ARTICLE

Received 31 Mar 2016 | Accepted 22 Jun 2016 | Published 8 Aug 2016

DOI: 10.1038/ncomms12387 OPEN

ATP-dependent substrate transport by the ABC transporter MsbA is proton-coupled

Himansha Singh1, Saroj Velamakanni1, Michael J. Deery2, Julie Howard2, Shen L. Wei1 & Hendrik W. van Veen1

ATP-binding cassette transporters mediate the transbilayer movement of a vast number of substrates in or out of cells in organisms ranging from bacteria to humans. Current alternating access models for ABC exporters including the multidrug and Lipid A transporter MsbA from Escherichia coli suggest a role for nucleotide as the fundamental source of free energy. These models involve cycling between conformations with inward- and outward-facing substrate-binding sites in response to engagement and hydrolysis of ATP at the nucleotide-binding domains. Here we report that MsbA also utilizes another major energy currency in the cell by coupling substrate transport to a transmembrane electrochemical proton gradient. The dependence of ATP-dependent transport on proton coupling, and the stimulation of MsbA-ATPase by the chemical proton gradient highlight the functional integration of both forms of metabolic energy. These ndings introduce ion coupling as a new parameter in the mechanism of this homodimeric ABC transporter.

1 Department of Pharmacology, University of Cambridge, Tennis Court Road, Cambridge CB2 1PD, UK. 2 Department of Biochemistry, Cambridge Centre for Proteomics, University of Cambridge, Tennis Court Road, Cambridge CB2 1GA, UK. Correspondence and requests for materials should be addressed to H.W.v.V. (email: mailto:[email protected]

Web End [email protected] ).

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ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms12387

ATP-binding cassette (ABC) multidrug exporters are embedded in the plasma membrane and actively extrude cytotoxic drugs from the cell1. They play a critical role in

the failure of pharmacological treatment of microbial diseases and cancers, affect drug pharmacokinetics in mammals and are a prime target for clinical research2,3. Some of these transporters, including the mammalian multidrug resistance P-glycoprotein ABCB1 and its bacterial homologues MsbA and LmrA, transport lipids and chemotherapeutic drugs from the inner leaet of the plasma membrane to the outer leaet and extracellular environment48.

ABC exporters are thought to utilize the free energy from ATP-binding and hydrolysis at two nucleotide-binding domains (NBDs) to transport substrates via a translocation pathway that is formed by two membrane domains (MDs)9,10. In ABCB1, these four domains are fused on a single polypeptide, whereas in bacterial MsbA and LmrA, an MD is fused to an NBD in a half-transporter that homodimerizes to form the full transporter. Current structural and biochemical data support an alternating access model in which the substrate-binding sites in the MDs are exposed to either side of the membrane as the transporter alternates between inward-facing and outward-facing conformational states1113. The transition from the inward-facing conformation to the outward-facing conformation is governed by ATP-binding-associated NBD dimerization, often referred to as the power stroke, after which ATP hydrolysis and ADP-and-Pi-release-dependent NBD dissociation resets the transporter to the inward-facing conformation. However, many important details of this mechanism remain to be elucidated. MsbA transports cytotoxic agents and the Lipid A anchor of lipopolysaccharides1417, and is an essential transporter in many Gram-negative bacteria1820. Here we show for Escherichia coli MsbA that ATP binding and hydrolysis are insufcient to drive drug transport in the absence of an electrochemical proton gradient. We conclude that proton coupling is essential in the nucleotide-dependent power stroke in MsbA.

ResultsStudies in intact cells. Energy coupling by MsbA was rst studied in ATP-depleted Lactococcus lactis cells with a very low internal ATP concentration of B7 mM (ref. 21) that were preloaded with 2 mM ethidium by reversed transport by MsbA15,16 (Fig. 1). After a steady state was reached, the addition of glucose raised the intracellular ATP concentration to B9 mM (ref. 21), and initiated a signicant ethidium efux activity by wild-type MsbA (MsbA-WT) compared with the non-expressing control (Fig. 1c,d). Surprisingly, ethidium efux was also observed for cells containing MsbA-MD (Fig. 1c,d), a truncated form of MsbA-WT that lacks the NBD and that is expressed in a similar orientation and at a moderately elevated level (117%) in the plasma membrane compared with MsbA-WT (Fig. 1a,b). To investigate the possibility that transport by MsbA-MD in these cells is dependent on an electrochemical proton gradient, also referred to as the protonmotive force (Dp, interior positive and acidic), or one of its components, the transmembrane pH gradient (DpH) and electrical membrane potential difference (Dc), measurements of ethidium efux by MsbA-MD were repeated in cells in which the magnitude and composition of the

Dp ( Dc ZDpH in which Z is approximately equal to 58 mV

at 20 C) was manipulated with the ionophores nigericin and valinomycin22. The results show that ethidium efux by MsbA-MD was completely inhibited in the presence of the Dc only. In contrast, signicant efux was observed in the presence of the DpH only (Fig. 1e). The results for MsbA-WT (Fig. 1f)

showed similarities with those for MsbA-MD, and both were

clearly different from non-expressing control cells for which no ethidium efux was observed (Fig. 1g). Previous studies in cells highlighted the dependency of ethidium efux by MsbA-WT on ATP binding and hydrolysis; the efux activity is strongly inhibited by impairment of the MsbA-ATPase activity down to 46% of WT activity through the deletion of the Walker A lysine residue at position 382 (DK382 mutation)16,23. Indeed, although the expression level of MsbA-DK382 was only slightly below that of MsbA-WT (77%; Fig. 1a), the ethidium transport activity of the mutant was strongly inhibited (Fig. 1c,d). Taken together, these ndings suggest that MsbA-mediated ethidium efux is dependent on both the electrochemical proton gradient and ATP hydrolysis.

Proton-coupled substrate transport in proteoliposomes. To investigate the dependence of transport activity of MsbA on the electrochemical proton gradient in the absence of nucleotides and other components, MsbA-WT, MsbA-MD, MsbA-DK382 and the transport-inactive triple mutant MsbA-DED (D41N in trans-membrane helix (TMH) 1, E149Q in TMH 3 and D252N in TMH 5) were afnity-puried and reconstituted in proteoliposomes prepared from E. coli phospholipids7,24. Unlike whole cells, spheroplasts and plasma membrane vesicles, these proteoliposomes are devoid of cytoplasmic constituents and alternative primary-active and secondary-active transporters, allowing studies on the transport and energetics of puried MsbA proteins in the absence of energy-transducing transport processes. The MsbA proteins incorporated equally well in proteoliposomes and were present in an inside-out orientation (Fig. 2a,b). Puried MsbA-WT and MsbA-MD samples used for the reconstitution experiments were examined by LC-MS/MS mass spectrometry. This analysis conrmed the lack of the native NBD in the MsbA-MD protein (Fig. 2c). The Mascot database was also searched against the UniProt L. lactis subsp. lactis database, which demonstrated insignicant levels of contaminating membrane transporters and ABC NBDs (Supplementary Data 1), below 0.01% for MsbA-WT and 0.7% for MsbA-MD when the exponentially modied protein abundance index was used as a measure for the protein abundance25.

To study the functionality of the MsbA proteins in the proteoliposomes, a DpH (interior acidic) was generated by pH jump (Fig. 3). In this method, proteoliposomes prepared in buffer pH 6.8 were diluted in buffer pH 8.0, imposing a difference between the interior pH and external pH by pH jump (pHin

6.8/pHout 8.0). This pH difference was sustained by dissociation of NH4 in the lumen of proteoliposomes and the outward diffusion of NH3. The Dc (interior positive) was imposed by diffusion of SCN from the lumen down an outwardly directed chemical gradient ([SCN ]in/[SCN ]out 100 mM versus

1 mM). No changes in ethidium uorescence were observed upon imposition of Dc and/or DpH in liposomes lacking MsbA proteins (Fig. 4a) or containing inactive MsbA-DED (Fig. 4b). These results are consistent with the mass spectrometry data showing the absence of contaminating membrane transporters in our protein preparations (Fig. 2c and Supplementary Data 1). However, for both MsbA-WT (Fig. 4c) and MsbA-MD (Fig. 4d), ethidium transport in the proteoliposomes with the imposed DpH (interior acidic) was signicantly higher, more than vefold for MsbA-WT compared with the equilibration level in the no-gradient controls (pHin 6.8/pHout 6.8 and pHin 8.0/pHout 8.0).

These results point to concentrative DpH-dependent accumulation of ethidium. In contrast, uptake of ethidium by MsbA-WT and MsbA-MD was not stimulated in the presence of a reversed DpH (DpHREV, interior alkaline), which was imposed by the passive diffusion of acetic acid from the lumen of the proteoliposomes

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NATURE COMMUNICATIONS | DOI: 10.1038/ncomms12387 ARTICLE

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Figure 1 | Ethidium efux in intact cells. (a) Immunoblot probed with anti-polyhistidine tag antibody (left) shows that MsbA-MD and MsbA-DK382 are expressed in the plasma membrane of L. lactis (5 mg total membrane protein per lane) at 117% and 77% of MsbA-WT, respectively, and that these proteins are absent in control cells (Ctrl). The migration of molecular mass markers is indicated. Histogram (right) shows MsbA signal intensities. (b) Availability of the cytosolic NH2-terminal His-tag in MsbA-WT and MsbA-MD to cleavage by proteinase K ( PK) at the external side of right-side-out (RSO) or

inside-out (ISO) membrane vesicles (3 mg protein per lane). Incubation without the protease (-PK) served as control. Uncleaved His-tag was detected on immunoblot (left). Signal intensities are shown in the histogram (right). (c) Efux of monovalent cationic ethidium was initiated by the addition of 20 mM

glucose (Glc) as a source of metabolic energy to ATP-depleted cells that were preloaded with 2 mM of the dye. Efux was observed for MsbA-WT but not for non-expressing control or MsbA-DK382, which exhibits a strongly reduced ATPase activity due to the absence of the catalytic Walker A lysine residue.

Remarkably, ethidium efux was also observed for a truncated form of MsbA-WT that lacks the NBD (MsbA-MD). (d) Histogram shows signicance of uorescence levels in (c) at t 400 s. (eg) Ethidium efux from cells containing MsbA-MD (e), MsbA-WT (f) or no MsbA proteins (g) to which

ionophores nigericin (Dc only, interior negative), valinomycin (DpH only, interior alkaline) or both (no Dp) were added at concentrations of 1.0 and 0.1 mM, respectively, 3 min prior to the addition of the glucose. Data represent observations in 3 or more independent experiments with independently prepared batches of cells. Values in histograms are expressed as means.e.m. (one-way analysis of variance; *Po0.05; **Po0.01; ***Po0.001; ****Po0.0001).

(Figs 3 and 4c,d). Upon the imposition of the Dc plus DpH (Dp, interior positive and acidic), ethidium transport was above control but was reduced compared with the activity obtained in the presence of the DpH only (Fig. 4c,d). As these results suggested that the imposed Dc (interior positive) was inhibitory

for ethidium transport in proteoliposomes, the effect of reversed Dc (DcREV, inside negative) was tested. The DcREV was imposed in the proteoliposomes by the electrogenic downhill diffusion of K from the lumen to the external buffer by valinomycin (added at 10 nmol (mg of protein) 1; Fig. 3), and was found

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ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms12387

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Figure 2 | Puried MsbA proteins in proteoliposomes. (a) Immunoblot of proteoliposomes prepared from E. coli phospholipids (5 mg protein per lane) (left) demonstrates the equal incorporation of puried transport-inactive triple mutant MsbA-DED, MsbA-MD, MsbA-DK382 and MsbA-WT, and the absence of membrane proteins in empty control liposomes (Ctrl). Histogram (right) shows MsbA signal intensities. (b) Availability of the His-tag in

MsbA-WT (3 mg protein per lane) to cleavage by Proteinase K (PK) at the external side of proteoliposomes (left) and corresponding signal intensities (right) demonstrate the inside-out orientation of the reconstituted protein. (c) Puried MsbA-WT and MsbA-MD preparations for reconstitution experiments were subjected to LCMS/MS mass spectrometry. Mascot protein coverage maps for MsbA-WT and MsbA-MD are shown. The sequence stretches in red correlate to the peptides that were identied in these experiments. The MsbA-MD sequence shows a lack of peptides identied along the NBD stretch of full-length MsbA-WT. Data represent observations in three or more independent experiments with independently prepared batches of proteoliposomes. Values in histograms are expressed as means.e.m. (a, one-way analysis of variance; b, unpaired student-t test; ***Po0.001).

to stimulate ethidium transport in the proteoliposomes, also when combined with the DpH (interior acidic), yielding DpDcREV DcREV ZDpH (Fig. 4e). No increase in ethidium

uorescence was observed under these conditions in liposomes lacking MsbA proteins (Fig. 4f). When taken together in the physiological context of the cell (Dp, interior negative and

alkaline), these ndings indicate that the DpH (interior alkaline) supports ethidium efux by MsbA-WT and MsbA-MD, whereas the Dc (interior negative) inhibits this activity.

Proton-coupled substrate transport by MsbA proteins was also observed for the neutral antibiotic chloramphenicol20. The 100-fold dilution of (proteo)liposomes in dilution buffer

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Figure 3 | Schematic showing methods for articial imposition of electrochemical ion gradients in proteoliposomes. The Dc (interior positive), DpH (interior acidic), Dp (interior positive and acidic), DcREV

(interior negative), DpDcREV (interior negative and acidic), or DpHREV (interior alkaline) were imposed by 100-fold dilution of proteoliposomes containing inside-out oriented MsbA-WT or MsbA-MD as described in the main text. Inclusion of DNA in the lumen allows the recording of the uorescence emission of accumulated ethidium.

containing 2 mM [3H]-chloramphenicol initiated the time-dependent accumulation of chloramphenicol in proteoliposomes containing reconstituted MsbA-WT or MsbA-MD in the presence of the imposed DpH (interior acidic), but not in the absence of the DpH or in empty liposomes without MsbA proteins (Fig. 5a,b). Thus, the proton dependence of MsbA-mediated transport is observed for two different substrates, chloramphenicol and ethidium, with different charge and hydrophobicity. Using (proteo)liposomes loaded with the pH indicator 20,70-bis-(2-carboxyethyl)-5-(and-6)-carboxyuorescein (BCECF), the uorescence emission of which increases at alkaline pH, chloramphenicol uptake by MsbA-WT in the proteoliposomes was found to be associated with proton efux down its chemical gradient (pHin 6.8/pHout 8.0; Fig. 5c). This result is consistent with the no-gradient control experiments in Fig. 4c in which ethidium transport by MsbA-WT in proteoliposomes was not initiated by changes in local pH in the lumen or external buffer (pHin 6.8/pHout 6.8 and pHin 8.0/pHout8.0) but required the imposition of a transmembrane DpH (interior acidic).

Proton coupling is functionally linked to ATP hydrolysis. In view of the nding that ethidium transport by MsbA is dependent on ATP hydrolysis (Fig. 1c) and components of the Dp (Figs 1f and 4c,e), the relationship between these two forms of metabolic energy was further studied in proteoliposomes. For this purpose, ethidium uptake in MsbA-WT-containing proteoliposomes was measured in the absence or presence of the imposed DpH (inside acidic; pHin 6.8/pHout 8.0) in buffer containing 2.5 mM

Mg-ATP or non-hydrolysable nucleotide analogue AMP-PNP. Remarkably, the ATP did not initiate ethidium accumulation in the absence of the DpH, nor did the nucleotide enhance DpH-dependent transport (Fig. 6a). However, the DpH-dependent accumulation of ethidium was strongly inhibited by the replacement of ATP by the non-hydrolysable analogue AMP-PNP (Fig. 6a). These data demonstrate the importance of ATP hydrolysis by MsbA-WT in experiments where ATP is co-applied with the imposed DpH. In agreement with this, measurements of the MsbA-ATPase activity in proteoliposomes showed that imposition of the DpH (pHin 6.8/pHout 8.0) stimulated the ATPase activity of MsbA-WT compared with controls

in which the DpH was dissipated through the addition of niger-icin (pHin becomes equal to pHout 8.0; Fig. 6b,c) or in which the

DpH was not imposed (pHin/pHout set at 8.0/8.0; Fig. 6d). In these experiments, the local pH near the MsbA-NBD at the external side of the membrane remained constant. These data suggest that the conformational changes in MsbA-WT associated with ethidium transport can occur in the absence of ATP in a reaction driven by a DpH and DcREV. However, when ion gradients are imposed in the presence of ATP, proton coupling becomes functionally linked to ATP binding and hydrolysis, which are required to drive the dimerization and dissociation of the NBDs during the propagation of the transport cycle. Although the MsbA-DK382 mutant can operate in a DpH-dependent manner in the absence of ATP, the addition of ATP traps this mutant in an ATP-bound state and renders it transport-inactive (Fig. 6e) in an analogous manner as observed in ATP-containing cells (Fig. 1c,d). This inhibitory trapping was mimicked by the addition of the non-hydrolysable AMP-PNP to MsbA-WT (Fig. 6a). The inhibitory effect of AMP-PNP on DpH-dependent ethidium accumulation in the proteoliposomes was not observed for MsbA-MD lacking the NBD (Fig. 6f).

MsbA-WT is more efcient than MsbA-MD. The observations on active drug transport by MsbA-MD raise questions about the functional importance of ATP binding and hydrolysis in full-length MsbA. The direct comparison of the transport activities of MsbA-WT and MsbA-MD in cells show that MsbA-WT catalyses ethidium efux to lower intracellular steady-state levels than MsbA-MD (Fig. 1c,d). When cell growth was measured in the presence of the MsbA substrate erythromycin15, MsbA protein expression caused signicant shifts in the erythromycin concentration at which the growth rate is half-maximal (IC50),

from 0.004 mM or the non-expressing control to 0.393 mM (P 0.008) for MsbA-WT and 0.094 mM (P 0.003) for MsbA

MD; the IC50 for MsbA-DK382 (0.051 mM) was close to control (Fig. 6g). Hence, the enhanced efciency of efux by full-length MsbA compared with the NBD-less protein was also found in the ability of the MsbA proteins to confer cellular resistance to the antibiotic erythromycin. The ATP-dependent dimerization of the NBDs with closure of the substrate-binding cavity towards the inside surface of the membrane facilitates capture of substrate from the cellular interior and/or inner membrane leaet, and enables efux against a larger drug concentration gradient and/or lipidwater partition coefcient. The ATP dependence therefore enhances the directionality of the transport reaction.

DiscussionAlthough MsbA is an ABC transporter that mediates substrate transport in an ATP-dependent manner, the experiments in intact cells and proteoliposomes prepared from E. coli phospholipids demonstrate for the rst time that the ATP-binding-associated power stroke during drug transport is assisted by proton coupling via apparent drugproton antiport. The dissipation of the DpH (interior alkaline) in cells by the addition of nigericin blocks MsbA-WT-mediated ethidium efux (Fig. 1f). Conversely, the articial imposition of the DpH (inside acidic) in proteoliposomes initiates (i) the accumulation of ethidium and chloramphenicol by puried, inside-out oriented MsbA-WT above the equilibration level (Figs 4c and 5a,b) and (ii) proton efux in a chloramphenicol-dependent manner (Fig. 5c). The role of the DpH in MsbA-mediated transport in cells is also supported by the observations on the erythromycin efux by MsbA-MD against the inwardly directed drug concentration gradient that impairs growth of the non-expressing control cells (Fig. 6g). Proton-coupled ethidium efux by MsbA-WT is inhibited by the

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ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms12387

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Figure 4 | Ethidium transport in proteoliposomes. (ad) Ethidium transport in DNA-loaded empty liposomes (a) or proteoliposomes containing the MsbA-DED triple mutant (b), MsbA-WT (c) or MsbA-MD (d) with imposed DpH (pHin 6.8/pHout 8.0), Dc (interior positive), proton-motive force (Dp Dc ZDpH in which Z equals B58 mV at 20 C), DpHREV (pHin 8.0/pHout 6.8), or in the absence of ion gradients (pHin 6.8/pHout 6.8, termed No

gradient and pHin 8.0/pHout 8.0, No gradient 8/8). No gradient 8/8 for (a,b,d) was very close to the No gradient control, and is not shown for clarity of presentation. The 5-fold accumulation of ethidium by MsbA-WT is indicated in the uorescence versus time graph in (c). (e,f) Effect of the imposition of a reversed DcREV (interior negative) without or with the DpH (interior acidic) (DpDcREV DcREV ZDpH) on ethidium transport in proteoliposomes

containing MsbA-WT (e) or empty liposomes (f). Data represent observations in three or more independent experiments with independently prepared batches of proteoliposomes. Values in histograms show signicance of uorescence levels at steady-state, and are expressed as means.e.m. (one-way analysis of variance; *Po0.05; **Po0.01; ***Po0.001; ****Po0.0001).

Dc (interior negative) in cells (Fig. 1f) and equivalent Dc (interior positive) in the proteoliposomes (Fig. 4c). Together with the observed stimulation of transport in proteoliposomes by the DcREV (interior negative; Fig. 4e), the data point to apparent electrogenic antiport of ethidium and nH with no1. Thus, two or more ethidium molecules are exchanged per H , which is consistent with the presence in this type of ABC transporter of two cavities at the MDMD interface that are related by twofold pseudosymmetry and that can be separated by mutation10,24,26,27. Proton-coupled transport is associated with the MD of MsbA; the observations on DpH dependence for MsbA-WT in intact cells and proteoliposomes could all be reproduced using MsbA-MD that lacks the NBD (Figs 1e and 4d).

Evidence was obtained that proton coupling operates in conjunction with a functional catalytic cycle at the NBDs when nucleotide is present. First, ethidium efux in metabolically active cells containing mM concentrations of ATP21 was inhibited by the MsbA-DK382 mutation (Fig. 1c). As the NBDs are conformationally coupled to the MDs, the reduced rate of ATP hydrolysis in the mutant will cause more persistent binding

of the nucleotide, which in turn will block the propagation of the catalytic cycle, and, hence, inhibit transport. Second, for MsbA-WT this transport reaction in proteoliposomes was signicantly inhibited by the inclusion of the non-hydrolysable ATP analogue AMP-PNP in the external buffer (Fig. 6a). Third, DpH (interior acidic)-dependent ethidium accumulation in proteoliposomes by MsbA-DK382 was inhibited by the addition of Mg-ATP to the external buffer where the NBDs reside (Fig. 6e). Fourth, the addition of ATP or AMP-PNP had no effect on DpH (interior acidic)-dependent ethidium accumulation in proteoliposomes containing MsbA-MD without the NBD (Fig. 6f). Finally, the imposition of a DpH stimulated the

MsbA-WT ATPase activity in proteoliposomes (Fig. 6bd). The dependence of drug transport on the genotype of the expressed or reconstituted MsbA proteins demonstrates that the drug transport activity is not dependent on auxiliary proteins but on MsbA itself. This conclusion is consistent with the mass spectrometry analysis demonstrating insignicant levels of contaminating membrane transporters or NBDs in our protein preparations (Fig. 2c).

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Figure 5 | Chloramphenicol/proton antiport in proteoliposomes. (a,b) Effect of the DpH on the uptake of 2 mM of the neutral antibiotic [3H]-chloramphenicol (CM) over time (a) and at 5 min (b) in proteoliposomes containing MsbA-WT or MsbA-MD, or in liposomes without MsbA proteins. (c) CM uptake by in proteoliposomes is associated with H efux through drug/proton antiport. The CM-dependent increase in uorescence emission of the trapped pH probe BCECF in MsbA-WT-containing proteoliposomes but not in empty control liposomes indicates an increase in the lumen pH during the MsbA-WT catalysed reaction. Histogram shows BCECF uorescence levels at 550 s. The error bars for some of the data points in (a) were too small to be displayed, and are hidden behind the data point symbols. Data represent observations in three or more independent experiments with independently prepared batches of proteoliposomes. Values in histograms are expressed as means.e.m. (one-way analysis of variance ; ***Po0.001;

****Po0.0001).

Protons can have different roles in the mechanisms of membrane transporters. A role of H in primary-active transport was previously described for the P-type Ca2 -ATPase (SERCA), in which protons neutralize Ca2 -coordinating carboxylates following substrate dissociation, essentially giving primary-active transmembrane proton-Ca2 antiport28,29. H binding and movement in proton-coupled secondary-active transporters are also known to induce changes in electrostatic and hydrogen-bonding interactions between interhelix side chains that underlie the conformational transitions associated with protonsubstrate symport and antiport30,31. The nding of proton-coupled transport by MsbA suggests that similar mechanistic principles are relevant for ABC exporters. Indeed, recent structural studies on the antibacterial peptide ABC exporter McjD from E. coli conclude that the conformational transitions required for substrate transport might not all be dependent on ATP binding and hydrolysis32. The MsbA data share similarities with observations on the dual mode of energy coupling by the arsenite and antimonite-translocating ArsB protein from E. coli33,34, which acts as a secondary-active metalloidproton antiporter, but when associated with the ArsA ATPase subunit can utilize ATP for improved extrusion efciency. The ndings for MsbA-MD are reminiscent to those described for the MD of the ABC exporter LmrA from L. lactis,

which catalyses apparent ethidiumproton symport22,35, illustrating that the coupled transport of substrate and protons is more widespread among ABC exporters. Our conclusions introduce proton coupling as a new parameter in the mechanism of MsbA, and point to the existence of proton-coupled conformational transitions in its transport cycle. This work is of fundamental importance for our understanding of how ABC exporters operate.

Methods

Bacterial strains and plasmids. The drug-hypersensitive L. lactis strain NZ9000 DlmrA DlmrCD strain devoid of the endogenous ABC multidrug transporters LmrA and LmrCD36,37 was used as a host for expression vector pNZ8048-derived plasmids36 that contain a chloramphenicol resistance marker gene, nisin-inducible nisA promoter and His-tagged wild-type (WT) or mutant MsbA gene, or truncated MsbA gene encoding the MD only.

Construction of MsbA mutants. To express N terminally His-tagged MsbA-MD, the corresponding region of the msbA gene from E. coli was PCR-amplied from pNZMsbA15 with the forward primer 50-GGAGGCACTCACCATGGGC-30 and the reverse primer 50-CGGATAAGTTCTAGATTAATTGCGGAATTCCACGT CGGC-30 to insert a TAA stop codon after the codon for N346, equivalent to H353 in previous work on LmrA22, followed by an XbaI site at the 30 end. NcoI and XbaI (Roche Applied Science, Herts, UK) were used to digest the PCR product, which was followed by ligation of the DNA fragment into the linearized vector pNZ8048 downstream of the nisA promoter, yielding pNZMsbA-MD. For the generation of

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a b

MsbA-WT

Time (s)

****

200 *

Normalized fluorescence

(%)

Rate of ATP hydrolysis nmol Pi min1 (mg protein)1

200

****

150

**

100

100

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No gradient

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No gradient + AMP-PNP

pH

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Nigericin

c d

600

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Fluorescence (a.u.)

Rate of ATP

hydrolysis nmol Pi min1

(mg protein)1

550

pH + nigericin

100

500

50

450

0 500 1,000 1,500

pH nigericin

Time (s)

0

pH

No gradient

e f

MsbA-K382

Time (s)

MsbA-MD

Time (s)

Normalized fluorescence

(%)

Normalized fluorescence

(%)

200

**

200

** **

**

100

100

0

0

pH

0 100 200

0 100 200

pH

ATP+pH

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No gradient + AMP-PNP

g

MsbA-WT

100

MsbA-MD

Control

MsbA-K382

Relative growth rate

(%)

50

0

0.0 0.2 0.4

[Erythromycin] (M)

Figure 6 | Relationship between ATP dependence and proton coupling by MsbA proteins. (a) Effect of the presence of 2.5 mM Mg-ATP or non-hydrolyzable nucleotide analogue AMP-PNP on imposed DpH (pHin 6.8/pHout 8.0)-dependent ethidium transport by MsbA-WT in DNA-loaded proteoliposomes. Histogram shows signicance of uorescence levels at steady-state. (b,c) MsbA-WT ATPase activity in proteoliposomes in which the

DpH (pHin 6.8/pHout 8.0) was dissipated in the presence of nigericin (leading to pHin 8.0/pHout 8.0) (b). This action of nigericin was conrmed using proteoliposomes (pHin 6.8/pHout 8.0) loaded with the pH probe BCECF (brown trace), the uorescence emission of which was enhanced by the increase in the lumen pH from 6.8 to 8.0 by the addition of the ionophore at t 0 s (orange trace) (c). (d) MsbA-WT ATPase activity in proteoliposomes in the

presence of an imposed DpH (pHin 6.8/pHout 8.0) or its absence (pHin 8.0/pHout 8.0). Note that the pH near the NBD of MsbA (at the external side of the proteoliposomes) remains constant in the experiments displayed in (b) and (d). (e,f) Experiments as described in (a) in proteoliposomes containing

MsbA-DK382 (e) or MsbA-MD (f). (g) Erythromycin resistance in cells expressing MsbA-WT (blue squares), MsbA-MD (red circles), MsbA-DK382 (green squres) compared to non-expressing control cells (black triangles). Maximum specic growth rate (mmax) was determined at each erythromycin concentration and is presented as a percentage of mmax in the absence of erythromycin. The error bars for some of the data points in (g) were too small to be displayed, and are hidden behind the data point symbols. Data represent observations in 3 or more independent experiments with independently prepared batches of proteoliposomes or cells. Values in histograms are expressed as means.e.m. (one-way analysis of variance except for (b,d) unpaired student-t test; *Po0.05; **Po0.01; ****Po0.0001).

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pNZMsbA-DED (D41N E149Q D252N) the following primers were used: D41N (forward) 50-GCCAGCAACACCTTCATGTTATCGCTCC-30, (reversed) 50-AAG

GTGTTGCTGGCTGCGTTGAGGATTA-30; E149Q (forward) 50-TGTGCGTCAA GGTGCGTCGATCATCGGC-30, (reversed) 50-ACGCACCTTGACGCACAACAG TAATCAG-30; D252N (forward) 50-CATCTCTAATCCGATCATTCAGCTG ATC-30, (reversed) 50-TGATCGGATTAGAGATGGAAGAGGCTGA-30. The DNA was sequenced to ensure that only the intended changes were introduced.

Growth conditions and protein expression. L. lactis NZ9000 DlmrA DlmrCD was grown overnight in M17 medium (Difco) supplemented with 0.5% glucose and5 mg ml 1 chloramphenicol at 30 C to an OD660 of 0.50.6. For protein expression, cells harbouring pNZMsbA, pNZMsbA-MD, pNZMsbA-DK382 (ref. 16), pNZMsbA-DED or pNZ8048 (empty vector) were incubated for 1 h at 30 C in the presence of a 1:1,000 dilution of the culture supernatant of nisin-A producingL. lactis strain NZ9700, corresponding to a nisin A concentration of B10 pg ml 1 (ref. 38), unless stated otherwise.

Ethidium transport in de-energized cells. L. lactis NZ9000 DlmrA DlmrCD cells expressing MsbA, MsbA-DK382 or MsbA-MD and non-expressing control cells were grown to an OD660 of 0.6, and protein expression was induced for 1 h at 30 C by 10 pg ml 1 nisin A. Cell pellets from 50 ml culture were harvested by centrifugation (6,500g for 10 min at 4 C) and washed with ice-cold washing buffer (50 mM KPi, pH 7.0, containing 5 mM MgSO4). To deplete intracellular ATP levels, cells were incubated with 0.5 mM of the protonophore 2,4-dinitrophenol for 30 min at 30 C. The protonophore was removed by centrifugation, followed by washing of cells with the washing buffer. Finally, the cells were resuspended in washing buffer to an OD660 of 5.0. For each measurement, cells were diluted at 1:10 into 2 ml washing buffer in a glass cuvette. Fluorescence was followed in a LS 55B Luminescence Spectrometer (PerkinElmer, MA, USA) at excitation and emission wavelengths of 500 and 580 nm with slit widths of 10 and 5 nm, respectively. Owing to differences in the uptake rates, ATP-depleted control cells and cells containing MsbA-WT or MsbA-MD were pre-loaded with 2 mM ethidium bromide for 50, 25 and 30 min, respectively, to a similar starting uorescence level. Active efux was subsequently initiated by the addition of 0.5% glucose, which re-energized the cells and uorescence was followed for B10 min. To further determine the inuence of the magnitude and composition of the Dp on MsbA-mediated transport, ionophores nigericin and valinomycin were added (nal concentration 1 and 0.1 mM, respectively) before activation of cells. When cells are suspended in high K containing buffer, nigericin mediates the antiport of H and K down their concentration gradients, thereby selectively dissipating DpH in an electroneutral manner. Furthermore, valinomycin mediates electrogenic uniport of K , allowing the electrophoretic uptake of K in cells with dissipation of the

Dc (ref. 39).

Preparation of inside-out membrane vesicles. Inside-out membrane vesicles were prepared from L. lactis NZ9000 DlmrA DlmrCD cells harbouring pNZ8048-based expression vectors using cell disruption equipment15. For this purpose, lactococcal cells were grown at 30 C to an OD660 of 0.60.8 and incubated for 1 h in the presence of nisin A to induce protein expression. Cells were then harvested by centrifugation at 13,000g, 12 min, 4 C and washed with ice-cold 100 mM KPi (pH 7.0) or 100 mM K-HEPES (pH 7.0) when the vesicles were prepared to measure ATPase activity. The cell pellet was resuspended in 20 mM KPi/K-HEPES containing Complete-Protease Inhibitor Cocktail (Roche) followed by the addition of 3 mg ml 1 lysozyme (from chicken egg white) and further incubation for 30 min at 30 C. Cell lysis was achieved by passage twice through a Basic Z 0.75 kW Benchtop Cell Disruptor (Constant Systems, Northlands, UK) at 20 kpsi. The suspension was supplemented with 10 mg ml 1 DNase and 10 mM MgSO4 andincubated for 30 min at 30 C to remove DNA. Subsequently, 15 mM K-EDTA (pH 7.0) was added to prevent the aggregation of membrane vesicles. A low spin at 13,000g for 40 min was performed to remove cell debris and whole cells. Membrane vesicles were harvested from the supernatant by ultra-centrifugation at 125,000g for 1 h at 4 C. The membrane vesicles were resuspended in 50 mM KPi/K-HEPES (pH 7.0) containing 10% glycerol and stored as 500 ml aliquots in liquid nitrogen. The expression of MsbA proteins in membrane vesicles was assessed on Coomassie-stained SDSPAGE, and immunoblots probed with primary mouse anti-polyhistidine tag antibody (Sigma-Aldrich, cat. no.: H1029) and secondary goat antimouse antibody (Sigma-Aldrich, cat. no.: A4416) were used at dilutions of 1:1,000 and 1:5,000, respectively (Supplementary Fig. 1).

Purication of His-tagged MsbA proteins. His-tagged MsbA proteins were puried from membrane vesicles by Ni2-nitrilotriacetic acid (NTA) afnity chromatography7,24,38. Membrane vesicles (diluted to 5 mg ml 1) were solubilized in buffer containing 50 mM KPi or K-HEPES (pH 8.0), 10% (v/v) glycerol, 0.1 M

NaCl and 1% (w/v) n-dodecyl-b-D-maltoside (DDM) (Melford Laboratories Ltd., UK) for 4 h by gently mixing on a rotating wheel at 4 C. Insoluble particles were removed by centrifuging the mixture at 125,000g, 4 C for 40 min. The solubilized protein was mixed with Ni2 -NTA resin at a ratio of 10 mg His-tagged protein per ml of resin. The resin was pre-equilibrated by washing thrice with ve resin volumes of Milli Q water and twice with ve resin volumes of wash Buffer A

(50 mM KPi or K-HEPES (pH 8.0), 0.1 M NaCl, 10% (v/v) glycerol, 0.05% (w/v) DDM and 20 mM imidazole). The suspension was left on a rotating wheel for overnight binding at 4 C, after which the resin was collected by centrifugation and transferred to a 2 ml volume Biospin disposable chromatography column (Bio-Rad). After subsequent washing with 20 volumes of wash Buffer A and 30 volumes of wash Buffer B (50 mM KPi or K-HEPES (pH 7.0), 0.1 M NaCl, 10% (v/v) glycerol, 0.05% (w/v) DDM and 20 mM imidazole added from 1 M imidazole stock (pH 8.0)), His-tagged protein was eluted with 34 volumes of Elution Buffer(50 mM KPi or K-HEPES (pH 7.0), 0.1 M NaCl, 5% (v/v) glycerol, 0.05% (w/v) DDM and 150 mM imidazole added from 1 M imidazole stock (pH 8.0)). The eluted puried protein was kept on ice and was immediately used for experiments. Purity of the protein was monitored on a 10% SDSPAGE with Coomassie Brilliant Blue staining.

LCMS/MS mass spectrometry analysis. Puried MsbA proteins were reduced (DTT) and alkylated (iodoacetamide) and subjected to enzymatic digestion with trypsin overnight at 37 C. Aliquots were then pipetted into a sample vial and loaded onto an autosampler for automated LCMS/MS analysis40. All LCMS/MS experiments were performed using a nanoAcquity UPLC (Waters Corp., Milford, MA) system and an LTQ Orbitrap Velos hybrid ion trap mass spectrometer (Thermo Scientic, Waltham, MA). Separation of peptides was performed by reverse-phase chromatography using a Waters reverse-phase nanocolumn (BEH C18, 75 mm inner diameter 250 m

M, 1.7 mm particle size) at ow rate of300 nl min 1. Peptides were initially loaded onto a pre-column (Waters UPLC

Trap Symmetry C18, 180 mm inner diameter 20 mm, 5 mm particle size) from the

nanoAcquity sample manager with 0.1% formic acid for 5 min at a ow rate of5 ml min 1. After this period, the column valve was switched to allow the elution of peptides from the pre-column onto the analytical column. Solvent A waswater 0.1% formic acid and solvent B was acetonitrile 0.1% formic acid. The

linear gradient employed was 540% B in 40 min (total LCMS/MS run time was 60 min). The LC eluant was sprayed into the mass spectrometer by means of a New Objective nanospray source. All m/z values of eluting ions were measured in the Orbitrap Velos mass analyser, set at a resolution of 30,000. Data dependent scans (Top 20) were employed to automatically isolate and generate fragment ions by collision-induced dissociation in the linear ion trap, resulting in the generation of MS/MS spectra. Ions with charge states of 2 and above were selected for

fragmentation. Post run, the data were processed using Protein Discoverer (version1.4., ThermoFisher). Briey, all MS/MS data were converted to mgf les and these les were then submitted to the Mascot search algorithm (Matrix Science, London, UK) and searched against the Uniprot L. lactis subsp. lactis strain IL1403 database (taxon identier 1360) using a xed modication of carbamidomethyl (C), variable modications of oxidation (M) and deamidation (NQ). The peptide mass tolerance was set to 25 ppm, the fragment ion mass tolerance to 0.8 Da and the maximum number of missed cleavages to 2.

Reconstitution of puried MsbA proteins. Puried protein (MsbA-WT, MsbA-DK382, MsbA-DED or MsbA-MD) was reconstituted in proteoliposomes prepared from acetoneether-washed E. coli phospholipids7,38,41 diluted to 4 mg ml 1 in chloroform, which were mixed in a ratio of 3:1 (w/w) with egg-yolk phosphatidylcholine (Avanti Polar Lipids Inc.). Solvent was evaporated using N2 gas after which the lipid mixture was rehydrated using Buffer 1 (10 mM K-HEPES (pH 6.8), 10 mM Tris-Cl, 100 mM K2SO4 and 100 mM NH4SCN) or Buffer 2 (10 mM

Tris-Cl (pH 8.0), 10 mM K-HEPES and 100 mM KSCN; see under Substrate transport in proteoliposomes), and 1 mg ml 1 of sonicated calf thymus DNA (Trevigen) for ethidium transport measurements. After resuspension, lipids were extruded 11 times through a 400-nm polycarbonate lter to form unilamellar liposomes of homogenous size and destabilized by the step-wise addition of Triton X-100 which was followed at OD540 (ref. 38). For reconstitution, puried protein was mixed with the detergent-destabilized liposomes in a 1/50 ratio (w/w) and incubated at room temperature (RT) for 30 min. Detergent was then removed using polystyrene bio-beads (Bio-Bead SM-2, Bio-Rad). For this purpose, Bio-Beads were pre-washed three times with methanol, once with ethanol and ve times with water before use. Successive extractions of detergent were achieved by incubating proteoliposomes, rst with 80 mg ml 1 Bio-Beads for 2 h at RT, then with 8 mg ml 1 Bio-Beads for 2 h at 4 C and nally with 8 mg ml 1 Bio-Beads for 18 h at 4 C. Proteoliposomes were harvested by centrifugation (130,000g for 30 min,4 C), resuspended in 3 ml Buffer 1 or 2, in which the liposomes were prepared, and incubated at 30 C for 20 min with 10 mM MgSO4 and 10 mg ml 1 DNase to remove any DNA contamination from the lipid bilayer. Finally, liposomes were harvested by centrifugation (130,000g for 30 min, 4 C), resuspended in 150200 ml

Buffer 1 or 2 that was used for their preparation and used immediately for transport studies. Samples were maintained on ice.

Substrate transport in proteoliposomes. Ethidium transport measurements with reconstituted proteoliposomes containing MsbA proteins were initiated by the 100-fold dilution of DNA-loaded proteoliposomes in 2 ml of external buffer in a 3-ml uorescence cuvette (to a nal concentration of 20 mg membrane protein per ml) to impose different electrochemical ion gradients. For this purpose, proteoliposomes in Buffer 1 (see under Reconstitution of puried MsbA proteins)

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were diluted 100-fold in Buffer i (10 mM K-HEPES (pH 8.0), 10 mM Tris-Cl and 100 mM K2SO4) to impose the Dp (interior positive and acidic), Buffer ii (10 mM

K-HEPES (pH 8.0), 10 mM Tris-Cl and 100 mM KSCN) to impose the DpH (interior acidic), or Buffer iii (10 mM K-HEPES (pH 6.8), 10 mM Tris-Cl, 50 mM (NH4)2SO4 and 100 mM K2SO4) to impose the Dc (interior positive). In experiments with the DcREV, proteoliposomes in Buffer 2 (see under Reconstitution of puried MsbA proteins) were diluted 100-fold into Buffer iv (10 mM NMG-HEPES (pH 6.8),10 mM Tris-Cl and 50 mM (NH4)2SO4) in the presence of 10 nmol per mg protein of valinomycin to impose the DcREV (interior negative), Buffer v (10 mM K-HEPES (pH 8.0), 10 mM Tris-Cl and 50 mM K2SO4) to impose the DpH (interior acidic), or Buffer vi (10 mM NMG-HEPES (pH 8.0) and 10 mM Tris-Cl) in the presence 10 nmol per mg protein valinomycin to impose the DpDcREV (interior negative and acidic). After 30 s of recording, ethidium bromide (2 mM) was added and uorescence was measured as a function of time in an LS 55B luminescence spectrometer (Perkin-Elmer Life Sciences) with excitation and emission wavelengths of 500 and 580 nm with slit widths of 10 and 5 nm, respectively.

In control experiments, proteoliposomes were diluted 100-fold in the buffer in which they were prepared (pHin 6.8/pHout 6.8 and pHin 8.0/pHout 8.0) to measure ethidium transport in the absence of ion gradients. In addition, empty liposomes were prepared with nickel NTA elution buffer instead of puried protein, and these were diluted in the same buffers as the proteoliposomes.

For measurements of DpH (interior acidic)-dependent chloramphenicol transport, proteoliposomes were generated as described for ethidium transport, but without DNA in the internal lumen, and diluted 100-fold (to 30 mg phospholipid per ml) in 500 ml dilution buffer in glass tubes containing 2 mM [3H]-chloramphenicol (3.33 TBq mol 1) (Sigma). At given time intervals, samples were withdrawn, diluted with 2 ml of ice-cold 0.1 M lithium chloride, ltered immediately through cellulose nitrate lters (0.45 mm pore size) and washed once with 2 ml of the lithium chloride solution. Radioactivity retained on the lters was measured by liquid scintillation counting. Transport data were corrected for binding of chloramphenicol to the nitrocellulose lters. To provide evidence for proton-coupled chloramphenicol transport by MsbA-WT, (proteo)liposomes were prepared in Buffer 1 (interior acidic; pH 6.8) containing 100 mM of the pH indicator BCECF (Molecular Probes). These (proteo)liposomes were diluted 100-fold in Buffer ii (pH 8.0) to impose a H gradient, or Buffer 1 for control measurements in the absence of an ion gradient. BCECF uorescence was measured with wavelengths for excitation at 502 nm and emission at 525 nm, and with slit widths of 10 and 15 nm, respectively. Experiments were performed in triplicate using independent batches of proteoliposomes.

ATPase activity in proteoliposomes. The ATPase activity of MsbA was monitored in reconstituted proteoliposomes in the absence or presence of the

DpH, using the Malachite Green assay to measure the liberation of Pi over time37,42. Proteoliposomes prepared in Buffer 1 were diluted 20-fold in Buffer ii as described under Substrate transport in proteoliposomes (Fig. 6b). To dissipate the DpH, 1 mM nigericin was added immediately after dilution of proteoliposomes, and the mixture was kept on ice for 5 min before the measurements of ATPase activity. The ATPase reaction was started by the addition of 2.5 mM Mg-ATP (high grade ATP from Sigma), after which Pi release was measured at 1 and 2 min. Following incubation at 30 C, the reactions were stopped by mixing 30-ml aliquots with activated malachite green-ammonium molybdate for 5 min in a 96-well plate. Samples were subsequently incubated for 25 min with 34% citric acid after which the OD600 was determined. Pi release between t 1 min and t 2 min was

calculated. To conrm that nigericin was able to dissipate the DpH, 100 mM BCECF was added to the preparation Buffer 1 to include the probe in the lumen of the proteoliposomes (Fig. 6c). BCECF uorescence emission was measured in a LS 55B luminescence spectrometer with excitation and emission wavelengths of 535 and 590 nm with slit widths of 10 and 5 nm, respectively. For the experiments in Fig. 6d, proteoliposomes prepared in buffer (pH 6.8 or 8.0) containing 10 mM Tris-Cl and 10 mM K-HEPES were diluted 20-fold in buffer (pH 8.0) containing 10 mM Tris-Cl and 10 mM K-HEPES.

Orientation of MsbA in the membrane. Right-side-out membrane vesicles were prepared by osmotic lysis of cells43. MsbA-WT expressing lactococcal cells from 1 l culture were collected by centrifugation at 13,000g for 15 min at 4 C. The pellet was washed once in 100 mM KPi (pH 7.0). Cells were resuspended in 5 ml of the same buffer containing half a tablet of complete protease inhibitor cocktail (Roche Applied Science), 10 mM MgSO4, 40 mg ml 1 lysozyme, and were incubated for 30 min at 30 C under mild shaking. The protoplast suspension was mixed with4.8 ml of a 0.75 M K2SO4, 10mg ml 1 DNase and RNase while stirring, and incubated for 2 min at 30 C. The homogenized, concentrated protoplast suspension was poured directly into 36 ml 100 mM KPi (pH 7.0). The lysate was incubated for 20 min at 30 C with vigorous swirling. K-EDTA, pH 7.0, was then added to 20 mM nal concentration, and the incubation was continued for 10 min at 30 C. Shortly after the addition of EDTA, the turbidity of the suspension decreased and the viscosity increased. Finally, MgSO4 was added to a nal concentration of 15 mM and the incubation was continued for another 15 min at 30 C; during this period the viscosity decreased. The lysates were centrifuged at 48,200g for 30 min at 4 C. The pellet was resuspended in 48 ml 50 mM KPi buffer, pH 7.0, containing 10 mM MgSO4. The sample was centrifuged at 750g for 60 min

at 4 C and the yellowish, milky, supernatant uid was carefully decanted and centrifuged at 48,200g for 30 min at 4 C. The high speed pellet obtained as described above was resuspended by homogenization in 1 ml 50 mM KPi buffer (pH 7.0) containing 10% glycerol and frozen in small aliquots of 100 ml and stored in liquid nitrogen.

The orientation of MsbA proteins in right-side-out membrane vesicles, inside-out membrane vesicles or proteoliposomes was assessed by determining the accessibility of the N-terminal His-tag to digestion by protease K in the external buffer41. Membrane proteins were diluted in 50 mM K-HEPES (pH 7.0) supplemented with 1 mM CaCl2. The digestion was initiated by addition of proteinase K at an enzyme-membrane protein ratio of 1:25 (w/w). The samples were subsequently incubated at 0 C for 10 min. The reaction was terminated by the addition of 10 mM phenylmethanesulphonyl uoride (from stock in ethanol), after which 3 SDSPAGE sample-loading buffer and 1 m

M DTT were added.

The samples were incubated at RT for 10 min and analysed on immunoblot as described under Preparation of inside-out membrane vesicles.

Cytotoxicity assays. L. lactis expressing MsbA-WT, MsbA-MD or MsbA-DK382, and non-expressing control cells were grown as described under Growth conditions and protein expression at 30 C in 96-well plates in the presence of a range of erythromycin concentrations. Nisin A was added at a concentration of 5 pg ml 1 to induce protein expression, and growth was monitored by measuring

OD660 in a Versamax plate reader (Molecular Devices Wokingham, UK) at 30 C. The maximum specic growth rate (mm) was determined from the change in OD660 over time, by tting the data to Nt N0 em t in which Nt and N0 are the cell

densities at times t and 0 h, respectively. The mm of the cells grown in the absence of drug was set at 100% to calculate relative growth rates (Fig. 6g).

Statistical analyses. Signicance of data obtained with whole cells and proteoliposomes was tested by one-way analysis of variance. Differences in proteinase-K and ATPase results were assessed using the unpaired student-t test. Asterisks directly above bars in the histograms refer to comparisons with control; asterisks above lines refer to specic comparisons: *Po0.05; **Po0.01;

***Po0.001; ****Po0.0001.

Data availability. Data that support the ndings of this study have been deposited in the University of Cambridge data repository with the accession code 1810/255838 (https://www.repository.cam.ac.uk/handle/1810/255838) or available from the corresponding author upon reasonable request.

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Acknowledgements

Himansha Singh is supported by the Cambridge Commonwealth, European and International Trust. Saroj Velamakanni was a recipient of a Cambridge Nehru Scholarship. Shen L. Wei was funded by the Cambridge Overseas Trust. This research in the Van Veen group was supported by Biotechnology and Biological Sciences Research Council (BBSRC) grant BB/I002383/1 and BB/C004663/1, Medical Research Council (MRC) grant G0401165 and by further support from the Human Frontier Science Program (HFSP) and the British Society for Antimicrobial Chemotherapy (BSAC).

Author contributions

H.S., S.V., M.J.D., J.H. and S.L.W. designed experiments, and generated and analysed data. H.S., S.V. and S.L.W. conducted reconstitution and transport experiments. M.J.D. and J.H. performed LCMS/MS. H.W.v.V. conceptualized, guided and planned the project, experiments and analyses. H.W.v.V., H.S. and M.J.D. designed gures and wrote the paper with input from S.V. and S.L.W. All authors approved the nal version of the manuscript.

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How to cite this article: Singh, H. et al. ATP-dependent substrate transport by the ABC transporter MsbA is proton-coupled. Nat. Commun. 7:12387 doi: 10.1038/ncomms12387 (2016).

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