Functional response of the small multidrug resistance protein EmrE to mutations in transmembrane helix 2

Escherichia coli EmrE is a small multidrug resistance protein encompassing four transmembrane (TM) sequences that oligomerizes to confer resistance to antimicrobials. Here we examined the effects on in vivo protein accumulation and ethidium resistance activity of single residue substitutions at conserved and variable positions in EmrE transmembrane segment 2 (TM2). We found that activity was reduced when conserved residues localized to one TM2 surface were replaced. Our findings suggest that conserved TM2 positions tolerate greater residue diversity than conserved sites in other EmrE TM sequences, potentially reflecting a source of substrate polyspecificity.     

Organic solvent extracted EmrE solubilized in dodecyl maltoside is monomeric and binds drug ligand

Ethidium multidrug resistance protein (EmrE) is a member of the small multidrug resistance family of proteins and is responsible for resistance to a diverse group of lipophilic cations. To examine the multimeric state(s), size-exclusion HPLC and sedimentation velocity experiments were performed with EmrE solubilized in N-dodecyl-beta-d-maltopyranoside (DM) detergent. EmrE was purified from Escherichia coli membranes using organic extraction with a 3:1 chloroform:methanol solvent followed by LH-20 chromatography and the recovered pure protein was re-solubilized in a buffer containing 2% DM. The purified protein was analyzed by SEC-HPLC to estimate the monodispersity and to determine the amount of bound detergent. The results show that EmrE is homogeneous in DM with a Stokes radius of 3.6nm compatible with that of a monomer. Sedimentation velocity experiments indicated that the EmrE preparation was monodisperse and supports the fact that the organic extracted protein solubilized in DM is monomeric. This monomeric form of the protein analyzed here is also shown to bind substrate in the micromolar range.     

Influence of quaternary cation compound on the size of the Escherichia coli small multidrug resistance protein,EmrE

EmrE is a member of the small multidrug resistance (SMR) protein family in Escherichia coli. It confers resistance to a wide variety of quaternary cation compounds (QCCs) as an efflux transporter driven by the transmembrane proton motive force. We have expressed hexahistidinyl (His₆) – myc epitope tagged EmrE, extracted it from membrane preparations using the detergent n-dodecyl-β-D-maltopyranoside (DDM), and purified it using nickel-affinity chromatography. The size of the EmrE protein, in DDM environment, was then examined in the presence and absence of a range of structurally different QCC ligands that varied in their chemical structure, charge and shape. We used dynamic light scattering and showed that the size and oligomeric state distributions are dependent on the type of QCC. We also followed changes in the Trp fluorescence and determined apparent dissociation constants (K_d). Overall, our in vitro analyses of epitope tagged EmrE demonstrated subtle but significant differences in the size distributions with different QCC ligands bound.     

Small multidrug resistance proteins: A multidrug transporter family that continues to grow

The small multidrug resistance (SMR) protein family is a bacterial multidrug transporter family. As suggested by their title, SMR proteins are composed of four transmembrane α-helices of approximately 100-140 amino acids in length. Since their designation as a family, many homologues have been identified and characterized both structurally and functionally. In this review the topology, structure, drug resistance, drug binding, and transport mechanisms of the entire SMR protein family are examined. Additionally, updated bioinformatic analysis of predicted and characterized SMR protein family members was also conducted. Based on SMR sequence alignments and phylogenetic analysis of current members, we propose that this small multidrug resistance transporter family should be expanded into three subclasses: (i) the small multidrug pumps (SMP), (ii) suppressor of groEL mutation proteins (SUG), and a third group (iii) paired small multidrug resistance proteins (PSMR). The roles of these three SMR subclasses are examined, and the well-characterized members, such as Escherichia coli EmrE and SugE, are described in terms of their function and structural organization.     

Antiparallel dimers of the small multidrug resistance protein EmrE are more stable than parallel dimers

The bacterial multidrug transporter EmrE is a dual-topology membrane protein and as such is able to insert into the membrane in two opposite orientations. The functional form of EmrE is a homodimer; however, the relative orientation of the subunits in the dimer is under debate. Using EmrE variants with fixed, opposite orientations in the membrane, we now show that, although the proteins are able to form parallel dimers, an antiparallel organization of the subunits in the dimer is preferred. Blue-native PAGE analyses of intact oligomers and disulfide cross-linking demonstrate that in membranes, the proteins form parallel dimers only if no oppositely orientated partner is present. Co-expression of oppositely orientated proteins almost exclusively yields antiparallel dimers. Finally, parallel dimers can be disrupted and converted into antiparallel dimers by heating of detergent-solubilized protein. Importantly, in vivo function is correlated clearly to the presence of antiparallel dimers. Our results suggest that an antiparallel arrangement of the subunits in the dimer is more stable than a parallel organization and likely corresponds to the functional form of the protein.     

31P-CP-MAS NMR studies on TPP+ bound to the ion-coupled multidrug transport protein EmrE

The binding of tetraphenylphosphonium (TPP⁺) to EmrE, a membrane-bound, 110 residue Escherichia coli multidrug transport protein, has been observed by ³¹P cross-polarisation–magic-angle spinning nuclear magnetic resonance spectroscopy (CP–MAS NMR). EmrE has been reconstituted into dimyristoyl phosphatidylcholine bilayers. CP–MAS could selectively distinguish binding of TPP⁺ to EmrE in the fluid membrane. A population of bound ligand appears shifted 4 ppm to lower frequency compared to free ligand in solution, which suggests a rather direct and specific type of interaction of the ligand with the protein. This is also supported by the observed restricted motion of the bound ligand. The observation of another weakly bound substrate population arises from ligand binding to negatively charged residues in the protein loop regions.     

EmrE dimerization depends on membrane environment

The small multi-drug resistant (SMR) transporter EmrE functions as a homodimer. Although the small size of EmrE would seem to make it an ideal model system, it can also make it challenging to work with. As a result, a great deal of controversy has surrounded even such basic questions as the oligomeric state. Here we show that the purified protein is a homodimer in isotropic bicelles with a monomer–dimer equilibrium constant (K_MD^2D) of 0.002–0.009 mol% for both the substrate-free and substrate-bound states. Thus, the dimer is stabilized in bicelles relative to detergent micelles where the K_MD^2D is only 0.8–0.95 mol% (Butler et al. 2004). In dilauroylphosphatidylcholine (DLPC) liposomes K_MD^2D is 0.0005–0.0008 mol% based on Förster resonance energy transfer (FRET) measurements, slightly tighter than bicelles. These results emphasize the importance of the lipid membrane in influencing dimer affinity.     

Two-component bacterial multidrug transporter, EbrAB: Mutations making each component solely functional

EbrAB in Bacillus subtilis belongs to a novel small multidrug resistance (SMR) family of multidrug efflux pumps. EmrE in Escherichia coli, a representative of SMR, functions as a homo-oligomer in the membrane. On the other hand, EbrAB requires a hetero-oligomeric configuration consisting of two polypeptides, EbrA and EbrB. Although both polypeptides have a high sequence similarity, expression of either single polypeptide does not confer the multidrug-resistance. We performed mutation studies on EbrA and B to determine why EbrAB requires the hetero-oligomerization. Mutants of EbrA and B lacking both the hydrophilic loops and the C-terminus regions conferred the multidrug-resistance solely by each protein. This suggests that the hydrophilic loops and the C-terminus regions constrain them to their respective conformations upon the formation of the functional hetero-oligomer.     

A light-driven proton pump from Haloterrigena turkmenica: functional expression in Escherichia coli membrane and coupling with a H+ co-transporter

A gene encoding putative retinal protein was cloned from Haloterrigena turkmenica (JCM9743). The deduced amino acid sequence was most closely related to that of deltarhodopsin, which functions as a light-driven H+ pump and was identified in a novel strain Haloterrigena sp. arg-4 (K. Ihara, T. Uemura, I. Katagiri, T. Kitajima-Ihara, Y. Sugiyama, Y. Kimura, Y. Mukohata, Evolution of the archaeal rhodopsins: Evolution rate changes by gene duplication and functional differentiation, J. Mol. Biol. 285 (1999) 163-174. GenBank Accession No. AB009620). Thus, we called the present protein H. turkmenica deltarhodopsin (HtdR) in this report. Differing from the Halobacterium salinarum bacteriorhodopsin (bR), functional expression of HtdR was achieved in Escherichia coli membrane with a high yield of 10-15 mg protein/L culture. The photocycle of purified HtdR was similar to that of bR. The photo-induced electrogenic proton pumping activity of HtdR was verified. We co-expressed both HtdR and EmrE, a proton-coupled multi-drug efflux transporter in E. coli, and the cells successfully extruded ethidium, a substrate of EmrE, on illumination.     

Structural and functional comparison of hexahistidine tagged and untagged forms of small multidrug resistance protein,EmrE

EmrE is a member of the small multidrug resistance (SMR) protein family in Escherichia coli. EmrE confers resistance to a wide variety of quaternary cation compounds (QCCs) as an efflux transporter driven by proton motive force. The purification yield of most membrane proteins are challenging because of difficulties in over expressing, isolating and solubilizing them and the addition of an affinity tag often improves purification. The purpose of this study is to compare the structure and function of hexahistidinyl (His₆) tagged (T-EmrE) and untagged (UT-EmrE) versions of EmrE. In vivo QCC resistance assays determined that T-EmrE demonstrated reduced resistance as compared to UT-EmrE. We isolated EmrE using the two different purification methods, an organic solvent extraction method used to isolate UT-EmrE and nickel affinity chromatography of T-EmrE. All proteins were solubilized in the same buffered n-dodecyl-β-d-maltopyranoside (DDM) detergent and their conformations were examined in the presence/absence of different QCCs. In vitro analysis of protein multimerization using SDS-Tricine PAGE and dynamic light scattering analysis revealed that both proteins predominated as monomers, but the formation of dimers was more constant and uniform in T-EmrE compared to UT-EmrE. The aromatic residue conformations of both proteins indicate that T-EmrE form is more aqueous exposed than UT-EmrE, but UT-EmrE appeared to have a more dynamic environment surrounding its aromatic residues. Using fluorescence to obtain QCC ligand-binding curves indicated that the two forms had differences in dissociation constants (K_d) and maximum specific one-site binding (B_max) values for particular QCCs. In vitro analyses of both proteins demonstrated subtle but significant differences in multimerization and QCC binding. In vivo analysis indicates differences caused by the addition of the tag, we also observed differences in vitro that could be a result of the tag and/or the different purification methods.