Outer Membrane Lipid Asymmetry Research Articles

How Bacteria Establish and Maintain Outer Membrane Lipid Asymmetry.

Gram-negative bacteria build an asymmetric outer membrane (OM), with lipopolysaccharides (LPS) and phospholipids (PLs) occupying the outer and inner leaflets, respectively. This distinct lipid arrangement is widely conserved within the Bacteria domain and confers strong protection against physical and chemical insults. The OM is physically separated from the inner membrane and the cytoplasm, where most cellular resources are located; therefore, the cell faces unique challenges in the assembly and maintenance of this asymmetric bilayer. Here, we present a framework for how gram-negative bacteria initially establish and continuously maintain OM lipid asymmetry, discussing the state-of-the-art knowledge of specialized lipid transport machines that place LPS and PLs directly into their corresponding leaflets in the OM, prevent excess PL accumulation and mislocalization, and correct any lipid asymmetry defects. We critically assess current studies, or the lack thereof, and highlight important future directions for research on OM lipid transport, homeostasis, and asymmetry.

Maintenance of bacterial outer membrane lipid asymmetry: insight into MlaA.

The outer membrane (OM) of Gram-negative bacteria acts as an effective barrier to protect against toxic compounds. By nature, the OM is asymmetric with the highly packed lipopolysaccharide (LPS) at the outer leaflet and glycerophospholipids at the inner leaflet. OM asymmetry is maintained by the Mla system, in which is responsible for the retrograde transport of glycerophospholipids from the OM to the inner membrane. This system is comprised of six Mla proteins, including MlaA, an OM lipoprotein involved in the removal of glycerophospholipids that are mis-localized at the outer leaflet of the OM. Interestingly, MlaA was initially identified - and called VacJ - based on its role in the intracellular spreading of Shigella flexneri.Many open questions remain with respect to the Mla system and the mechanism involved in the translocation of mislocated glycerophospholipids at the outer leaflet of the OM, by MlaA. After summarizing the current knowledge on MlaA, we focus on the impact of mlaA deletion on OM lipid composition and biophysical properties of the OM. How changes in OM lipid composition and biophysical properties can impact the generation of membrane vesicles and membrane permeability is discussed. Finally, we explore whether and how MlaA might be a candidate for improving the activity of antibiotics and as a vaccine candidate.Efforts dedicated to understanding the relationship between the OM lipid composition and the mechanical strength of the bacterial envelope and, in turn, how such properties act against external stress, are needed for the design of new targets or drugs for Gram-negative infections.

Molecular mechanism of phospholipid transport at the bacterial outer membrane interface

The outer membrane (OM) of Gram-negative bacteria is an asymmetric lipid bilayer with outer leaflet lipopolysaccharides and inner leaflet phospholipids (PLs). This unique lipid asymmetry renders the OM impermeable to external insults, including antibiotics and bile salts. To maintain this barrier, the OmpC-Mla system removes mislocalized PLs from the OM outer leaflet, and transports them to the inner membrane (IM); in the first step, the OmpC-MlaA complex transfers PLs to the periplasmic chaperone MlaC, but mechanistic details are lacking. Here, we biochemically and structurally characterize the MlaA-MlaC transient complex. We map the interaction surfaces between MlaA and MlaC in Escherichia coli, and show that electrostatic interactions are important for MlaC recruitment to the OM. We further demonstrate that interactions with MlaC modulate conformational states in MlaA. Finally, we solve a 2.9-Å cryo-EM structure of a disulfide-trapped OmpC-MlaA-MlaC complex in nanodiscs, reinforcing the mechanism of MlaC recruitment, and highlighting membrane thinning as a plausible strategy for directing lipids for transport. Our work offers critical insights into retrograde PL transport by the OmpC-Mla system in maintaining OM lipid asymmetry.

Dynamic players and intricate interactions: An integrated investigation of the Mla lipid transport system

The Maintenance of outer membrane (OM) Lipid Asymmetry system mediates retrograde phospholipid transport from the OM to the inner membrane (IM) in Gram-negative bacteria. However, the interactions between the various subunits of the IM and OM complexes are not well understood. In a recent study in 2023 by MacRae etal. in the Journal of Biological Chemistry, the authors examine components in the Maintenance of OM Lipid Asymmetry complex, define the interaction interfaces between members of the pathway, and propose a molecular model of the lipid transfer process from the OM to the IM that will help elucidate intricacies of lipid transport.

Cross-talk between phospholipid synthesis and peptidoglycan expansion by a cell wall hydrolase

The Gram-negative bacterial cell envelope is a complex multilayered structure comprising a bilayered phospholipid (PL) membrane that surrounds the cytoplasm (inner membrane or IM) and an asymmetric outer membrane (OM) with PLs in the inner leaflet and lipopolysaccharides in the outer leaflet. Between these two layers is the periplasmic space, which contains a highly cross-linked mesh-like glycan polymer, peptidoglycan (PG). During cell expansion, coordinated synthesis of each of these components is required to maintain the integrity of the cell envelope; however, it is currently not clear how such coordination is achieved. In this study, we show that a cross-link-specific PG hydrolase couples the expansion of PG sacculus with that of PL synthesis in the Gram-negative model bacterium,Escherichiacoli. We find that unregulated activity of a PG hydrolytic enzyme, MepS is detrimental for growth of E.coli during fatty acid (FA)-limiting conditions. Further genetic and biochemical analyses revealed that cellular availability of FA or PL alters the post-translational stability of MepS by modulating the proteolytic activity of a periplasmic adaptor-protease complex, NlpI-Prc toward MepS. Our results indicate that loss of OM lipid asymmetry caused by alterations in PL abundance leads to the generation of a signal to the NlpI-Prc complex for the stabilization of MepS, which subsequently cleaves the cross-links to facilitate expansion of PG. In summary, our study shows the existence of a molecular cross-talk that enables coordinated expansion of the PG sacculus with that of membrane synthesis for balanced cell-envelope biogenesis.

Protein–protein interactions in the Mla lipid transport system probed by computational structure prediction and deep mutational scanning

The outer membrane (OM) of Gram-negative bacteria is an asymmetric bilayer that protects the cell from external stressors, such as antibiotics. The Mla transport system is implicated in the Maintenance of OM Lipid Asymmetry by mediating retrograde phospholipid transport across the cell envelope. Mla uses a shuttle-like mechanism to move lipids between the MlaFEDB inner membrane complex and the MlaA-OmpF/C OM complex, via a periplasmic lipid-binding protein, MlaC. MlaC binds to MlaD and MlaA, but the underlying protein-protein interactions that facilitate lipid transfer are not well understood. Here, we take an unbiased deep mutational scanning approach to map the fitness landscape of MlaC from Escherichia coli, which provides insights into important functional sites. Combining this analysis with AlphaFold2 structure predictions and binding experiments, we map the MlaC-MlaA and MlaC-MlaD protein-protein interfaces. Our results suggest that the MlaD and MlaA binding surfaces on MlaC overlap to a large extent, leading to a model in which MlaC can only bind one of these proteins at a time. Low-resolution cryo-electron microscopy (cryo-EM) maps of MlaC bound to MlaFEDB suggest that at least two MlaC molecules can bind to MlaD at once, in a conformation consistent with AlphaFold2 predictions. These data lead us to a model for MlaC interaction with its binding partners and insights into lipid transfer steps that underlie phospholipid transport between the bacterial inner and OMs.

Knockout of mlaA increases Escherichia coli virulence in a silkworm infection model.

The mlaA gene encodes a lipoprotein to maintain an outer membrane lipid asymmetry in gram-negative bacteria. Although the role of mlaA in bacterial virulence has been studied in several bacterial species, there are no reports of its role in E. coli virulence. In this study, we found that knockout of mlaA in E. coli increased its virulence against silkworms. The mlaA-knockout mutant was sensitive to several antibiotics and detergents, but resistant to vancomycin and chlorhexidine. The mlaA-knockout mutant grew faster than the parent strain in the presence of silkworm hemolymph. The mlaA-knockout mutant also produced a larger amount of outer membrane vesicles than the parent strain. These findings suggest that mlaA knockout causes E. coli resistance to specific antimicrobial substances and increases outer membrane vesicle production, thereby enhancing E. coli virulence properties in the silkworm infection model.

Of zones, bridges and chaperones - phospholipid transport in bacterial outer membrane assembly and homeostasis.

The outer membrane (OM) is a formidable permeability barrier that protects Gram-negative bacteria from detergents and antibiotics. It possesses exquisite lipid asymmetry, requiring the placement and retention of lipopolysaccharides (LPS) in the outer leaflet, and phospholipids (PLs) in the inner leaflet. To establish OM lipid asymmetry, LPS are transported from the inner membrane (IM) directly to the outer leaflet of the OM. In contrast, mechanisms for PL trafficking across the cell envelope are much less understood. In this review, we summarize and discuss recent advances in our understanding of PL transport, making parallel comparisons to well-established pathways for OM lipoprotein (Lol) and LPS (Lpt). Insights into putative PL transport systems highlight possible connections back to the 'Bayer bridges', adhesion zones between the IM and the OM that had been observed more than 50 years ago, and proposed as passages for export of OM components, including LPS and PLs.

Pal depletion results in hypervesiculation and affects cell morphology and outer-membrane lipid asymmetry in bordetellae

Current vaccines against Bordetella pertussis do not prevent colonization and transmission of the bacteria, and vaccine-induced immunity wanes rapidly. Besides, efficacy of vaccines for Bordetella bronchiseptica remains unclear. Novel vaccines could be based on outer-membrane vesicles (OMVs), but vesiculation of bordetellae needs to be increased for cost-effective vaccine production. Here, we focused on increasing OMV production by reducing the anchoring of the outer membrane to the peptidoglycan layer. Inactivation of rmpM, tolR, and pal failed, presumably because their products are essential in bordetellae. Conditional pal mutants were constructed, which were hypervesiculating under Pal-depletion conditions. SDS-PAGE and Western blot analyses showed that the protein composition of OMVs produced under Pal-depletion conditions resembled that of the outer membrane but differed from that of OMVs released by the wild type. Pal depletion affected the cell morphology and appeared to increase the amounts of cell-surface-exposed phospholipids, possibly reflecting a role for the Tol-Pal system in retrograde phospholipid transport. We also identified additional lipoproteins in bordetellae with a putative peptidoglycan-anchoring domain. However, their inactivation did not influence OMV production. We conclude that the conditional pal mutants could be valuable for the development of OMV-based vaccines.

Inactivation of the Mla system and outer-membrane phospholipase A results in disrupted outer-membrane lipid asymmetry and hypervesiculation in Bordetella pertussis

Bordetella pertussis is the causative agent of a respiratory infection known as whooping cough. With the goal of improving the production of outer-membrane vesicles (OMVs), we studied here the mechanisms that are involved in maintaining lipid asymmetry in the outer membrane of this organism. We identified homologues of the phospholipid (PL)-transport systems Mla and Pqi and of outer-membrane phospholipase A (OMPLA). Inactivation of mlaF, encoding the ATPase of the Mla system, together with pldA, which encodes OMPLA, resulted in an accumulation of PLs at the cell surface as demonstrated by the binding of a phosphatidylethanolamine-specific fluorescent probe to intact cells of this strain. The corresponding single mutations did hardly or not affect binding of the probe. These results are consistent with a retrograde transport directionality of the Mla system in B. pertussis and indicate that PLs accumulating at the cell surface in the mlaF mutant are degraded by OMPLA. Consequently, the mlaF mutant showed a conditional growth defect due to the production of free fatty acids by OMPLA, which could be compensated by inactivation of OMPLA or by sequestration of the produced fatty acids with starch. The mlaF pldA double mutant showed markedly increased OMV production, and representative antigens were detected in these OMVs as in wild-type OMVs. Further phenotypic characterization showed that the barrier function of the outer membrane of the mlaF pldA mutant was compromised as manifested by increased susceptibility to SDS and to several antibiotics. Moreover, inactivation of mlaF alone or together with pldA resulted in increased biofilm formation, which was, however, not directly related to increased vesiculation as the addition of purified OMVs to the wild-type strain decreased biofilm formation. We conclude that the absence of MlaF together with OMPLA results in PL accumulation in the outer leaflet of the outer membrane, and the increased vesiculation of the mutant could be useful in the development of novel, OMV-based pertussis vaccines.

ATP disrupts lipid-binding equilibrium to drive retrograde transport critical for bacterial outer membrane asymmetry

The hallmark of the gram-negative bacterial envelope is the presence of the outer membrane (OM). The OM is asymmetric, comprising lipopolysaccharides (LPS) in the outer leaflet and phospholipids (PLs) in the inner leaflet; this critical feature confers permeability barrier function against external insults, including antibiotics. To maintain OM lipid asymmetry, the OmpC-Mla system is believed to remove aberrantly localized PLs from the OM and transport them to the inner membrane (IM). Key to the system in driving lipid trafficking is the MlaFEDB ATP-binding cassette transporter complex in the IM, but mechanistic details, including transport directionality, remain enigmatic. Here, we develop a sensitive point-to-point invitro lipid transfer assay that allows direct tracking of [14C]-labeled PLs between the periplasmic chaperone MlaC and MlaFEDB reconstituted into nanodiscs. We reveal that MlaC spontaneously transfers PLs to the IM transporter in an MlaD-dependent manner that can be further enhanced by coupled ATP hydrolysis. In addition, we show that MlaD is important for modulating productive coupling between ATP hydrolysis and such retrograde PL transfer. We further demonstrate that spontaneous PL transfer also occurs from MlaFEDB to MlaC, but such anterograde movement is instead abolished by ATP hydrolysis. Our work uncovers a model where PLs reversibly partition between two lipid-binding sites in MlaC and MlaFEDB, and ATP binding and/or hydrolysis shift this equilibrium to ultimately drive retrograde PL transport by the OmpC-Mla system. These mechanistic insights will inform future efforts toward discovering new antibiotics against gram-negative pathogens.

Articles of Significant Interest in This Issue.

Antimicrobial peptides (AMPs) are promising antibacterials because of their low propensity for resistance development and their ability to kill resistant bacteria. Kathayat et al. (e00567-21) showed that small peptides (NPSRQERR, PDENK, and VHTAPK) were effective in reducing infections with avian pathogenic Escherichia coli (APEC), a form of extraintestinal pathogenic E. coli (ExPEC), in chickens. Further, they showed that these peptides likely affect MlaA-OmpC/F, a system critical for maintaining bacterial outer membrane lipid asymmetry, which represents a high-value target for treating antibiotic-resistant infections. This work highlights a valuable approach for development of novel therapies for ExPEC and other related Gram-negative pathogens.

Peptides Affecting the Outer Membrane Lipid Asymmetry System (MlaA-OmpC/F) Reduce Avian Pathogenic Escherichia coli (APEC) Colonization in Chickens.

Avian pathogenic Escherichia coli (APEC), an extraintestinal pathogenic E. coli (ExPEC), causes colibacillosis in chickens and is reportedly associated with urinary tract infections and meningitis in humans. Development of resistance is a major limitation of current ExPEC antibiotic therapy. New antibacterials that can circumvent resistance problem such as antimicrobial peptides (AMPs) are critically needed. Here, we evaluated the efficacy of Lactobacillus rhamnosus GG (LGG)-derived peptides against APEC and uncovered their potential antibacterial targets. Three peptides (NPSRQERR [P1], PDENK [P2], and VHTAPK [P3]) displayed inhibitory activity against APEC. These peptides were effective against APEC in biofilm and chicken macrophage HD11 cells. Treatment with these peptides reduced the cecum colonization (0.5 to 1.3 log) of APEC in chickens. Microbiota analysis revealed two peptides (P1 and P2) decreased Enterobacteriaceae abundance with minimal impact on overall cecal microbiota of chickens. Bacterial cytological profiling showed peptides disrupt APEC membranes either by causing membrane shedding, rupturing, or flaccidity. Furthermore, gene expression analysis revealed that peptides downregulated the expression of ompC (>13.0-fold), ompF (>11.3-fold), and mlaA (>4.9-fold), genes responsible for the maintenance of outer membrane (OM) lipid asymmetry. Consistently, immunoblot analysis also showed decreased levels of OmpC and MlaA proteins in APEC treated with peptides. Alanine scanning studies revealed residues crucial (P1, N, E, R and P; P2, D and E; P3, T, P, and K) for their activity. Overall, our study identified peptides with a new antibacterial target that can be developed to control APEC infections in chickens, thereby curtailing poultry-originated human ExPEC infections. IMPORTANCE Avian pathogenic Escherichia coli (APEC) is a subgroup of extraintestinal pathogenic E. coli (ExPEC) and considered a foodborne zoonotic pathogen transmitted through consumption of contaminated poultry products. APEC shares genetic similarities with human ExPECs, including uropathogenic E. coli (UPEC) and neonatal meningitis E. coli (NMEC). Our study identified Lactobacillus rhamnosus GG (LGG)-derived peptides (P1 [NPSRQERR], P2 [PDENK], and P3 [VHTAPK]) effective in reducing APEC infection in chickens. Antimicrobial peptides (AMPs) are regarded as ideal candidates for antibacterial development because of their low propensity for resistance development and ability to kill resistant bacteria. Mechanistic studies showed peptides disrupt the APEC membrane by affecting the MlaA-OmpC/F system responsible for the maintenance of outer membrane (OM) lipid asymmetry, a promising new druggable target to overcome resistance problems in Gram-negative bacteria. Altogether, these peptides can provide a valuable approach for development of novel anti-ExPEC therapies, including APEC, human ExPECs, and other related Gram-negative pathogens. Furthermore, effective control of APEC infections in chickens can curb poultry-originated ExPEC infections in humans.

Structural insights into outer membrane asymmetry maintenance in Gram-negative bacteria by MlaFEDB.

The highly asymmetric outer membrane of Gram-negative bacteria functions in the defense against cytotoxic substances, such as antibiotics. The Mla pathway maintains outer membrane lipid asymmetry by transporting phospholipids between the inner and outer membranes. It comprises six Mla proteins, MlaFEDBCA, including the ABC transporter MlaFEDB, which functions via an unknown mechanism. Here we determine cryo-EM structures of Escherichia coli MlaFEDB in an apo state and bound to phospholipid, ADP or AMP-PNP to a resolution of 3.3-4.1 Å and establish a proteoliposome-based transport system that includes MlaFEDB, MlaC and MlaA-OmpF to monitor the transport direction of phospholipids. In vitro transport assays and in vivo membrane permeability assays combined with mutagenesis identify functional residues that not only recognize and transport phospholipids but also regulate the activity and structural stability of the MlaFEDB complex. Our results provide mechanistic insights into the Mla pathway, which could aid antimicrobial drug development.

The Mla pathway in Acinetobacter baumannii has no demonstrable role in anterograde lipid transport

The asymmetric outer membrane (OM) of Gram-negative bacteria functions as a selective permeability barrier to the environment. Perturbations to OM lipid asymmetry sensitize the cell to antibiotics. As such, mechanisms involved in lipid asymmetry are fundamental to our understanding of OM lipid homeostasis. One such mechanism, the Maintenance of lipid asymmetry (Mla) pathway has been proposed to extract mislocalized glycerophospholipids from the outer leaflet of the OM and return them to the inner membrane (IM). Work on this pathway in Acinetobacter baumannii support conflicting models for the directionality of the Mla system being retrograde (OM to IM) or anterograde (IM to OM). Here, we show conclusively that A. baumannii mla mutants exhibit no defects in anterograde transport. Furthermore, we identify an allele of the GTPase obgE that is synthetically sick in the absence of Mla; providing another link between cell envelope homeostasis and stringent response.

Cryo-EM Structure of a Bacterial Lipid Transporter YebT

The outer membrane (OM) of Gram-negative bacteria is asymmetric, with lipopolysaccharides (LPSs) on the outer surface and phospholipids (PLs) on the inner surface. This unique organization of OM makes Gram-negative bacteria resistant to many toxic chemicals. How this asymmetric distribution of lipids is maintained has been studied for decades with previous reports of an Mla (Maintenance of OM Lipid Asymmetry) system to be involved. Furthermore, the OM of Gram-negative bacteria is about 20 nm away from inner membrane (IM) where the lipids are synthesized. Therefore, how nascent lipids travel across the periplasmic space and arrive at the inner surface of OM is another interesting question. YebT is a homologue of MlaD in the Mla pathway, but its role in lipid distribution of the OM and IM is largely unknown. Here we report the first high-resolution (~3.0 Å) cryo-EM structure of full-length E. coli YebT in a substrate-bound state. Our structure with details of lipid interaction indicates that YebT is a lipid transporter spanning between IM and OM. We also demonstrate the symmetry mismatch in YebT and the existence of many other conformations of YebT revealing the intrinsic dynamics of this lipid channel. And a brief discussion on possible mechanisms of lipid transport is also included.

Characterization of Interactions and Phospholipid Transfer between Substrate Binding Proteins of the OmpC-Mla System

The outer membrane (OM) of Gram-negative bacteria is a permeability barrier that impedes the entry of external insults, such as antibiotics and bile salts. This barrier function depends critically on the asymmetric lipid distribution across the bilayer, with lipopolysaccharides (LPS) facing outside and phospholipids (PLs) facing inside. In Escherichia coli, the OmpC-Mla system is believed to maintain OM lipid asymmetry by removing surface exposed PLs and shuttling them back to the inner membrane (IM). How proteins in the pathway interact to mediate PL transport across the periplasm is not known. Evidence for direct transfer of PLs between these proteins is also lacking. In this study, we mapped the interaction surfaces between the two PL-binding proteins, MlaC and MlaD, using site-specific in vivo photo-cross-linking, and obtained a physical picture for how these proteins may transfer PLs. Furthermore, we demonstrated using purified proteins that MlaD spontaneously transfers PLs to MlaC, suggesting that the latter has a higher affinity for PLs. Our work provides insights into the mechanism of bacterial intermembrane lipid transport important for the maintenance of OM lipid asymmetry.

The architecture of the OmpC–MlaA complex sheds light on the maintenance of outer membrane lipid asymmetry in Escherichia coli

A distinctive feature of the Gram-negative bacterial cell envelope is the asymmetric outer membrane (OM), where lipopolysaccharides and phospholipids (PLs) reside in the outer and inner leaflets, respectively. This unique lipid asymmetry renders the OM impermeable to external insults, including antibiotics and bile salts. In Escherichia coli, the complex comprising osmoporin OmpC and the OM lipoprotein MlaA is believed to maintain lipid asymmetry by removing mislocalized PLs from the outer leaflet of the OM. How this complex performs this function is unknown. Here, we defined the molecular architecture of the OmpC-MlaA complex to gain insights into its role in PL transport. Using in vivo photo-cross-linking and molecular dynamics simulations, we established that MlaA interacts extensively with OmpC and is located entirely within the lipid bilayer. In addition, MlaA forms a hydrophilic channel, likely enabling PL translocation across the OM. We further showed that flexibility in a hairpin loop adjacent to the channel is critical in modulating MlaA activity. Finally, we demonstrated that OmpC plays a functional role in maintaining OM lipid asymmetry together with MlaA. Our work offers glimpses into how the OmpC-MlaA complex transports PLs across the OM and has important implications for future antibacterial drug development.

Modulation of Haemophilus influenzae interaction with hydrophobic molecules by the VacJ/MlaA lipoprotein impacts strongly on its interplay with the airways

Airway infection by nontypeable Haemophilus influenzae (NTHi) associates to chronic obstructive pulmonary disease (COPD) exacerbation and asthma neutrophilic airway inflammation. Lipids are key inflammatory mediators in these disease conditions and consequently, NTHi may encounter free fatty acids during airway persistence. However, molecular information on the interplay NTHi-free fatty acids is limited, and we lack evidence on the importance of such interaction to infection. Maintenance of the outer membrane lipid asymmetry may play an essential role in NTHi barrier function and interaction with hydrophobic molecules. VacJ/MlaA-MlaBCDEF prevents phospholipid accumulation at the bacterial surface, being the only system involved in maintaining membrane asymmetry identified in NTHi. We assessed the relationship among the NTHi VacJ/MlaA outer membrane lipoprotein, bacterial and exogenous fatty acids, and respiratory infection. The vacJ/mlaA gene inactivation increased NTHi fatty acid and phospholipid global content and fatty acyl specific species, which in turn increased bacterial susceptibility to hydrophobic antimicrobials, decreased NTHi epithelial infection, and increased clearance during pulmonary infection in mice with both normal lung function and emphysema, maybe related to their shared lung fatty acid profiles. Altogether, we provide evidence for VacJ/MlaA as a key bacterial factor modulating NTHi survival at the human airway upon exposure to hydrophobic molecules.

Molecular basis for the maintenance of lipid asymmetry in the outer membrane of Escherichia coli

A distinctive feature of the Gram‐negative bacterial cell envelope is the presence of an asymmetric outer membrane (OM), where lipopolysaccharides (LPS) and phospholipids (PLs) reside in the outer and inner leaflets, respectively. This unique lipid asymmetry renders the OM impermeable to external insults, thus allowing survival of bacteria in harsh environments. In Escherichia coli, the OmpC‐Mla system is responsible for maintenance of OM lipid asymmetry. Osmoporin OmpC and the OM lipoprotein MlaA form a complex proposed to remove PLs from the outer leaflet of the OM. How this complex is organized in the OM to perform this function is not known. In this report, we define the molecular architecture of the OmpC‐MlaA complex to gain insights into its function in PL transport. We show that MlaA sits entirely within the OM lipid bilayer, and interacts with the OmpC trimer at its dimeric interfaces. Molecular dynamics simulations reveal a membrane‐spanning hydrophilic channel within MlaA, suggesting a path for PL translocation across the OM. We demonstrate that a hydrophobic hairpin loop adjacent to this putative channel is critical for modulating the activity of MlaA; restricting flexibility of this structure significantly perturbs the function of the complex. Finally, we establish that OmpC plays an active role in maintaining OM lipid asymmetry together with MlaA. Our work provides a glimpse into the molecular mechanism of how the OmpC‐MlaA complex may extract PLs from the outer leaflet of the OM, and highlights key features that could be exploited in the development of future antimicrobial drugs.Support or Funding InformationNational University of Singapore Graduate School for Integrative Sciences and Engineering scholarship (to J.Y.).Singapore Ministry of Education Academic Research Fund Tier 3 grant (MOE2012‐T3‐1‐008) grant to (P.J.B.).Singapore Ministry of Education Academic Research Fund Tier 1 and Tier 2 (MOE2013‐T2‐1‐148) grants (to S.‐S.C.).This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.