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The ABC exporter MsbA probed by solid state NMR - Challenges and opportunities

De Gruyter
Biological Chemistry
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ABC transporters form a superfamily of integral membrane proteins involved in translocation of substrates across the membrane driven by ATP hydrolysis. Despite available crystal structures and extensive biochemical data, many open questions regarding their transport mechanisms remain. Therefore, there is a need to explore spectroscopic techniques such as solid state NMR in order to bridge the gap between structural and mechanistic data. In this study, we investigate the feasibility of using E. coli MsbA as a model ABC transporter for solid state NMR studies. We show that optimised solubilisation and reconstitution procedures enable preparing stable and homogenous protein samples. Depending on the solubilisation times, MsbA can be obtained in either an apo- or in a native lipid-A bound form. Building onto these optimizations, the first promising MAS-NMR spectra with narrow lines have been recorded. However, further sensitivity improvements are required so that complex NMR experiments can be recorded within a reasonable amount of time. We therefore demonstrate the usability of paramagnetic doping for rapid data acquisition and explore dynamic nuclear polarisation as a method for general signal enhancement. Our results demonstrate that solid state NMR provides an opportunity to address important biological questions related to complex mechanisms of ABC transporters.
Reconstitution of MsbA. (a) Optimised DMPC/DMPA (9:1) liposome destabilisation for homogenous MsbA proteoliposome preparation. Destabilisation was followed by changes in optical density at 540 nm (black squares). Liposomes are fully saturated at R SAT and fully solubilised at R SOL. The ATPase activity determined from proteoliposomes after detergent removal (bars) shows a maximum at R OPT. Since the amount of MsbA within the proteoliposomes is the same for all destabilisation conditions starting from R OPT , ATPase activity reports on NBD accessibility / homogeneity of MsbA orientation. ATPase activities were determined at an ATP concentration of 6mM. (b) Effect of extrusion of lipids through membranes of different pore size used to prepare unilamellar vesicles (MsbA in DMPC/DMPA (9:1), LPR=50 mol/mol) on sample homogeneity as seen by sucrose density gradients (10-70% w/v). (c) Characterisation of basal ATPase activity using the colorimetric molybdate blue assay for MsbA in 0.015% DDM (black), reconstituted in destabilised DMPC/DMPA (9:1) (red), reconstituted in E. coli polar lipids (blue), reconstituted in DMPC/DMPA (9:1) (magenta). A LPR of 75 mol/mol was used in all cases. (d) Determination of the 15 N transversal relaxation time T 2 ' of [U-15 N]-MsbA reconstituted into different lipid mixtures. The largest value is obtained for DMPC/DMPA (9:1) with a LPR of 50 mol/mol, which corresponds to the smallest homogeneous 15 N linewidth (27 Hz) indicating good spectral resolution.
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Biological Chemistry ’Just Accepted’ paper / ISSN (online) 1437-4315 / DOI: 10.1515/hsz-2015-0119
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Highlight Issue CRC 807 “Transport and Communication across Membranes”
The ABC Exporter MsbA probed by Solid state NMR – Challenges and Opportunities
Hundeep Kaur1, Andrea Lakatos1, Roberta Spadaccini1,2,
Ramona Vogel1, Christian Hoffmann1, Johanna Becker-Baldus1,
Olivier Ouari3, Paul Tordo3, Hassane Mchaourab4 and Clemens Glaubitz1*
(1) Institute for Biophysical Chemistry & Centre for Biomolecular Magnetic Resonance,
Goethe-University Frankfurt, Germany, Max-von-Laue-Str. 9, 60438 Frankfurt am
Main
(2) Department of Sciences and Technologies, Universita' del Sannio, Benevento, Via
Port'Arsa, 11, 82100 Benevento Italia
(3) Aix-Marseille Université, CNRS, ICR UMR 7273, 13013 Marseille, France
(4) Department of Molecular Physiology & Biophysics, Vanderbilt University, 2215
Garland Avenue, TN 37232 Nashville, USA
(*) Corresponding author
Email: glaubitz@em.uni-frankfurt.de
Tel/Fax: +49-69-798-29927/29
Short Title: MAS-NMR on ABC Transporters
Biological Chemistry ’Just Accepted’ paper
ISSN (online) 1437-4315
DOI: 10.1515/hsz-2015-0119
Biological Chemistry ’Just Accepted’ paper / ISSN (online) 1437-4315 / DOI: 10.1515/hsz-2015-0119
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Abstract
ABC transporters form a superfamily of integral membrane proteins involved in translocation
of substrates across the membrane driven by ATP hydrolysis. Despite available crystal
structures and extensive biochemical data, many open questions regarding their transport
mechanisms remain. Therefore, there is a need to explore spectroscopic techniques such as
solid state NMR in order to bridge the gap between structural and mechanistic data. In this
study, we investigate the feasibility of using E. coli MsbA as a model ABC transporter for
solid state NMR studies. We show that optimised solubilisation and reconstitution procedures
enable preparing stable and homogenous protein samples. Depending on the duration of
solubilisation, MsbA can be obtained in either an apo- or in a native lipid-A bound form.
Building onto these optimizations, the first promising MAS-NMR spectra with narrow lines
have been recorded. However, further sensitivity improvements are required so that complex
NMR experiments can be recorded within a reasonable amount of time. We therefore
demonstrate the usability of paramagnetic doping for rapid data acquisition and explore
dynamic nuclear polarisation as a method for general signal enhancement. Our results
demonstrate that solid state NMR provides an opportunity to address important biological
questions related to complex mechanisms of ABC transporters.
Keywords
ABC transporter; DNP; Lipid A; MAS-NMR; MsbA; PRE
Biological Chemistry ’Just Accepted’ paper / ISSN (online) 1437-4315 / DOI: 10.1515/hsz-2015-0119
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Introduction
ABC (ATP Binding Cassette) transporters are a superfamily of membrane proteins that use
ATP as a source of energy to translocate a variety of substrates across the cell membrane.
Mammalian transporters such as P-glycoprotein are of great physiological importance and
belong generally to the exporters subclass (George & Jones, 2012; Higgins & Linton, 2004).
In prokaryotes, ABC transporters act as nutrient importers, -drug exporters and lipid flippases.
All ABC transporters show a similar modular topology with two highly conserved nucleotide
binding domains (NBDs) for ATP hydrolysis and two transmembrane domains (TMDs),
which are specialised towards binding and translocating a range of substrates. The nucleotide
binding domain consists of the canonical signature motif LSGGQ, also known as the C-loop,
and the conserved Walker A and B domains along with the D-, Q- and H- loops (Jones &
George, 2013). These modules are either fused into one single polypeptide chain or assemble
separately into homo- or heterodimers (Higgins & Linton, 2004).
The apparently similar architecture of ABC transporters implies a unified molecular transport
mechanism. There are however contradicting data questioning this assumption at least for
exporters. Nucleotide-bound outward facing structures have both NBDs in close contact as
found for MsbA and Sav1866 (Dawson & Locher, 2006; Ward et al, 2007), which is in
contrast to the apo-state structures of MsbA and PgP (Aller et al, 2009; Ward et al, 2007) in
which a V-shape with well separated NBDs is observed. The latter contradicts biochemical
studies from which models were derived in which the NBDs are permanently in contact with
each other (George & Jones, 2012). Interestingly, a recent pulsed EPR study on LmrA, a
homologue to MsbA from L. lactis, revealed that the apo state covers a large conformational
space, which is restricted upon nucleotide binding (Hellmich et al, 2012b). Such an apo state
is not likely to be populated in the cell as the ATP concentration is significantly higher than
the Km of ATP hydrolysis, but particular sample preparation or crystallisation conditions
might favour certain apo state subpopulations.
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So far, progress in ABC transporter research has relied on X-ray crystallography combined
with biochemical approaches. Furthermore, pulsed EPR spectroscopy, which provides
distance measurements via electron dipole-dipole couplings, has become very important for
identifying domain movements during the catalytic and transport cycles (Buchaklian & Klug,
2005; Dong et al, 2005; Mishra et al, 2014). In addition, first applications of single molecule
methods for imaging as well as for spectroscopy have been reported (Cooper & Altenberg,
2013; Kim et al, 2015). However, compared to other families of membrane proteins, many
spectroscopic techniques remain underrepresented although unique mechanistic data could be
obtained to complement crystallographic approaches. Especially NMR spectroscopy could
provide site-resolved data at atomic resolution, which would be helpful in understanding
details of ATP hydrolysis, substrate binding and release mechanism, NBD-TMD cross talk
and general structural dynamics.
In general, NMR spectroscopy on membrane proteins is challenging. Membrane-mimicking
environments suitable for different NMR approaches are illustrated in Figure 1. For liquid-
state NMR, the chosen protein/detergent complex has to be small enough to ensure fast
isotropic tumbling while preserving at the same time functional integrity. One possible
disadvantage is the high curvature of detergent micelles creating an unnatural environment for
membrane proteins. A potential solution is offered by the use of isotropic bicelles or
nanodiscs, which are larger than micelles, but still soluble. All of these three systems have
been used successfully for liquid-state NMR (Raschle et al, 2010), but proteins of the size of
full length ABC transporters pose a general problem due to their molecular weight.
Solid state NMR does not suffer from line broadening due to increased molecular weight and
allows working under even more native-like conditions using lipid bilayers. Oriented solid
state NMR (O-SSNMR) relies on macroscopically ordered samples, which are either prepared
on glass plates as solid support or more elegantly by utilising the spontaneous alignment of
anisotropic bicelles within the magnetic field, which can be controlled by the addition of
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lanthanides (De Angelis & Opella, 2007; Prosser et al, 1996) (Figure 1). However, most
applications rely on magic angle sample spinning for which proteoliposomes can be used
directly. Fast sample rotation about an axis inclined to the magnetic field at 54.7° (the “magic
angle”), averages all anisotropic interactions leading to well-resolved spectra (Figure 1). This
approach has been extensively used for hypothesis-driven studies or for obtaining 3D
structure models of membrane embedded proteins (Ader et al, 2009; Mao et al, 2014; Park et
al, 2012; Wang et al, 2013).
Due to their size and often challenging biochemical properties, ABC transporters are
especially difficult targets for NMR spectroscopy. Only a few initial studies on full
transporters, all of them based on solid state NMR, have been published so far. For L. lactis
LmrA, reconstitution conditions, time-resolved 31P - magic angle sample spinning (MAS)
NMR (Hellmich et al, 2008) and wideline 2H-solid state NMR (Siarheyeva et al, 2007) have
been reported. The studies were later complemented by EPR spectroscopy (Hellmich et al,
2012b) and by solution state NMR on the isolated NBDs (Hellmich et al, 2012a). Optimized
reconstitution conditions and first MAS-NMR spectra were also reported for BmrA from B.
subtilis (Kunert et al, 2014). The first solid state NMR experiments on an ABC importer were
described for ArtMP in 2D-crystals (Akbey et al, 2014; Lange et al, 2010).
Here, we explore MsbA as a potential target for further solid state NMR studies. As
mentioned above, MsbA has been in the focus of a number of studies, but additional
spectroscopic data can be especially useful towards completing the mechanistic picture.
MsbA is a 584 amino acid E. coli ABC exporter, functional as a homodimer of 130 kDa.
Absence of MsbA in E. coli leads to cell death, which can partly be attributed to the toxic
nature of lipid A accumulating inside the cell, and partly because of reduced integrity of the
outer E. coli membrane, which consist of lipopolysaccharide (LPS) with lipid A as the core
moiety (Zhou et al, 1998).
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An up to 4 fold in-vitro stimulation of ATPase activity of MsbA in the presence of 3-deoxy-
D-manno-2-octulosonic-lipid A has been shown (Doerrler & Raetz, 2002). In addition,
transport or stimulated ATPase activity has been demonstrated for many other substrates such
as Hoechst 33342, daunomycin, daunorubicin, erythromycin, vinblastine and ethidium
(Eckford & Sharom, 2008c; Eckford & Sharom, 2010; Siarheyeva & Sharom, 2009).
The Xray crystallographic data of MsbA from E. coli (pdb id: 3B5W; 5.3Å), S. typhimurium
(pdb id: 3B5X; 5.5Å) and V. cholerae (pdb id: 3B5Y, 3B6O; 3.7Å) have shown an inward
facing V-shaped structure with separated NBDs in the apo-state and an outward facing
conformation upon nucleotide binding (Ward et al, 2007). It has also been observed by Cryo
EM studies that MsbA in complex with different nucleotides (AMP.PNP, ADP-Vi, ADP-
AlFx) forms a unique lattice under same crystallization conditions (Ward et al, 2009). Hints
towards association and dissociation of NBDs by ATP have also been provided by cross
linking studies (Doshi et al, 2010) and an intermediate closed state was suggested (Doshi et al,
2013). MsbA was also subject to rather extensive and detailed cw- and pulsed EPR studies,
which has not only provided evidence for conformational changes but has also given a first
impression of the extent of conformational dynamics within defined catalytic states of MsbA.
Large amplitude domain movements between an open apo into the closed nucleotide-bound
state have been reported in both micelles and proteoliposomes. It was demonstrated that lipid
A binds at the surface of helix 6 and global conformational changes were observed for
adenosine-5-(β,γ-imido)triphosphate (AMP.PNP) binding and for the ADP.Vi bound high
energy state (Borbat et al, 2007; Mishra et al, 2014; Smriti et al, 2009).
Further in this paper, we present first solid state NMR data on MsbA, which could be
obtained through optimisation of key steps during sample preparation. Special emphasis has
been given to the reconstitution step, which is crucial for obtaining a homogenous stable
preparation and for keeping the membrane proteins stable in vitro (Geertsma et al, 2008;
Rigaud et al, 1995; Rigaud & Levy, 2003; Sanders & Landis, 1995). The small sample
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volume used for MAS NMR (10 - 40 µL) presents an additional constraint, which requires a
small lipid to protein ratio. We also evaluate concepts to improve sensitivity based on Gd3+-
doping with rapid data acquisition as well as dynamic nuclear polarisation. Finally, first data
of lipid A in complex with MsbA will be presented and discussed.
Results and Discussion
(a) Preparing MsbA for solid state NMR
In order to prepare isotope-labelled samples, MsbA was overexpressed in M9 minimal
medium resulting in a reproducible yield of approximately 10 mg per litre of culture. The
yield even increased to up to 35 mg when amino acids were added to the medium for reverse
labelling. It was found that MsbA in complex with lipid A could be purified from E. coli
membranes solubilised with 1.25% n-Dodecyl β-D-Maltopyranoside (DDM) for 1 h, while a
duration of 12 h resulted in apo-state MsbA (see below). Sample homogeneity and stability
were verified by size exclusion chromatography (0.015% DDM) directly after purification
and after storage at room temperature for 24 h (Figure 2a). Purity of the preparation was
determined by SDS-PAGE (Figure 2b) and confirmed by Matrix Assisted Laser Desorption
Ionisation Mass Spectrometry (MALDI-MS) (Figure 2e). The MALDI spectrum clearly
shows single, double and triple charged peaks of the MsbA monomer corresponding to its
molecular weight including the His-tag with its peptide linker. A western blot of the
preparation using Anti-His AP-conjugate was run for confirmation of sample purity (Figure
2d). Long-term stability was further checked by SDS PAGE on MsbA reconstituted in 1,2-
dimyristoyl-sn-glycero-3-phosphocholine (DMPC) / 1,2-dimyristoyl-sn-glycero-3-phosphate
(DMPA) (9:1) (see below for choice of lipid mixture) stored at room temperature. No
degradation was observed for up to 30 days (Figure 2c).
The reconstitution of MsbA into liposomes has been tested for different lipids and for
different reconstitution conditions. Unilamellar vesicles were prepared by extrusion followed
by detergent destabilisation to aid homogeneous insertion of MsbA. As detergent is added,
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liposomes start swelling resulting in a change of turbidity of the liposomal solution, which
can be followed by monitoring the optical density at 540 nm as shown in Figure 3a for
DMPC/DMPA (9:1). The liposomes are fully saturated at the detergent concentration RSAT
but dissolve completely at RSOL resulting in a clear solution. It has been described that
homogeneity and reconstitution efficiency of membrane proteins at RSAT is low but improves
at a slightly higher concentration further referred to as ROPT (Geertsma et al, 2008; Rigaud &
Levy, 2003). In order to find ROPT, we have reconstituted MsbA into DMPC/DMPA
liposomes destabilised by increasing DDM concentrations in the range between RSAT and
RSOL. Detergent was completely removed by Bio-Beads SM-2 and the resulting
proteoliposomes were analysed with respect to the amount of incorporated MsbA and with
respect to ATPase activity dependent on homogeneity of incorporation. The degree of MsbA
insertion, as determined using a Lowry assay after re-solubilising the proteoliposomes, was
found to be almost complete and independent of the level of liposome destabilisation. In
contrast, the ATPase activity of MsbA proteoliposomes showed a strong dependence on the
DDM concentration, which means that the homogeneity of MsbA orientation, or in other
words the NBD accessibility, varies. The highest activity implies most uniform orientation
and is observed for ROPT = 3 mM (Figure 3a). This reconstitution procedure allowed preparing
samples with a molar lipid-to-protein ratio (LPR) of approx. 50. Furthermore, a clear effect on
sample homogeneity due to the size of the unilamellar vesicles, which depends on the pore
diameter of the extrusion membranes, was seen (Figure 3b). The most homogeneous samples
were obtained for vesicles with an average diameter of 0.1 µm.
The ATPase activity in different proteoliposomes is compared to detergent solubilised MsbA
in Figure 3c. Very similar values were observed. The slightly higher activity in DDM could
be caused by some inaccessible NBDs in proteoliposomes. The activity in E. coli polar lipids
and in DMPC/DMPA is almost identical and their values are consistent with previously
reported data (Zou & McHaourab, 2009).
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Our data show that active and homogeneous MsbA proteoliposomes with a lipid to protein
ratio (LPR) compatible with the requirements of MAS-NMR can be prepared. One of the
most important criteria for NMR spectroscopy is spectral resolution. Therefore, [U-15N]-
MsbA has been reconstituted into proteoliposomes containing different lipid compositions
(see Figure 3d). We have carried out 15N spin-echo experiments to determine the 15N
transverse relaxation time T2(De Paepe et al, 2003). Spin echo decays are shown in Figure
3d. Their values clearly depend on LPR and/or on the lipid composition and are found
between 7.2 ms and 11.4 ms corresponding to homogeneous linewidths of 45 and 27 Hz.
MsbA in DMPC/DMPA (9.1) at an LPR of 50 in mol/mol has been used for all further
experiments as it shows the longest T2’ and also the same activity as in E. coli polar lipids.
(b) 2D-MAS NMR spectra on MsbA containing proteoliposomes
Based on these optimised conditions, uniform- and extensive selective labelled samples were
prepared. Temperature dependent 13C - cross polarisation (CP) - MAS NMR spectra were
recorded to probe the effect of the lipid and water phase on resolution and signal intensity
(Figure 4a). The overall signal intensity is almost the same in frozen samples (255 K)
compared to the lipid gel phase (273 K), but resolution improves in the non-frozen case. In
the liquid-crystalline phase at 313 K, CP signal intensities decreased compared to 273 K due
to increased mobility on the intermediate timescale (µs) interfering with cross polarisation and
proton decoupling. On the other hand, the directly measured averaged C-H dipole couplings
in MsbA are close to the rigid limit of 21.5 kHz (order parameter SCH=0.9) and are not
significantly reduced when comparing all three cases (Figure 4c). This means that fast and
large amplitude motions do not play a major role, at least not for the residues, which can be
cross-polarised. The temperature dependence of all resonances as seen by direct polarisation
is shown in Figure 4b. In principle, the same trend as for cross polarisation is observed.
Usually, highly mobile region undergoing fast, large-amplitude fluctuations will be
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suppressed in CP experiments, but become visible under direct polarisation. As this is not a
dominating phenomenon here, MsbA must be relatively rigid and well structured.
Two-dimensional 13C-13C Proton Driven Spin Diffusion (PDSD) spectra were recorded to
assess spectral resolution (Figure 5a). In order to avoid spectral overcrowding in this initial
analysis due to the large size of the MsbA dimer, we have used extensive reverse labelling in
order to simplify our spectra. In the resulting protein, only eight types of amino acids (D, E,
Q, G, H, K, T, S) are 13C- and 15N labelled corresponding to 35% of all residues. In order to
minimize isotope scrambling, the amino acids used for reverse labelling were carefully
chosen. This choice was based on the work of Bellstedt and co-workers who performed
individual amino acid-selective unlabeling experiments in E. coli BL21(DE3) (Bellstedt et al,
2013). Their data indicate residual carbon scrambling for Ala but not for Arg, Cys, Ile, Leu,
Met, Phe, Pro, Tyr and Val. Indeed, unwanted signals in the Ala Cα-Cβ region of our PDSD
spectrum are observed (Figure 5a). Overall, good spectral dispersion is obtained and
resolution and sensitivity is good enough to identify individual cross peaks with linewidth
between 0.5 and 0.7 ppm (Figs. 5b and c). These values are slightly larger than the
homogenous linewidth (Figure 5b), which is due to 13C-13C and 13C-15N J-couplings as well as
due to remaining sample heterogeneities. The resolution of individual cross-peaks is further
illustrated for an MsbA sample in which only lysines are 15N and 13C labelled. Based on the
secondary structure dependent chemical shift index (Wang & Jardetzky, 2002), the NCA
spectrum of [13C-15N-K]-MsbA can be divided into regions originating from α-helices, β-
sheets and random coils (Figure 5c). MsbA contains 22 lysines (plus one in the linker between
His-tag and protein). Based on the crystal structure, 15 lysines are located in the N-terminal
TMDs (9 x α-helix, 6 x turns/loops/end-residues of helices) and 7 are found in the C-terminal
NBDs (4x α-helix, 1x β-sheet, 2 x turns/loops/end-residues of helices) including K382 in the
Walker A motif. Therefore, the β-sheet resonances in Figure 5c can be mainly assigned to the
β-sheet regions found in the NBDs around residue K365.
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(c) Options to improve NMR sensitivity
Although the spectra described above demonstrate that site-resolved data can be successfully
obtained from MsbA, further improvements in detection sensitivity would be helpful in order
to carry out a resonance assignment and/or to obtain site-resolved structural details. Here, two
different approaches have been evaluated with respect to their compatibility with this ABC
exporter. In the following part, improving the signal-to-noise ratio (SNR) per unit time by
rapid data acquisition based on paramagnetic doping is described. This is followed by a
comparison with the signal enhancements achieved by dynamic nuclear polarisation.
Generally, an experiment requires long recycle delays (seconds) between successive scans for
the recovery of spin polarization, which depends on the size of the spin lattice relaxation time
T1. For quantitative spectra, a recycle delay time of 5 x T1 is required, while the optimum
between magnetisation recovery and data acquisition per unit time results in 1.3 x T1. One
possibility to improve the SNR per unit time is therefore given by reducing T1 through the
addition of suitable paramagnetic relaxation agents to the protein sample so that more spectra
can be accumulated within the same period of time. It has been successfully demonstrated that
1H-T1, which determines the recycle delay time in cross polarisation experiments, is
significantly reduced in a homogeneous manner in microcrystalline samples by doping with
Cu2+-EDTA. In combination with very fast MAS rates, low power decoupling schemes,
perdeuterated samples and short recycle delays (0.2 - 0.3 s), a significant improvement in
SNR per unit time has been achieved (Linser et al, 2007; Wickramasinghe et al, 2009). We
could show for green proteorhodopsin (GPR) that doping with Gd3+-DOTA results in
dramatically reduced 1H-T1 at much lower dopant concentrations compared to Cu2+-EDTA
(Ullrich et al, 2014). Rapid data acquisition at moderate MAS rates (10 kHz) was achieved by
utilising MAS probes with a reduced electric field component of the applied RF during
decoupling, which reduces sample heating.
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Due to its very high relaxivity and its successful demonstration on GPR we have applied
Gd3+-DOTA doping to [U-15N]-MsbA containing proteoliposomes in order to improve SNR
per unit time. In Figure 6a, the averaged amide proton spin lattice relaxation time (1H-T1) of
MsbA as a function of dopant concentration is shown. It changes from 650 ms for the
diamagnetic sample to 80 ms in presence of 1mM Gd3+-DOTA, which is a reduction by
almost 90%. By reducing the recycle delay accordingly, the theoretical gain in SNR per unit
time compared to the non-doped sample could be 3-fold as shown before for GPR. However,
such an improvement is hardly possible considering the limited duty cycle of conventional
MAS probes, but even with longer recycle delays of 1 s, a 20% better SNR is achieved upon
doping (Figure 6a).
The effect of paramagnetic doping on multidimensional spectra of MsbA was then examined
in order to test whether the relaxation enhancement spreads homogeneously through the
sample and whether additional line broadening occurs. In Figure 6b 13C-13C PDSD spectra of
[U-13C,15N]-MsbA with and without doping are compared. Recycle delays of 3 s and 1 s,
respectively, were chosen to obtain quantitative spectra. Under these conditions the spectrum
of the doped sample was recorded three times faster compared to the non-doped sample.
Neither significant peak shifts nor line broadening were observed and, as already observed for
GPR (Ullrich et al, 2014), the paramagnetic relaxation enhancement occurs within the whole
protein. These results confirm the great advantage of using Gd3+-DOTA as paramagnetic
doping to enhance sensitivity through a better SNR per time unit in solid state NMR
spectroscopy of membrane proteins.
A more general approach is given by dynamic nuclear polarisation (DNP), which allows
transfer of the large electron polarization to nuclei (γe/γn ~ 660) (review see e.g. (Maly et al,
2008)). The most commonly used mechanism for DNP enhanced solid state NMR relies on
the cross effect using allowed transitions in a three spin system consisting of two dipolar
coupled electron spins and a nearby proton from which magnetization spreads throughout the
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sample. The polarization transfer from electrons to the nuclear spins is most efficient when
using bi-radicals with strongly dipolar coupled paramagnetic centres such as in AMUPol
(Sauvee et al, 2013) (Figure 6c). The basic experimental scheme is illustrated in Figure 6c: A
high power microwave source (gyrotron) is coupled to a NMR spectrometer. The microwaves
are directed directly at the rotating sample through a waveguide. The microwave frequency
has to match the electron Larmor frequency in the NMR magnet (e.g. 263 GHz vs. 400 MHz
at 9.4 T). Using this setup, NMR experiments are conducted as usual but under continuous
microwave irradiation using an additional channel (Figure 6d). For these experiments, low
temperatures are needed (~100 K) to reach sufficiently long electron relaxation times of the
polarizing agents added to the sample. In addition, it is also required to immerse water-
containing samples in a glass-forming matrix acting as cryo-protectant and at the same time
preventing radical aggregation (Zagdoun et al, 2013). Here, MsbA containing
proteoliposomes prepared as described above were incubated with D8-glycerol/H2O/D2O
mixture containing the radical AMUPol (20 mM). Performing DNP experiments at 263
GHz/400 MHz at 100 K on these samples resulted in 20-fold signal enhancement (Figure 6d),
which enables a 400-times faster data acquisition. Comparable enhancements on other
membrane proteins using the same experimental setup but different polarizing agents have
been reported from our group (Mao et al, 2013; Mao et al, 2014; Ong et al, 2013).!
Upon comparing both approaches, it seems obvious that Dynamic Nuclear Polarization (DNP)
clearly outperforms PRE in terms of sensitivity. However, the best choice of methods depends
on a number of boundary conditions, which need to be considered. Paramagnetic Relaxation
Enhancement (PRE) experiments can be performed at high fields and non-frozen samples
ensuring best spectral resolution especially in case of extensively labelled samples. Fast data
acquisition bears the risk of sample heating due to high power proton decoupling. However,
this approach will become fully accessible once MAS probes with reduced electric fields and
higher duty cycles become available, which are currently being developed. In contrast, DNP
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works best at lower fields and especially requires performing such experiments under
cryogenic conditions. This requirement is often associated with freezing-induced
heterogeneity resulting in line-broadening as seen in Figs. 6d and 7d. Therefore, this approach
is best applied to cases with reduced spectra complexity. Furthermore, working at low
temperatures is especially useful when particular states need to be trapped or unfavourable
dynamics has to be quenched (Bajaj et al, 2009; Ong et al, 2013).
(d) MsbA in complex with lipid A
Membrane proteins are usually extracted from their native membrane using buffers
with high (1-1.5%) detergent concentration and solubilisation times of 30 min to 1 h. MsbA
extracted with DDM as detergent, applied in a concentration of 1.25% w/v for 1 h showed a
high basal activity and its activity could not be stimulated with Hoechst 33342 (see Figure
7a). We tested the effect of different solubilisation times on the activity of MsbA in detergent
micelles. The basal activity of MsbA was elevated at short solubilisation times (2.8
µmol/mg/min after 1 h) and it decreased as the solubilisation time was increased (1.43
µmol/mg/min after overnight). A clear stimulation in the activity of protein by Hoechst 33342
could only be observed for the sample prepared by overnight solubilisation. Practically no
stimulation was seen for shorter solubilisation times. We explain this phenomenon with the
presence of the native substrate, Lipid A, in the binding pocket of MsbA, which could only be
effectively removed when the protein was exposed to detergent for 12 h or longer.
Lipid A is the hydrophobic membrane anchor of the LPS from the outer membrane of Gram-
negative bacteria. It is an endotoxin, responsible for the activation of the host innate immune
system (Zhou et al, 1998). Lipid A is structurally heterogeneous. It consists of a conserved
diglucosamine disaccharide backbone with fatty acids attached as ester- or amide linked
substituents. Phosphate groups are also attached to 4´and/or 1 positions. Variations in its
structure can usually occur in the number, position and type of fatty acids and also in number
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of phosphate groups to which additional monosaccharides might be attached. The structural
variation of lipid A can also vary from bacteria to bacteria or/and depend on environmental
factors such as the presence of divalent cations, temperature and other growth conditions
(Erridge et al, 2002; Raetz & Whitfield, 2002; Rebeil et al, 2004). The standard and most
abundant structure of lipid A from E. coli is depicted in Figure 7a. However, many different
variants have been isolated so far from different E. coli strains (Baltzer & Mattsbybaltzer,
1986; El Hamidi et al, 2005; Henderson et al, 2013; Jones et al, 2008).
We used solid state NMR in order to demonstrate the presence of lipid A in our
preparations. In the 31P MAS-NMR spectrum of MsbA solubilised for only one hour, two
signals could be seen at 6.57 and 2.06 ppm, which were not present when the protein was
solubilised overnight (Fig 7b). Baltzer and Mattsby-Baltzer (Baltzer & Mattsbybaltzer, 1986)
measured the 31P NMR spectra of seven different lipid A fractions isolated from E. coli strain
0111. Their 31P chemical shifts were ranging between 5.5 and 1.7 ppm. Taking into account
the different experimental conditions (solution state NMR at 45°C of isolated lipid A
molecules in chloroform/methanol/water mixture vs. solid state NMR at 3°C of lipid A bound
to MsbA embedded within liposomes at pH 7.4) these results correspond well to our 31P NMR
data and support the assignment of the two 31P resonances as lipid A signals.
13C-13C PDSD spectra of [13C,15N-DEQGHKTS]-MsbA prepared by one hour
solubilisation recorded with 20 and 100 ms mixing time (Figure 7c and d, black) also showed
additional cross peaks as compared with the spectrum of an overnight solubilised sample
(Figure 7c, red). The 1D chemical shifts of these signals at 81.5, 101.2 and 103.0 ppm and
two additional resonances in the spectrum recorded with longer mixing time at 97.2 and 104.0
ppm are typical for cyclic sugars. Ribeiro et al. assigned all 13C chemical shifts of standard
lipid A from E. coli by multidimensional solution NMR techniques. Based on their results the
signal at 97.2 ppm can be assigned to C-1 from the second glucosamine unit and those with a
chemical shift at around 100 ppm should arise from the C-1` of the first glucosamine
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monomer. These carbon atoms are highlighted in red on Figure 7a. The observation of three
peaks with chemical shifts of approx. 100 ppm indicates that three structurally different types
of lipid A are present. Additional cross-peaks could be detected between C-1 and the other
carbons from the glucosamine moiety at 68.5, 61.7 and 55.0 ppm by DNP-enhanced MAS-
NMR at low temperature. These 13C spectra show that the co-purified Lipid A was at least
partially 13C labelled using the expression protocol described here.
Based on these observations, it can be concluded that MsbA in DDM can only be prepared in
a pure apo-state by overnight solubilisation. Other types of detergents (e.g. DM, LDAO) were
used successfully also with one hour of solubilisation and the activity of the obtained protein
showed clear stimulation with Hoechst 33342 (Doerrler & Raetz, 2002; Eckford & Sharom,
2008b; Eckford & Sharom, 2008c; Siarheyeva & Sharom, 2009).
Conclusions and Perspective
We have shown that milligram quantities of isotope labelled, pure, stable and mono-
disperse MsbA can be produced. Reconstitution into DMPC/DMPA liposomes represents the
optimum in terms of homogeneity, dense packing, ATPase activity and spectral resolution.
First 2D-MAS NMR experiments of extensively and selectively labelled samples show that
individual sites can be resolved. We have successfully demonstrated the applicability of Gd3+-
doping to improve signal-to-noise per unit time, which is especially useful for studies at high
field and at non-frozen samples. Furthermore, we have demonstrated a large signal
enhancement by DNP, which will become essential for freeze-trapping functional states on
selectively labelled MsbA. These approaches allowed us to identify 13C-labelled lipid A in
complex with labelled MsbA by utilising the duration of detergent solubilisation. These initial
experiments confirm that MsbA is a promising target for further in-depth solid state NMR
studies especially with respect to nucleotide and lipid interactions, which are currently in
progress and will be reported elsewhere.
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Materials and methods
(a) Reagents
Luria broth, Tris and HEPES were obtained from Carl Roth GmbH & Co. Ni-NTA beads
were purchased from Qiagen and Biobeads were ordered from Bio-Rad. ATP and sodium
meta-arsenite were purchased from Sigma-Aldrich. Complete EDTA free protease inhibitor
cocktail tablets were bought from Roche and Run Blue precast SDS-PAGE gels from
Expedeon. Lipids were obtained from Avanti Polar Lipids. All other compounds were from
PanReac AppliChem reagents. For size exclusion chromatography Sephadex 200 10/300GL
and PD10 column for buffer exchange were from GE Healthcare Life Sciences. Labelled
glucose (13C) and other amino acids were ordered from Cambridge Isotope Laboratories (CIL)
while ammonium chloride (15N) was obtained from Cortecnet. The Gd3+-DOTA complex was
bought from BOC sciences.
(b) Expression and Purification of MsbA
MsbA was cloned into a pET 19b vector containing an N-terminal His10 tag connected via an
11 amino acid peptide linker (Borbat et al, 2007). The plasmid was transformed into
C43(DE3) cells for protein expression. For obtaining a high yield of isotope labelled MsbA,
cells were grown initially in LB-medium, collected by centrifugation and transferred to M9
minimal medium (Marley et al, 2001). Expression was started by adding 10 ml of preculture
to one liter of LB at 37 ˚C and 220 rpm. When the OD600nm reached 0.6 - 0.7, cells were
harvested and then resuspended into 500 ml of M9 minimal medium. The cells were further
incubated at 37 ˚C, 220 rpm for one hour for adaptation. The protein expression was induced
with 1mM IPTG at 20 ˚C and 260 rpm once the OD600nm has reached a value between 1.7 and
2.1 After 17 h of expression, the cells were harvested and resuspended in buffer A (10 mM
Tris, 250 mM Sucrose, 150 mM NaCl, 2.5 mM MgSO4, pH 7.5) with protease inhibitor, 0.5
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mM dithiothreitol (DTT) and DNAase. Membranes were prepared by passing the resuspended
cells through a cell disrupter at a pressure of 1.5-1.7 kbar (2-3 times), followed by
centrifugation at 8000 rpm for 10 min to remove cell debris and a final ultracentrifugation
step at 55000 rpm for one hour. Membranes were solubilised in buffer B (50 mM HEPES,
300 mM NaCl, 5 mM MgCl2, 10% Glycerol, pH 7.5) with 1.25% DDM, 0.5mM DTT and 10
mM imidazole at 4°C either overnight (apo sample) or for one hour (lipid A bound sample).
The insoluble fraction was removed by ultracentrifugation at 55000 rpm for 1 h. The
remaining supernatant was loaded onto Ni-NTA prewashed with buffer B containing 50 mM
imidazole. After 1.5 -2 h binding, elution was carried out using buffer B containing 0.015%
DDM and 400 mM imidazole. SDS - PAGE, size exclusion chromatography using Sephadex
200 column and MALDI-MS were done to confirm purity and homogeneity of the protein.
Using this procedure, [U-15N]-MsbA, [U-13C,15N]-MsbA, [13C,15N-K]-MsbA and [13C,15N-
DEQGHKTS]-MsbA were produced. Samples were prepared by supplemented M9 with 13C-
glucose (2 g/l M9 minimal media) and 15NH4Cl (1 g/l M9 minimal media). For [13C,15N-
DEQGHKTS]-MsbA, unlabelled amino acids Ala (0.5 g/l), Cys (0.05 g/l), Val (0.23 g/l), Leu
(0.23 g/l), Ile (0.23 g/l), Met (0.25 g/l), Pro (0.1 g/l), Phe (0.13 g/l), Tyr (0.17 g/l), Trp (0.05
g/l), Asn (0.4 g/l), Arg (0.4 g/l) were added for extensive reverse labelling. In case of
[13C,15N-K]-MsbA, 13C-15N-Lys together with all other unlabelled amino acids was added to
M9 minimal medium.
(c) Reconstitution of MsbA
The following lipid mixtures were used for reconstitution: DMPC:DMPA (9:1), E. coli polar
lipids, E. coli PE:PG:CA (65 : 25 : 10) and POPC:POPG:CA (65 : 25 : 10) at molar lipid to
protein ratios of 75 : 1 and 50 : 1. Each lipid mixture was solubilised in CHCl3:CH3OH (2:1)
and drying under a stream of nitrogen gas followed by vacuum rotor evaporation. The dried
lipids were resuspended in buffer C (50 mM HEPES, 50 mM NaCl) and extruded 11 times
through membranes with pore diameters of 0.1, 0.2 and 0.4 µm. Liposomes were destabilised
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with 3 mM DDM. After dropwise addition of protein in the DDM/liposome solution, the
mixture was allowed to incubate at room temperature for 30 min. Detergent was removed by
biobeads (80 mg/ml), which were first added for 12 h at 4 °C and then twice for one hour at
room temperature. Sample homogeneity was verified by a discontinuous sucrose gradient
prepared by layering 1 ml of 10, 30, 50 and 70% (w/v) sucrose in 50 mM HEPES, 50 mM
NaCl. About 400 µL of sample was layered on top of the sucrose solution and centrifuged at
28,000 rpm for 16 h at 4 °C.
(d) ATPase activity
The activity of MsbA was determining by monitoring the release of inorganic phosphate.
Each reaction mixture containing MsbA (solubilized in detergent or reconstituted into
liposomes) and ATP (0.2 – 5 mM) in buffer (50 mM HEPES, 50 mM NaCl, 10 mM MgCl2)
was incubated at 37 ˚C for 20 min. Control samples for each reaction were kept on ice. The
reaction was stopped by adding 12% SDS. The release of inorganic phosphate (Pi) was
measured using the molybdenium blue method (Chifflet et al, 1988; González-Romo et al,
1992). Stimulated activity was observed by determining the release of Pi upon adding
Hoechst 33342 at increasing concentrations of 0.001, 0.01, 0.1, 1, 10, 100, 1000 and 10000
µM in the presence of 0.2 mM ATP (Eckford & Sharom, 2008a).
(e) Sample preparation for NMR
For MAS-NMR, proteoliposomes were pelleted and centrifuged into 3.2 or 4 mm MAS
rotors. Usually, an amount of 10 - 15 mg of MsbA was used. For paramagnetic relaxation
enhancement, samples were doped with the appropriate amount of gadolinium-!1,4,7,10-
tetraazacyclododecane-1,4,7,10-tetraacetic acid (Gd3+-DOTA) (Ullrich et al, 2014). The Gd3+-
DOTA powder was dissolved in NMR buffer and added to the sample at the desired
concentration. The sample was incubated for 15 minutes at 4 °C followed by
ultracentrifugation and transfer into a 4 mm MAS rotor.
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For DNP, reconstituted samples were incubated overnight at 4 °C with 20 mM AMUPOL in a
buffer containing 10 % H2O, 30 % D8-glycerol and 60 % D2O. The solution was removed
carefully and the pellets were transferred to a 3.2 mm zirconium oxide rotor by centrifugation.
(f) Solid state NMR
For all NMR experiments, standard settings for cross polarisation (CP) and decoupling were
used. A typical 1H 90° pulse had a duration of 3 µs, the CP contact time was chosen between
0.8 and 1 ms and high power proton decoupling of 70-100 kHz was applied using SPINAL64
(Fung et al, 2000). Spectra were processed using TOPSPIN 3.2. An exponential window
function was applied to 1D data and a shifted cos2 function was used for 2D spectra.
Depending on the experiment, between 10 and 20 mg of MsbA were used.
15N-T2 measurements (Figure 3d): 15N-spin echo experiments on [U-15N]-MsbA were
recorded at 270K at 10kHz sample spinning using a Bruker 600WB Avance I spectrometer
with a 4 mm DVT-HCN E-free MAS probe. The rotor-synchronized spin echo was acquired
after a CP step under high power proton decoupling with a 3 s recycle delay. The full integral
intensity of the amide region (109 – 121 ppm) was used for data analysis.
Temperature-dependent spectra (Figure 4): The temperature-dependant experiments on [U-
13C]-MsbA were recorded at 10 kHz sample spinning using a Bruker 600WB Avance I
spectrometer with a 4 mm DVT-HCN E-free MAS probe. Order parameters were derived
from 13C-1H dipolar couplings measured from PISEMA experiments (Dvinskikh et al, 2003;
Wu et al, 1994). A 50 kHz RF field was used during the Lee–Goldberg spin exchange at the
magic angle.
13C-13C and 13C-15N correlation spectra (Figure 5): The 13C-13C through space correlation
spectra on [13C,15N-DEQGHKTS]-MsbA were recorded using a proton-driven spin diffusion
experiment (PDSD) (Szeverenyi et al, 1982) at 14 kHz sample spinning and 270K using a
Bruker 850WB Avance III spectrometer equipped with a 3.2 mm DVT-HXY MAS probe.
Spectra were recorded with 800 increments and 128 scans each, with a 20 ms mixing time and
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a 3 s recycle delay. Spectral widths were 80 kHz in ω2 and 52 kHz in ω1. The NCA spectrum
of [15N-Lys]-MsbA was recorded at 11.4 kHz sample spinning at 270 K using a Bruker
600WB Avance I spectrometer with a 4 mm DVT-HCN E-free MAS probe. For the NC cross
polarisation step, a mixing time of 6 ms was applied. A constant 15N lock field of 28.5 kHz
(2.5 x νr) and a linearly ramped (90-100) 13C field around 1.5 x νr was used. The CW
decoupling during this step was set to 100 kHz. The spectrum was acquired with 200
increments with 512 scans each and 3 s recycle delay. Spectral widths were 60 kHz in ω2 and
5.5 kHz ω1.
Gd3+-DOTA doping (Figs. 6a,b): All experiments were carried out using a Bruker 600WB
Avance I spectrometer with a 4 mm DVT-HCN E-free MAS probe. Amide proton T1 values
(Figure 6a) were obtained by saturation recovery experiments following a 15N CP step.
Relaxation times were determined by analysing the full intensity of the 15N amide resonances
(109 – 121 ppm). The 13C-13C PDSD spectrum (Figure 6b) was recorded with a 20 ms mixing
time and 512 increments with 144 scans each. Spectral widths were 60 kHz in ω2 and 40 kHz
in ω1. Upon Gd3+-DOTA doping, the recycle delay was reduced from 3 to 1 s.
DNP-enhanced MAS-NMR (Figs. 6d, 7a): The DNP enhanced MAS NMR spectra were
recorded using a Bruker DNP system consisting of a 400 MHz WB Avance II spectrometer, a
263 GHz Gyrotron as a microwave source and a 3.2 mm HCN-DNP-MAS probe. The
temperature was set 105K and a sample-spinning rate of 8 kHz was used. The 13C-13C PDSD
spectrum was acquired with a 100 ms mixing time and 256 increments with 32 scans each.
Spectral widths were 40 kHz in ω2 and 25 kHz in ω1. A recycle delay of 2.5 s was used.
MsbA in complex with Lipid A (Figure 7): The 13C-13C PDSD spectrum of [13C,15N-
DEQGHKTS]-MsbA were acquired at 14kHz sample spinning and 270 K using a Bruker
850WB Avance III spectrometer equipped with a 3.2 mm DVT-HXY MAS probe. Mixing
times of 20 and 100 ms were applied and spectra were recorded with 800 increments with 128
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scans each. Spectral widths were 80 kHz in ω2 and 52 kHz in ω1. A recycle delay of 3 s was
used. 31P MAS NMR spectra (Figure 7b) were recorded at 10kHz sample spinning and 270K
using a Bruker 600WB Avance I spectrometer with a 4 mm DVT-HX MAS probe. A CP
contact time of 3 ms was applied followed by high power proton decoupling.
Acknowledgements
The work was supported by a DFG research grant through SFB 807 ‘Transport and
communication across membranes’ and by a DFG equipment grant (GL 307/4-1) to C.G.. H.
M. acknowledges support by NIH grant U54-GM087519. MALDI-MS data were kindly
provided by Dr. Ute Bahr (Institute for Pharmaceutical Chemistry, Goethe University
Frankfurt)
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Figures and Legends!
Figure 1: Membrane mimicking environments for investigating membrane proteins by NMR
spectroscopy. Micelles, bicelles and nanodiscs are used to keep the protein soluble, which
would make them suitable to solution state NMR but their total molecular weight when
incorporating proteins such as ABC transporters limits this approach. Oriented solid state
NMR exploits the spontaneous alignment of bicelles in magnetic fields. The most universal
approach is based on MAS-NMR, which enables experiments directly on proteoliposomes as
demonstrated in this paper for the ABC exporter MsbA.
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Figure 2: Purification and stability of MsbA. (a) Size exclusion chromatogram of MsbA in
DDM, freshly eluted (black) and after 24 h at room temperature (red). The intensity
differences are due the different amounts of protein used. (b) SDS PAGE of MsbA in DDM
after NiNTA purification. (c) SDS PAGE of MsbA reconstituted in DMPC:DMPA (9:1)
mol/mol) at LPR = 75 mol/mol) after storage for 30 days at room temperature. (d) Western
blot analysis of MsbA using an anti His-conjugate antibody. (e) MALDI mass spectra of
MsbA in detergent.
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Figure 3. Reconstitution of MsbA. (a) Optimised DMPC/DMPA (9:1) liposome
destabilisation for homogenous MsbA proteoliposome preparation. Destabilisation was
followed by changes in optical density at 540 nm (black squares). Liposomes are fully
saturated at RSAT and fully solubilised at RSOL. The ATPase activity determined from
proteoliposomes after detergent removal (bars) shows a maximum at ROPT. Since the amount
of MsbA within the proteoliposomes is the same for all destabilisation conditions starting
from ROPT, ATPase activity reports on NBD accessibility / homogeneity of MsbA orientation.
ATPase activities were determined at an ATP concentration of 6mM. (b) Effect of extrusion
of lipids through membranes of different pore size used to prepare unilamellar vesicles (MsbA
in DMPC/DMPA (9:1), LPR=50 mol/mol) on sample homogeneity as seen by sucrose density
gradients (10-70% w/v). (c) Characterisation of basal ATPase activity using the colorimetric
molybdate blue assay for MsbA in 0.015% DDM (black), reconstituted in destabilised
DMPC/DMPA (9:1) (red), reconstituted in E. coli polar lipids (blue), reconstituted in
DMPC/DMPA (9:1) (magenta). A LPR of 75 mol/mol was used in all cases. (d)
Determination of the 15N transversal relaxation time T2of [U-15N]-MsbA reconstituted into
different lipid mixtures. The largest value is obtained for DMPC/DMPA (9:1) with a LPR of
50 mol/mol, which corresponds to the smallest homogeneous 15N linewidth (27 Hz) indicating
good spectral resolution.
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Figure 4. Temperature dependant 13C spectra of MsbA: (a) 13C-CP spectra, (b) directly
polarised (DP) spectra and (c) C-H dipolar spectra of MsbA in DMPC/DMPA in the gel phase
and below the freezing point of water (255 K), in the gel phase above the freezing point of
water (273 K) and in the liquid-crystalline phase (313 K). Resolution in both (a) and (b) is
better compared to frozen samples. Sensitivity slightly decreases with increasing temperature,
but there is no direct dependence on the lipid phase transition. DP spectra visualize all regions
of the protein while CP filters mainly regions, which are less flexible. This is also seen in (c) ,
which displays the average C-H dipole coupling in MsbA from cross-polarised segments. The
splittings are close to the rigid limit of 21.5 kHz indicating that these parts of the protein are
not involved in large amplitude fluctuations.
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Figure 5. 2D-MAS NMR spectra of MsbA: (a) Aliphatic region of the 13C-13C PDSD
spectrum (20 ms mixing time) of [13C,15N-DEQGHKTS]-MsbA reconstituted in
DMPC/DMPA (9:1) at LPR=50 mol/mol. Labelling was achieved using extensive reverse
labelling (see materials and methods). The homogeneous sample preparation results in a
number of individually resolved cross peaks. (b) A 1D trace taken at 62.5 ppm shows a 0.5
ppm linewidth (106 Hz) at half height for an isolated peak. (c) 15N-13C NCA spectrum of [13C,
15N-K]-MsbA with secondary structure regions highlighted (1- and 2-times standard
deviation) (Wang & Jardetzky, 2002). MsbA contains 22 lysines.
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Figure 6. Approaches to improve the detection sensitivity for MAS-NMR on MsbA. (a)
Sample doping with Gd3+-DOTA reduces the averaged amide 1H-T1 in 15N-MsbA
significantly. In presence of 1 mM Gd3+-DOTA, 1H-T1 was reduced by almost 90%. A
comparison of 15N-CP MAS spectra of dia- and paramagnetic MsbA samples recorded each
with a recycle delay of 1 s shows a 20%-fold better SNR upon doping. (b) Superposition of
13C-13C PDSD spectra of diamagnetic (black) and paramagnetic (red) MsbA samples recorded
with recycle delays of 3 and 1 sec, respectively. The number of scans and the amount of
sample was the same in both spectra. The spectrum of the doped sample was recorded three
times faster. Cross sections along ω2 for Cα-Cβ cross peaks show no doping induced line
broadening and no relevant peak shifts. (c) Basic setup for dynamic nuclear polarisation
(DNP). Samples are doped with suitable biradicals such as AmuPOL. NMR experiments are
conducted under continuous microwave irradiation resulting in a large sensitivity
enhancement. (d) 1D 13C-CP spectra of MsbA with and without microwave irradiation
demonstrate a 20-fold signal increase.
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Figure 7. Lipid A in complex with MsbA: (a) Stimulation of MsbA ATPase activity by
Hoechst-33342 depending on the duration of detergent solubilisation prior to purification. The
longer the sample has been solubilised the more pronounced is substrate-stimulated ATPase
activity. (b) 31P-CP spectra of MsbA reconstituted in DMPC/DMPA lipid bilayers after one
hour and after overnight solubilisation from E. coli membranes. The sample exposed for only
one hour to detergent shows two additional 31P signals, which are tentatively assigned to the
phosphate groups of Lipid A within the binding pocket of MsbA. Shown here is the structure
of the most abundant and toxic form of E. coli Lipid A. (c) 13C-13C PDSD spectra (20ms
mixing time) of MsbA samples prepared using overnight (red) and one hour (black)
solubilisation. The latter spectrum (black) shows signals typical for sugar molecules (box).
(d) 13C-13C PDSD spectra (100ms mixing time) of MsbA samples exposed to one hour
solubilisation at 270K (black) and 110K under DNP-conditions (blue). In the spectrum
recorded under DNP condition additional signals from the sugar backbone of Lipid A can be
clearly assigned.!
... Since the binding pocket is within the TMD and accessible from the membrane phase, the reasons could be reduced accessibility and/or reduced G907 membrane penetration in these lipids. The selection of DMPC/DMPA as lipids for reconstitution was primarily driven by previously published studies in which it was shown that MsbA preparations are stable, active, and provide well-resolved NMR spectra 27,61,62,73 . However, it was also shown that the G907 inhibitor affinity was affected by the detergent and lipid environment of MsbA 47 . ...
... Protein expression and purification. Wild-type MsbA was expressed and purified as described previously 27,61,62,73 . Using a pET-19b vector containing an N-terminal His10-tag connected via an 11 amino acid peptide linker, the wild-type MsbA gene was cloned and transformed into E. coli C43(DE3) cells for protein expression. ...
... Reconstitution in DMPC/DMPA lipids and ADP orthovanadate and Hoechst 33342 trapping. Reconstitution of MsbA was performed as in previous studies 27,61,62,73 . Nine mols of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC, Avanti Lipids) were mixed with one mol of 1,2-dimyristoyl-sn-glycero-3phosphate (DMPA, Avanti Lipids) in CHCl 3 /CH 3 OH (2:1) solvent and dried under nitrogen gas flow. ...
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The ABC transporter MsbA plays a critical role in Gram-negative bacteria in the regulation of the outer membrane by translocating core-LPS across the inner membrane. Additionally, a broad substrate specificity for lipophilic drugs has been shown. The allosteric interplay between substrate binding in the transmembrane domains and ATP binding and turnover in the nucleotide-binding domains must be mediated via the NBD/TMD interface. Previous studies suggested the involvement of two intracellular loops called coupling helix 1 and 2 (CH1, CH2). Here, we demonstrate by solid-state NMR spectroscopy that substantial chemical shift changes within both CH1 and CH2 occur upon substrate binding, in the ATP hydrolysis transition state, and upon inhibitor binding. CH2 is domain-swapped within the MsbA structure, and it is noteworthy that substrate binding induces a larger response in CH2 compared to CH1. Our data demonstrate that CH1 and CH2 undergo structural changes as part of the TMD-NBD cross-talk.
... MsbA (130 kDa, 584 residues [233,237]) is a homodimer that consists of two TMDs, each of which has six transmembrane (TM) helices and two cytosolic NBDs [69]. This protein is classified in group IV based on TMD fold arrangement (Figure 1). ...
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Multidrug resistance (MDR) proteins belonging to the ATP-Binding Cassette (ABC) transporter group play a crucial role in the export of cytotoxic drugs across cell membranes. These proteins are particularly fascinating due to their ability to confer drug resistance, which subsequently leads to the failure of therapeutic interventions and hinders successful treatments. One key mechanism by which multidrug resistance (MDR) proteins carry out their transport function is through alternating access. This mechanism involves intricate conformational changes that enable the binding and transport of substrates across cellular membranes. In this extensive review, we provide an overview of ABC transporters, including their classifications and structural similarities. We focus specifically on well-known mammalian multidrug resistance proteins such as MRP1 and Pgp (MDR1), as well as bacterial counterparts such as Sav1866 and lipid flippase MsbA. By exploring the structural and functional features of these MDR proteins, we shed light on the roles of their nucleotide-binding domains (NBDs) and transmembrane domains (TMDs) in the transport process. Notably, while the structures of NBDs in prokaryotic ABC proteins, such as Sav1866, MsbA, and mammalian Pgp, are identical, MRP1 exhibits distinct characteristics in its NBDs. Our review also emphasizes the importance of two ATP molecules for the formation of an interface between the two binding sites of NBD domains across all these transporters. ATP hydrolysis occurs following substrate transport and is vital for recycling the transporters in subsequent cycles of substrate transportation. Specifically, among the studied transporters, only NBD2 in MRP1 possesses the ability to hydrolyze ATP, while both NBDs of Pgp, Sav1866, and MsbA are capable of carrying out this reaction. Furthermore, we highlight recent advancements in the study of MDR proteins and the alternating access mechanism. We discuss the experimental and computational approaches utilized to investigate the structure and dynamics of MDR proteins, providing valuable insights into their conformational changes and substrate transport. This review not only contributes to an enhanced understanding of multidrug resistance proteins but also holds immense potential for guiding future research and facilitating the development of effective strategies to overcome multidrug resistance, thus improving therapeutic interventions.
... A final notable feature of these data is the observation that the presence of the transportable ligand substrate Hoechst 33342 does not affect the putative equilibrium between IF and OF conformations in the apo state, and nor does it significantly affect the proportion of MsbA dimers that reach the Vi-trapped state. Since Hoechst 33342 was present at optimal concentration for stimulation of ATPase activity [37], these findings appear at odds with data for P-gp, which showed that substrates stimulated the formation of the Vi-trapped state [38] and that the extent of Vi-trapping was correlated with the fold stimulation of steady-state ATPase activity by the substrate [39]. ...
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ATP-binding cassette (ABC) transporters comprise a large superfamily of primary active transporters, which are integral membrane proteins that couple energy to the uphill vectorial transport of substrates across cellular membranes, with concomitant hydrolysis of ATP. ABC transporters are found in all living organisms, coordinating mostly import in prokaryotes and export in eukaryotes. Unlike the highly conserved nucleotide binding domains (NBDs), sequence conservation in the transmembrane domains (TMDs) is low, with their divergent nature likely reflecting a need to accommodate a wide range of substrate types in terms of mass and polarity. An explosion in high resolution structural analysis over the past decade and a half has produced a wealth of structural information for ABCs. Based on the structures, a general mechanism for ABC transporters has been proposed, known as the Switch or Alternating Access Model, which holds that the NBDs are widely separated, with the TMDs and NBDs together forming an intracellular-facing inverted “V” shape. Binding of two ATPs and the substrate to the inward-facing conformation induces a transition to an outward conformation. Despite this apparent progress, certainty around the transport mechanism for any given ABC remains elusive. How substrate binding and transport is coupled to ATP binding and hydrolysis is not known, and there is a large body of biochemical and biophysical data that is at odds with the widely separated NBDs being a functional physiological state. An alternative Constant Contact model has been proposed in which the two NBSs operate 180 degrees out of phase with respect to ATP hydrolysis, with the NBDs remaining in close proximity throughout the transport cycle and operating in an asymmetric allosteric manner. The two models are discussed in the light of recent nuclear magnetic resonance and hydrogen-deuterium exchange mass spectrometry analyses of three ABC exporters.
... The non-equilibrium magnetization at the beginning of the mixing time is responsible for the asymmetric 31 P-31 P 2D spectra. ADP in three different chemical states is involved in the exchange, namely (i) bound ADP which is sufficiently immobilized in the ATP-binding site so that CP is efficient and can be detected in31 P CP experiments; (ii) loosely bound ADP (e.g. possibly ADP is retained only by the Walker A motif but other motifs are not fully engaged in the stabilisation of the nucleotide) that gives only a weak 31 P CP signal and (iii) free ADP in solution which is not detected in 31 P CP (Figure 6C). ...
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The detailed mechanism of ATP hydrolysis in ATP-binding cassette (ABC) transporters is still not fully understood. Here, we employed 31P solid-state NMR to probe the conformational changes and dynamics during the catalytic cycle by locking the multidrug ABC transporter BmrA in pre-hydrolytic, transition and post-hydrolytic states, using a combination of mutants and ATP analogues. The 31P spectra reveal that ATP binds strongly in the pre-hydrolytic state to both ATP-binding sites as inferred from the analysis of the non-hydrolytic E504A mutant. In the transition state of wild-type BmrA, the symmetry of the dimer is broken and only a single site is tightly bound to ADP:Mg2+:vanadate, while the second site is more ‘open’ allowing exchange with the nucleotides in the solvent. In the post-hydrolytic state, weak binding, as characterized by chemical exchange with free ADP and by asymmetric 31P-31P 2D correlation spectra, is observed for both sites. Revisiting the 13C spectra in light of these findings confirms the conformational non-equivalence of the two nucleotide-binding sites in the transition state. Our results show that following ATP binding, the symmetry of the ATP-binding sites of BmrA is lost in the ATP hydrolysis step, but is then recovered in the post-hydrolytic ADP-bound state.
... Particularly, in solid-state NMR, faster magic-angle spinning (MAS) recently reduced sample needs by a spectacular factor of 100 through proton detection under MAS frequencies exceeding 100 kHz (Agarwal et al., 2014;Bockmann et al., 2015;Lecoq et al., 2018;Lecoq et al., 2019;Wang et al., 2019), a milestone that enables investigation of submilligram amounts of sample. As solid-state NMR can typically target large protein assemblies such as viral capsids (Zhang et al., 2016;Wang et al., 2017;Quinn et al., 2018), envelopes (David et al., 2018), microtubules (Guo et al., 2019), or membrane proteins (Jirasko et al., 2020) and their assemblies (Ong et al., 2013;Kaur et al., 2015;Kaur et al., 2016;Kaur et al., 2018;Kaur et al., 2019), an in vitro protein synthesis system using a high-yielding eukaryotic ribosome is a central asset for such studies. This approach can generally be used to also produce proteins of pathogens that hijack the eukaryotic host cell machinery during infections making it a powerful tool for pathogen research. ...
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Cell-free protein synthesis (CFPS) systems are gaining more importance as universal tools for basic research, applied sciences, and product development with new technologies emerging for their application. Huge progress was made in the field of synthetic biology using CFPS to develop new proteins for technical applications and therapy. Out of the available CFPS systems, wheat germ cell-free protein synthesis (WG-CFPS) merges the highest yields with the use of a eukaryotic ribosome, making it an excellent approach for the synthesis of complex eukaryotic proteins including, for example, protein complexes and membrane proteins. Separating the translation reaction from other cellular processes, CFPS offers a flexible means to adapt translation reactions to protein needs. There is a large demand for such potent, easy-to-use, rapid protein expression systems, which are optimally serving protein requirements to drive biochemical and structural biology research. We summarize here a general workflow for a wheat germ system providing examples from the literature, as well as applications used for our own studies in structural biology. With this review, we want to highlight the tremendous potential of the rapidly evolving and highly versatile CFPS systems, making them more widely used as common tools to recombinantly prepare particularly challenging recombinant eukaryotic proteins.
... In the ABC transporters field, solid-state NMR is less used, due to the high molecular weight of these proteins that makes spectra assignment very challenging [80,81]. However, NMR has been used to follow in real time the hydrolysis of ATP [82], and it enabled the discovery that MsbA, LmrA and TmrAB can couple ATP hydrolysis to an adenylate kinase activity, where ADP is converted into AMP and ATP [83]. ...
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ATP-binding cassette (ABC) exporters have been studied now for more than four decades, and recent structural investigation has produced a large number of protein database entries. Yet, important questions about how ABC exporters function at the molecular level remain debated, such as which are the molecular recognition hotspots and the allosteric couplings dynamically regulating the communication between the catalytic cycle and the export of substrates. This conundrum mainly arises from technical limitations confining all research to in vitro analysis of ABC transporters in detergent solutions or embedded in membrane-mimicking environments. Therefore, a largely unanswered question is how ABC exporters operate in situ, namely in the native membrane context of a metabolically active cell. This review focuses on novel mechanistic insights into type I ABC exporters gained through a unique combination of structure determination, biochemical characterization, generation of conformation-specific nanobodies/sybodies and double electron–electron resonance. © 2020 The Authors. FEBS Letters published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies
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Solid-state NMR with magic-angle spinning (MAS) is an important method in structural biology. While NMR can provide invaluable information about local geometry on an atomic scale even for large biomolecular assemblies lacking long-range order, it is often limited by low sensitivity due to small nuclear spin polarization in thermal equilibrium. Dynamic nuclear polarization (DNP) has evolved during the last decades to become a powerful method capable of increasing this sensitivity by two to three orders of magnitude, thereby reducing the valuable experimental time from weeks or months to just hours or days; in many cases, this allows experiments that would be otherwise completely unfeasible. In this review, we give an overview of the developments that have opened the field for DNP-enhanced biomolecular solid-state NMR including state-of-the-art applications at fast MAS and high magnetic field. We present DNP mechanisms, polarizing agents, and sample constitution methods suitable for biomolecules. A wide field of biomolecular NMR applications is covered including membrane proteins, amyloid fibrils, large biomolecular assemblies, and biomaterials. Finally, we present perspectives and recent developments that may shape the field of biomolecular DNP in the future.
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