Highly efficient over-production in E. coli of YvcC, a multidrug-like ATP-binding cassette transporter from Bacillus subtilis

ATP-binding cassette (ABC) transporters have often been refractory to over-expression. Using the C41(DE3) E. coli as a host strain, membrane vesicles highly enriched (>50%) in YvcC, a previously uncharacterized ABC transporter from Bacillus subtilis homologous to P-glycoprotein multidrug transporters, were obtained. The functionality of YvcC was assessed by its high vanadate-sensitive ATPase activity and its ability to transport a fluorescent drug, the Hoechst 33342.     

Optimized purification of a heterodimeric ABC transporter in a highly stable form amenable to 2-D crystallization

Optimized protocols for achieving high-yield expression, purification and reconstitution of membrane proteins are required to study their structure and function. We previously reported high-level expression in Escherichia coli of active BmrC and BmrD proteins from Bacillus subtilis, previously named YheI and YheH. These proteins are half-transporters which belong to the ABC (ATP-Binding Cassette) superfamily and associate in vivo to form a functional transporter able to efflux drugs. In this report, high-yield purification and functional reconstitution were achieved for the heterodimer BmrC/BmrD. In contrast to other detergents more efficient for solubilizing the transporter, dodecyl-ß-D-maltoside (DDM) maintained it in a drug-sensitive and vanadate-sensitive ATPase-competent state after purification by affinity chromatography. High amounts of pure proteins were obtained which were shown either by analytical ultracentrifugation or gel filtration to form a monodisperse heterodimer in solution, which was notably stable for more than one month at 4°C. Functional reconstitution using different lipid compositions induced an 8-fold increase of the ATPase activity (k _cat∼5 s⁻¹). We further validated that the quality of the purified BmrC/BmrD heterodimer is suitable for structural analyses, as its reconstitution at high protein densities led to the formation of 2-D crystals. Electron microscopy of negatively stained crystals allowed the calculation of a projection map at 20 Å resolution revealing that BmrC/BmrD might assemble into oligomers in a lipidic environment.     

ATP-binding cassette transporters in Escherichia coli

ATP-binding cassette (ABC) transporters are integral membrane proteins that actively transport molecules across cell membranes. In Escherichia coli they consist primarily of import systems that involve in addition to the ABC transporter itself a substrate binding protein and outer membrane receptors or porins, and a number of transporters with varied functions. Recent crystal structures of a number of ATPase domains, substrate binding proteins, and full-length transporters have given new insight in the molecular basis of transport. Bioinformatics approaches allow an approximate identification of all ABC transporters in E. coli and their relation to other known transporters. Computational approaches involving modeling and simulation are beginning to yield insight into the dynamics of the transporters. We summarize the function of the known ABC transporters in E. coli and mechanistic insights from structural and computational studies.     

The putative ABC transporter YheH/YheI is involved in the signalling pathway that activates KinA during sporulation initiation

The primary kinases that control the supply of phosphate to the phosphorelay are KinA and KinB, although it is not yet known what type of signal(s) activates these kinases. Our systematic study of protein-protein interactions using yeast two-hybrid analysis revealed an interaction between KinA and YheH. YheH with the preceding gene product YheI is categorized as an ABC transporter. Overexpression of yheH/yheI in the kinB mutant resulted in a reduced sporulation efficiency. Moreover, reporter assays using Spo0A approximately P dependent promoters revealed that the deficiency in sporulation is probably due to a failure in the activation of Spo0A. Our results further suggest that the N-terminal region of YheH may play an important role in sensing the signal to be delivered to the C-terminally bound KinA.     

ABC transporters do not contribute to extracellular translocation of hyaluronan in human breast cancer in vitro

Extracellular translocation of the polysaccharide, hyaluronan (HA) has been thought to be mediated via its transmembrane synthetic enzyme, hyaluronan synthase (HAS) but recent studies have indicated that the ATP-Binding-Cassette (ABC) transporter, MRP5 contributes to this process. Liberated and cell-associated HA contributes to breast cancer initiation and progression, and therefore the inhibition of ABC transporters and consequently HA transport could provide therapeutic benefit in the treatment of breast cancer. Quantitation of ABC transporter genes, MRP1-5, BCRP and MDR1 were determined in six breast cancer cell lines selected for their differential HA synthetic rates. Low endogenous expression of transporters was detected but no significant correlation existed between ABC transporter and HAS gene expression or HA production. A dose titration of up to ten times the IC₅₀ of ten small molecule ABC transporter inhibitors did not significantly inhibit HA export in four breast cancer cell lines. Unlike the changes observed after inhibition of HA synthesis by the characterised inhibitor 4-MU, inhibition of ABC transporters did not alter the cell morphology, HA glycocalyx or the intracellular quantity or localisation of HA. Collectively these data indicate that ABC transporters do not contribute to the extracellular transport of HA in breast cancer, supporting a role for the hyaluronan synthase in translocation.     

Fructose uptake in Bifidobacterium longum NCC2705 is mediated by an ATP-binding cassette transporter

Recently, a putative ATP-binding cassette (ABC) transport system was identified in Bifidobacterium longum NCC2705 that is highly up-regulated during growth on fructose as the sole carbon source. Cloning and expression of the corresponding ORFs (bl0033-0036) result in efficient fructose uptake by bacteria. Sequence analysis reveals high similarity to typical ABC transport systems and suggests that these genes are organized as an operon. Expression of FruE is induced by fructose, ribose, or xylose and is able to bind these sugars with fructose as the preferred substrate. Our data suggest that BL0033-0036 constitute a high affinity fructose-specific ABC transporter of B. longum NCC2705. We thus suggest to rename the coding genes to fruEKFG and the corresponding proteins to FruE (sugar-binding protein), FruK (ATPase subunit), FruF, and FruG (membrane permeases). Furthermore, protein-protein interactions between the components of the transporter complex were determined by GST pulldown and Western blot analysis. This revealed interactions between the membrane subunits FruF and FruG with FruE, which in vivo is located on the external side of the membrane, and with the cytoplasmatic ATPase FruK. This is in line with the proposed model for bacterial ABC sugar transporters.     

Overexpression, purification, and functional characterization of ATP-binding cassette transporters in the yeast, Pichia pastoris

The ATP-binding cassette (ABC) transporter superfamily is a large gene family that has been highly conserved throughout evolution. The physiological importance of these membrane transporters is highlighted by the large variety of substrates they transport, and by the observation that mutations in many of them cause heritable diseases in human. Likewise, overexpression of certain ABC transporters, such as P-glycoprotein and members of the multidrug resistance associated protein (MRP) family, is associated with multidrug resistance in various cells and organisms. Understanding the structure and molecular mechanisms of transport of the ABC transporters in normal tissues and their possibly altered function in human diseases requires large amounts of purified and active proteins. For this, efficient expression systems are needed. The methylotrophic yeast Pichia pastoris has proven to be an efficient and inexpensive experimental model for high-level expression of many proteins, including ABC transporters. In the present review, we will summarize recent advances on the use of this system for the expression, purification, and functional characterization of P-glycoprotein and two members of the MRP subfamily.     

A Multitask ATPase Serving Different ABC-Type Sugar Importers in Bacillus subtilis

Bacillus subtilis is able to utilize arabinopolysaccharides derived from plant biomass. Here, by combining genetic and physiological analyses we characterize the AraNPQ importer and identify primary and secondary transporters of B. subtilis involved in the uptake of arabinosaccharides. We show that the ABC-type importer AraNPQ is involved in the uptake of α-1,5-arabinooligosaccharides, at least up to four l-arabinosyl units. Although this system is the key transporter for α-1,5-arabinotriose and α-1,5-arabinotetraose, the results indicate that α-1,5-arabinobiose also is translocated by the secondary transporter AraE. This broad-specificity proton symporter is the major transporter for arabinose and also is accountable for the uptake of xylose and galactose. In addition, MsmX is shown to be the ATPase that energizes the incomplete AraNPQ importer. Furthermore, the results suggest the existence of at least one more unidentified MsmX-dependent ABC importer responsible for the uptake of nonlinear α-1,2- and α-1,3-arabinooligosaccharides. This study assigns MsmX as a multipurpose B. subtilis ATPase required to energize different saccharide transporters, the arabinooligosaccharide-specific AraNPQ-MsmX system, a putative MsmX-dependent ABC transporter specific for nonlinear arabinooligosaccharides, and the previously characterized maltodextrin-specific MdxEFG-MsmX system.Transport across biological membranes is a fundamental process for life and is accomplished by channels, primary and secondary transporters, and group translocators (19). ATP-binding cassette (ABC) transporters constitute one of the largest families of translocation facilitators and are distributed across all domains of life. Although they are involved in a variety of distinct processes, such as nutrient uptake, resistance to antibiotics and other drugs, lipid trafficking, cell division, sporulation, immune response, and pathogenesis, all ABC transporters, regardless of the polarity of transport (exporters and importers), share a structure and a general mechanism (reviewed in references 3 and 8). Their organization comprises two transmembrane domains (TMDs) coupled to two cytosolic nucleotide-binding domains (NBDs), or ATP-binding cassettes, responsible for ATP binding and hydrolysis-driven conformational changes.The majority of the eukaryotic ABC transporters are exporters facilitating translocation from the cytoplasm. In contrast, prokaryotic ABC permeases are involved mainly in the import of nutrients, vitamins, and trace elements (3, 6, 8). Canonical bacterial ABC importers are dependent predominantly on high-affinity substrate-binding proteins (BPDs) that capture the substrate and deliver it to the transporter. The canonical maltose/maltodextrin importer MalEFGK₂ of Escherichia coli/Salmonella enterica serovar Typhimurium (5) is one of the most-characterized members of this superfamily of translocation facilitators, serving as model for ABC importers in general (14, 15). In Gram-negative bacteria, BPDs are proteins located in the periplasmic space between the inner and outer membranes. In Gram-positive organisms, which are devoid of this type of cellular compartment, BPDs often are lipoproteins that are anchored to the extracellular side of the cytoplasmic membrane via its N-terminal domain (3 and 8 and references therein).In nature, the major source of carbohydrates for microorganisms to utilize is plant biomass. Thus, in their natural habitat, such as soil, aquatic environments, or animal digestive tracts, bacteria secrete a vast number of polysaccharolytic enzymes for the degradation of plant-derived polysaccharides. The resulting mono-, di-, and oligosaccharides enter the cell mainly through specific ABC transporters. The number of well-characterized ABC transporters devoted to the uptake of products resulting from the degradation of hemicellulose is very scarce (6), and in Gram-positive organisms only two systems, BxlEFG of Streptomyces thermoviolaceus (31) and XynEFG (29) of Geobacillus staerothermophilus, both dedicated to the transport of xylodextrins, have been characterized in detail.An in silico analysis of the Bacillus subtilis genome estimated the existence of at least 78 ABC transporters based on the identification of 86 NBDs in 78 proteins, 103 MSD proteins, and 37 BPD proteins, which account for about 5% of the protein-coding genes of this model organism (17). At least 10 ABC systems are predicted to be involved in the uptake of sugars (20). One of these ABC importers, AraNPQ, is clustered together with genes encoding enzymes involved in arabinose catabolism and the degradation of arabinooligosaccharides in a large operon, araABDLMNPQ-abfA (23). AraN is the BPD, and AraP and AraQ are the TMDs. This transporter, which lacks the NBD protein partner, was proposed to be involved in the uptake of arabinose oligomers mainly by genomic context and in silico analysis (10, 11, 23).Here, by combining genetic and physiological analyses, we characterize the AraNPQ importer and identify primary and secondary transporters of B. subtilis involved in the uptake of arabinosaccharides. Furthermore, this study assigns the role of MsmX as a multipurpose B. subtilis ATPase required to energize different saccharide transporters.     

Bacillus licheniformis bacitracin-resistance ABC transporter: relationship to mammalian multidrug resistance

The nucleotide sequence of the Bacillus licheniformis bacitracin-resistance locus was determined. The presence of three open reading frames, bcrA, bcrB and bcrC, was revealed. The BcrA protein shares a high degree of homology with the hydrophilic ATP-binding components of the ABC family of transport proteins. The bcrB and bcrC genes were found to encode hydro-phobic proteins, which may function as membrane components of the permease. Apart from Bacillus subtilis, these genes also confer resistance upon the Gram-negative Escherichia coli. The presumed function of the Bcr transporter is to remove the bacitracin molecule from its membrane target. In addition to the homology of the nucleotide-binding sites, BcrA protein and mammalian multidrug transporter or P-glycoprotein share collateral detergent sensitivity of resistant cells and possibly the mode of Bcr transport activity within the membrane. The advantage of the resistance phenotype of the Bcr transporter was used to construct deletions within the nucleotide-binding protein to determine the Importance of various regions in transport.     

Two closely related ABC transporters in Streptococcus mutans are involved in disaccharide and/or oligosaccharide uptake

Streptococcus mutans has a large number of transporters apparently involved in the uptake of carbohydrates. At least two of these, the multiple sugar metabolism transporter, MsmEFGK, and the previously uncharacterized MalXFGK, are members of the ATP-binding cassette (ABC) superfamily. Mutation analysis revealed that the MsmEFGK and MalXFGK transporters are principally involved in the uptake of distinct disaccharides and/or oligosaccharides. Furthermore, the data also indicated an unusual protein interaction between the components of these two related transporters. Strains lacking msmE (which encodes a solute binding protein) can no longer utilize raffinose or stachyose but grow normally on maltodextrins in the absence of MalT, a previously characterized EII^mal phosphotransferase system component. In contrast, a mutant of malX (which encodes a solute binding protein) cannot utilize maltodextrins but grows normally on raffinose or stachyose. Radioactive uptake assays confirmed that MalX, but not MsmE, is required for uptake of [U-¹⁴C]maltotriose and that MalXFGK is principally involved in the uptake of maltodextrins with as many as 7 glucose units. Surprisingly, inactivation of the corresponding ATPase components did not result in an equivalent abolition of growth: the malK mutant can grow on maltotetraose as a sole carbon source, and the msmK mutant can utilize raffinose. We propose that the ATPase domains of these ABC transporters can interact with either their own or the alternative transporter complex. Such unexpected interaction of ATPase subunits with distinct membrane components to form complete multiple ABC transporters may be widespread in bacteria.     

Mdr65 decreases toxicity of multiple insecticides in Drosophila melanogaster

ABC transporters are ubiquitous membrane-bound proteins, present in both prokaryotes and eukaryotes. The major function of eukaryotic ABC transporters is to mediate the efflux of a variety of substrates (including xenobiotics) out of cells. ABC transporters have been widely investigated in humans, particularly for their involvement in multidrug resistance (MDR). Considerably less is known about their roles in transport and/or excretion in insects. ABC transporters are only known to function as exporters in insects. Drosophila melanogaster has 56 ABC transporter genes, including eight which are phylogenetically most similar to the human Mdr genes (ABCB1 clade). We investigated the role of ABC transporters in the ABCB1 clade in modulating the susceptibility to insecticides. We took advantage of the GAL4/UAS system in D. melanogaster to knockdown the expression levels of Mdr65, Mdr50, Mdr49 and ABCB6 using transgenic UAS-RNAi lines and conditional driver lines. The most notable effects were increased sensitivities to nine different insecticides by silencing of Mdr65. Furthermore, a null mutation of Mdr65 decreased the malathion, malaoxon and fipronil LC₅₀ values by a factor of 1.9, 2.1 and 3.9, respectively. Altogether, this data demonstrates the critical role of ABC transporters, particularly Mdr65, in altering the toxicity of specific, structurally diverse, insecticides in D. melanogaster.     

A Sensory Complex Consisting of an ATP-binding Cassette Transporter and a Two-component Regulatory System Controls Bacitracin Resistance in Bacillus subtilis

Resistance against antimicrobial peptides in many Firmicutes bacteria is mediated by detoxification systems that are composed of a two-component regulatory system (TCS) and an ATP-binding cassette (ABC) transporter. The histidine kinases of these systems depend entirely on the transporter for sensing of antimicrobial peptides, suggesting a novel mode of signal transduction where the transporter constitutes the actual sensor. The aim of this study was to investigate the molecular mechanisms of this unusual signaling pathway in more detail, using the bacitracin resistance system BceRS-BceAB of Bacillus subtilis as an example. To analyze the proposed communication between TCS and the ABC transporter, we characterized their interactions by bacterial two-hybrid analyses and could show that the permease BceB and the histidine kinase BceS interact directly. In vitro pulldown assays confirmed this interaction, which was found to be independent of bacitracin. Because it was unknown whether BceAB-type transporters could detect their substrate peptides directly or instead recognized the peptide-target complex in the cell envelope, we next analyzed substrate binding by the transport permease, BceB. Direct and specific binding of bacitracin by BceB was demonstrated by surface plasmon resonance spectroscopy. Finally, in vitro signal transduction assays indicated that complex formation with the transporter influenced the autophosphorylation activity of the histidine kinase. Taken together, our findings clearly show the existence of a sensory complex composed of TCS and ABC transporters and provide the first functional insights into the mechanisms of stimulus perception, signal transduction, and antimicrobial resistance employed by Bce-like detoxification systems.     

Contributions of Aspergillus fumigatus ATP-Binding Cassette Transporter Proteins to Drug Resistance and Virulence

In yeast cells such as those of Saccharomyces cerevisiae, expression of ATP-binding cassette (ABC) transporter proteins has been found to be increased and correlates with a concomitant elevation in azole drug resistance. In this study, we investigated the roles of two Aspergillus fumigatus proteins that share high sequence similarity with S. cerevisiae Pdr5, an ABC transporter protein that is commonly overproduced in azole-resistant isolates in this yeast. The two A. fumigatus genes encoding the ABC transporters sharing the highest sequence similarity to S. cerevisiae Pdr5 are called abcA and abcB here. We constructed deletion alleles of these two different ABC transporter-encoding genes in three different strains of A. fumigatus. Loss of abcB invariably elicited increased azole susceptibility, while abcA disruption alleles had variable phenotypes. Specific antibodies were raised to both AbcA and AbcB proteins. These antisera allowed detection of AbcB in wild-type cells, while AbcA could be visualized only when overproduced from the hspA promoter in A. fumigatus. Overproduction of AbcA also yielded increased azole resistance. Green fluorescent protein fusions were used to provide evidence that both AbcA and AbcB are localized to the plasma membrane in A. fumigatus. Promoter fusions to firefly luciferase suggested that expression of both ABC transporter-encoding genes is inducible by azole challenge. Virulence assays implicated AbcB as a possible factor required for normal pathogenesis. This work provides important new insights into the physiological roles of ABC transporters in this major fungal pathogen.     

Stress responses ofBacillus subtilis to high osmolarity environments: Uptake and synthesis of osmoprotectants

A decrease in the water content of the soil imposes a considerable stress on the voil-living bacteriumBacillus subtilis: water exits from the cells, resulting in decreased turgor and cessation of growth. Under these adverse circumstances,B. subtilis actively modulates the osmolarity of its cytoplasm to maintain turgor within acceptable boundaries. A rapid uptake of potassium ions via turgor-responsive transport systems is the primary stress response to a sudden increase in the external osmolarity. This is followed by the massive accumulation of the so-called compatible solutes, i.e., organic osmolytes that are highly congruous with cellular functions and hence can be accumulated by bacterial cells up to molar concentrations. Initially, the compatible solute proline is accumulated viade novo synthesis, butB. subtilis can also acquire proline from the environment by an osmoregulated transport system, OpuE. The preferred compatible solute ofB. subtilis is the potent osmoprotectant glycine betaine. This trimethylammonium compound can be taken up by the cell through three high-affinity transport systems: the multicomponent ABC transporters OpuA and OpuC, and the single-component transporter OpuD. The OpuC systems also mediates the accumulation of a variety of naturally occurring betaines, each of which can confer a considerable degree of osmotic tolerance. In addition to the uptake of glycine betaine from the environment,B. subtilis can also synthesize this osmoprotectant but it requires exogenously provided choline as its precursor. Two evolutionarily closely related ABC transport systems, OpuB and OpuC, mediate the uptake of choline which is then converted by the GbsA and GbsB enzymes in a two-step oxidation process into glycine betaine. Our data show that the intracellular accumulation of osmoprotectants is of central importance for the cellular defence ofB. subtilis against high osmolarity stress.     

ABC-type transporters and cuticle assembly: Linking function to polarity in epidermis cells

The aerial organs of plants are covered with a cuticle, a continuous layer overlaying the outermost cell walls of the epidermis. The cuticle is composed of two major classes of the lipid biopolymers: cutin and waxes, collectively termed cuticular lipids. Biosynthesis and transport of cuticular lipids occur predominantly in the epidermis cells. In the transport pathway, cuticular lipids are exported from their site of biosynthesis in the ER/plastid to the extracellular space through the plasma membrane and cell wall. Growing evidence suggests that ATP-binding cassette (ABC) transporters are implicated in transport of cuticular lipids across the plasma membrane of epidermal cells. The Arabidopsis ABC-type transporter protein CER5 (WBC12) was reported to act as a wax monomers transporter. In recent works, our group and others showed that a CER5-related protein, DESPERADO (DSO/WBC11), is required for cutin and wax monomers transport through the plasma membrane of Arabidopsis epidermis cells. Unlike the cer5 mutant, DSO loss-of-function had a profound effect on plant growth and development, particularly dwarfism, postgenital organ fusions, and altered epidermal cell differentiation. The partially overlapping function of CER5 and DSO and the fact that these proteins are half-size ABC transporters suggest that they might form a hetero-dimeric complex while transporting wax components. An intriguing observation was the polar localization of DSO in the distal part of epidermis cells. This polar expression might be explained by DSO localization within lipid rafts, specific plasma membrane microdomains which are associated with polar protein expression. In this review we suggest possible mechanisms for cuticular lipids transport and a link between DSO function and polar expression. Furthermore, we also discuss the subsequent transport of cuticular constituents through the hydrophobic cell wall and the possible involvement of lipid transfer proteins in this process.Key words: ABC transporter, cuticular lipids, polar expression, plasma membrane, epidermis