Fact-checked by Grok 2 weeks ago

Efflux pump

An efflux pump is a transmembrane transport protein embedded in the cell membrane of microorganisms, including bacteria and fungi, that actively extrudes a wide range of toxic substances—such as antibiotics, chemotherapeutic agents, and environmental toxins—from the cytoplasm or periplasm to the external environment, thereby maintaining cellular homeostasis and conferring resistance to antimicrobial compounds. These pumps utilize energy sources like the proton motive force (PMF) or ATP hydrolysis to drive the export process, and their overexpression or mutation can lead to multidrug resistance (MDR), a major challenge in treating bacterial infections. Efflux pumps are ubiquitous in prokaryotes, with notable examples in pathogens like Escherichia coli and Pseudomonas aeruginosa, where they contribute to intrinsic resistance by reducing intracellular drug concentrations below lethal levels. Efflux pumps are classified into five major superfamilies based on their protein architecture, substrate specificity, and energy coupling mechanisms: the transporters, which use ; the major facilitator superfamily (MFS), driven by PMF; the family, prominent in for broad-spectrum export; the small multidrug resistance (SMR) family; and the multidrug and toxic compound extrusion (MATE) family. In , many pumps form tripartite complexes, such as AcrAB-TolC in E. coli, consisting of an inner membrane transporter (AcrB), a periplasmic adaptor (AcrA), and an outer membrane channel (TolC), enabling substrate passage across both membranes. These systems recognize structurally diverse substrates through flexible binding sites, allowing cooperative or redundant efflux pathways that enhance bacterial survival under stress. Beyond , efflux pumps play roles in bacterial , including the export of metabolic byproducts, signals, and factors, which support formation and host . Their expression is tightly regulated by environmental cues, such as exposure or changes, through transcriptional regulators (e.g., MarR or AcrR) and two-component systems, often leading to upregulated activity in response to sublethal drug concentrations. As MDR pathogens increasingly rely on efflux-mediated , research focuses on pump inhibitors (e.g., phenylalanine-arginine β-naphthylamide) to restore efficacy, highlighting their potential as therapeutic targets.

Overview

Definition and Mechanism

Efflux pumps are proteins that actively expel toxic substances, agents, drugs, or metabolic byproducts from the or to the extracellular environment, thereby preventing their intracellular accumulation and maintaining cellular . These proteins function as a primary mechanism in microorganisms, enabling the extrusion of a wide range of substrates to regulate the internal milieu. The general mechanism of efflux pumps involves energy-dependent transport of substrates against their concentration gradients, powered primarily by in primary active transporters or by secondary energy sources such as the proton motive force (PMF) or sodium ion gradients. This process follows the alternating access model, in which the pump undergoes conformational changes to alternate between inward-facing and outward-facing states, allowing binding from the intracellular side, translocation across the , and release to the exterior. For instance, in proton-driven systems, the influx of protons through the pump provides the energy to drive antiport of substrates outward. Efflux pumps typically consist of transmembrane domains that form substrate-binding sites and facilitate translocation through the , coupled with energy-coupling modules such as nucleotide-binding domains (NBDs) in ATP-dependent pumps like those in the ABC family, where powers the conformational shifts. These core elements enable the recognition and export of diverse substrates, often with broad specificity. Efflux pumps exhibit evolutionary conservation across the domains of life, including , , and eukaryotes, indicating their origin from ancient membrane transporter systems that predated the emergence of modern pressures. Phylogenetic analyses suggest that multidrug efflux capabilities evolved independently within major transporter superfamilies, underscoring their fundamental role in cellular physiology.

Classification and Families

Efflux pumps are classified primarily based on phylogenetic relationships, structural features, energy coupling mechanisms, and substrate specificity, which can range from broad-spectrum multidrug transport to narrow substrate recognition. Bioinformatics analyses, such as those in the Transporter Classification Database (TCDB), have identified over 1,500 transporter families overall, with efflux pumps distributed across several superfamilies that encompass numerous subfamilies tailored to specific organisms and substrates. In , the major superfamilies include the , major facilitator superfamily (MFS), resistance-nodulation-division (), multidrug and toxic compound extrusion (MATE), and small multidrug resistance (SMR) families, each distinguished by their energy sources and architectural elements. The superfamily relies on for energy, featuring proteins with 12 transmembrane segments and nucleotide-binding domains; examples include the MacAB-TolC tripartite system in . The MFS uses the proton motive force (PMF), typically comprising 12-14 transmembrane helices in a single-component structure, as seen in the pump of . RND pumps, prominent in , also harness PMF and form tripartite complexes spanning the inner membrane, , and outer membrane; a key example is AcrAB-TolC in , which exports a wide array of antibiotics and dyes. The MATE family couples sodium or proton gradients to transport, with 12 transmembrane helices, exemplified by in , which effluxes fluoroquinolones and cationic compounds. SMR pumps are small homotetramers using PMF, containing four transmembrane helices per subunit, such as EmrE in E. coli that expels quaternary cationics. In eukaryotes, efflux pumps are predominantly from the ABC superfamily, which shares the ATP-dependent mechanism with bacterial counterparts but exhibits greater diversity in subfamilies; humans encode 48 ABC genes across seven subfamilies (A-G), with ABCB1 (P-glycoprotein or MDR1) serving as a prominent example that confers multidrug resistance by expelling chemotherapeutic agents from cells in tissues like the liver and kidney. MFS homologs are also present, particularly in plants and fungi, where they utilize PMF for substrate extrusion; for instance, CaMdr1p in the fungus Candida albicans facilitates azole antifungal efflux. Classification in eukaryotes emphasizes sequence homology and functional roles in cellular homeostasis and xenobiotic detoxification, often overlapping with bacterial systems in evolutionary terms.

Bacterial Efflux Pumps

Structure

Bacterial efflux pumps are membrane proteins that typically consist of 12-14 transmembrane α-helices per , forming a bundle that spans the inner , and they often assemble into dimers, trimers, or higher-order oligomers to facilitate export. The ABC family features a modular with four distinct domains: two transmembrane domains, each comprising six α-helices that form a translocation pathway, and two cytoplasmic nucleotide-binding domains responsible for ATP and . These pumps typically function as dimers or heterodimers, with the transmembrane domains adopting an inward-facing conformation in the apo state. In contrast, the MFS family consists of monomeric proteins with 12-14 transmembrane α-helices organized into two bundles of six helices each, connected by a long intracellular loop, enabling a where the bundles alternately tilt to between cytoplasmic and periplasmic sides. family pumps form elaborate assemblies spanning both inner and outer , comprising an inner membrane trimeric pump (e.g., AcrB with 12 transmembrane α-helices per ), a periplasmic adaptor protein (e.g., AcrA hexamer), and an outer membrane β-barrel channel (e.g., TolC trimer), which together create a continuous conduit. MATE family members are monomeric with 12 transmembrane α-helices divided into a core scaffold domain (helices 1-4 and 10-12) and a substrate-binding domain (helices 5-9), allowing vertical translocation of substrates across the via an . The SMR family includes the smallest pumps, with each subunit featuring only four short transmembrane α-helices and brief hydrophilic loops, assembling into dimers where the subunits form a compact bundle with a central pore for passage. Substrate sites across these families are typically hydrophobic pockets located within the transmembrane regions, capable of accommodating diverse amphipathic molecules through flexible aromatic residues; these sites often exhibit , where substrate induces conformational changes or modulates interactions with regulatory proteins. Key structural insights have been gained from high-resolution techniques, including the 3.0 Å of the ABC pump Sav1866 from in 2006, which revealed the alternating access mechanism of its domains, and subsequent cryo-EM structures of the RND pump AcrAB-TolC from starting in the 2010s, resolving the tripartite assembly at near-atomic . Additionally, recent AlphaFold2 predictions since 2021 have modeled uncharacterized bacterial efflux pumps, aiding in the of conserved motifs and potential sites in understudied variants.

Function and Energy Sources

Bacterial efflux pumps facilitate the export of a wide array of substrates from the or inner to the through a dynamic process. Substrate recognition occurs via polyspecific binding sites that accommodate diverse molecules, such as antibiotics, dyes, and solvents, primarily through hydrophobic and aromatic interactions with residues in the pump's pockets. For instance, in RND pumps like AcrB, substrates bind to distal and proximal pockets lined with residues, triggering a series of conformational changes that alternate between inward- and outward-facing states to drive export. This polyspecificity arises from flexible, spacious regions that do not require high sequence similarity among substrates, enabling recognition of structurally unrelated compounds via non-specific van der Waals forces and π-π stacking. The transport in these pumps involves substrate-induced conformational shifts that couple to translocation. In MFS pumps, such as EmrD, a rocker-switch alternates the orientation of transmembrane helices, opening the alternately to the and . RND systems employ a rotating with three protomers in (loose), (tight), and extrusion (open) conformations, creating a peristaltic wave that propels substrates through the assembly toward the outer membrane channel. MATE pumps similarly undergo alternating , while ABC transporters use nucleotide-binding domain (NBD) dimerization to power a full of substrate and release. Energy for transport is derived from distinct sources across efflux pump families, ensuring efficient antiport or active pumping against concentration gradients. ABC family pumps, such as MacAB, harness ATP hydrolysis: ATP binding to the NBDs induces their closure and dimerization, which transmits mechanical force through coupling helices to the transmembrane domains, flipping the substrate from inward- to outward-facing orientation; subsequent hydrolysis and ADP/Pi release resets the pump for the next cycle. In contrast, MFS, RND, and MATE families primarily utilize the proton motive force (PMF) or sodium gradient for secondary active transport. For RND pumps like AcrB-TolC, proton translocation through dedicated pathways in the transmembrane domain drives conformational cycling, with a typical stoichiometry of 1-2 H⁺ imported per substrate molecule exported, optimizing energy efficiency under varying pH conditions. MFS pumps, exemplified by MdfA, exchange 1-2 H⁺ or Na⁺ for each substrate via similar antiport mechanisms, while MATE pumps like NorM often couple Na⁺ influx (or H⁺ in some variants) to drug efflux, with stoichiometries around 2 Na⁺ per substrate. Expression of bacterial efflux pumps is tightly regulated to balance energy costs and cellular needs, primarily through transcriptional control mechanisms responsive to environmental cues. Local repressor proteins, such as MarR in Escherichia coli, bind operator regions of operons like marRAB to inhibit transcription of AcrAB under basal conditions; substrates like salicylate or antibiotics bind MarR, inducing conformational changes that release it from DNA and derepress pump expression. Global regulation involves two-component systems that sense stress signals, such as the BaeSR system in E. coli, where the BaeS sensor kinase detects membrane perturbations or bile salts, phosphorylating the BaeR response regulator to activate transcription of pumps like MdtABC. Similar systems, including AdeRS in Acinetobacter baumannii and EvgAS in E. coli, respond to pH shifts, oxidative stress, or antimicrobial presence, ensuring inducible upregulation during environmental challenges. Beyond contributing to , bacterial efflux pumps serve essential physiological roles in maintaining cellular and . They export bile salts in the , as seen with AcrAB-TolC in E. coli and Salmonella typhimurium, protecting enteric from host-derived detergents during colonization. Additionally, these pumps eliminate metabolic waste products, such as in E. coli via MdtEF-TolC, preventing toxic accumulation and supporting under conditions. In non-pathogenic contexts, efflux systems like MexAB-OprM in export solvents and endogenous toxins, aiding survival in diverse ecological niches such as or .

Role in Antimicrobial Resistance

Efflux pumps in contribute to by actively expelling antibiotics from the cell, thereby reducing intracellular concentrations to sublethal levels that prevent effective killing. This mechanism enables both intrinsic resistance, through constitutive low-level expression providing protection, and inducible resistance, where environmental cues or genetic changes trigger upregulated efflux activity. In , tripartite efflux systems like those from the resistance-nodulation-division () family span the inner membrane, , and outer membrane to efficiently export diverse substrates. A prominent example is the AcrAB-TolC pump in and other , which expels fluoroquinolones and tetracyclines, conferring multidrug resistance by lowering minimum inhibitory concentrations (MICs) for these agents. Similarly, the MexAB-OprM pump in plays a key role in resistance, including to penicillins, cephalosporins, and like , by extruding these drugs from the periplasmic space and reducing their efficacy in clinical isolates. Post-2020 studies have further linked pumps, such as AcrAB-TolC, to resistance in , where efflux synergizes with production to elevate MICs against agents like imipenem. Overexpression of efflux pumps amplifies ; for instance, in the transcriptional MarR lead to derepression and increased AcrAB-TolC expression in E. coli, resulting in 4- to 8-fold elevations for multiple antibiotics. In P. aeruginosa, in the MexR regulator, such as L57Q or R83C, similarly drive MexAB-OprM overexpression, enhancing to novel / inhibitor combinations like ceftazidime-avibactam. Additionally, plasmid-mediated dissemination of efflux pump genes facilitates rapid spread of determinants across bacterial populations. From an evolutionary perspective, (HGT) accelerates the dissemination of efflux pump genes, as seen with plasmid-borne variants like tmexCD-toprJ in , enabling interspecies resistance exchange. In biofilms, efflux pumps not only persist by expelling but also support community resilience; for example, MexAB-OprM in P. aeruginosa biofilms exports signaling molecules like phenazines, promoting formation and tolerance to sub-MIC antibiotic levels. This interplay fosters persistent infections where pumps aid bacterial survival and HGT hotspots. These mechanisms underpin resistance in WHO critical priority pathogens, including carbapenem-resistant Enterobacteriaceae (E. coli, Klebsiella pneumoniae) and multidrug-resistant P. aeruginosa, complicating treatment of nosocomial infections and contributing to over 1.27 million annual antimicrobial resistance-attributable deaths globally in 2019. The 2025 WHO GLASS report indicates that around one in six bacterial infections worldwide involves resistant strains, with efflux pumps contributing to resistance in key Gram-negative pathogens like E. coli and P. aeruginosa.

Eukaryotic Efflux Pumps

Structure and Diversity

Eukaryotic efflux pumps, particularly those belonging to the ATP-binding cassette () superfamily, exhibit more complex architectures than their bacterial counterparts, often featuring larger molecular sizes and additional post-translational modifications. A typical full-length eukaryotic ABC exporter, such as human (P-gp or MDR1/ABCB1), has a molecular weight of approximately 170 kDa and consists of two homologous halves, each comprising six transmembrane (TM) helices in the (TMD) and a nucleotide-binding domain (NBD), for a total of 12 TM helices. These proteins are frequently N-glycosylated, which contributes to their stability and trafficking, and are localized to the plasma membrane or intracellular membranes, such as the . The structural diversity within eukaryotic efflux pumps is pronounced, reflecting adaptations to varied physiological roles across kingdoms. In the ABCB subfamily, multidrug resistance proteins like MDR1/P-gp are characterized by two pseudosymmetric halves connected by a flexible linker , enabling conformational changes between inward- and outward-facing states during transport. The ABCC subfamily, including the multidrug resistance-associated proteins (MRPs) such as MRP1 (ABCC1), often features an additional N-terminal TMD with five TM helices, resulting in a larger ~190 kDa structure specialized for exporting conjugates and other amphipathic anions. In , pleiotropic (PDR) transporters like AtPDR8 (ABCG36) represent a specialized ABCG subfamily variant, functioning as half-transporters that often dimerize and localize to the plasma membrane for defense against xenobiotics. Prominent examples illustrate this diversity. The structure of human MDR1/ABCB1 was resolved by cryo-EM in an inward-facing conformation, revealing a large central accessible from the for binding. In fungi, the Cdr1 from shares the canonical 12 TM helix core but displays unique adaptations for efflux, as shown in recent high-resolution cryo-EM structures capturing nucleotide- and -bound states. Certain eukaryotic pumps exhibit asymmetric architectures, such as the TAP1/TAP2 heterodimer in the ABCB subfamily, where the two non-identical subunits assemble to form a peptide-binding essential for in the . This heterodimeric arrangement contrasts with the symmetric homodimers common in other exporters.

Physiological Functions

Eukaryotic efflux pumps, primarily ATP-binding cassette () transporters, play essential roles in cellular by facilitating the export of potentially harmful substances. In processes, these pumps actively remove xenobiotics, , and endogenous toxins from cells. For instance, (P-gp, encoded by ABCB1) in mammals exports a broad range of xenobiotics, including alkaloids and therapeutic drugs, from hepatocytes and renal cells, thereby aiding in their clearance and preventing accumulation. Similarly, ABCC1 (MRP1) and ABCC2 () transporters export such as and mercury as conjugates, contributing to cellular protection against metal toxicity in various tissues. In , ABC transporters like those in the pleiotropic drug resistance (PDR) subfamily handle the efflux of secondary metabolites, maintaining intracellular balance during environmental stress. These pumps exhibit distinct tissue distribution that underscores their protective functions in physiological barriers. High expression of P-gp is observed in the , blood-brain barrier, and , where it limits the entry of toxins into sensitive compartments, ensuring systemic . Regulation of these transporters often involves nuclear receptors; for example, the pregnane X receptor (PXR) induces MDR1 (ABCB1) expression in response to exposure, enhancing capacity in the liver and intestine. This inducible mechanism allows cells to adapt to fluctuating toxin loads while preserving normal physiological operations. In developmental contexts, efflux pumps contribute to protection during embryogenesis and organismal defense. In mammals, Abcb1 (P-gp) in the actively exports maternal toxins and drugs, such as and , back into the maternal circulation, reducing fetal exposure and preventing teratogenic effects; studies in Abcb1 knockout mice demonstrate 2.4- to 16-fold increases in fetal drug levels, leading to developmental abnormalities like cleft palate upon toxin challenge. In plants, NpPDR1 in plumbaginifolia exports antimicrobial diterpenes like sclareol from glandular trichomes, bolstering defense and supporting reproductive tissue integrity. Organelle-specific efflux pumps further support intracellular . In mitochondria, ABCB10 facilitates the early steps of heme biosynthesis by promoting the export of intermediates like δ-aminolevulinic acid () to the , with knockdown leading to reduced levels and impaired . Lysosome-related organelles rely on pumps such as ABCA3, which transports phospholipids like and phosphatidylglycerol into lamellar bodies, essential for production and lipid in alveolar cells. These localized functions highlight the versatility of eukaryotic efflux pumps in maintaining compartmental integrity.

Role in Drug Resistance and Disease

In eukaryotic cells, efflux pumps such as (P-gp, encoded by ABCB1 or MDR1) play a critical role in by actively extruding chemotherapeutic agents from tumor cells, thereby reducing intracellular drug concentrations and diminishing treatment efficacy. Overexpression of MDR1 has been observed in various solid tumors and hematological malignancies, where it confers resistance to substrates including like and taxanes like . For instance, in and ovarian cancers, elevated MDR1 levels correlate with poorer responses to these agents, as the pump expels them from the before they can induce . Studies indicate that MDR1 overexpression contributes to approximately 50% of cases of refractory cancer, particularly in advanced stages where multidrug resistance (MDR) phenotypes emerge, complicating standard therapies. In infectious diseases, eukaryotic efflux pumps similarly drive resistance to antimicrobial agents. In fungal pathogens like , the Cdr1 expels antifungals such as , leading to reduced intracellular accumulation and clinical treatment failures in . This mechanism is a primary contributor to resistance in clinical isolates, where Cdr1 overexpression can increase minimum inhibitory concentrations by several-fold. In parasitic infections, the Plasmodium falciparum multidrug resistance protein 1 (PfMDR1) modulates sensitivity to artemisinin-based combination therapies (ACTs) and other antimalarials like and lumefantrine by transporting them out of the parasite's digestive . Mutations and amplification of pfmdr1 have been linked to delayed parasite clearance and higher rates of treatment failure in endemic regions. Genetic variations in efflux pump genes further influence drug resistance and disease outcomes. Polymorphisms in ABCB1, such as the C3435T single nucleotide variant in exon 26, alter P-gp expression levels and folding, affecting the efflux of diverse substrates and leading to variable patient responses to chemotherapy and other drugs. The T allele is associated with reduced P-gp activity in some populations, potentially enhancing drug efficacy but also increasing toxicity risks. In neurodegenerative diseases, P-gp at the blood-brain barrier (BBB) regulates the efflux of neurotoxic compounds and therapeutics; its dysregulation, often due to genetic factors or disease-related inflammation, impairs clearance of amyloid-beta and tau proteins, exacerbating conditions like Alzheimer's disease. Reduced BBB P-gp function correlates with accelerated progression in these disorders, highlighting efflux pumps' dual role in protection and pathology. Eukaryotic efflux pumps pose significant therapeutic challenges by fostering MDR phenotypes, where cells resist multiple unrelated drugs through coordinated pump upregulation, often triggered by prior exposure or genetic/epigenetic changes. This limits the success of targeted therapies across cancers and infections, as seen in the persistence of resistant subpopulations. Recent research from 2023–2025 has illuminated the role of (breast cancer resistance protein) in stem cells, where its overexpression protects these quiescent cells from chemotherapeutics like mitoxantrone and inhibitors, promoting tumor recurrence and . Structural studies and inhibitor screens have identified ABCG2 as a key driver in stem cell-mediated resistance, underscoring the need for pump-targeted strategies to eradicate residual disease.

Inhibitors and Therapeutic Strategies

Types of Inhibitors

Efflux pump inhibitors (EPIs) are classified based on their specificity, chemical origin, and mechanisms of action, targeting various transporter families such as , , MFS, and across bacterial and eukaryotic systems. Broad-spectrum inhibitors exhibit non-specific activity against multiple pump families, often by interfering with energy sources or general sites. For instance, verapamil, a , inhibits transporters like (P-gp or MDR1) in eukaryotes and pumps in by competitively to substrate sites, thereby blocking drug extrusion. Family-specific inhibitors selectively target particular efflux pump superfamilies, exploiting unique structural features for higher potency. In ABC transporters, tariquidar acts as a third-generation inhibitor of MDR1/P-gp by binding to the nucleotide-binding domains (NBDs), preventing ATP hydrolysis and thus inhibiting the pump's conformational changes required for transport. For RND pumps, such as AcrAB-TolC in Gram-negative bacteria, phenylalanine-arginine β-naphthylamide (PAβN) binds allosterically to the distal substrate-binding pocket, disrupting the pump's peristaltic motion and efflux activity. Natural compounds derived from and microbes represent another category of , often with dual roles in modulating pump expression and function. , a from Rauwolfia serpentina, reverses multidrug resistance by competitively inhibiting MFS pumps like in and pumps in other , binding to sites and reducing expulsion. Peptide-based natural derivatives, such as MC-207,110 (also known as PAβN), target bacterial and MFS pumps in pathogens like and by mimicking substrates and occupying binding pockets, thereby potentiating accumulation. EPIs can also be categorized by their mechanistic classes, which determine how they interfere with pump dynamics. Competitive inhibitors function as substrate mimics, directly vying for sites on ; examples include verapamil and PAβN, which occupy hydrophobic pockets in and pumps, respectively, preventing access. Non-competitive inhibitors, such as certain pyridopyrimidines, trap pumps in an inward-facing conformation by allosteric , halting the efflux cycle without displacing substrates. Additionally, some inhibitors are themselves subject to efflux by the pumps, limiting their efficacy unless used at higher concentrations or in combinations that overwhelm the system.

Development and Clinical Applications

The development of efflux pump inhibitors (EPIs) began in the 1980s with the identification of first-generation compounds like verapamil, which was found to reverse multidrug resistance in cancer cells by inhibiting P-glycoprotein (P-gp, ABCB1) activity. This calcium channel blocker was tested in early clinical settings but exhibited limited potency and significant toxicity, necessitating dose reductions in chemotherapy regimens. In the 1990s, second-generation inhibitors such as cyclosporine and its non-immunosuppressive analog PSC-833 (valspodar) emerged, offering improved specificity for P-gp and broader inhibition of ABC transporters like ABCC1 and ABCG2. High-throughput screening efforts in the early 2000s led to third-generation EPIs, including elacridar, which potently targets both ABCB1 and ABCG2 with reduced pharmacokinetic interactions. Clinical trials of have faced substantial hurdles, particularly in . A phase III trial of PSC-833 combined with cytarabine, , and in patients under 60 years with newly diagnosed (AML) showed no in complete remission rates (75% in both arms), disease-free (1.34 vs. 1.09 years), or overall (1.86 vs. 1.69 years), primarily due to pharmacokinetic interference requiring chemotherapy dose reductions and increased toxicities like grade 3/4 liver and mucosal damage. Similarly, a phase III placebo-controlled trial of zosuquidar (a third-generation ABCB1 ) with cytarabine and in older AML patients (>60 years) failed to enhance overall (7.2 vs. 9.4 months) or remission rates (51.9% vs. 48.9%), attributed to P-gp-independent resistance mechanisms and higher early mortality (22.2% vs. 16.3% at day 42). These setbacks highlight the challenges of achieving sufficient efflux modulation without compromising drug or . In bacterial applications, EPIs like phenylalanine-arginine β-naphthylamide (PAβN) have been explored as adjuvants to potentiate antibiotics against Gram-negative pathogens. PAβN, discovered in 2001, competitively inhibits resistance-nodulation-division (RND) pumps such as MexAB-OprM in Pseudomonas aeruginosa, enhancing the activity of fluoroquinolones (e.g., levofloxacin) and macrolides (e.g., erythromycin) by up to 8- to 16-fold in minimum inhibitory concentrations. It has shown promise in restoring susceptibility to antibiotics like azithromycin in multidrug-resistant Escherichia coli and Acinetobacter baumannii. However, clinical translation is limited by PAβN's toxicity to mammalian cells at therapeutic doses and poor specificity, as it permeabilizes outer membranes nonspecifically and fails to broadly target all substrates like tetracyclines. Emerging strategies are addressing these limitations through innovative approaches. CRISPR interference (CRISPRi) has enabled targeted knockdown of efflux pump genes in research settings, such as repressing Rv1257c, Rv1667c, and others in H37Rv, revealing their roles in drug tolerance and identifying Rv1258c as a key contributor to intrinsic resistance. Nanoparticle-based delivery systems, including nanoparticles, act as EPIs by binding bacterial membranes and inhibiting efflux pumps like AcrAB-TolC in E. coli, synergizing with antibiotics to reduce formation and minimum inhibitory concentrations by 4- to 8-fold while minimizing host toxicity. Recent advances include computationally designed inhibitors for pumps in (MDR-TB); for instance, modeling targeting the S292L mutation in Rv1258c has yielded novel co-therapy candidates that restore pyrazinamide efficacy by blocking efflux, with preclinical data showing enhanced bacterial killing in 2025 studies.

References

  1. [1]
    Multidrug efflux pumps: structure, function and regulation - Nature
    Jul 12, 2018 · These transporters provide several antibiotic efflux pathways that can work in a cooperative manner or provide redundant functionality.Missing: biology definition
  2. [2]
    Efflux pumps of Gram-negative bacteria: what they do, how ... - NIH
    Bacterial efflux pumps (EPs) are proteins that are localized and imbedded in the plasma membrane of the bacterium and whose function is to recognize noxious ...
  3. [3]
    Efflux Pump - an overview | ScienceDirect Topics
    Efflux pumps are defined as mechanisms in microorganisms that regulate their internal environment by extruding toxic substances, including antimicrobial agents ...
  4. [4]
    Role of bacterial efflux pumps in antibiotic resistance, virulence, and ...
    Efflux pumps play a central role in making a bacterium resistant to multiple antibiotics due to their ability to expel a wide range of structurally diverse ...
  5. [5]
    Types and Mechanisms of Efflux Pump Systems and the Potential of ...
    Efflux pumps work by transporting antibiotics out of the bacterial cell so that there is a low intracellular level of antibiotics, meaning that the antibiotics ...
  6. [6]
    Function and Inhibitory Mechanisms of Multidrug Efflux Pumps - PMC
    Dec 3, 2021 · Multidrug efflux pumps are inner membrane transporters that export multiple antibiotics from the inside to the outside of bacterial cells.Missing: definition | Show results with:definition
  7. [7]
    Evolutionary origins of multidrug and drug-specific efflux pumps in ...
    Phylogenetic analyses of the four transporter families that contain drug efflux permeases indicate that drug resistance arose rarely during the evolution of ...
  8. [8]
    The Transporter Classification Database (TCDB): 2021 update
    Nov 10, 2020 · These systems are classified into 1536 transporter families based on their phylogenies and functions.
  9. [9]
    Bacterial Multidrug Efflux Pumps at the Frontline of Antimicrobial ...
    Apr 13, 2022 · Efflux transporters are mainly grouped into the following superfamilies: ATP-Binding Cassette (ABC) superfamily, Multidrug and Toxic Compound ...
  10. [10]
    NorM of Vibrio parahaemolyticus Is an Na + -Driven Multidrug Efflux ...
    NorM of Vibrio parahaemolyticusapparently is a new type of multidrug efflux protein, with no significant sequence similarity to any known transport proteins ...
  11. [11]
    The Role of Eukaryotic and Prokaryotic ABC Transporter Family in ...
    This review focuses on drug resistance by ABC efflux transporters in human, viral, parasitic, fungal and bacterial cells
  12. [12]
    Structures and General Transport Mechanisms by the Major ...
    Apr 22, 2021 · During global, rocker-switch structural transitions in MFS transporters, cavity-closing contacts are predominantly formed by TMs lining the ...
  13. [13]
    Structure of the AcrAB-TolC multidrug efflux pump - PMC
    This pump assembly comprises the outer-membrane channel TolC, the secondary transporter AcrB located in the inner membrane, and the periplasmic AcrA.Missing: review | Show results with:review
  14. [14]
    Bacterial multidrug efflux pumps: Mechanisms, physiology and ...
    Bacterial multidrug efflux pumps constitute an important class of resistance determinant. The RND efflux pumps utilize a three-step, functional rotating ...
  15. [15]
    https://www.sciencedirect.com/science/article/pii/S0006291X14009711
  16. [16]
    https://doi.org/10.1016/j.bbrc.2014.05.090
  17. [17]
    https://doi.org/10.3389/fmicb.2021.737288
  18. [18]
    Efflux-Mediated Resistance in Enterobacteriaceae - PubMed Central
    Aug 1, 2025 · Efflux pumps play a pivotal role in antibiotic resistance by lowering the intracellular concentration of antimicrobials below effective ...
  19. [19]
    Efflux pump-mediated resistance to new beta lactam antibiotics in ...
    Aug 29, 2024 · Here we review recent studies that suggest RND efflux pumps in clinically relevant gram-negative bacteria may play critical but underappreciated roles.
  20. [20]
    Efflux, Signaling and Warfare in a Polymicrobial World - PMC - NIH
    Apr 8, 2023 · Furthermore, in some cases efflux pump genes can also be acquired via horizontal gene transfer, increasing the complexity of efflux potential ...
  21. [21]
    Structure and Mechanism of Human ABC Transporters
    May 9, 2023 · Humans have 48 ABC genes organized into seven distinct families. Of these genes, 44 (in five distinct families) encode for membrane transporters ...
  22. [22]
    Structural diversity of ABC transporters - PMC - PubMed Central
    The 14 currently available structures of ABC transporters have greatly advanced insight into the transport mechanism and revealed a tremendous structural ...
  23. [23]
    Structures of P-glycoprotein reveal its conformational flexibility and ...
    P-gp is a ∼170-kDa molecule comprised of two pseudosymmetric halves, each containing a nucleotide-binding domain (NBD) and a transmembrane domain (TMD).
  24. [24]
    The multidrug resistance‐associated protein (MRP/ABCC) subfamily ...
    Dec 6, 2005 · Consequently, ABCC1-mediated ATP-dependent extrusion of organic anions such as leukotriene C4 and other related glutathione conjugates (GS-X) ...
  25. [25]
    Loss of AtPDR8, a Plasma Membrane ABC Transporter of ...
    AtPDR8 is the only member of the pleiotropic drug resistance (PDR) ABC transporter subclass in Arabidopsis that is constitutively highly expressed.
  26. [26]
    Inward- and outward-facing X-ray crystal structures of homodimeric ...
    Jan 8, 2019 · A recent study reported the cryo-EM structure of human P-gp in an outward-facing conformation. The structure has only a small opening on the ...<|separator|>
  27. [27]
    Cryo-EM structures of Candida albicans Cdr1 reveal azole-substrate ...
    Sep 6, 2024 · In C. albicans, Cdr1 acts as an efflux pump to effectively remove azole compounds from fungal cells. This prevents their accumulation to harmful ...
  28. [28]
    Structure of the transporter associated with antigen processing ... - NIH
    TAP is an ER-resident transporter formed by two homologous subunits, TAP1 and TAP2. Similar to other ABC transporters, it contains two nucleotide-binding ...Table 1 · The Peptide-Binding Pocket · The Tap/icp47 Interface
  29. [29]
    https://www.nature.com/articles/s41467-024-52107-w
  30. [30]
    Glutathione-coordinated metal complexes as substrates for cellular ...
    ABC transporters such as MRP1 and MRP2 detoxify the cell from certain metals by exporting the cations as a metal–glutathione complex. The ability of the ...
  31. [31]
    (PDF) ABC Transporters and Heavy Metals - ResearchGate
    The first evidence showing that ABC transporters are involved in heavy metal resistance in eukaryotic cells has been obtained from experiments.
  32. [32]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC8086996/
  33. [33]
    https://www.researchgate.net/publication/281216296_ABC_Transporters_and_Heavy_Metals
  34. [34]
    https://doi.org/10.1172/JCI7963
  35. [35]
    ABC transporters in lipid homeostasis - Reactome Pathway Database
    ABCAs mediate lipid efflux · ABCA3 transports PC, PG from ER membrane to lamellar body · ABCAs mediate lipid influx · ABCA12 transports lipids from cytosol to ...
  36. [36]
    ABCB1 (MDR1) induction defines a common resistance mechanism ...
    Jul 14, 2016 · Resistance correlated with increased ABCB1 expression and was reversible following treatment with the ABCB1 inhibitors verapamil and elacridar.
  37. [37]
    A Phase I Trial of Doxorubicin, Paclitaxel, and Valspodar (PSC 833 ...
    Modulation of MDR with inhibitors of P-gp may improve the efficacy of chemotherapy (12, 22). Doxorubicin and paclitaxel are substrates of P-gp (the protein ...Patients And Methods · Paclitaxel Assay · Discussion<|separator|>
  38. [38]
    Cell Migration Related to MDR—Another Impediment to Effective ...
    The overexpression of certain ABC proteins results in an apparent increase in carcinoma cell resistance to chemotherapeutics (e.g., paclitaxel, docetaxel, ...
  39. [39]
    A Ciprofloxacin Derivative with Four Mechanisms of Action ...
    One approach is to target multidrug resistance protein-1 (MDR1), which is overexpressed in approximately 50% of cancer patients. Additionally, reports confirm a ...
  40. [40]
    Purification and characterization of Cdr1, the drug-efflux pump ...
    Cdr1 is a membrane ABC exporter in Candida that expels azole antifungals, causing drug resistance. This study describes its purification and characterization.
  41. [41]
    The structure of Plasmodium falciparum multidrug resistance protein ...
    Aug 1, 2023 · Plasmodium falciparum Multidrug resistance protein 1 (PfMDR1) is an ATP-binding cassette (ABC) transporter that contributes to antimalarial drug ...
  42. [42]
    pfmdr1 (Plasmodium falciparum multidrug drug resistance gene 1)
    Pfmdr1 has emerged as the central gene in P. falciparum ACT resistance. Understanding the basis of this role is critical for epidemiologic surveillance and ...
  43. [43]
    ABCB1 C1236T, G2677TA and C3435T Genetic Polymorphisms ...
    May 8, 2024 · Genetic variants among ABCB1 gene C1236T, C3435T and G2677TA (Figure 1) may have a direct influence in function and expression of P-GP, and are ...
  44. [44]
    Genetics of ABCB1 in Cancer - MDPI
    ABCB1 SNPs have also been associated with changes in P-gp efflux activity. While there is much debate on whether ABCB1 C3435T influences P-gp expression ...Genetics Of Abcb1 In Cancer · 4. Abcb1 In Normal Tissues · 5. Abcb1 In Cancers
  45. [45]
    Blood-brain barrier P-glycoprotein function in neurodegenerative ...
    P-glycoprotein (P-gp) at the blood-brain barrier (BBB) functions as an active efflux pump by extruding a substrate from the brain.
  46. [46]
    Regulation of ABC Efflux Transporters at Blood-Brain Barrier in ...
    Here, we present an overview of the pathways that regulate the major ABC efflux transporters at BBB and their dysregulation in neurological disease.
  47. [47]
    Targeting breast cancer resistance protein (BCRP/ABCG2) in cancer
    Nov 30, 2024 · A novel, effective and non-toxic BCRP inhibitor to reverse the MDR of breast cancer, and boost the success rate of chemotherapy is a serious challenge at ...
  48. [48]
    The role of ABCG2 in health and disease: Linking cancer therapy ...
    Jan 1, 2025 · ABCG2 has received most of its pharmacological attention as a potential candidate to cause multidrug resistance (MDR) in cancer cells treated ...
  49. [49]
    Revisiting strategies to target ABC transporter-mediated drug ...
    Oct 15, 2025 · These stem cells can produce significant treatment failure and high relapse rates in brain cancer. Studies have reported that ABC transporters ...
  50. [50]
    Verapamil and its metabolite norverapamil inhibit the ... - PNAS
    Verapamil, primarily used as a calcium channel inhibitor, is known to inhibit diverse efflux pumps and to potentiate bedaquiline and clofazimine activity in M. ...
  51. [51]
    Types and Mechanisms of Efflux Pump Systems and the Potential of ...
    Feb 23, 2024 · This review focuses on the types of various efflux pumps detected in A. baumannii, their molecular mechanisms of action, the substrates they transport, and the ...
  52. [52]
    Tariquidar (XR9576): a P-glycoprotein drug efflux pump inhibitor
    Tariquidar is a potent, specific, noncompetitive inhibitor of P-glycoprotein. Tariquidar inhibits the ATPase activity of P-glycoprotein, suggesting that the ...
  53. [53]
    The Efflux Inhibitor Phenylalanine-Arginine Beta-Naphthylamide ...
    Here we report that PAβN enhances the potency of β-lactam antibiotics against wild type and AmpC-overexpressing strains of P. aeruginosa, as well as a strain ...
  54. [54]
    Function and Inhibitory Mechanisms of Multidrug Efflux Pumps
    This review article describes the role of multidrug efflux pumps in drug resistance ... Multiple RND-type efflux pumps exist inside Gram-negative bacteria.
  55. [55]
    Bacterial efflux pump inhibitors from natural sources
    Efflux pumps are able to extrude structurally diverse compounds, including antibiotics used in a clinical setting; the latter are rendered therapeutically ...
  56. [56]
    MexXY-OprM Efflux Pump Is Required for Antagonism of ...
    MC-207,110 has been recently identified as an inhibitor of MexAB-OprM, MexCD-OprJ, and MexEF-OprN efflux pumps from P. aeruginosa and the AcrAB-TolC pump from E ...
  57. [57]
    Efflux pump inhibitors for bacterial pathogens: From bench to bedside
    The five classes of efflux pumps in bacteria, (i) ATP-binding cassette superfamily, (ii) major facilitator superfamily, (iii) multidrug and toxic compound ...
  58. [58]
    https://journals.asm.org/doi/10.1128/aac.45.7.2001-2007.2001
  59. [59]
    Revisiting the role of efflux pumps in multidrug-resistant cancer - PMC
    Jul 11, 2019 · We present recent evidence indicating that it is time to revisit the investigation into the role of ABC transporters in efficient drug delivery in various ...
  60. [60]
    https://pubmed.ncbi.nlm.nih.gov/2566376/