ABCB1/MDR1/P-gp employs an ATP-dependent twist-and-squeeze mechanism to export hydrophobic drugs.

ABCB1, also called MDR1 or P-glycoprotein, exports various hydrophobic compounds and plays an essential role as a protective physiological barrier in several organs, including the brain, testis, and placenta. However, little is known about the structural mechanisms that allow ABCB1 to recognize hydrophobic compounds of diverse structures or the coupling of ATP hydrolysis to uphill substrate export. High-resolution X-ray crystal structures of the pre- and post-transport states and FRET analyses in living cells have revealed that an aromatic hydrophobic network at the top of the inner cavity is key for the conformational change in ABCB1 that is triggered by a hydrophobic substrate. ATP binding, but not hydrolysis, induces a progressive network that results in a twisting motion of the whole protein, squeezing out the substrate directly to the extracellular space. This twist-and-squeeze mechanism by which ABCB1 exports hydrophobic substrates is distinct from those of other transporters.

ABC proteins in evolution.

ATP-binding cassette (ABC) proteins play diverse roles in all living organisms, making them an attractive model for evolution. Early evolution of ancestral unicellular organisms entailed the acquisition of at least three types of ABC proteins: type 1 ABC proteins to import nutrients, and type 2 and 3 ABC proteins to generate the outer cell membrane by flopping and loading lipids onto acceptors, respectively. To export various toxic lipophilic compounds, cells evolutionarily acquired a fourth type of ABC protein. This suggests that ABC proteins may have played an important role in evolution, especially when life became terrestrial, protecting plants and animals from water loss and pathogen infection. ABC proteins are also assumed to have accelerated the evolution of vertebrates by allowing cholesterol to function for intramembrane signaling. In this review, we discuss the roles of ABC proteins in the evolution of bacteria, plants, and animals.

In vivo FRET analyses reveal a role of ATP hydrolysis-associated conformational changes in human P-glycoprotein.

P-glycoprotein (P-gp; also known as MDR1 or ABCB1) is an ATP-driven multidrug transporter that extrudes various hydrophobic toxic compounds to the extracellular space. P-gp consists of two transmembrane domains (TMDs) that form the substrate translocation pathway and two nucleotide-binding domains (NBDs) that bind and hydrolyze ATP. At least two P-gp states are required for transport. In the inward-facing (pre-drug transport) conformation, the two NBDs are separated, and the two TMDs are open to the intracellular side; in the outward-facing (post-drug transport) conformation, the NBDs are dimerized, and the TMDs are slightly open to the extracellular side. ATP binding and hydrolysis cause conformational changes between the inward-facing and the outward-facing conformations, and these changes help translocate substrates across the membrane. However, how ATP hydrolysis is coupled to these conformational changes remains unclear. In this study, we used a new FRET sensor that detects conformational changes in P-gp to investigate the role of ATP binding and hydrolysis during the conformational changes of human P-gp in living HEK293 cells. We show that ATP binding causes the conformational change to the outward-facing state and that ATP hydrolysis and subsequent release of γ-phosphate from both NBDs allow the outward-facing state to return to the original inward-facing state. The findings of our study underscore the utility of using FRET analysis in living cells to elucidate the function of membrane proteins such as multidrug transporters.

Inward- and outward-facing X-ray crystal structures of homodimeric P-glycoprotein CmABCB1.

P-glycoprotein extrudes a large variety of xenobiotics from the cell, thereby protecting tissues from their toxic effects. The machinery underlying unidirectional multidrug pumping remains unknown, largely due to the lack of high-resolution structural information regarding the alternate conformational states of the molecule. Here we report a pair of structures of homodimeric P-glycoprotein: an outward-facing conformational state with bound nucleotide and an inward-facing apo state, at resolutions of 1.9 Å and 3.0 Å, respectively. Features that can be clearly visualized at this high resolution include ATP binding with octahedral coordination of Mg2+; an inner chamber that significantly changes in volume with the aid of tight connections among transmembrane helices (TM) 1, 3, and 6; a glutamate-arginine interaction that stabilizes the outward-facing conformation; and extensive interactions between TM1 and TM3, a property that distinguishes multidrug transporters from floppases. These structural elements are proposed to participate in the mechanism of the transporter.

Experimental phase determination with selenomethionine or mercury-derivatization in serial femtosecond crystallography.

Serial femtosecond crystallography (SFX) using X-ray free-electron lasers (XFELs) holds enormous potential for the structure determination of proteins for which it is difficult to produce large and high-quality crystals. SFX has been applied to various systems, but rarely to proteins that have previously unknown structures. Consequently, the majority of previously obtained SFX structures have been solved by the molecular replacement method. To facilitate protein structure determination by SFX, it is essential to establish phasing methods that work efficiently for SFX. Here, selenomethionine derivatization and mercury soaking have been investigated for SFX experiments using the high-energy XFEL at the SPring-8 Angstrom Compact Free-Electron Laser (SACLA), Hyogo, Japan. Three successful cases are reported of single-wavelength anomalous diffraction (SAD) phasing using X-rays of less than 1 Šwavelength with reasonable numbers of diffraction patterns (13 000, 60 000 and 11 000). It is demonstrated that the combination of high-energy X-rays from an XFEL and commonly used heavy-atom incorporation techniques will enable routine de novo structural determination of biomacromolecules.

An isomorphous replacement method for efficient de novo phasing for serial femtosecond crystallography.

Serial femtosecond crystallography (SFX) with X-ray free electron lasers (XFELs) holds great potential for structure determination of challenging proteins that are not amenable to producing large well diffracting crystals. Efficient de novo phasing methods are highly demanding and as such most SFX structures have been determined by molecular replacement methods. Here we employed single isomorphous replacement with anomalous scattering (SIRAS) for phasing and demonstrate successful application to SFX de novo phasing. Only about 20,000 patterns in total were needed for SIRAS phasing while single wavelength anomalous dispersion (SAD) phasing was unsuccessful with more than 80,000 patterns of derivative crystals. We employed high energy X-rays from SACLA (12.6 keV) to take advantage of the large anomalous enhancement near the LIII absorption edge of Hg, which is one of the most widely used heavy atoms for phasing in conventional protein crystallography. Hard XFEL is of benefit for de novo phasing in the use of routinely used heavy atoms and high resolution data collection.

Structural basis for gating mechanisms of a eukaryotic P-glycoprotein homolog.

P-glycoprotein is an ATP-binding cassette multidrug transporter that actively transports chemically diverse substrates across the lipid bilayer. The precise molecular mechanism underlying transport is not fully understood. Here, we present crystal structures of a eukaryotic P-glycoprotein homolog, CmABCB1 from Cyanidioschyzon merolae, in two forms: unbound at 2.6-Å resolution and bound to a unique allosteric inhibitor at 2.4-Å resolution. The inhibitor clamps the transmembrane helices from the outside, fixing the CmABCB1 structure in an inward-open conformation similar to the unbound structure, confirming that an outward-opening motion is required for ATP hydrolysis cycle. These structures, along with site-directed mutagenesis and transporter activity measurements, reveal the detailed architecture of the transporter, including a gate that opens to extracellular side and two gates that open to intramembranous region and the cytosolic side. We propose that the motion of the nucleotide-binding domain drives those gating apparatuses via two short intracellular helices, IH1 and IH2, and two transmembrane helices, TM2 and TM5.

Deleting two C-terminal alpha-helices is effective to crystallize the bacterial ABC transporter Escherichia coli MsbA complexed with AMP-PNP.

An MsbA deletion mutant DeltaC21 that lacks the two C-terminal alpha-helices was expressed in Escherichia coli strain C41 and purified by metal-affinity and gel-filtration chromatography. Purified DeltaC21 retained 26% of the activity of the wild-type ATPase and had a similar binding affinity to fluorescent nucleotide derivatives. Although crystals of wild-type MsbA complexed with adenosine 5'-(beta,gamma-imido)triphosphate could not be obtained, crystals of DeltaC21 that diffracted to 4.5 A resolution were obtained. The preliminary DeltaC21 structure had the outward-facing conformation, in contrast to the previously reported E. coli MsbA structure. This result suggests that deletion of the C-terminal alpha-helices may play a role in facilitating the outward-facing nucleotide-bound crystal structure of EcMsbA.

Selective labeling of tag-fused protein by tryptophan-sensitized luminescence of a terbium complex.

A Tb3+ complex with two di(2-picolyl)amine (DPA) moieties and an oligo-aspartate peptide containing a tryptophan residue have been designed as a new binding pair for use in protein labeling.

Functional role of the linker region in purified human P-glycoprotein.

Human P-glycoprotein (P-gp), which conveys multidrug resistance, is an ATP-dependent drug efflux pump that transports a wide variety of structurally unrelated compounds out of cells. P-gp possesses a 'linker region' of approximately 75 amino acids that connects two homologous halves, each of which contain a transmembrane domain followed by a nucleotide-binding domain. To investigate the role of the linker region, purified human P-gp was cleaved by proteases at the linker region and then compared with native P-gp. Based on a verapamil-stimulated ATP hydrolase assay, size-exclusion chromatography analysis and a thermo-stability assay, cleavage of the P-gp linker did not directly affect the preservation of the overall structure or the catalytic process in ATP hydrolysis. However, linker cleavage increased the k(cat) values both with substrate (k(sub)) and without substrate (k(basal)), but decreased the k(sub)/k(basal) values of all 10 tested substrates. The former result indicates that cleaving the linker activates P-gp, while the latter result suggests that the linker region maintains the tightness of coupling between the ATP hydrolase reaction and substrate recognition. Inspection of structures of the P-gp homolog, MsbA, suggests that linker-cleaved P-gp has increased ATP hydrolase activity because the linker interferes with a conformational change that accompanies the ATP hydrolase reaction. Moreover, linker cleavage affected the specificity constants [k(sub)/K(m(D))] for some substrates (i.e. linker cleavage probably shifts the substrate specificity profile of P-gp). Thus, this result also suggests that the linker region regulates the inherent substrate specificity of P-gp.

Improved expression and purification of human multidrug resistance protein MDR1 from baculovirus-infected insect cells.

Multidrug resistance protein MDR1 (P-glycoprotein/ABCB1) is an ATP-dependent efflux pump for various cytotoxic agents, and is implicated in the resistance of human tumors to chemotherapeutic drugs. To achieve the three-dimensional structural analysis for its mechanistic implications, large amounts of high-quality and homogeneous MDR1 protein are essential. Here we report a cost-effective method for large-scale expression of human MDR1 using a baculovirus/insect expressSF+ cell system and an alterative purification method to maintain MDR1 in a monodispersed state. After extensively optimizing the detergent, pH, and additives, a high yield (2.8 mg/L) of purified MDR1 was obtained by immobilized metal chelate affinity and size-exclusion chromatographies with 49% recovery. The purified MDR1 exhibited specific ATP hydrolase activity (1.7 micromol/min/mg) in the presence of a substrate, verapamil. This value was 14-fold greater than the basal activity without the drug. Size-exclusion chromatography analysis of purified MDR1 showed a monodispersed elution profile. The present purification method provides suitable material for structural and functional studies on human MDR1.

Cholesterol fill-in model: mechanism for substrate recognition by ABC proteins.

Many of the 48 or 49 human ABC proteins are involved in lipid homeostasis and in defence against hydrophobic substances in food and the environment. Defects in their functions cause various diseases, suggesting that they play very important roles in human health; however, the mechanism of how they handle enormous numbers of hydrophobic compounds with various structures and molecular weights, or phospholipids and cholesterol, major components of cellular membranes, is not known. We compared the functions of drug-transporting and lipid-transporting ABC proteins, and found that (1) ABC proteins, either lipid or drug transporters, have a similar substrate binding site which recognizes PL and cholesterol, or drugs and cholesterol; (2) Cholesterol in membranes binds to various ABC proteins together with PL or drugs, and plays an important role in substrate recognition, especially by ABCB1/MDR1, where cholesterol fills the empty space in the substrate binding site when small drugs bind to it. ABC proteins exert very flexible substrate recognition, i.e., one-to-many interaction rather than the conventional rigid one-to-one interaction. We propose calling the mechanism the "cholesterol fill-in model".

A stilbene synthase from Japanese red pine (Pinus densiflora): implications for phytoalexin accumulation and down-regulation of flavonoid biosynthesis.

Stilbene synthase (STS) and chalcone synthase (CHS) are plant-specific polyketide synthases that play key roles in the stilbenoid and flavonoid biosyntheses, respectively. We have recently isolated from Pinus densiflora three STS cDNAs (PDSTS1, PDSTS2, and PDSTS3) and one CHS cDNA (PDCHSX). We then heterologously expressed these cDNAs in Escherichia coli and characterized their properties. An unusual STS isozyme, PDSTS3, lacks the common C-terminal extension of STS because of a frame-shift mutation and shows the highest pinosylvin-forming activity among the STSs tested. Pinosylvin was shown to be a potent inhibitor of PDCHSX (K(i) = 6 microM) as well as PDSTS2 (K(i) = 13 microM), which presumably maintains the balance between the stilbenoid and flavonoid biosyntheses. PDSTS3 was insensitive to product inhibition. We identified PDSTS3 in the pine seedlings as well as full-length STS. The data provide evidence that PDSTS3 is involved in the potential regulation of the stilbenoid and flavonoid biosynthetic pathways in pine trees.