for clinically significant drug resistance, is composed of two transmembrane domains (TMDs) and two nucleotide binding domains (NBDs). We have probed the nature of the drug binding pocket by performing systematic mutagenesis of the primary sequences of the 12 transmembrane segments (TMSs) found in the TMDs. All mutated proteins were expressed equally well and localized properly at the plasma membrane in the heterologous host Saccharomyces cerevisiae, but some variants differed significantly in efflux activity, substrate specificity, and coupled ATPase activity. Replacement of the majority of the amino acid residues with alanine or glycine yielded neutral mutations, but about 42% of the variants lost resistance to drug efflux substrates completely or selectively. A predicted three-dimensional homology model shows that all the TMSs, apart from TMS4 and TMS10, interact directly with the drug-binding cavity in both the open and closed Cdr1p conformations. However, TMS4 and TMS10 mutations can also induce total or selective drug susceptibility. Functional data and homology modeling assisted identification of critical amino acids within a drug-binding cavity that, upon mutation, abolished resistance to all drugs tested singly or in combinations. The open and closed Cdr1p models enabled the identification of amino acid residues that bordered a drug-binding cavity dominated by hydrophobic residues. The disposition of TMD residues with differential effects on drug binding and transport are consistent with a large polyspecific drug binding pocket in this yeast multidrug transporter.     

Transmembrane segment 1 of human P-glycoprotein contributes to the drug-binding pocket

P-glycoprotein (P-gp; ABCB1) actively transports a broad range of structurally unrelated compounds out of the cell. An important step in the transport cycle is coupling of drug binding with ATP hydrolysis. Drug substrates such as verapamil bind in a common drug-binding pocket at the interface between the TM (transmembrane) domains of P-gp and stimulate ATPase activity. In the present study, we used cysteine-scanning mutagenesis and reaction with an MTS (methanethiosulphonate) thiol-reactive analogue of verapamil (MTS-verapamil) to test whether the first TM segment [TM1 (TM segment 1)] forms part of the drug-binding pocket. One mutant, L65C, showed elevated ATPase activity (10.7-fold higher than an untreated control) after removal of unchanged MTS-verapamil. The elevated ATPase activity was due to covalent attachment of MTS-verapamil to Cys65 because treatment with dithiothreitol returned the ATPase activity to basal levels. Verapamil covalently attached to Cys65 appears to occupy the drug-binding pocket because verapamil protected mutant L65C from modification by MTS-verapamil. The ATPase activity of the MTS-verapamil-modified mutant L65C could not be further stimulated with verapamil, calcein acetoxymethyl ester or demecolcine. The ATPase activity could be inhibited by cyclosporin A but not by trans-(E)-flupentixol. These results suggest that TM1 contributes to the drug-binding pocket.     

Identification of Residues in the Drug Translocation Pathway of the Human Multidrug Resistance P-glycoprotein by Arginine Mutagenesis

P-glycoprotein (P-gp, ATP-binding cassette B1) is a drug pump that extracts toxic drug substrates from the plasma membrane and catalyzes their ATP-dependent efflux. To map the residues in the drug translocation pathway, we performed arginine-scanning mutagenesis on all transmembrane (TM) segments (total = 237 residues) of a P-gp processing mutant (G251V) defective in folding (15% maturation efficiency) (glycosylation state used to monitor folding). The rationale was that arginines introduced into the drug-binding sites would mimic drug rescue and enhance maturation of wild-type or processing mutants of P-gp. It was found that 38 of the 89 mutants that matured had enhanced maturation. Enhancer mutations were found in 11 of the 12 TM segments with the largest number found in TMs 6 and 12 (seven in each), TMs that are critical for P-gp-drug substrate interactions. Modeling of the TM segments showed that the enhancer arginines were found on the hydrophilic face, whereas inhibitory arginines were located on a hydrophobic face that may be in contact with the lipid bilayer. It was found that many of the enhancer arginines caused large alterations in P-gp-drug interactions in ATPase assays. For example, mutants A302R (TM5), L339R (TM6), G872R (TM10), F942R (TM11), Q946R (TM11), V982R (TM12), and S993R (TM12) reduced the apparent affinity for verapamil by ∼10-fold, whereas the F336R (TM6) and M986R (TM12) mutations caused at least a 10-fold increase in apparent affinity for rhodamine B. The results suggest that P-gp contains a large aqueous-filled drug translocation pathway with multiple drug-binding sites that can accommodate the bulky arginine side chains to promote folding of the protein.The human multidrug resistance P-glycoprotein (P-gp, ATP-binding cassette B1)² is an ATP-dependent drug pump that mediates efflux of a broad range of hydrophobic compounds out of the cell (1). It is expressed in the epithelium of liver, kidney, and gastrointestinal tract and at the blood-brain or blood-testes barrier where it functions to protect us from cytotoxic compounds. It is clinically important because it contributes to multidrug resistance in diseases such as cancer and AIDS (1).P-gp is an ATP-binding cassette transporter of 1280 amino acids that consists of two homologous halves (2). Each half begins with a transmembrane domain (TMD) containing six TM segments followed by a nucleotide-binding domain (NBD).A key goal to understanding the mechanism of P-gp drug transport is to identify the amino acids that line the drug translocation pathway. Because P-gp extracts drug substrates from the lipid bilayer, the drug-binding pocket/drug translocation pathway are predicted to reside in the transmembrane (TM) segments. We previously showed that the TMDs alone were sufficient for drug binding (3). Expression of the TMDs as separate polypeptides showed that both TMD1 and TMD2 were required for binding drug substrate (4). The results of studies utilizing cysteine-scanning mutagenesis and labeling with thiol-reactive drug substrates suggested that all of the TM segments contribute to the drug-binding pocket/drug translocation pathway (reviewed in Ref. 5). The next step is to identify the specific amino acids that line the drug translocation pathway. It is important to identify amino acids that line the drug translocation pathway and to compare whether the biochemical evidence supports a model of P-gp structure in the closed conformation (6) (NBDs close together that was based on the bacterial Sav1866 crystal structure (7)) or the recent crystal structure of mouse P-gp in the open conformation (NBDs far apart) (8). There have been concerns that the mouse P-gp structure may be a non-native structure or in a conformation that exists very transiently (9).Our approach to map the drug translocation pathway has been to use arginine-scanning mutagenesis of the TM segments of a P-gp processing mutant (G251V) that shows partial maturation (∼15% maturation efficiency) (10). Maturation efficiency can be used to detect folding of P-gp in whole cells by monitoring the conversion of P-gp from a core-glycosylated (150 kDa) protein to a mature protein (170 kDa) that contains complex carbohydrate. Because mutant G251V shows partial maturation, we can detect whether an introduced arginine promotes, inhibits, or has a neutral effect on folding. The rationale for using arginine-scanning mutagenesis was that arginine has a large free energy barrier (17 kcal/mol) for insertion into the lipid bilayer because it is highly charged (11). Therefore, introduction of an arginine into a lipid face of the G251V mutant would likely inhibit maturation, whereas an arginine introduced into the aqueous face of the drug translocation pathway would not inhibit maturation of the mutant P-gp.In an initial study on TM1, we demonstrated the feasibility of the approach (10). All arginines introduced into the predicted lipid-facing positions inhibited maturation, whereas those introduced into positions predicted to face the drug translocation pathway did not. A particularly intriguing observation was that some arginines promoted maturation. The residues at these positions were coincidentally at positions identical to those that reacted with thiol-reactive drug substrates in cysteine-scanning mutagenesis studies and were found to be within the drug-binding pocket (10, 12). This suggested that arginine-scanning mutagenesis could be a useful approach for identifying residues in the drug translocation pathway and for determining the orientation of the TM segments in the membrane.Arginines that promote maturation appear to identify positions that are important for P-gp-drug interactions because they appear to mimic drug rescue of P-gp. It was also found that the ability of arginines (such as I306R in TM5) to promote maturation involved global enhancement of P-gp folding rather than simply compensating for a localized mutation (such as G251V) because other processing mutants could also be rescued (12). Because these arginine mutations enhance folding of P-gp in general, they will be described as enhancer rather than suppressor arginines. In this study we performed arginine-scanning mutagenesis on TMs 2–12 of P-gp processing mutant G251V to determine their orientations in the membrane and to identify residues that line the drug translocation pathway.     

Conformational Flexibility and Peptide Interaction of the Translocation ATPase SecA

The SecA ATPase forms a functional complex with the protein-conducting SecY channel to translocate polypeptides across the bacterial cell membrane. SecA recognizes the translocation substrate and catalyzes its unidirectional movement through the SecY channel. The recent crystal structure of the Thermotoga maritima SecA-SecYEG complex shows the ATPase in a conformation where the nucleotide-binding domains (NBDs) have closed around a bound ADP-BeFx complex and SecA's polypeptide-binding clamp is shut. Here, we present the crystal structure of T. maritima SecA in isolation, determined in its ADP-bound form at 3.1 Å resolution. SecA alone has a drastically different conformation in which the nucleotide-binding pocket between NBD1 and NBD2 is open and the preprotein cross-linking domain has rotated away from both NBDs, thereby opening the polypeptide-binding clamp. To investigate how this clamp binds polypeptide substrates, we also determined a structure of Bacillus subtilis SecA in complex with a peptide at 2.5 Å resolution. This structure shows that the peptide augments the highly conserved β-sheet at the back of the clamp. Taken together, these structures suggest a mechanism by which ATP hydrolysis can lead to polypeptide translocation.     

Suppressor mutations in the transmembrane segments of P-glycoprotein promote maturation of processing mutants and disrupt a subset of drug-binding sites

Defective folding of cystic fibrosis transmembrane conductance regulator protein missing Phe508 (DeltaF508) is the major cause of cystic fibrosis. The folding defect in DeltaF508 cystic fibrosis transmembrane conductance regulator might be correctable because misfolding of a P-glycoprotein (P-gp; ABCB1) mutant lacking the equivalent residue (DeltaY490) could be corrected with drug substrates or by introduction of an arginine residue into transmembrane (TM) segments 5 (I306R) or 6 (F343R). Possible mechanisms of arginine rescue were that they mimicked some of the effects of drug substrate interactions with P-gp or that they affected global folding such that all drug substrate/modulator interactions with P-gp were altered. To distinguish between these mechanisms, we tested whether arginines introduced into other TMs predicted to line the drug-binding pocket (TM1 or TM3) would affect folding. It was found that mutation of L65R(TM1) or T199R(TM3) promoted maturation of processing mutants. We then tested whether arginine suppressor mutations had local or global effects on P-gp interactions with drug substrates and modulators. The L65R(TM1), T199R(TM3), I306R(TM5), or F343R(TM6) mutations were introduced into the P-gp mutant L339C(TM6)/F728C(TM7), and thiol cross-linking was carried out in the presence of various concentrations of vinblastine, cyclosporin A, or rhodamine B. The presence of arginine residues reduced the apparent affinity of P-gp for vinblastine (L65R, T199R, and I306R), cyclosporin (I306R and F343R), or rhodamine B (F343R) by 4-60-fold. These results show that the arginine mutations affect a subset of drug-binding sites and suggest that they rescue processing mutants by mimicking drug substrate interactions with P-gp.     

Nucleotide binding, ATP hydrolysis, and mutation of the catalytic carboxylates of human P-glycoprotein cause distinct conformational changes in the transmembrane segments

P-Glycoprotein (P-gp, ABCB1) transports a variety of structurally unrelated cytotoxic compounds out of the cell. Each homologous half of P-gp has a transmembrane (TM) domain containing six TM segments and a nucleotide-binding domain (NBD) and is joined by a linker region. It has been postulated that binding of two ATP molecules at the NBD interface to form a "nucleotide sandwich" induces drug efflux by altering packing of the TM segments that make up the drug-binding pocket. To test if ATP binding alone could alter packing of the TM segments, we introduced catalytic carboxylate mutations (E556Q in NBD1 and E1201Q in NBD2) into double-cysteine mutants that exhibited ATP-dependent cross-linking so that the mutants could bind but not hydrolyze ATP. It was found that ATP binding alone could alter disulfide cross-linking between the TM segments. For example, ATP inhibited cross-linking of mutant L339C(TM6)/V982C(TM12)/E556Q(NBD1)/E1201Q(NBD2) but promoted cross-linking of mutant F343C(TM6)/V982C(TM12)/E556Q(NBD1)/E1201Q(NBD2). Cross-linking of some mutants, however, appeared to require ATP hydrolysis as introduction of the catalytic carboxylate mutations into mutant L332C(TM6)/L975C(TM12) inhibited ATP-dependent cross-linking. Cross-linking between cysteines in the TM segments also could be altered via introduction of a single catalytic carboxylate mutation into mutant L332C(TM6)/L975C(TM12) or by using the nonhydrolyzable ATP analogue, AMP.PNP. The results show that the TM segments are quite sensitive to changes within the ATP-binding sites because different conformations could be detected in the presence of ATP, AMP.PNP, during ATP hydrolysis or through mutation of the catalytic carboxylates.     

Insertion of an arginine residue into the transmembrane segments corrects protein misfolding

Deletion of Phe-508 (DeltaF508) in cystic fibrosis transmembrane conductance regulator causes cystic fibrosis because of misfolding of the protein. P-glycoprotein (P-gp) containing the equivalent mutation (DeltaY490) is also misfolded but can be rescued with drug substrates. Whether rescue is due to direct binding of drug substrate to the transmembrane (TM) segments or to indirect effects on cellular protein folding pathways is still controversial. P-gp-drug substrate interactions likely involve hydrogen bonds. If the mechanism of drug rescue involves changes to TM packing then we should be able to identify suppressor mutations in the TM segments that can mimic the drug rescue effects. We predicted that an arginine residue in the TM segments predicted to line the drug-binding pocket of P-gp (I306(TM5) or F343(TM6)) might suppress DeltaY490 P-gp protein misfolding because it has the highest propensity to form hydrogen bonds. We show that R306(TM5) or R343(TM6) increased the relative amount of mature DeltaY490 P-gp by 6-fold. Most other changes to Ile-306 or Phe-343 did not enhance maturation of DeltaY490 P-gp. The I306R mutant also promoted maturation of misprocessed mutants that had mutations in the second nucleotide-binding domain (L1260A), the cytoplasmic loops (G251V, F804A), the linker region (P709A), or in TM segments (G300V, G722A). These results show that arginine residues in the TM domains can mimic the drug rescue effects and are effective suppressor mutations for processing mutations located throughout the molecule.