The Q-loop of DrrA is involved in producing the closed conformation of the nucleotide binding domains and in transduction of conformational changes between DrrA and DrrB

Two-component systems regulate ABC transporters in antimicrobial peptide production, immunity and resistance

Bacteria offer resistance to a broad range of antibiotics by activating their export channels of ATP-binding cassette transporters. These transporters perform a central role in vital processes of self-immunity, antibiotic transport and resistance. The majority of ATP-binding cassette transporters are capable of detecting the presence of antibiotics in an external vicinity and are tightly regulated by two-component systems. The presence of an extracellular loop and an adjacent location of both the transporter and two-component system offers serious assistance to induce a quick and specific response against antibiotics. Both systems have demonstrated their ability of sensing such agents, however, the exact mechanism is not yet fully established. This review highlighted the three key functions of antibiotic resistance, transport and self-immunity of ATP-binding cassette transporters and an adjacent two-component regulatory system.

Conformational changes in a multidrug resistance ABC transporter DrrAB: Fluorescence-based approaches to study substrate binding

Bacterial multidrug transporter DrrAB exhibits overlapping substrate specificity with mammalian P-glycoprotein. DrrA hydrolyzes ATP, and the energy is transduced to carrier DrrB resulting in export of drugs. Previous studies suggested that DrrB contains a large and flexible drug-binding pocket made of aromatic residues contributed by several transmembrane helices with different drugs binding to both specific and shared residues in this pocket. However, direct binding of drugs to DrrAB or the mechanism of substrate-induced conformational changes between DrrA and DrrB has so far not been investigated. We used two fluorescence-based approaches to determine substrate binding to purified DrrAB. Our analysis shows that DrrB binds drugs with variable affinities and contains multiple drug binding sites. This work also provides evidence for two asymmetric nucleotide binding sites in DrrA with strikingly different binding affinities. Using targeted fluorescence labeling, we provide clear evidence of long-range conformational changes occurring between DrrA and DrrB. It is proposed that the transduction pathway from the nucleotide-binding DrrA subunit to the substrate binding DrrB subunit includes Q-loop and CREEM motifs in DrrA and EAA-like motif in DrrB. This study lays a solid groundwork for examining roles of various conserved regions of DrrA and DrrB in transduction of conformational changes.

Role of Aromatic and Negatively Charged Residues of DrrB in Multisubstrate Specificity Conferred by the DrrAB System of Streptomyces peucetius

Resistance to the anticancer antibiotics, doxorubicin and daunorubicin, in the producer organism Streptomyces peucetius is conferred by an ABC transporter made of two proteins, DrrA and DrrB, which together form a dedicated exporter for these two antibiotics. Surprisingly, however, the DrrAB system exhibits broad substrate specificity overlapping with well-studied multidrug resistance transporters, including P-glycoprotein. Therefore, it provides an excellent model for studying the molecular basis of multispecificity in a prototype efflux system with the potential to unravel the origin and evolution of multidrug resistance. It has been suggested that multispecificity in multidrug exporters may be generally determined by the number and location of aromatic residues. Strategically placed negatively charged residues may also be critical for binding of cationic lipophilic drugs. We selected 13 aromatic and four negatively charged residues on the basis of their location in and/or near the predicted drug-binding pocket of DrrB for analysis. Indeed, mutations of most tested residues drastically inhibited doxorubicin efflux. Interestingly, several mutants lost resistance to doxorubicin and verapamil simultaneously but retained resistance to Hoechst 33342 and/or ethidium bromide, suggesting the presence of overlapping as well as independent drug-binding sites in a common drug-binding pocket of DrrB. This study provides the first comprehensive analysis of residues involved in drug binding in a bacterial multidrug resistance protein of the ABC superfamily, and it shows strong similarity in the molecular mechanism of polyspecific drug recognition between DrrAB and Pgp. Altogether, we conclude that aromatic residue-based multidrug specificity is conserved across domains and over long evolutionary periods. The significance of these findings is discussed.

Characterization of a novel domain 'GATE' in the ABC protein DrrA and its role in drug efflux by the DrrAB complex

A novel domain, GATE (Glycine-loop And Transducer Element), is identified in the ABC protein DrrA. This domain shows sequence and structural conservation among close homologs of DrrA as well as distantly-related ABC proteins. Among the highly conserved residues in this domain are three glycines, G215, G221 and G231, of which G215 was found to be critical for stable expression of the DrrAB complex. Other conserved residues, including E201, G221, K227 and G231, were found to be critical for the catalytic and transport functions of the DrrAB transporter. Structural analysis of both the previously published crystal structure of the DrrA homolog MalK and the modeled structure of DrrA showed that G215 makes close contacts with residues in and around the Walker A motif, suggesting that these interactions may be critical for maintaining the integrity of the ATP binding pocket as well as the complex. It is also shown that G215A or K227R mutation diminishes some of the atomic interactions essential for ATP catalysis and overall transport function. Therefore, based on both the biochemical and structural analyses, it is proposed that the GATE domain, located outside of the previously identified ATP binding and hydrolysis motifs, is an additional element involved in ATP catalysis.

The DrrAB efflux system of Streptomyces peucetius is a multidrug transporter of broad substrate specificity

The soil bacterium Streptomyces peucetius produces two widely used anticancer antibiotics, doxorubicin and daunorubicin. Present within the biosynthesis gene cluster in S. peucetius is the drrAB operon, which codes for a dedicated ABC (ATP binding cassette)-type transporter for the export of these two closely related antibiotics. Because of its dedicated nature, the DrrAB system is believed to belong to the category of single-drug transporters. However, whether it also contains specificity for other known substrates of multidrug transporters has never been tested. In this study we demonstrate under both in vivo and in vitro conditions that the DrrAB system can transport not only doxorubicin but is also able to export two most commonly studied MDR substrates, Hoechst 33342 and ethidium bromide. Moreover, we demonstrate that many other substrates (including verapamil, vinblastine, and rifampicin) of the well studied multidrug transporters inhibit DrrAB-mediated Dox transport with high efficiency, indicating that they are also substrates of the DrrAB pump. Kinetic studies show that inhibition of doxorubicin transport by Hoechst 33342 and rifampicin occurs by a competitive mechanism, whereas verapamil inhibits transport by a non-competitive mechanism, thus suggesting the possibility of more than one drug binding site in the DrrAB system. This is the first in-depth study of a drug resistance system from a producer organism, and it shows that a dedicated efflux system like DrrAB contains specificity for multiple drugs. The significance of these findings in evolution of poly-specificity in drug resistance systems is discussed.

Glutamine residues in Q-loops of multidrug resistance protein MRP1 contribute to ATP binding via interaction with metal cofactor

Structural analyses of bacterial ATP-binding-cassette transporters revealed that the glutamine residue in Q-loop plays roles in interacting with: 1) a metal cofactor to participate in ATP binding; 2) a putative catalytic water molecule to participate in ATP hydrolysis; 3) other residues to transmit the conformational changes between nucleotide-binding-domains and transmembrane-domains, in ATP-dependent solute transport. We have mutated the glutamines at 713 and 1375 to asparagine, methionine or leucine to determine the functional roles of these residues in Q-loops of MRP1. All these single mutants significantly decreased Mg·ATP binding and increased the K(m) (Mg·ATP) and V(max) values in Mg·ATP-dependent leukotriene-C4 transport. However, the V(max) values of the double mutants Q713N/Q1375N, Q713M/Q1375M and Q713L/Q1375L were lower than that of wtMRP1, implying that the double mutants cannot efficiently bind Mg·ATP. Interestingly, MRP1 has higher affinity for Mn·ATP than for Mg·ATP and the Mn·ATP-dependent leukotriene-C4 transport activities of Q713N/Q1375N and Q713M/Q1375M are significantly higher than that of wtMRP1. All these results suggest that: 1) the glutamine residues in Q-loops contribute to ATP-binding via interaction with a metal cofactor; 2) it is most unlikely that these glutamine residues would play crucial roles in ATP hydrolysis and in transmitting the conformational changes between nucleotide-binding-domains and transmembrane-domains.

The extreme C terminus of the ABC protein DrrA contains unique motifs involved in function and assembly of the DrrAB complex

Two novel regulatory motifs, LDEVFL and C-terminal regulatory Glu (E)-rich motif (CREEM), are identified in the extreme C terminus of the ABC protein DrrA, which is involved in direct interaction with the N-terminal cytoplasmic tail of the membrane protein DrrB and in homodimerization of DrrA. Disulfide cross-linking analysis showed that the CREEM and the region immediately upstream of CREEM participate directly in forming an interaction interface with the N terminus of DrrB. A series of mutations created in the LDEVFL and CREEM motifs drastically affected overall function of the DrrAB transporter. Mutations in the LDEVFL motif also significantly impaired interaction between the C terminus of DrrA and the N terminus of DrrB as well as the ability of DrrA and DrrB to co-purify, therefore suggesting that the LDEVFL motif regulates CREEM-mediated interaction between DrrA and DrrB and plays a key role in biogenesis of the DrrAB complex. Modeling analysis indicated that the LDEVFL motif is critical for conformational integrity of the C-terminal domain of DrrA and confirmed that the C terminus of DrrA forms an independent domain. This is the first report which describes the presence of an assembly domain in an ABC protein and uncovers a novel mechanism whereby the ABC component facilitates the assembly of the membrane component. Homology sequence comparisons showed the presence of the LDEVFL and CREEM motifs in close prokaryotic and eukaryotic homologs of DrrA, suggesting that these motifs may play a similar role in other homologous drug and lipid export systems.

Functional significance of the E loop, a novel motif conserved in the lantibiotic immunity ATP-binding cassette transport systems

Lantibiotics are peptide-derived antibacterial substances produced by some Gram-positive bacteria and characterized by the presence of unusual amino acids, like lanthionines and dehydrated amino acids. Because lantibiotic producers may be attacked by self-produced lantibiotics, they express immunity proteins on the cytoplasmic membrane. An ATP-binding cassette (ABC) transport system mediated by the LanFEG protein complex is a major system in lantibiotic immunity. Multiple-sequence alignment analysis revealed that LanF proteins contain the E loop, a variant of the Q loop, which is a well-conserved motif in the nucleotide-binding domains (NBDs) of general ABC transporters. To elucidate E loop function, we introduced a mutation in the NukF protein, which is involved in the nukacin-ISK-1 immunity system. Amino acid replacement of glutamic acid in the E loop with glutamine (E85Q) resulted in slight decreases in the immunity level and transport activity. Additionally, the E85A mutation severely impaired the immunity level and transport activity. On the other hand, ATPase activities of purified E85Q and E85A mutants were almost similar to that of the wild type. These results suggested that the E loop found in ABC transporters involved in lantibiotic immunity plays a significant role in the function of these transporters, especially in the structural change of transmembrane domains.

Translational coupling controls expression and function of the DrrAB drug efflux pump

This study investigates the role of translational coupling in the expression and function of DrrA and DrrB proteins, which form an efflux pump for the export of anticancer drugs doxorubicin and daunorubicin in the producer organism Streptomyces peucetius. Interest in studying the role of translational coupling came from the initial observation that DrrA and DrrB proteins confer doxorubicin resistance only when they are expressed in cis. Because of the presence of overlapping stop and start codons in the intergenic region between drrA and drrB, it has been assumed that the translation of drrB is coupled to the translation of the upstream gene drrA even though direct evidence for coupling has been lacking. In this study, we show that the expression of drrB is indeed coupled to translation of drrA. We also show that the introduction of non-coding sequences between the stop codon of drrA and the start of drrB prevents formation of a functional complex, although both proteins are still produced at normal levels, thus suggesting that translational coupling also plays a crucial role in proper assembly. Interestingly, replacement of drrA with an unrelated gene was found to result in very high drrB expression, which becomes severely growth inhibitory. This indicates that an additional mechanism within drrA may optimize expression of drrB. Based on the observations reported here, it is proposed that the production and assembly of DrrA and DrrB are tightly linked. Furthermore, we propose that the key to assembly of the DrrAB complex lies in co-folding of the two proteins, which requires that the genes be maintained in cis in a translationally coupled manner.

Structure, function, and evolution of bacterial ATP-binding cassette systems

SUMMARY

ATP-binding cassette (ABC) systems are universally distributed among living organisms and function in many different aspects of bacterial physiology. ABC transporters are best known for their role in the import of essential nutrients and the export of toxic molecules, but they can also mediate the transport of many other physiological substrates. In a classical transport reaction, two highly conserved ATP-binding domains or subunits couple the binding/hydrolysis of ATP to the translocation of particular substrates across the membrane, through interactions with membrane-spanning domains of the transporter. Variations on this basic theme involve soluble ABC ATP-binding proteins that couple ATP hydrolysis to nontransport processes, such as DNA repair and gene expression regulation. Insights into the structure, function, and mechanism of action of bacterial ABC proteins are reported, based on phylogenetic comparisons as well as classic biochemical and genetic approaches. The availability of an increasing number of high-resolution structures has provided a valuable framework for interpretation of recent studies, and realistic models have been proposed to explain how these fascinating molecular machines use complex dynamic processes to fulfill their numerous biological functions. These advances are also important for elucidating the mechanism of action of eukaryotic ABC proteins, because functional defects in many of them are responsible for severe human inherited diseases.