Your search keyword '"Lipopolysaccharide transport"' showing total 149 results

1. The Prediction of LptA and LptC Protein–Protein Interactions and Virtual Screening for Potential Inhibitors.

Author

Ren, Yixin, Dong, Wenting, Li, Yan, Cao, Weiting, Xiao, Zengshuo, Zhou, Ying, Teng, Yun, You, Xuefu, Yang, Xinyi, Huang, Huoqiang, and Wang, Hao

Subjects

*PROTEIN-protein interactions, *DRUG discovery, *CHEMICAL libraries, *GRAM-negative bacteria, *MOLECULAR dynamics

Abstract

Antibiotic resistance in Gram-negative bacteria remains one of the most pressing challenges to global public health. Blocking the transportation of lipopolysaccharides (LPS), a crucial component of the outer membrane of Gram-negative bacteria, is considered a promising strategy for drug discovery. In the transportation process of LPS, two components of the LPS transport (Lpt) complex, LptA and LptC, are responsible for shuttling LPS across the periplasm to the outer membrane, highlighting their potential as targets for antibacterial drug development. In the current study, a protein–protein interaction (PPI) model of LptA and LptC was constructed, and a molecular screening strategy was employed to search a protein–protein interaction compound library. The screening results indicated that compound 18593 exhibits favorable binding free energy with LptA and LptC. In comparison with the molecular dynamics (MD) simulations on currently known inhibitors, compound 18593 shows more stable target binding ability at the same level. The current study suggests that compound 18593 may exhibit an inhibitory effect on the LPS transport process, making it a promising hit compound for further research. [ABSTRACT FROM AUTHOR]

Published

2024

2. The Prediction of LptA and LptC Protein–Protein Interactions and Virtual Screening for Potential Inhibitors

Author

Yixin Ren, Wenting Dong, Yan Li, Weiting Cao, Zengshuo Xiao, Ying Zhou, Yun Teng, Xuefu You, Xinyi Yang, Huoqiang Huang, and Hao Wang

Subjects

antibiotic resistance, gram-negative bacteria, lipopolysaccharide transport, CADD, protein–protein interaction, Organic chemistry, QD241-441

Abstract

Antibiotic resistance in Gram-negative bacteria remains one of the most pressing challenges to global public health. Blocking the transportation of lipopolysaccharides (LPS), a crucial component of the outer membrane of Gram-negative bacteria, is considered a promising strategy for drug discovery. In the transportation process of LPS, two components of the LPS transport (Lpt) complex, LptA and LptC, are responsible for shuttling LPS across the periplasm to the outer membrane, highlighting their potential as targets for antibacterial drug development. In the current study, a protein–protein interaction (PPI) model of LptA and LptC was constructed, and a molecular screening strategy was employed to search a protein–protein interaction compound library. The screening results indicated that compound 18593 exhibits favorable binding free energy with LptA and LptC. In comparison with the molecular dynamics (MD) simulations on currently known inhibitors, compound 18593 shows more stable target binding ability at the same level. The current study suggests that compound 18593 may exhibit an inhibitory effect on the LPS transport process, making it a promising hit compound for further research.

Published

2024

3. Suppressor Mutations in LptF Bypass Essentiality of LptC by Forming a Six-Protein Transenvelope Bridge That Efficiently Transports Lipopolysaccharide

Author

Federica A. Falchi, Rebecca J. Taylor, Sebastian J. Rowe, Elisabete C. C. M. Moura, Tiago Baeta, Cedric Laguri, Jean-Pierre Simorre, Daniel E. Kahne, Alessandra Polissi, and Paola Sperandeo

Subjects

ABC transporter, ATPase, lipopolysaccharide transport, cell envelope, outer membrane biogenesis, proteoliposomes, Microbiology, QR1-502

Abstract

ABSTRACT Lipopolysaccharide (LPS) is an essential component of the outer membrane (OM) of many Gram-negative bacteria, providing a barrier against the entry of toxic molecules. In Escherichia coli, LPS is exported to the cell surface by seven essential proteins (LptA-G) that form a transenvelope complex. At the inner membrane, the ATP-binding cassette (ABC) transporter LptB2FG associates with LptC to power LPS extraction from the membrane and transfer to the periplasmic LptA protein, which is in complex with the OM translocon LptDE. LptC interacts both with LptB2FG and LptADE to mediate the formation of the transenvelope bridge and regulates the ATPase activity of LptB2FG. A genetic screen has previously identified suppressor mutants at a residue (R212) of LptF that are viable in the absence of LptC. Here, we present in vivo evidence that the LptF R212G mutant assembles a six-protein transenvelope complex in which LptA mediates interactions with LptF and LptD in the absence of LptC. Furthermore, we present in vitro evidence that the mutant LptB2FG complexes restore the regulation of ATP hydrolysis as it occurs in the LptB2FGC complex to achieve wild-type efficient coupling of ATP hydrolysis and LPS movement. We also show the suppressor mutations restore the wild-type levels of LPS transport both in vivo and in vitro, but remarkably, without restoring the affinity of the inner membrane complex for LptA. Based on the sensitivity of lptF suppressor mutants to selected stress conditions relative to wild-type cells, we show that there are additional regulatory functions of LptF and LptC that had not been identified. IMPORTANCE The presence of an external LPS layer in the outer membrane makes Gram-negative bacteria intrinsically resistant to many antibiotics. Millions of LPS molecules are transported to the cell surface per generation by the Lpt molecular machine made, in E. coli, by seven essential proteins. LptC is the unconventional regulatory subunit of the LptB2FGC ABC transporter, involved in coordinating energy production and LPS transport. Surprisingly, despite being essential for bacterial growth, LptC can be deleted, provided that a specific residue in the periplasmic domain of LptF is mutated and LptA is overexpressed. Here, we apply biochemical techniques to investigate the suppression mechanism. The data produced in this work disclose an unknown regulatory function of LptF in the transporter that not only expands the knowledge about the Lpt complex but can also be targeted by novel LPS biogenesis inhibitors.

Published

2023

4. An outlook for food sterilization technology: targeting the outer membrane of foodborne gram-negative pathogenic bacteria

Author

Qian Wu, Yong Zhao, Yingjie Pan, Zhenhua Huang, Zhaohuan Zhang, Pradeep K. Malakar, and Jinrong Tong

Subjects

0301 basic medicine, 030109 nutrition & dietetics, business.industry, Pathogenic bacteria, 04 agricultural and veterinary sciences, Biology, Membrane transport, Sterilization (microbiology), Food safety, medicine.disease_cause, biology.organism_classification, 040401 food science, Applied Microbiology and Biotechnology, Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, 0404 agricultural biotechnology, medicine, Bacterial outer membrane, business, Biogenesis, Bacteria, Food Science

Abstract

Foodborne pathogenic gram-negative bacteria are major causes of diseases in human populations worldwide. Removing these infectious bacteria are mainly done using appropriate sterilization technologies. One target for sterilization is the outer membrane of gram-negative bacteria which are crucial for growth and survival. The outer membrane of gram-negative bacteria is composed of outer membrane protein (OMPs), Lipproteins (Lpp) and Lipopolysaccharides (LPS), which depend on specific transmembrane transport systems, such as β-Barrel Assembly Machinery (Bam), Localization of Lipoprotein (Lol) and lipopolysaccharide transport system (Lpt). In this outlook paper, we review, initially, standard sterilization technologies in the field of food safety. Then the novel sterilizing agents targeting outer membrane biogenesis in gram-negative bacteria will be summarized and highlighted. We hope this review can provide new insights for developing novel food sterilization technologies.

Published

2021

5. Affinity Purification and Coimmunoprecipitation of Transenvelope Protein Complexes in Gram-Negative Bacteria

Abstract

Multiprotein complexes are important machineries that organize a large number of different proteins into functional units. Studying protein-protein interactions in the complexes, rather than individual proteins, is a fundamental step to gaining functional insights into a biological process. Here, we present the sequential affinity purification and coimmunoprecipitation system that was applied to enable the efficient purification of all the proteins that compose the Lpt system complex in Escherichia coli and their identification by western blotting and mass spectrometry (MS).

Published

2022

6. Cryo-EM structures of LptB2FG and LptB2FGC from Klebsiella pneumoniae in complex with lipopolysaccharide

Author

Qingshan Luo, Xueqing Xu, and Huigang Shi

Subjects

biology, Lipopolysaccharide, Klebsiella pneumoniae, Biophysics, Transporter, Cell Biology, biology.organism_classification, Biochemistry, Microbiology, Lipopolysaccharide transport, Transmembrane domain, chemistry.chemical_compound, chemistry, Inner membrane, lipids (amino acids, peptides, and proteins), Bacterial outer membrane, Molecular Biology, Bacteria

Abstract

Lipopolysaccharide (LPS) is an essential component of the outer membrane (OM) in most Gram-negative bacteria. LPS transport from the inner membrane (IM) to the OM is achieved by seven lipopolysaccharide transport proteins (LptA-G). LptB2FG, an type VI ATP-binding cassette (ABC) transporter, forms a stable complex with LptC, extracts LPS from the IM and powers LPS transport to the OM. Here we report the cryo-EM structures of LptB2FG and LptB2FGC from Klebsiella pneumoniae in complex with LPS. The KpLptB2FG-LPS structure provides detailed interactions between LPS and the transporter, while the KpLptB2FGC-LPS structure may represent an intermediate state that the transmembrane helix of LptC has not been fully inserted into the transmembrane domains of LptB2FG.

Published

2021

7. Lipopolysaccharide biogenesis and transport at the outer membrane of Gram-negative bacteria.

Author

Sperandeo, Paola, Martorana, Alessandra M., and Polissi, Alessandra

Subjects

*LIPOPOLYSACCHARIDES, *GRAM-negative bacteria, *GLYCOLIPIDS, *ANTIBIOTICS, *ANTI-infective agents

Abstract

The outer membrane (OM) of Gram-negative bacteria is an asymmetric lipid bilayer containing a unique glycolipid, lipopolysaccharide (LPS) in its outer leaflet. LPS molecules confer to the OM peculiar permeability barrier properties enabling Gram-negative bacteria to exclude many toxic compounds, including clinically useful antibiotics, and to survive harsh environments. Transport of LPS poses several problems to the cells due to the amphipatic nature of this molecule. In this review we summarize the current knowledge on the LPS transport machinery, discuss the challenges associated with this process and present the solutions that bacterial cells have evolved to address the problem of LPS transport and assembly at the cell surface. Finally, we discuss how knowledge on LPS biogenesis can be translated for the development of novel antimicrobial therapies. This article is part of a Special Issue entitled: Bacterial Lipids edited by Russell E. Bishop. [ABSTRACT FROM AUTHOR]

Published

2017

8. The Lipopolysaccharide Export Pathway in Escherichia coli: Structure, Organization and Regulated Assembly of the Lpt Machinery

Author

Alessandra Polissi and Paola Sperandeo

Subjects

outer membrane, lipopolysaccharide transport, Escherichia coli, Biology (General), QH301-705.5

Abstract

The bacterial outer membrane (OM) is a peculiar biological structure with a unique composition that contributes significantly to the fitness of Gram-negative bacteria in hostile environments. OM components are all synthesized in the cytosol and must, then, be transported efficiently across three compartments to the cell surface. Lipopolysaccharide (LPS) is a unique glycolipid that paves the outer leaflet of the OM. Transport of this complex molecule poses several problems to the cells due to its amphipatic nature. In this review, the multiprotein machinery devoted to LPS transport to the OM is discussed together with the challenges associated with this process and the solutions that cells have evolved to address the problem of LPS biogenesis.

Published

2014

9. Affinity Purification and Coimmunoprecipitation of Transenvelope Protein Complexes in Gram-Negative Bacteria

Author

Martorana, AM, Santambrogio, C, Polissi, A, Sperandeo, P, Martorana, A, Santambrogio, C, and Polissi, A

Subjects

Affinity purification, Coimmunoprecipitation, Lipopolysaccharide transport, Lpt system, Mass spectrometry, Protein complex, Settore BIO/19 - Microbiologia Generale

Abstract

Multiprotein complexes are important machineries that organize a large number of different proteins into functional units. Studying protein-protein interactions in the complexes, rather than individual proteins, is a fundamental step to gaining functional insights into a biological process. Here, we present the sequential affinity purification and coimmunoprecipitation system that was applied to enable the efficient purification of all the proteins that compose the Lpt system complex in Escherichia coli and their identification by western blotting and mass spectrometry (MS).

Published

2022

10. Cracking outer membrane biogenesis.

Author

Guest, Randi L. and Silhavy, Thomas J.

Subjects

*GRAM-negative bacteria, *LIPOPROTEINS, *CELL anatomy, *ANTIBIOTICS, *PERMEABILITY, *LIPOPOLYSACCHARIDES

Abstract

The outer membrane is a distinguishing feature of the Gram-negative envelope. It lies on the external face of the peptidoglycan sacculus and forms a robust permeability barrier that protects extracytoplasmic structures from environmental insults. Overcoming the barrier imposed by the outer membrane presents a significant hurdle towards developing novel antibiotics that are effective against Gram-negative bacteria. As the outer membrane is an essential component of the cell, proteins involved in its biogenesis are themselves promising antibiotic targets. Here, we summarize key findings that have built our understanding of the outer membrane. Foundational studies describing the discovery and composition of the outer membrane as well as the pathways involved in its construction are discussed. • Gram-negative bacteria contain an outer membrane that lies on the external face of the peptidoglycan sacculus. • The outer membrane consists of lipopolysaccharide, phospholipids, lipoproteins, and integral beta-barrel proteins. • Components of the outer membrane are made in the cytoplasm and transported to their final destination. • Many of the proteins that build the outer membrane are excellent targets for novel antibiotic development. • The discovery of the outer membrane, its components, and the proteins involved in its construction are reviewed. [ABSTRACT FROM AUTHOR]

Published

2023

11. Synthesis and antimicrobial activity against Pseudomonas aeruginosa of macrocyclic β-hairpin peptidomimetic antibiotics containing N-methylated amino acids.

Author

Vetterli, Stefan U., Moehle, Kerstin, and Robinson, John A.

Subjects

*ANTI-infective agents, *PSEUDOMONAS aeruginosa, *DRUG synthesis, *HAIRPIN (Genetics), *PEPTIDOMIMETICS, *ANTIBIOTICS, *AMINO acids

Abstract

Antimicrobial resistance among Gram-negative bacteria is a growing problem, fueled by the paucity of new antibiotics that target these microorganisms. One novel family of macrocyclic β-hairpin-shaped peptidomimetics was recently shown to act specifically against Pseudomonas spp. by a novel mechanism of action, targeting the outer membrane protein LptD, which mediates lipopolysaccharide transport to the cell surface during outer membrane biogenesis. Here we explore the mode of binding of one of these β-hairpin peptidomimetics to LptD in Pseudomonas aeruginosa , by examining the effects on antimicrobial activity following N-methylation of individual peptide bonds. An N -methyl scan of the cyclic peptide revealed that residues on both sides of the β-hairpin structure at a non-hydrogen bonding position likely mediate hydrogen-bonding interactions with the target LptD. Structural analyses by NMR spectroscopy further reinforce the conclusion that the folded β-hairpin structure of the peptidomimetic is critical for binding to the target LptD. Finally, new NMe analogues with potent activity have been identified, which opens new avenues for optimization in this family of antimicrobial peptides. [ABSTRACT FROM AUTHOR]

Published

2016

12. Effect of common bean seed exudates on growth, lipopolysaccharide production, and lipopolysaccharide transport gene expression of Rhizobium anhuiense

Author

Quanju Xiang, Ke Zhao, Bilal Adil, Xiumei Yu, Peng Qin, Kaiwei Xu, Qiang Chen, Yanhong Yan, Jie Wang, Xiaoqiong Chen, Menggen Ma, Xiaoping Zhang, and Yunfu Gu

Subjects

0106 biological sciences, Exudate, Lipopolysaccharide, Immunology, 01 natural sciences, Applied Microbiology and Biotechnology, Microbiology, Rhizobia, Lipopolysaccharide transport, Cell wall, 03 medical and health sciences, chemistry.chemical_compound, Symbiosis, Gene expression, Genetics, medicine, Molecular Biology, 030304 developmental biology, 0303 health sciences, biology, Chemistry, Cell growth, General Medicine, biology.organism_classification, medicine.symptom, 010606 plant biology & botany

Abstract

Lipopolysaccharide (LPS) is essential for successful nodulation during the symbiosis of rhizobia and legumes. However, the detailed mechanism of the LPS in this process has not yet been clearly elucidated. In this study, the effects of common bean seed exudates on the growth, lipopolysaccharide production, and lipopolysaccharide transport genes expression (lpt) of Rhizobium anhuiense were investigated. Rhizobium anhuiense exposed to exudates showed changes in LPS electrophoretic profiles and content, whereby the LPS band was wider and the LPS content was higher in R. anhuiense treated with seed exudates. Exudates enhanced cell growth of R. anhuiense in a concentration-dependent manner; R. anhuiense exposed to higher doses of the exudate showed faster growth. Seven lpt genes of R. anhuiense were amplified and sequenced. Sequences of six lpt genes, except for lptE, were the same as those found in previously analyzed R. anhuiense strains, while lptE shared low sequence similarity with other strains. Exposure to the exudates strongly stimulated the expression of all lpt genes. Approximately 6.7- (lptG) to 301-fold (lptE) increases in the transcriptional levels were observed after only 15 min of exposure to exudates. These results indicate that seed exudates affect the LPS by making the cell wall structure more conducive to symbiotic nodulation.

Published

2020

13. Increased Phospholipid Transfer Protein Activity Is Associated With Markers of Enhanced Lipopolysaccharide Clearance in Human During Cardiopulmonary Bypass

Author

Maxime Nguyen, Thomas Gautier, Guillaume Reocreux, Gaëtan Pallot, Guillaume Maquart, Pierre-Alain Bahr, Annabelle Tavernier, Jacques Grober, David Masson, Belaid Bouhemad, Pierre-Grégoire Guinot, Service d'anesthésie - réanimation chirurgicale [CHU de Dijon], Centre Hospitalier Universitaire de Dijon - Hôpital François Mitterrand (CHU Dijon), Lipides - Nutrition - Cancer [Dijon - U1231] (LNC), Université de Bourgogne (UB)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement-Institut National de la Santé et de la Recherche Médicale (INSERM), Laboratoire d'Excellence : Lipoprotéines et Santé : prévention et Traitement des maladies Inflammatoires et du Cancer (LabEx LipSTIC), École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut Gustave Roussy (IGR)-Centre Hospitalier Régional Universitaire de Nancy (CHRU Nancy)-Centre Hospitalier Régional Universitaire de Besançon (CHRU Besançon)-Université de Bourgogne (UB)-Centre Hospitalier Universitaire de Dijon - Hôpital François Mitterrand (CHU Dijon)-Centre Régional de Lutte contre le cancer Georges-François Leclerc [Dijon] (UNICANCER/CRLCC-CGFL), UNICANCER-UNICANCER-Institut National de la Santé et de la Recherche Médicale (INSERM)-Fédération Francophone de la Cancérologie Digestive, FFCD-Université de Montpellier (UM)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement-Etablissement français du sang [Bourgogne-Franche-Comté] (EFS [Bourgogne-Franche-Comté])-Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC), Université Bourgogne Franche-Comté [COMUE] (UBFC)-Université Bourgogne Franche-Comté [COMUE] (UBFC)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement, Université de Bourgogne (UB)-Institut National de la Santé et de la Recherche Médicale (INSERM)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement, and Dijon, Institut Agro

Subjects

medicine.medical_specialty, Lipopolysaccharide, Inflammation, Cardiovascular Medicine, 030204 cardiovascular system & hematology, [SDV.BBM.BM] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, High-density lipoprotein, Phospholipid transfer protein, Internal medicine, Diseases of the circulatory (Cardiovascular) system, Medicine, Lipoprotein, Original Research, 030304 developmental biology, 0303 health sciences, Triglyceride, business.industry, Cholesterol, Cardiopulmonary bypass, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Endotoxemia, 3. Good health, Endocrinology, chemistry, RC666-701, Phospholipid transfer protein (PLTP), lipids (amino acids, peptides, and proteins), medicine.symptom, Cardiology and Cardiovascular Medicine, business

Abstract

Introduction: Lipopolysaccharide (LPS) is a component of gram-negative bacteria, known for its ability to trigger inflammation. The main pathway of LPS clearance is the reverse lipopolysaccharide transport (RLT), with phospholipid transfer protein (PLTP) and lipoproteins playing central roles in this process in experimental animal models. To date, the relevance of this pathway has never been studied in humans. Cardiac surgery with cardiopulmonary bypass is known to favor LPS digestive translocation. Our objective was to determine whether pre-operative PLTP activity and triglyceride or cholesterol-rich lipoprotein concentrations were associated to LPS concentrations in patients undergoing cardiac surgery with cardiopulmonary bypass.Methods: A post-hoc analysis was conducted on plasma samples obtained from patients recruited in a randomized controlled trial.Total cholesterol, high density lipoprotein cholesterol (HDLc), low density lipoprotein cholesterol (LDLc), triglyceride and PLTP activity were measured before surgery. LPS concentration was measured by mass spectrometry before surgery, at the end of cardiopulmonary bypass and 24 h after admission to the intensive care unit.Results: High PLTP activity was associated with lower LPS concentration but not with inflammation nor post-operative complications. HDLc, LDLc and total cholesterol were not associated with LPS concentration but were lower in patients developing post-operative adverse events. HDLc was negatively associated with inflammation biomarkers (CRP, PCT). Triglyceride concentrations were positively correlated with LPS concentration, PCT and were higher in patients with post-operative complications.Conclusion: Our study supports the role of PLTP in LPS elimination and the relevance of RLT in human. PLTP activity, and not cholesterol rich lipoproteins pool size seemed to be the limiting factor for RLT. PLTP activity was not directly related to post-operative inflammation and adverse events, suggesting that LPS clearance is not the main driver of inflammation in our patients. However, HDLc was associated with lower inflammation and was associated with favorable outcomes, suggesting that HDL beneficial anti-inflammatory effects could be, at least in part independent of LPS clearance.

Published

2021

14. The lipopolysaccharide-transporter complex LptB2FG also displays adenylate kinase activity in vitro dependent on the binding partners LptC/LptA

Author

Cédric Laguri, Isabel Ayala, Karine Giandoreggio-Barranco, Jean-Pierre Simorre, Tiago Baeta, Paola Sperandeo, Elisabete C.C. M. Moura, Alessandra Polissi, Institut de biologie structurale (IBS - UMR 5075), Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Grenoble Alpes (UGA)

Subjects

Lipopolysaccharides, Models, Molecular, Accelerated Communication, nuclear magnetic resonance (NMR), ATPase, STD, saturation transfer difference, Adenylate kinase, ATP-binding cassette transporter, Biochemistry, adenylate kinase, Lipopolysaccharide transport, 03 medical and health sciences, 0302 clinical medicine, Adenosine Triphosphate, Escherichia coli, Inner membrane, AK, adenylate kinase, Molecular Biology, OM, outer membrane, 030304 developmental biology, 0303 health sciences, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], biology, Chemistry, Escherichia coli Proteins, Membrane Proteins, Biological Transport, Cell Biology, Periplasmic space, LptAm, monomeric version of LptA, Transmembrane protein, NMR, Cell biology, IM, inner membrane, TBS, Tris-buffered saline, biology.protein, SMA, styrene-maleic acid, cell wall, LPS, lipopolysaccharide, ATP-Binding Cassette Transporters, ABC transporter, Bacterial outer membrane, Carrier Proteins, 030217 neurology & neurosurgery, lipopolysaccharide (LPS), Lpt, lipopolysaccharide transporter system, TM, transmembrane

Abstract

Lipopolysaccharide (LPS) is an essential glycolipid that covers the surface of gram-negative bacteria. The transport of LPS involves a dedicated seven-protein transporter system called the lipopolysaccharide transport system (Lpt) machinery that physically spans the entire cell envelope. The LptB2FG complex is an ABC transporter that hydrolyzes ATP to extract LPS from the inner membrane for transport to the outer membrane. Here, we extracted LptB2FG directly from the inner membrane with its original lipid environment using styrene-maleic acid polymers. We found that styrene-maleic acid polymers-LptB2FG in nanodiscs display not only ATPase activity but also a previously uncharacterized adenylate kinase (AK) activity, as it catalyzed phosphotransfer between two ADP molecules to generate ATP and AMP. The ATPase and AK activities of LptB2FG were both stimulated by the interaction on the periplasmic side with the periplasmic LPS transport proteins LptC and LptA and inhibited by the presence of the LptC transmembrane helix. We determined that the isolated ATPase module (LptB) had weak AK activity in the absence of transmembrane proteins LptF and LptG, and one mutation in LptB that weakens its affinity for ADP led to AK activity similar to that of fully assembled complex. Thus, we conclude that LptB2FG is capable of producing ATP from ADP, depending on the assembly of the Lpt bridge, and that this AK activity might be important to ensure efficient LPS transport in the fully assembled Lpt system.

Published

2021

15. Lipopolysaccharide Transport System Links Physiological Roles of σE and ArcA in the Cell Envelope Biogenesis in Shewanella oneidensis

Author

Haichun Gao, Peilu Xie, Huihui Liang, Jiahao Wang, and Yujia Huang

Subjects

Microbiology (medical), envelope stress response, cell envelope, Physiology, Cellular respiration, Microbiology, Bacterial cell structure, Lipopolysaccharide transport, lipopolysaccharide transport system, Genetics, Shewanella oneidensis, Arc (protein), General Immunology and Microbiology, Ecology, biology, Chemistry, regulation, Cell Biology, biology.organism_classification, σE, QR1-502, Cell biology, Infectious Diseases, Cytoplasm, Cell envelope, Biogenesis, Arc regulatory system

Abstract

The bacterial cell envelope is not only a protective structure that surrounds the cytoplasm but also the place where a myriad of biological processes take place. This multilayered complex is particularly important for electroactive bacteria such as Shewanella oneidensis, as it generally hosts branched electron transport chains and numerous reductases for extracellular respiration. However, little is known about how the integrity of the cell envelope is established and maintained in these bacteria. By tracing the synthetic lethal effect of Arc two-component system and σE in S. oneidensis, in this study, we identified the lipopolysaccharide transport (Lpt) system as the determining factor. Both Arc and σE, by regulating transcription of lptFG and lptD, respectively, are required for the Lpt system to function properly. The ArcA loss results in an LptFG shortage that triggers activation of σE and leads to LptD overproduction. LptFG and LptD at abnormal levels cause a defect in the lipopolysaccharide (LPS) transport, leading to cell death unless σE-dependent envelope stress response is in place. Overall, our report reveals for the first time that Arc works together with σE to maintain the integrity of the S. oneidensis cell envelope by participating in the regulation of the LPS transport system. IMPORTANCE Arc is a well-characterized global regulatory system that modulates cellular respiration by responding to changes in the redox status in bacterial cells. In addition to regulating expression of respiratory enzymes, Shewanella oneidensis Arc also plays a critical role in cell envelope integrity. The absence of Arc and master envelope stress response (ESR) regulator σE causes a synthetic lethal phenotype. Our research shows that the Arc loss downregulates lptFG expression, leading to cell envelope defects that require σE-mediated ESR for viability. The complex mechanisms revealed here underscore the importance of the interplay between global regulators in bacterial adaption to their natural inhabits.

Published

2021

16. Suppressor Mutations in LptF Bypass Essentiality of LptC by Forming a Six-Protein Transenvelope Bridge That Efficiently Transports Lipopolysaccharide.

Author

Falchi FA, Taylor RJ, Rowe SJ, Moura ECCM, Baeta T, Laguri C, Simorre JP, Kahne DE, Polissi A, and Sperandeo P

Subjects

Lipopolysaccharides metabolism, Suppression, Genetic, Membrane Proteins metabolism, Biological Transport physiology, ATP-Binding Cassette Transporters metabolism, Adenosine Triphosphate metabolism, Carrier Proteins metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism

Abstract

Lipopolysaccharide (LPS) is an essential component of the outer membrane (OM) of many Gram-negative bacteria, providing a barrier against the entry of toxic molecules. In Escherichia coli, LPS is exported to the cell surface by seven essential proteins (LptA-G) that form a transenvelope complex. At the inner membrane, the ATP-binding cassette (ABC) transporter LptB 2 FG associates with LptC to power LPS extraction from the membrane and transfer to the periplasmic LptA protein, which is in complex with the OM translocon LptDE. LptC interacts both with LptB 2 FG and LptADE to mediate the formation of the transenvelope bridge and regulates the ATPase activity of LptB 2 FG. A genetic screen has previously identified suppressor mutants at a residue (R212) of LptF that are viable in the absence of LptC. Here, we present in vivo evidence that the LptF R212G mutant assembles a six-protein transenvelope complex in which LptA mediates interactions with LptF and LptD in the absence of LptC. Furthermore, we present in vitro evidence that the mutant LptB 2 FG complexes restore the regulation of ATP hydrolysis as it occurs in the LptB 2 FGC complex to achieve wild-type efficient coupling of ATP hydrolysis and LPS movement. We also show the suppressor mutations restore the wild-type levels of LPS transport both in vivo and in vitro , but remarkably, without restoring the affinity of the inner membrane complex for LptA. Based on the sensitivity of lptF suppressor mutants to selected stress conditions relative to wild-type cells, we show that there are additional regulatory functions of LptF and LptC that had not been identified. IMPORTANCE The presence of an external LPS layer in the outer membrane makes Gram-negative bacteria intrinsically resistant to many antibiotics. Millions of LPS molecules are transported to the cell surface per generation by the Lpt molecular machine made, in E. coli, by seven essential proteins. LptC is the unconventional regulatory subunit of the LptB 2 FGC ABC transporter, involved in coordinating energy production and LPS transport. Surprisingly, despite being essential for bacterial growth, LptC can be deleted, provided that a specific residue in the periplasmic domain of LptF is mutated and LptA is overexpressed. Here, we apply biochemical techniques to investigate the suppression mechanism. The data produced in this work disclose an unknown regulatory function of LptF in the transporter that not only expands the knowledge about the Lpt complex but can also be targeted by novel LPS biogenesis inhibitors.

Published

2023

17. Lipopolysaccharide transport to the cell surface: periplasmic transport and assembly into the outer membrane.

Author

May, Janine M., Sherman, David J., Simpson, Brent W., Ruiz, Natividad, and Kahne, Daniel

Subjects

*LIPOPOLYSACCHARIDES, *GRAM-negative bacteria, *MEMBRANE proteins, *PROTEIN transport, *ESCHERICHIA coli periplasm, *LIPOPROTEINS

Abstract

Gram-negative bacteria possess an outer membrane (OM) containing lipopolysaccharide (LPS). Proper assembly of the OM not only prevents certain antibiotics from entering the cell, but also allows others to be pumped out. To assemble this barrier, the seven-protein lipopolysaccharide transport (Lpt) system extracts LPS from the outer leaflet of the inner membrane (IM), transports it across the periplasm and inserts it selectively into the outer leaflet of the OM. As LPS is important, if not essential, in most Gram-negative bacteria, the LPS biosynthesis and biogenesis pathways are attractive targets in the development of new classes of antibiotics. The accompanying paper (Simpson BW, May JM, Sherman DJ, Kahne D, Ruiz N. 2015 Phil. Trans. R. Soc. B 370, 20150029. (doi:10.1098/rstb.2015.0029)) reviewed the biosynthesis of LPS and its extraction from the IM. This paper will trace its journey across the periplasm and insertion into the OM. [ABSTRACT FROM AUTHOR]

Published

2015

18. An induced folding process characterizes the partial-loss of function mutant LptAI36D in its interactions with ligands.

Author

Santambrogio, Carlo, Sperandeo, Paola, Barbieri, Francesca, Martorana, Alessandra M., Polissi, Alessandra, and Grandori, Rita

Subjects

*PROTEIN folding, *GENETIC mutation, *LIGANDS (Biochemistry), *LIPOPOLYSACCHARIDES, *GLYCOLIPIDS

Abstract

Lipopolysaccharide (LPS) is an essential glycolipid of the outer membrane (OM) of Gram-negative bacteria with a tripartite structure: lipid A, oligosaccharide core and O antigen. Seven essential LPS-transport proteins (LptABCDEFG) move LPS to the cell surface. Lpt proteins are linked by structural homology, featuring a β-jellyroll domain that mediates protein–protein interactions and LPS binding. Analysis of LptA–LPS interaction by fluorescence spectroscopy is used here to evaluate the contribution of each LPS moiety in protein−ligand interactions, comparing the wild-type (wt) protein to the I36D mutant. In addition to a crucial role of lipid A, an unexpected contribution emerges for the core region in recognition and binding of Lpt proteins. [ABSTRACT FROM AUTHOR]

Published

2015

19. A Single Nucleotide Polymorphism in lptG Increases Tolerance to Bile Salts, Acid, and Staining of Calcofluor-Binding Polysaccharides in Salmonella enterica Serovar Typhimurium E40

Author

Amy C. L. Wong, Taylor A. Wahlig, Andrew J. Stasic, Eliot Stanton, Charles W. Kaspar, and Jared J. Godfrey

Subjects

Microbiology (medical), LPS, biology, lptG, Chemistry, SNP, acid tolerance, biology.organism_classification, Microbiology, Molecular biology, QR1-502, Lipopolysaccharide transport, Salmonella enterica, medicine, bile salts, Leucine, S. enterica, Bacterial outer membrane, Protein precursor, extracellular polymeric substance, Gene, Bacteria, Novobiocin, Original Research, medicine.drug

Abstract

The outer membrane of Salmonella enterica plays an important role in combating stress encountered in the environment and hosts. The transport and insertion of lipopolysaccharides (LPS) into the outer membrane involves lipopolysaccharide transport proteins (LptA-F) and mutations in the genes encoding for these proteins are often lethal or result in the transport of atypical LPS that can alter stress tolerance in bacteria. During studies of heterogeneity in bile salts tolerance, S. enterica serovar Typhimurium E40 was segregated into bile salts tolerant and sensitive cells by screening for growth in TSB with 10% bile salts. An isolate (E40V) with a bile salts MIC >20% was selected for further characterization. Whole-genome sequencing of E40 and E40V using Illumina and PacBio SMRT technologies revealed a non-synonymous single nucleotide polymorphism (SNP) in lptG. Leucine at residue 26 in E40 was substituted with proline in E40V. In addition to growth in the presence of 10% bile salts, E40V was susceptible to novobiocin while E40 was not. Transcriptional analysis of E40 and E40V, in the absence of bile salts, revealed significantly greater (p < 0.05) levels of transcript in three genes in E40V; yjbE (encoding for an extracellular polymeric substance production protein), yciE (encoding for a putative stress response protein), and an uncharacterized gene annotated as an acid shock protein precursor (ASPP). No transcripts of genes were present at a greater level in E40 compared to E40V. Corresponding with the greater level of these transcripts, E40V had greater survival at pH 3.35 and staining of Calcofluor-binding polysaccharide (CBPS). To confirm the SNP in lptG was associated with these phenotypes, strain E40E was engineered from E40 to encode for the variant form of LptG (L26P). E40E exhibited the same differences in gene transcripts and phenotypes as E40V, including susceptibility to novobiocin, confirming the SNP was responsible for these differences.

Published

2021

20. Cardiolipin aids in lipopolysaccharide transport to the gram-negative outer membrane

Author

M. Stephen Trent, Martin V. Douglass, and François Cléon

Subjects

Lipopolysaccharides, Multidisciplinary, Lipopolysaccharide, Cardiolipins, Escherichia coli Proteins, Mutant, Biological Transport, ATP-binding cassette transporter, Biological Sciences, Cell biology, Lipopolysaccharide transport, chemistry.chemical_compound, Bacterial Outer Membrane, Bacterial Proteins, chemistry, Escherichia coli, Cardiolipin, Inner membrane, ATP-Binding Cassette Transporters, Cell envelope, Bacterial outer membrane, Acyltransferases

Abstract

In Escherichia coli, cardiolipin (CL) is the least abundant of the three major glycerophospholipids in the gram-negative cell envelope. However, E. coli harbors three distinct enzymes that synthesize CL: ClsA, ClsB, and ClsC. This redundancy suggests that CL is essential for bacterial fitness, yet CL-deficient bacteria are viable. Although multiple CL–protein interactions have been identified, the role of CL still remains unclear. To identify genes that impact fitness in the absence of CL, we analyzed high-density transposon (Tn) mutant libraries in combinatorial CL synthase mutant backgrounds. We found LpxM, which is the last enzyme in lipid A biosynthesis, the membrane anchor of lipopolysaccharide (LPS), to be critical for viability in the absence of clsA. Here, we demonstrate that CL produced by ClsA enhances LPS transport. Suppressors of clsA and lpxM essentiality were identified in msbA, a gene that encodes the indispensable LPS ABC transporter. Depletion of ClsA in ∆lpxM mutants increased accumulation of LPS in the inner membrane, demonstrating that the synthetic lethal phenotype arises from improper LPS transport. Additionally, overexpression of ClsA alleviated ΔlpxM defects associated with impaired outer membrane asymmetry. Mutations that lower LPS levels, such as a YejM truncation or alteration in the fatty acid pool, were sufficient in overcoming the synthetically lethal ΔclsA ΔlpxM phenotype. Our results support a model in which CL aids in the transportation of LPS, a unique glycolipid, and adds to the growing repertoire of CL–protein interactions important for bacterial transport systems.

Published

2021

21. The metagenomic landscape of xenobiotics biodegradation in mangrove sediments

Author

Melline F. Noronha, Valéria Maia de Oliveira, Matthias Hess, Lucélia Cabral, Anne Hélène Fostier, Gileno Vieira Lacerda-Júnior, Sanderson Tarciso Pereira de Sousa, Larissa Richter, and Fernando Dini Andreote

Subjects

Geologic Sediments, Hydrolases, Health, Toxicology and Mutagenesis, 0211 other engineering and technologies, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Xenobiotics, Lipopolysaccharide transport, XENOBIÓTICO, chemistry.chemical_compound, Bioremediation, Biotransformation, Metals, Heavy, Gene Library, 0105 earth and related environmental sciences, 021110 strategic, defence & security studies, Chromate transport, biology, Microbiota, Public Health, Environmental and Occupational Health, Drug Resistance, Microbial, General Medicine, biology.organism_classification, Pollution, Fosmid, Biodegradation, Environmental, Petroleum, chemistry, Biochemistry, Metagenomics, Wetlands, Xenobiotic, Geobacter

Abstract

Metagenomics is a powerful approach to study microorganisms present in any given environment and their potential to maintain and improve ecosystem health without the need of cultivating these microorganisms in the laboratory. In this study, we combined a cultivation-independent metagenomics approach with functional assays to identify the detoxification potential of microbial genes evaluating their potential to contribute to xenobiotics resistance in oil-impacted mangrove sediments. A metagenomic fosmid library containing 12,960 clones from highly contaminated mangrove sediment was used in this study. For assessment of metal resistance, clones were grown in culture medium with increasing concentrations of mercury. The analyses metagenomic library sequences revealed the presence of genes related to heavy metals and antibiotics resistance in the oil-impacted mangrove microbiome. The taxonomic profiling of these sequences suggests that at the genus level, Geobacter was the most abundant genus in our dataset. A functional screening assessment of the metagenomic library successfully detected 24 potential heavy metal tolerant clones, six of which were capable of growing with increased concentrations of mercury. The genetic characterization of selected clones allowed the detection of genes related to detoxification processes, such as chromate transport protein ChrA, haloacid dehalogenase-like hydrolase, lipopolysaccharide transport system, and 3-oxoacyl-[acyl-carrier-protein] reductase. Clones were capable of growing in medium containing increased concentrations of metals and antibiotics, but none manifested strong mercury removal from culture medium characteristic of mercuric reductase activity. These results suggest that resistance to xenobiotic stress varies greatly and that additional studies to elucidate the potential of metal biotransformation need to be carried out with the goal of improving bioremediation application.

Published

2019

22. The structure of lipopolysaccharide transport protein B (LptB) from Burkholderia pseudomallei

Author

Alice Dawson, William N. Hunter, and Genady Pankov

Subjects

Models, Molecular, Burkholderia pseudomallei, Lipopolysaccharide, Biophysics, ATP-binding cassette transporter, Crystallography, X-Ray, Biochemistry, Research Communications, Conserved sequence, Lipopolysaccharide transport, Lipid A, 03 medical and health sciences, chemistry.chemical_compound, Glycolipid, Bacterial Proteins, Structural Biology, Genetics, Inner membrane, Amino Acid Sequence, 030304 developmental biology, 0303 health sciences, 030306 microbiology, Condensed Matter Physics, Protein Subunits, chemistry, lipids (amino acids, peptides, and proteins), Bacterial outer membrane

Abstract

The thick outer membrane (OM) of Gram-negative bacteria performs an important protective role against hostile environments, supports cell integrity, and contributes to surface adhesion and in some cases also to virulence. A major component of the OM is lipopolysaccharide (LPS), a complex glycolipid attached to a core containing fatty-acyl chains. The assembly and transport of lipid A, the membrane anchor for LPS, to the OM begins when a heteromeric LptB2FG protein complex extracts lipid A from the outer leaflet of the inner membrane. This process requires energy, and upon hydrolysis of ATP one component of the heteromeric assembly, LptB, triggers a conformational change in LptFG in support of lipid A transport. A structure of LptB from the intracellular pathogen Burkholderia pseudomallei is reported here. LptB forms a dimer that displays a relatively fixed structure irrespective of whether it is in complex with LptFG or in isolation. Highly conserved sequence and structural features are discussed that allow LptB to fuel the transport of lipid A.

Published

2019

23. Structural basis of lipopolysaccharide extraction by the LptB2FGC complex

Author

Maofu Liao, Benjamin J. Orlando, and Yanyan Li

Subjects

Lipopolysaccharides, Models, Molecular, Lipopolysaccharide, Article, Protein–protein interaction, Lipopolysaccharide transport, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Escherichia coli, Inner membrane, 030304 developmental biology, 0303 health sciences, Multidisciplinary, 030306 microbiology, Escherichia coli Proteins, Cryoelectron Microscopy, Membrane Proteins, Transporter, Periplasmic space, Protein Subunits, Transmembrane domain, chemistry, Multiprotein Complexes, Biophysics, lipids (amino acids, peptides, and proteins), Vanadates, Bacterial outer membrane, Protein Binding

Abstract

In Gram-negative bacteria, lipopolysaccharide is essential for outer membrane formation and antibiotic resistance. The seven lipopolysaccharide transport (Lpt) proteins A-G move lipopolysaccharide from the inner to the outer membrane. The ATP-binding cassette transporter LptB2FG, which tightly associates with LptC, extracts lipopolysaccharide out of the inner membrane. The mechanism of the LptB2FG-LptC complex (LptB2FGC) and the role of LptC in lipopolysaccharide transport are poorly understood. Here we characterize the structures of LptB2FG and LptB2FGC in nucleotide-free and vanadate-trapped states, using single-particle cryo-electron microscopy. These structures resolve the bound lipopolysaccharide, reveal transporter-lipopolysaccharide interactions with side-chain details and uncover how the capture and extrusion of lipopolysaccharide are coupled to conformational rearrangements of LptB2FGC. LptC inserts its transmembrane helix between the two transmembrane domains of LptB2FG, which represents a previously unknown regulatory mechanism for ATP-binding cassette transporters. Our results suggest a role for LptC in achieving efficient lipopolysaccharide transport, by coordinating the action of LptB2FG in the inner membrane and Lpt protein interactions in the periplasm.

Published

2019

24. Lipopolysaccharide Transport Involves Long-Range Coupling between Cytoplasmic and Periplasmic Domains of the LptB 2 FGC Extractor

Author

Natividad Ruiz, Emily A. Lundstedt, and Brent W. Simpson

Subjects

0303 health sciences, biology, 030306 microbiology, ATPase, Periplasmic space, Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, Transmembrane domain, Cytoplasm, biology.protein, Biophysics, Inner membrane, Cell envelope, Bacterial outer membrane, Molecular Biology, 030304 developmental biology

Abstract

The cell surface of the Gram-negative cell envelope contains lipopolysaccharide (LPS) molecules, which form a permeability barrier against hydrophobic antibiotics. The LPS transport (Lpt) machine composed of LptB2FGCADE forms a proteinaceous trans-envelope bridge that allows for the rapid and specific transport of newly synthesized LPS from the inner membrane (IM) to the outer membrane (OM). This transport is powered from the IM by the ATP-binding cassette transporter LptB2FGC. The ATP-driven cycling between closed- and open-dimer states of the ATPase LptB2 is coupled to the extraction of LPS by the transmembrane domains LptFG. However, the mechanism by which LPS moves from a substrate-binding cavity formed by LptFG at the IM to the first component of the periplasmic bridge, the periplasmic β-jellyroll domain of LptF, is poorly understood. To better understand how LptB2FGC functions in Escherichia coli, we searched for suppressors of a defective LptB variant. We found that defects in LptB2 can be suppressed by both structural modifications to the core oligosaccharide of LPS and changes in various regions of LptFG, including a periplasmic loop in LptF that connects the substrate-binding cavity in LptFG to the periplasmic β-jellyroll domain of LptF. These novel suppressors suggest that interactions between the core oligosaccharide of LPS and periplasmic regions in the transporter influence the rate of LPS extraction by LptB2FGC. Together, our genetic data reveal a path for the bi-directional coupling between LptB2 and LptFG that extends from the cytoplasm to the entrance to the periplasmic bridge of the transporter.IMPORTANCEGram-negative bacteria are intrinsically resistant to many antibiotics due to the presence of lipopolysaccharide (LPS) at their cell surface. LPS is transported from its site of synthesis at the inner membrane to the outer membrane by the Lpt machine. Lpt proteins form a transporter that spans the entire envelope and is thought to function similarly to a PEZ candy dispenser. This trans-envelope machine is powered by the cytoplasmic LptB ATPase through a poorly understood mechanism. Using genetic analyses in Escherichia coli, we found that LPS transport involves long-ranging bi-directional coupling across cellular compartments between cytoplasmic LptB and periplasmic regions of the Lpt transporter. This knowledge could be exploited in developing antimicrobials that overcome the permeability barrier imposed by LPS.

Published

2021

25. The Escherichia coli Outer Membrane β-Barrel Assembly Machinery (BAM) Anchors the Peptidoglycan Layer by Spanning It with All Subunits

Author

Jean-François Collet, Tanneke den Blaauwen, Elisa Consoli, and UCL - SSS/DDUV/BCHM - Biochimie-Recherche métabolique

Subjects

0301 basic medicine, Braun’s lipoprotein, Protein subunit, 030106 microbiology, Braun's lipoprotein, outer membrane, peptidoglycan, Article, Catalysis, Protein–protein interaction, Lipopolysaccharide transport, lcsh:Chemistry, Inorganic Chemistry, 03 medical and health sciences, chemistry.chemical_compound, immunolabelling, Escherichia coli, Inner membrane, Physical and Theoretical Chemistry, Integral membrane protein, lcsh:QH301-705.5, Molecular Biology, Spectroscopy, BAM complex, Escherichia coli Proteins, Organic Chemistry, General Medicine, Computer Science Applications, 030104 developmental biology, chemistry, lcsh:Biology (General), lcsh:QD1-999, Biophysics, Peptidoglycan, Bacterial outer membrane, Bacterial Outer Membrane Proteins, β-barrel assembly machinery

Abstract

Gram-negative bacteria possess a three-layered envelope composed of an inner membrane, surrounded by a peptidoglycan (PG) layer, enclosed by an outer membrane. The envelope ensures protection against diverse hostile milieus and offers an effective barrier against antibiotics. The layers are connected to each other through many protein interactions. Bacteria evolved sophisticated machineries that maintain the integrity and the functionality of each layer. The β-barrel assembly machinery (BAM), for example, is responsible for the insertion of the outer membrane integral proteins including the lipopolysaccharide transport machinery protein LptD. Labelling bacterial cells with BAM-specific fluorescent antibodies revealed the spatial arrangement between the machinery and the PG layer. The antibody detection of each BAM subunit required the enzymatic digestion of the PG layer. Enhancing the spacing between the outer membrane and PG does not abolish this prerequisite. This suggests that BAM locally sets the distance between OM and the PG layer. Our results shed new light on the local organization of the envelope.

Published

2021

26. The Lipopolysaccharide Export Pathway in Escherichia coli: Structure, Organization and Regulated Assembly of the Lpt Machinery.

Author

Polissi, Alessandra and Sperandeo, Paola

Abstract

The bacterial outer membrane (OM) is a peculiar biological structure with a unique composition that contributes significantly to the fitness of Gram-negative bacteria in hostile environments. OM components are all synthesized in the cytosol and must, then, be transported efficiently across three compartments to the cell surface. Lipopolysaccharide (LPS) is a unique glycolipid that paves the outer leaflet of the OM. Transport of this complex molecule poses several problems to the cells due to its amphipatic nature. In this review, the multiprotein machinery devoted to LPS transport to the OM is discussed together with the challenges associated with this process and the solutions that cells have evolved to address the problem of LPS biogenesis. [ABSTRACT FROM AUTHOR]

Published

2014

27. Structure-function characterization of the conserved regulatory mechanism of the Escherichia coli M48 metalloprotease BepA

Author

Shu-Sin Chng, Faye C. Morris, Gabriela Boelter, Richard W. Meek, Manuel Banzhaf, George Kritikos, Andrew L. Lovering, Yanina R. Sevastsyanovich, Jack A. Bryant, Ian R. Henderson, Adam F. Cunningham, Zhi-Soon Chong, and Ian T. Cadby

Subjects

Proteases, LptD, outer membrane, BepA, Crystallography, X-Ray, medicine.disease_cause, M48 metalloprotease, Sensitivity and Specificity, Microbiology, Permeability, Lipopolysaccharide transport, Structure-Activity Relationship, 03 medical and health sciences, Escherichia coli, medicine, structure, Amino Acid Sequence, Molecular Biology, 030304 developmental biology, BAM complex, 0303 health sciences, biology, 030306 microbiology, Chemistry, Escherichia coli Proteins, lipopolysaccharide, Mutagenesis, Active site, protease, Periplasmic space, Cell biology, Tetratricopeptide, Metalloproteases, biology.protein, Bacterial outer membrane, Function (biology), Biogenesis, Research Article, Bacterial Outer Membrane Proteins

Abstract

M48 metalloproteases are widely distributed in all domains of life. E. coli possesses four members of this family located in multiple cellular compartments. The functions of these proteases are not well understood. Recent investigations revealed that one family member, BepA, has an important role in the maturation of a central component of the lipopolysaccharide (LPS) biogenesis machinery. Here, we present the structure of BepA and the results of a structure-guided mutagenesis strategy, which reveal the key residues required for activity that inform how all M48 metalloproteases function., The asymmetric Gram-negative outer membrane (OM) is the first line of defense for bacteria against environmental insults and attack by antimicrobials. The key component of the OM is lipopolysaccharide, which is transported to the surface by the essential lipopolysaccharide transport (Lpt) system. Correct folding of the Lpt system component LptD is regulated by a periplasmic metalloprotease, BepA. Here, we present the crystal structure of BepA from Escherichia coli, solved to a resolution of 2.18 Å, in which the M48 protease active site is occluded by an active-site plug. Informed by our structure, we demonstrate that free movement of the active-site plug is essential for BepA function, suggesting that the protein is autoregulated by the active-site plug, which is conserved throughout the M48 metalloprotease family. Targeted mutagenesis of conserved residues reveals that the negative pocket and the tetratricopeptide repeat (TPR) cavity are required for function and degradation of the BAM complex component BamA under conditions of stress. Last, we show that loss of BepA causes disruption of OM lipid asymmetry, leading to surface exposed phospholipid. IMPORTANCE M48 metalloproteases are widely distributed in all domains of life. E. coli possesses four members of this family located in multiple cellular compartments. The functions of these proteases are not well understood. Recent investigations revealed that one family member, BepA, has an important role in the maturation of a central component of the lipopolysaccharide (LPS) biogenesis machinery. Here, we present the structure of BepA and the results of a structure-guided mutagenesis strategy, which reveal the key residues required for activity that inform how all M48 metalloproteases function.

Published

2020

28. Mutational analysis of the essential lipopolysaccharide-transport protein LptH of Pseudomonas aeruginosa to uncover critical oligomerization sites

Author

Luca Federici, Romano Silvestri, Antonio Coluccia, Francesco Imperi, Adele Di Matteo, Paolo Visca, Carlo Travaglini-Allocatelli, Romina Scala, Alessandra Lo Sciuto, Scala, R., Di Matteo, A., Coluccia, A., Lo Sciuto, A., Federici, L., Travaglini-Allocatelli, C., Visca, P., Silvestri, R., and Imperi, F.

Subjects

0301 basic medicine, Lipopolysaccharides, Cytoplasm, LPS, 030106 microbiology, Mutant, DNA Mutational Analysis, lcsh:Medicine, conditional mutant, Crystallography, X-Ray, Article, Lipopolysaccharide transport, 03 medical and health sciences, Plasmid, Bacterial Proteins, Escherichia coli, biochemistry, lcsh:Science, Multidisciplinary, Binding Sites, Bacteria, Chemistry, Circular Dichroism, lcsh:R, Genetic Complementation Test, Bacteriology, Periplasmic space, Recombinant Proteins, Cell biology, Complementation, 030104 developmental biology, Mutation, Periplasm, Pseudomonas aeruginosa, lcsh:Q, Protein folding, Homologous recombination, Bacterial outer membrane, Genome, Bacterial, Plasmids

Abstract

Lipopolysaccharide (LPS) is a critical component of the outer membrane (OM) of many Gram-negative bacteria. LPS is translocated to the OM by the LPS transport (Lpt) system. In the human pathogen Pseudomonas aeruginosa, the periplasmic Lpt component, LptH, is essential for LPS transport, planktonic and biofilm growth, OM stability and infectivity. LptH has been proposed to oligomerize and form a protein bridge that accommodates LPS during transport. Based on the known LptH crystal structure, here we predicted by in silico modeling five different sites likely involved in LptH oligomerization. The relevance of these sites for LptH activity was verified through plasmid-mediated expression of site-specific mutant proteins in a P. aeruginosa lptH conditional mutant. Complementation and protein expression analyses provided evidence that all mutated sites are important for LptH activity in vivo. It was observed that the lptH conditional mutant overcomes the lethality of nonfunctional lptH variants through RecA-mediated homologous recombination between the wild-type lptH gene in the genome and mutated copies in the plasmid. Finally, biochemical assays on purified recombinant proteins showed that some LptH variants are indeed specifically impaired in oligomerization, while others appear to have defects in protein folding and/or stability.

Published

2020

29. Thanatin Impairs Lipopolysaccharide Transport Complex Assembly by Targeting LptC–LptA Interaction and Decreasing LptA Stability

Author

Jean-Pierre Simorre, Emanuela Erba, Cédric Laguri, Alessandra Romanelli, Alessandra M. Martorana, Elisabete C.C. M. Moura, Alessandra Polissi, Paola Sperandeo, Tiago Baeta, Dipartimento di Scienze Farmacologiche e Biomolecolari, Università degli Studi di Milano [Milano] (UNIMI), Institut de biologie structurale (IBS - UMR 5075), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Grenoble Alpes (UGA), Dipartimento di Scienze Farmaceutiche 'Pietro Pratesi' [Milan, Italie], and Università degli Studi di Milano = University of Milan (UNIMI)

Subjects

Microbiology (medical), thanatin, Antimicrobial peptides, lcsh:QR1-502, ATP-binding cassette transporter, Microbiology, lcsh:Microbiology, Bacterial cell structure, Lipopolysaccharide transport, 03 medical and health sciences, antimicrobial peptides, Inner membrane, 030304 developmental biology, Original Research, BACTH technique, 0303 health sciences, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], 030306 microbiology, Chemistry, lipopolysaccharide, Periplasmic space, Translocon, Lpt system, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, NMR, Cell biology, Bacterial outer membrane, bacterial cell wall

Abstract

International audience; The outer membrane (OM) of Gram-negative bacteria is a highly selective permeability barrier due to its asymmetric structure with lipopolysaccharide (LPS) in the outer leaflet. In Escherichia coli, LPS is transported to the cell surface by the LPS transport (Lpt) system composed of seven essential proteins forming a transenvelope bridge. Transport is powered by the ABC transporter LptB2FGC, which extracts LPS from the inner membrane (IM) and transfers it, through LptC protein, to the periplasmic protein LptA. Then, LptA delivers LPS to the OM LptDE translocon for final assembly at the cell surface. The Lpt protein machinery operates as a single device, since depletion of any component leads to the accumulation of a modified LPS decorated with repeating units of colanic acid at the IM outer leaflet. Moreover, correct machine assembly is essential for LPS transit and disruption of the Lpt complex results in LptA degradation. Due to its vital role in cell physiology, the Lpt system represents a good target for antimicrobial drugs. Thanatin is a naturally occurring antimicrobial peptide reported to cause defects in membrane assembly and demonstrated in vitro to bind to the N-terminal β-strand of LptA. Since this region is involved in both LptA dimerization and interaction with LptC, we wanted to elucidate the mechanism of inhibition of thanatin and discriminate whether its antibacterial effect is exerted by the disruption of the interaction of LptA with itself or with LptC. For this purpose, we here implemented the Bacterial Adenylate Cyclase Two-Hybrid (BACTH) system to probe in vivo the Lpt interactome in the periplasm. With this system, we found that thanatin targets both LptC-LptA and LptA-LptA interactions, with a greater inhibitory effect on the former. We confirmed in vitro the disruption of LptC-LptA interaction using two different biophysical techniques. Finally, we observed that in cells treated with thanatin, LptA undergoes degradation and LPS decorated with colanic acid accumulates. These data further support inhibition or disruption of Lpt complex assembly as the main killing mechanism of thanatin against Gram-negative bacteria.

Published

2020

30. Outer Membrane Translocon Communicates with Inner Membrane ATPase To Stop Lipopolysaccharide Transport

Author

Ran Xie, Daniel Kahne, and Rebecca J. Taylor

Subjects

Lipopolysaccharides, 0301 basic medicine, Lipopolysaccharide, Proteolipids, ATPase, 030106 microbiology, Biochemistry, Article, Catalysis, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Colloid and Surface Chemistry, ATP hydrolysis, Escherichia coli, Inner membrane, Adenosine Triphosphatases, biology, Chemistry, Escherichia coli Proteins, Hydrolysis, Biological Transport, General Chemistry, Translocon, 030104 developmental biology, Membrane, biology.protein, Biophysics, lipids (amino acids, peptides, and proteins), Carrier Proteins, Bacterial outer membrane, Bacterial Outer Membrane Proteins

Abstract

The survival of Gram-negative bacteria depends on assembly of the asymmetric outer membrane, which creates a barrier that prevents entry of toxic molecules including antibiotics. The outer leaflet of the outer membrane is composed of lipopolysaccharide, which is made at the inner membrane and pushed across a protein bridge that spans the inner and outer membranes. We have developed a fluorescent assay to follow lipopolysaccharide (LPS) transport across a bridge linking proteoliposomes that mimic the inner and outer membranes. We show that LPS is delivered to the leaflet of the outer membrane proteoliposome that corresponds to the outer leaflet of the membrane in a cell. Transport stops long before substrates at the inner membrane are exhausted. Using mutants of the transport machinery, we find that the final amount of LPS delivered into the membrane depends on the affinity of the outer membrane translocon for LPS. Furthermore, ATP hydrolysis depends on delivery of LPS into the outer membrane. Therefore, the transport process is regulated by the outer membrane translocon causing ATP hydrolysis in the inner membrane proteoliposome to stop. Negative feedback from the outer membrane to the inner membrane provides a mechanism for long distance control over LPS transport.

Published

2018

31. Outer-membrane protein LptD (PA0595) plays a role in the regulation of alginate synthesis in Pseudomonas aeruginosa

Author

Hansi Kumari, Sundar Pandey, Laura Florez, Camila Delgado, and Kalai Mathee

Subjects

0301 basic medicine, Microbiology (medical), Mutation, Pseudomonas aeruginosa, Chemistry, 030106 microbiology, Mutant, General Medicine, medicine.disease_cause, Microbiology, Cell biology, Lipopolysaccharide transport, Complementation, 03 medical and health sciences, Sigma factor, medicine, Bacterial outer membrane, Gene, Research Article

Abstract

PURPOSE: The presence of alginate-overproducing (Alg(+)) strains of Pseudomonas aeruginosa in cystic fibrosis patients is indicative of chronic infection. The Alg(+) phenotype is generally due to a mutation in the mucA gene, encoding an innermembrane protein that sequesters AlgT/U, the alginate-specific sigma factor. AlgT/U release from the anti-sigma factor MucA is orchestrated via a complex cascade called regulated intramembrane proteolysis. The goal of this study is to identify new players involved in the regulation of alginate production. METHODOLOGY: Previously, a mutant with a second-site suppressor of alginate production (sap), sap27, was isolated from the constitutively Alg(+) PDO300 that harbours the mucA22 allele. A cosmid from a P. aeruginosa minimum tiling path library was identified via en masse complementation of sap27. The cosmid was transposon mutagenized to map the contributing gene involved in the alginate production. The identified gene was sequenced in sap27 along with algT/U, mucA, algO and mucP. The role of the novel gene was explored using precise in-frame algO and algW deletion mutants of PAO1 and PDO300. RESULTS/KEY FINDINGS: The gene responsible for restoring the mucoid phenotype was mapped to lptD encoding an outer-membrane protein. However, the sequencing of sap27 revealed a mutation in algO, but not in lptD. In addition, we demonstrate that lipopolysaccharide transport protein D (LptD)-dependent alginate production requires AlgW in PAO1 and AlgO in PDO300. CONCLUSION: LptD plays a specific role in alginate production. Our findings suggest that there are two pathways for the production of alginate in P. aeruginosa, one involving AlgW in the wild-type, and one involving AlgO in the mucA22 mutant.

Published

2018

32. Novobiocin Enhances Polymyxin Activity by Stimulating Lipopolysaccharide Transport

Author

Vadim Baidin, Tristan W. Owens, James Lee, Karanbir S. Pahil, Michael D. Mandler, and Daniel Kahne

Subjects

Acinetobacter baumannii, Lipopolysaccharides, 0301 basic medicine, Lipopolysaccharide, medicine.drug_class, ATPase, Polymyxin, 030106 microbiology, Biochemistry, DNA gyrase, Article, Catalysis, Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, medicine, Polymyxins, Novobiocin, biology, Chemistry, Biological Transport, General Chemistry, biochemical phenomena, metabolism, and nutrition, 030104 developmental biology, DNA Gyrase, Colistin, biology.protein, lipids (amino acids, peptides, and proteins), Bacterial outer membrane, medicine.drug

Abstract

Gram-negative bacteria are challenging to kill with antibiotics due to their impenetrable outer membrane containing lipopolysaccharide (LPS). The polymyxins, including colistin, are the drugs of last resort for treating Gram-negative infections. These drugs bind LPS and disrupt the outer membrane; however, their toxicity limits their usefulness. Polymyxin has been shown to synergize with many antibiotics including novobiocin, which inhibits DNA gyrase, by facilitating transport of these antibiotics across the outer membrane. Recently, we have shown that novobiocin not only inhibits DNA gyrase, but also binds and stimulates LptB, the ATPase that powers LPS transport. Here, we report the synthesis of novobiocin derivatives that separate these two activities. One analog retains LptB-stimulatory activity but is unable to inhibit DNA gyrase. This analog, which is not toxic on its own, nevertheless enhances the lethality of polymyxin by binding LptB and stimulating LPS transport. Therefore, LPS transport agonism contributes substantially to novobiocin-polymyxin synergy. We also report other novobiocin analogs that inhibit DNA gyrase better than or equal to novobiocin, but bind better to LptB and therefore have even greater LptB stimulatory activity. These compounds are more potent than novobiocin when used in combination with polymyxin. Novobiocin analogs optimized for both gyrase inhibition and LPS transport agonism may allow the use of lower doses of polymyxin, increasing its efficacy and safety.

Published

2018

33. Disruption of the E. coli LptC dimerization interface and characterization of lipopolysaccharide and LptA binding to monomeric LptC

Author

Elizabeth L. Noey, Kathryn M. Schultz, Candice S. Klug, and Matthew A. Fischer

Subjects

0301 basic medicine, Circular dichroism, Protein family, Chemistry, Dimer, 030106 microbiology, Site-directed spin labeling, Periplasmic space, Biochemistry, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Biophysics, Inner membrane, Bacterial outer membrane, Molecular Biology

Abstract

Lipopolysaccharide (LPS) is an essential element of nearly all Gram-negative bacterial outer membranes and serves to protect the cell from adverse environmental stresses. Seven members of the lipopolysaccharide transport (Lpt) protein family function together to transport LPS from the inner membrane (IM) to the outer leaflet of the outer membrane of bacteria such as Escherichia coli. Each of these proteins has a solved crystal structure, including LptC, which is a largely periplasmic protein that is associated with the IM LptB2 FG complex and anchored to the membrane by an N-terminal helix. LptC directly binds LPS and is hypothesized to be involved in the transfer of LPS to another periplasmic protein, LptA. Purified and in solution, LptC forms a dimer. Here, point mutations designed to disrupt formation of the dimer are characterized using site-directed spin labeling double electron electron resonance (DEER) spectroscopy, light scattering, circular dichroism, and computational modeling. The computational studies reveal the molecular interactions that drive dimerization of LptC and elucidate how the disruptive mutations change this interaction, while the DEER and light scattering studies identify which mutants disrupt the dimer. And, using electron paramagnetic resonance spectroscopy and comparing the results to the previous quantitative characterization of the interactions between dimeric LptC and LPS and LptA, the functional consequences of monomeric LptC were also determined. These results indicate that disruption of the dimer does not affect LPS or LptA binding and that monomeric LptC binds LPS and LptA at levels similar to dimeric LptC.

Published

2018

34. LPS Transport: Flipping Out over MsbA

Author

Bradley J. Voss and M. Stephen Trent

Subjects

Lipopolysaccharides, 0301 basic medicine, 030106 microbiology, Transport pathways, Biological Transport, ATP-binding cassette transporter, Transporter, Biology, Lipopolysaccharide synthesis, Article, General Biochemistry, Genetics and Molecular Biology, Cell biology, Lipopolysaccharide transport, 03 medical and health sciences, 030104 developmental biology, Bacterial Proteins, Escherichia coli, lipids (amino acids, peptides, and proteins), ATP-Binding Cassette Transporters, General Agricultural and Biological Sciences, LPS transport

Abstract

Lipopolysaccharide (LPS) in the outer membrane of Gram-negative bacteria is critical for their cell envelope assembly. LPS synthesized in the cytoplasmic leaflet of the inner membrane is flipped to the periplasmic leaflet by MsbA, an ATP-binding cassette transporter. Despite substantial efforts, the structural mechanisms underlying MsbA-driven LPS flipping remain elusive. Here, we use single-particle cryo-EM to elucidate the structures of lipid nanodisc-embedded MsbA in three functional states. The 4.2 Å-resolution structure of the transmembrane domains of nucleotide-free MsbA reveals that LPS binds deeply inside MsbA at the height of the periplasmic leaflet, establishing extensive hydrophilic and hydrophobic interactions with MsbA. Two subnanometer-resolution structures of MsbA with ADP-vanadate and ADP reveal an unprecedented closed and an inward-facing conformation, respectively. Our study uncovers the long-sought-after structural basis for LPS recognition, delineates the conformational transitions of MsbA to flip LPS, and paves the way for structural characterization of other lipid flippases.

Published

2018

35. The Antibiotic Novobiocin Binds and Activates the ATPase That Powers Lipopolysaccharide Transport

Author

Rebecca M. Davis, Janine M. May, Michael B. Lazarus, Brent W. Simpson, Suguru Okuda, Natividad Ruiz, Walter Massefski, David J. Sherman, Daniel Kahne, Tristan W. Owens, and Michael D. Mandler

Subjects

Lipopolysaccharides, 0301 basic medicine, ATPase, Biochemistry, DNA gyrase, Article, Catalysis, Lipopolysaccharide transport, 03 medical and health sciences, Adenosine Triphosphate, Colloid and Surface Chemistry, ATP hydrolysis, Escherichia coli, medicine, heterocyclic compounds, Binding site, Novobiocin, Adenosine Triphosphatases, Binding Sites, biology, Chemistry, Hydrolysis, Biological Transport, General Chemistry, biochemical phenomena, metabolism, and nutrition, Transmembrane protein, Anti-Bacterial Agents, Enzyme Activation, carbohydrates (lipids), 030104 developmental biology, DNA Gyrase, biology.protein, bacteria, Bacterial outer membrane, medicine.drug

Abstract

Novobiocin is an orally active antibiotic that inhibits DNA gyrase by binding the ATP-binding site in the ATPase subunit. Although effective against Gram-positive pathogens, novobiocin has limited activity against Gram-negative organisms due to the presence of the lipopolysaccharide-containing outer membrane, which acts as a permeability barrier. Using a novobiocin-sensitive Escherichia coli strain with a leaky outer membrane, we identified a mutant with increased resistance to novobiocin. Unexpectedly, the mutation that increases novobiocin resistance was not found to alter gyrase, but the ATPase that powers lipopolysaccharide (LPS) transport. Co-crystal structures, biochemical, and genetic evidence show novobiocin directly binds this ATPase. Novobiocin does not bind the ATP binding site but rather the interface between the ATPase subunits and the transmembrane subunits of the LPS transporter. This interaction increases the activity of the LPS transporter, which in turn alters the permeability of the outer membrane. We propose that novobiocin will be a useful tool for understanding how ATP hydrolysis is coupled to LPS transport.

Published

2017

36. The lipopolysaccharide transport (Lpt) machinery: A nonconventional transporter for lipopolysaccharide assembly at the outer membrane of Gram-negative bacteria

Author

Alessandra Polissi, Paola Sperandeo, and Alessandra M. Martorana

Subjects

Lipopolysaccharides, 0301 basic medicine, Gram-negative bacteria, Lipopolysaccharide, Protein Conformation, 030106 microbiology, ATP-binding cassette transporter, Models, Biological, Biochemistry, Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Gram-Negative Bacteria, Carbohydrate Conformation, Lipid bilayer, Molecular Biology, biology, Biological Transport, Minireviews, Cell Biology, biology.organism_classification, Cell biology, 030104 developmental biology, chemistry, ATP-Binding Cassette Transporters, lipids (amino acids, peptides, and proteins), Carrier Proteins, Bacterial outer membrane, Bacteria, Biogenesis, Bacterial Outer Membrane Proteins

Abstract

The outer membrane (OM) of Gram-negative is a unique lipid bilayer containing LPS in its outer leaflet. Because of the presence of amphipathic LPS molecules, the OM behaves as an effective permeability barrier that makes Gram-negative bacteria inherently resistant to many antibiotics. This review focuses on LPS biogenesis and discusses recent advances that have contributed to our understanding of how this complex molecule is transported across the cellular envelope and is assembled at the OM outer leaflet. Clearly, this knowledge represents an important platform for the development of novel therapeutic options to manage Gram-negative infections.

Published

2017

37. Lipopolysaccharide biogenesis and transport at the outer membrane of Gram-negative bacteria

Author

Paola Sperandeo, Alessandra Polissi, and Alessandra M. Martorana

Subjects

Lipopolysaccharides, Models, Molecular, 0301 basic medicine, Gram-negative bacteria, Lipopolysaccharide, ATP-binding cassette transporter, Lipopolysaccharide transport, Cell membrane, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, Gram-Negative Bacteria, medicine, Molecular Biology, Molecular Structure, biology, Membrane transport protein, Lipogenesis, Cell Membrane, Membrane Transport Proteins, Biological Transport, Cell Biology, biology.organism_classification, 030104 developmental biology, medicine.anatomical_structure, Biochemistry, chemistry, biology.protein, ATP-Binding Cassette Transporters, lipids (amino acids, peptides, and proteins), Bacterial outer membrane, Biogenesis, Bacterial Outer Membrane Proteins

Abstract

The outer membrane (OM) of Gram-negative bacteria is an asymmetric lipid bilayer containing a unique glycolipid, lipopolysaccharide (LPS) in its outer leaflet. LPS molecules confer to the OM peculiar permeability barrier properties enabling Gram-negative bacteria to exclude many toxic compounds, including clinically useful antibiotics, and to survive harsh environments. Transport of LPS poses several problems to the cells due to the amphipatic nature of this molecule. In this review we summarize the current knowledge on the LPS transport machinery, discuss the challenges associated with this process and present the solutions that bacterial cells have evolved to address the problem of LPS transport and assembly at the cell surface. Finally, we discuss how knowledge on LPS biogenesis can be translated for the development of novel antimicrobial therapies. This article is part of a Special Issue entitled: Bacterial Lipids edited by Russell E. Bishop.

Published

2017

38. Structural insight into lipopolysaccharide transport from the Gram-negative bacterial inner membrane to the outer membrane

Author

Xiaodi Tang, Haohao Dong, Changjiang Dong, and Zhengyu Zhang

Subjects

Lipopolysaccharides, Models, Molecular, 0301 basic medicine, Gram-negative bacteria, Lipopolysaccharide, Protein Conformation, 030106 microbiology, Biological Transport, Active, ATP-binding cassette transporter, Models, Biological, Lipopolysaccharide transport, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Cell Wall, Gram-Negative Bacteria, Inner membrane, Molecular Biology, biology, Hydrolysis, Cell Membrane, Cell Biology, Periplasmic space, biology.organism_classification, Transmembrane protein, Cell biology, 030104 developmental biology, chemistry, Biochemistry, ATP-Binding Cassette Transporters, lipids (amino acids, peptides, and proteins), Bacterial outer membrane, Bacterial Outer Membrane Proteins

Abstract

Lipopolysaccharide (LPS) is an important component of the outer membrane (OM) of Gram-negative bacteria, playing essential roles in protecting bacteria from harsh environments, in drug resistance and in pathogenesis. LPS is synthesized in the cytoplasm and translocated to the periplasmic side of the inner membrane (IM), where it matures. Seven lipopolysaccharide transport proteins, LptA-G, form a trans‑envelope complex that is responsible for LPS extraction from the IM and transporting it across the periplasm to the OM. The LptD/E of the complex transports LPS across the OM and inserts it into the outer leaflet of the OM. In this review we focus upon structural and mechanistic studies of LPS transport proteins, with a particular focus upon the LPS ABC transporter LptB2FG. This ATP binding cassette transporter complex consists of twelve transmembrane segments and has a unique mechanism whereby it extracts LPS from the periplasmic face of the IM through a pair of lateral gates and then powers trans‑periplasmic transport to the OM through a slide formed by either of the periplasmic domains of LptF or LptG, LptC, LptA and the N-terminal domain of LptD. The structural and functional studies of the seven lipopolysaccharide transport proteins provide a platform to explore the unusual mechanisms of LPS extraction, transport and insertion from the inner membrane to the outer membrane. This article is part of a Special Issue entitled: Bacterial Lipids edited by Russell E. Bishop.

Published

2017

39. Characterization of and lipopolysaccharide binding to the E. coli LptC protein dimer

Author

Kathryn M. Schultz and Candice S. Klug

Subjects

0301 basic medicine, Chemistry, 030106 microbiology, Protein dimer, Periplasmic space, Biochemistry, Transport protein, Lipopolysaccharide binding, Lipopolysaccharide transport, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Membrane protein, Biophysics, Inner membrane, lipids (amino acids, peptides, and proteins), Bacterial outer membrane, Molecular Biology

Abstract

Lipopolysaccharide (LPS, endotoxin) is the major component of the outer leaflet of the outer membrane of Gram-negative bacteria such as Escherichia coli and Salmonella typhimurium. LPS is a large lipid containing several acyl chains as its hydrophobic base and numerous sugars as its hydrophilic core and O-antigen domains, and is an essential element of the organisms' natural defenses in adverse environmental conditions. LptC is one of seven members of the lipopolysaccharide transport (Lpt) protein family that functions to transport LPS from the inner membrane (IM) to the outer leaflet of the outer membrane of the bacterium. LptC is anchored to the IM and associated with the IM LptFGB2 complex. It is hypothesized that LPS binds to LptC at the IM, transfers to LptA to cross the periplasm, and is inserted by LptDE into the outer leaflet of the outer membrane. The studies described here comprehensively characterize and quantitate the binding of LPS to LptC. Site-directed spin labeling electron paramagnetic resonance spectroscopy was utilized to characterize the LptC dimer in solution and monitor spin label mobility changes at 10 sites across the protein upon addition of exogenous LPS. The results indicate that soluble LptC forms concentration-independent N-terminal dimers in solution, LptA binding does not change the conformation of the LptC dimer nor appreciably disrupt the LptC dimer in vitro, and LPS binding affects the entire LptC protein, with the center and C-terminal regions showing a greater affinity for LPS than the N-terminal domain, which has similar dissociation constants to LptA.

Published

2017

40. Structural studies of β-hairpin peptidomimetic antibiotics that target LptD in Pseudomonas sp.

Author

Schmidt, Jasmin, Patora-Komisarska, Krystyna, Moehle, Kerstin, Obrecht, Daniel, and Robinson, John A.

Subjects

*PEPTIDOMIMETICS, *ANTIBIOTICS, *PSEUDOMONAS, *AQUEOUS solutions, *CYCLIC peptides, *LIPOPOLYSACCHARIDES

Abstract

Abstract: We report structural studies in aqueous solution on backbone cyclic peptides that possess potent antimicrobial activity specifically against Pseudomonas sp. The peptides target the β-barrel outer membrane protein LptD, which plays an essential role in lipopolysaccharide transport to the outer membrane. The peptide L27-11 contains a 12-residue loop (T1W2L3K4K5R6R7W8K9K10A11K12) linked to a DPro–LPro template. Two related peptides were also studied, one with various Lys to ornithine or diaminobutyric acid substitutions as well as a DLys6 (called LB-01), and another containing the same loop sequence, but linked to an LPro–DPro template (called LB-02). NMR studies and MD simulations show that L27-11 and LB-01 adopt β-hairpin structures in solution. In contrast, LB-02 is more flexible and importantly, adopts a wide variety of different backbone conformations, but not β-hairpin conformations. L27-11 and LB-01 show antimicrobial activity in the nanomolar range against Pseudomonas aeruginosa , whereas LB-02 is essentially inactive. Thus the β-hairpin structure of the peptide is important for antimicrobial activity. An alanine scan of L27-11 revealed that tryptophan side chains (W2/W8) displayed on opposite faces of the β-hairpin represent key groups contributing to antimicrobial activity. [Copyright &y& Elsevier]

Published

2013

41. Novel Structure of the Conserved Gram-Negative Lipopolysaccharide Transport Protein A and Mutagenesis Analysis

Author

Suits, Michael D.L., Sperandeo, Paola, Dehò, Gianni, Polissi, Alessandra, and Jia, Zongchao

Subjects

*ENDOTOXINS, *CARRIER proteins, *GRAM-negative bacteria, *MUTAGENESIS

Abstract

Abstract: Lipopolysaccharide (LPS) transport protein A (LptA) is an essential periplasmic localized transport protein that has been implicated together with MsbA, LptB, and the Imp/RlpB complex in LPS transport from the inner membrane to the outer membrane, thereby contributing to building the cell envelope in Gram-negative bacteria and maintaining its integrity. Here we present the first crystal structures of processed Escherichia coli LptA in two crystal forms, one with two molecules in the asymmetric unit and the other with eight. In both crystal forms, severe anisotropic diffraction was corrected, which facilitated model building and structural refinement. The eight-molecule form of LptA is induced when LPS or Ra-LPS (a rough chemotype of LPS) is included during crystallization. The unique LptA structure represents a novel fold, consisting of 16 consecutive antiparallel β-strands, folded to resemble a slightly twisted β-jellyroll. Each LptA molecule interacts with an adjacent LptA molecule in a head-to-tail fashion to resemble long fibers. Site-directed mutagenesis of conserved residues located within a cluster that delineate the N-terminal β-strands of LptA does not impair the function of the protein, although their overexpression appears more detrimental to LPS transport compared with wild-type LptA. Moreover, altered expression of both wild-type and mutated proteins interfered with normal LPS transport as witnessed by the production of an anomalous form of LPS. Structural analysis suggests that head-to-tail stacking of LptA molecules could be destabilized by the mutation, thereby potentially contributing to impair LPS transport. [Copyright &y& Elsevier]

Published

2008

42. High-Pressure EPR Spectroscopy Studies of the E. coli Lipopolysaccharide Transport Proteins LptA and LptC

Author

Kathryn M. Schultz and Candice S. Klug

Subjects

0301 basic medicine, education.field_of_study, Atmospheric pressure, Chemistry, 030106 microbiology, Population, Analytical chemistry, Periplasmic space, medicine.disease_cause, Atomic and Molecular Physics, and Optics, Transport protein, law.invention, Lipopolysaccharide transport, 03 medical and health sciences, 030104 developmental biology, Protein structure, law, medicine, Biophysics, education, Electron paramagnetic resonance, Escherichia coli

Abstract

The use of pressure is an advantageous approach to the study of protein structure and dynamics because it can shift the equilibrium populations of protein conformations toward higher energy states that are not of sufficient population to be observable at atmospheric pressure. Recently, the Hubbell group at the University of California, Los Angeles, reintroduced the application of high pressure to the study of proteins by electron paramagnetic resonance (EPR) spectroscopy. This methodology is possible using X-band EPR spectroscopy due to advances in pressure intensifiers, sample cells, and resonators. In addition to the commercial availability of the pressure generation and sample cells by Pressure Biosciences Inc., a five-loop-four-gap resonator required for the initial high pressure EPR spectroscopy experiments by the Hubbell group, and those reported here, was designed by James S. Hyde and built and modified at the National Biomedical EPR Center. With these technological advances, we determined the effect of pressure on the essential periplasmic lipopolysaccharide (LPS) transport protein from Escherichia coli, LptA, and one of its binding partners, LptC. LptA unfolds from the N-terminus to the C-terminus, binding of LPS does not appreciably stabilize the protein under pressure, and monomeric LptA unfolds somewhat more readily than oligomeric LptA upon pressurization to 2 kbar. LptC exhibits a fold and relative lack of stability upon LPS binding similar to LptA, yet adopts an altered, likely monomeric, folded conformation under pressure with only its C-terminus unraveling. The pressure-induced changes likely correlate with functional changes associated with binding and transport of LPS.

Published

2017

43. Structural basis for lipopolysaccharide extraction by ABC transporter LptB2FG

Author

Xinzheng Zhang, Le Xiao, Chuanqi Sun, Tingting Li, Min Zhou, Huigang Shi, Xu Yang, Dianfan Li, Kun Wang, Guangyu Zhu, Qingshan Luo, Yihua Huang, and Shan Yu

Subjects

0301 basic medicine, 030106 microbiology, Transporter, ATP-binding cassette transporter, Periplasmic space, Biology, Lipopolysaccharide transport, 03 medical and health sciences, Transmembrane domain, 030104 developmental biology, Biochemistry, Structural Biology, Cytoplasm, Biophysics, Inner membrane, Bacterial outer membrane, Molecular Biology

Abstract

After biosynthesis, bacterial lipopolysaccharides (LPS) are transiently anchored to the outer leaflet of the inner membrane (IM). The ATP-binding cassette (ABC) transporter LptB2FG extracts LPS molecules from the IM and transports them to the outer membrane. Here we report the crystal structure of nucleotide-free LptB2FG from Pseudomonas aeruginosa. The structure reveals that lipopolysaccharide transport proteins LptF and LptG each contain a transmembrane domain (TMD), a periplasmic β-jellyroll-like domain and a coupling helix that interacts with LptB on the cytoplasmic side. The LptF and LptG TMDs form a large outward-facing V-shaped cavity in the IM. Mutational analyses suggest that LPS may enter the central cavity laterally, via the interface of the TMD domains of LptF and LptG, and is expelled into the β-jellyroll-like domains upon ATP binding and hydrolysis by LptB. These studies suggest a mechanism for LPS extraction by LptB2FG that is distinct from those of classical ABC transporters that transport substrates across the IM.

Published

2017

44. Mutations in pmrB Confer Cross-Resistance between the LptD Inhibitor POL7080 and Colistin in Pseudomonas aeruginosa

Author

Alexander R. Loftis, Thulasi Warrier, Keith P. Romano, Bradley E. Poulsen, Bradley L. Pentelute, Azin Saebi, Phuong H. Nguyen, and Deborah T. Hung

Subjects

POL7001, antibiotic resistance, medicine.drug_class, Polymyxin, Antibiotics, POL7080, Microbial Sensitivity Tests, Biology, medicine.disease_cause, polymyxins, Peptides, Cyclic, Microbiology, Lipopolysaccharide transport, pmrB, 03 medical and health sciences, Antibiotic resistance, Bacterial Proteins, Mechanisms of Resistance, multidrug resistance, Pseudomonas, Drug Resistance, Bacterial, medicine, Pharmacology (medical), 030304 developmental biology, Pharmacology, 0303 health sciences, 030306 microbiology, Pseudomonas aeruginosa, Colistin, murepavadin, Gene Expression Regulation, Bacterial, biology.organism_classification, 3. Good health, Anti-Bacterial Agents, Multiple drug resistance, Infectious Diseases, Mutation, medicine.drug, Bacterial Outer Membrane Proteins, Transcription Factors

Abstract

Pseudomonas aeruginosa is a major bacterial pathogen associated with a rising prevalence of antibiotic resistance. We evaluated the resistance mechanisms of P. aeruginosa against POL7080, a species-specific, first-in-class antibiotic in clinical trials that targets the lipopolysaccharide transport protein LptD. We isolated a series of POL7080-resistant strains with mutations in the two-component sensor gene pmrB., Pseudomonas aeruginosa is a major bacterial pathogen associated with a rising prevalence of antibiotic resistance. We evaluated the resistance mechanisms of P. aeruginosa against POL7080, a species-specific, first-in-class antibiotic in clinical trials that targets the lipopolysaccharide transport protein LptD. We isolated a series of POL7080-resistant strains with mutations in the two-component sensor gene pmrB. Transcriptomic and confocal microscopy studies support a resistance mechanism shared with colistin, involving lipopolysaccharide modifications that mitigate antibiotic cell surface binding.

Published

2019

45. Structure-function analysis of the Escherichia coli β–barrel assembly enhancing protease BepA suggests a role for a self-inhibitory state

Author

Ian R. Henderson, Richard W. Meek, Adam F. Cunningham, Manuel Banzhaf, George Kritikos, Faye C. Morris, Ian T. Cadby, Shu-Sin Chng, Jack A. Bryant, Andrew L. Lovering, Yana R. Sevastsyanovich, and Zhi-Soon Chong

Subjects

Lipopolysaccharide transport, Tetratricopeptide, Protease, Chemistry, medicine.medical_treatment, Mutagenesis, medicine, Biophysics, Periplasmic space, Binding site, Bacterial outer membrane, Barrier function

Abstract

The asymmetric Gram-negative outer membrane (OM) is the first line of defence for the bacteria against environmental insults and attack by antimicrobials. The key component of the OM barrier is the surface exposed lipopolysaccharide, which is transported to the surface by the essential lipopolysaccharide transport (Lpt) system. Correct folding of the Lpt system OM component, LptD, is essential and is regulated by a periplasmic metalloprotease, BepA. Here we present the crystal structure of BepA, solved to a resolution of 1.9 Å. Our structure comprises the zinc-bound m48 protease domain and a tetratricopeptide repeat (TPR) domain, consisting of four 2-helix TPR motifs and four non-TPR helices, leading to a nautilus-like shape in which the TPR repeats cup the protease domain. Using targeted mutagenesis approaches, we demonstrate that the protein is auto-regulated by the active-site plug. Further to this we reveal that mutation of a negative pocket, formed at the interface between the m48 and TPR domains, impairs BepA activity suggesting the pocket as a possible substrate binding site. We also identify a potential protein interaction site within the TPR cavity as being important for BepA function. Lastly, we provide evidence to show that increased antibiotic susceptibility in the absence of correctly functioning BepA occurs through disruption of OM lipid asymmetry, leading to reduced barrier function and increased cell permeability.

Published

2019

46. Defects in Efflux ( oprM ), β-Lactamase ( ampC ), and Lipopolysaccharide Transport ( lptE ) Genes Mediate Antibiotic Hypersusceptibility of Pseudomonas aeruginosa Strain Z61

Author

Nicole V Johnson, S. Whitney Barnes, John R. Walker, Xiaoyu Shen, Angela L. Woods, Naomi N. K. Kreamer, Charles R. Dean, and David A. Six

Subjects

Pharmacology, 0303 health sciences, Mutation, 030306 microbiology, Chemistry, Pseudomonas aeruginosa, Mutant, Mutagenesis (molecular biology technique), biochemical phenomena, metabolism, and nutrition, medicine.disease_cause, Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, Infectious Diseases, medicine, Pharmacology (medical), Efflux, Bacterial outer membrane, Escherichia coli, 030304 developmental biology

Abstract

Antibiotic hypersensitive bacterial mutants (e.g., Escherichia coli imp) are used to investigate intrinsic resistance and are exploited in antibacterial discovery to track weak antibacterial activity of novel inhibitor compounds. Pseudomonas aeruginosa Z61 is one such drug-hypersusceptible strain generated by chemical mutagenesis, although the genetic basis for hypersusceptibility is not fully understood. Genome sequencing of Z61 revealed nonsynonymous single-nucleotide polymorphisms in 153 genes relative to its parent strain, and three candidate mutations (in oprM, ampC, and lptE) predicted to mediate hypersusceptibility were characterized. The contribution of these mutations was confirmed by genomic restoration of the wild-type sequences, individually or in combination, in the Z61 background. Introduction of the lptE mutation or genetic inactivation of oprM and ampC genes alone or together in the parent strain recapitulated drug sensitivities. This showed that disruption of oprM (which encodes a major outer membrane efflux pump channel) increased susceptibility to pump substrate antibiotics, that inactivation of the inducible β-lactamase gene ampC contributed to β-lactam susceptibility, and that mutation of the lipopolysaccharide transporter gene lptE strongly altered the outer membrane permeability barrier, causing susceptibility to large antibiotics such as rifampin and also to β-lactams.

Published

2019

47. Role of LptD in Resistance to Glutaraldehyde and Pathogenicity in Riemerella anatipestifer

Author

Li Huang, Mingshu Wang, Ting Mo, Mafeng Liu, Francis Biville, Dekang Zhu, Renyong Jia, Shun Chen, Xinxin Zhao, Qiao Yang, Ying Wu, Shaqiu Zhang, Juan Huang, Bin Tian, Yunya Liu, Ling Zhang, Yanling Yu, Leichang Pan, Mujeeb Ur Rehman, Xiaoyue Chen, and Anchun Cheng

Subjects

Microbiology (medical), 0303 health sciences, Riemerella anatipestifer, Membrane permeability, biology, 030306 microbiology, Chemistry, lipopolysaccharide, Biofilm, lcsh:QR1-502, Drug resistance, LptD, biology.organism_classification, Microbiology, hydrophobic drug resistance, lcsh:Microbiology, Lipopolysaccharide transport, 03 medical and health sciences, Minimum inhibitory concentration, membrane permeability, Pathogen, Bacteria, 030304 developmental biology

Abstract

Riemerella anatipestifer is a gram-negative bacterium that causes disease in ducks and other birds. Despite being an important pathogen in poultry, the pathogenesis and drug resistance mechanisms of this bacterium are poorly understood. An analysis of our unpublished RNA-Seq data showed that lptD, a gene encoding one of the lipopolysaccharide transport components, is transcribed at higher levels in strain CH-1 than in strain ATCC11845. In addition, strain CH-1 has been shown to display broader drug resistance than strain ATCC11845. Since LptD is involved in LPS biogenesis and drug resistance, we wondered if lptD is associated with increased R. anatipestifer resistance to glutaraldehyde, a disinfectant used in the production industry. In this study, the minimal inhibitory concentration (MIC) of glutaraldehyde for strain CH-1 was determined to be 0.125% (vol/vol), whereas an MIC of 0.05% (vol/vol) was observed for strain ATCC11845. Furthermore, the level of lptD transcription in strain CH-1 was consistently 2-fold higher than that observed in strain ATCC11845. Moreover, lptD transcription was upregulated in both strains at a subinhibitory concentration of glutaraldehyde. The role of lptD in R. anatipestifer was further assessed by constructing an ATCC11845 mutant strain with low lptD expression, R. anatipestifer ATCC11845 lptD -. The growth of R. anatipestifer ATCC11845 lptD - was severely impaired, and this strain was more susceptible than the wild-type strain to glutaraldehyde. Moreover, compared to the wild-type strain, R. anatipestifer ATCC11845 lptD - exhibited decreased biofilm formation and was more sensitive to duck serum. Finally, low lptD expression led to decreased colonization in ducklings. These results suggest that LptD is involved in R. anatipestifer glutaraldehyde resistance and pathogenicity.

Published

2019

48. lptGcontributes to changes in membrane permeability and the emergence of multidrug hypersusceptibility in a cystic fibrosis isolate ofPseudomonas aeruginosa

Author

Anna Selmecki, Baha Abdalhamid, Nancy D. Hanson, Lucas B. Harrison, and Randal C. Fowler

Subjects

Imipenem, Membrane permeability, medicine.drug_class, subinhibitory, Antibiotics, Mutation, Missense, carbapenem resistance, lcsh:QR1-502, Porins, Microbial Sensitivity Tests, Special Issue: Antimicrobial Resistance, Biology, Real-Time Polymerase Chain Reaction, medicine.disease_cause, Microbiology, Meropenem, Permeability, lcsh:Microbiology, cystic fibrosis, Lipopolysaccharide transport, Drug Resistance, Bacterial, polycyclic compounds, medicine, Humans, Pseudomonas Infections, Whole Genome Sequencing, Reverse Transcriptase Polymerase Chain Reaction, lptG, Pseudomonas aeruginosa, Cell Membrane, Doripenem, hypersusceptibility, Original Articles, lipopolysaccharides, Anti-Bacterial Agents, Codon, Nonsense, ATP-Binding Cassette Transporters, Electrophoresis, Polyacrylamide Gel, Efflux, medicine.drug

Abstract

Purpose In the lungs of cystic fibrosis patients, Pseudomonas aeruginosa is exposed to a myriad of antibiotics leading to alterations in antibiotic susceptibility. This study identifies mutations resulting in hypersusceptibility in isogenic mutants of a P. aeruginosa clinical isolate, PA34. Methods PA34 was exposed to subinhibitory concentrations of doripenem or meropenem during growth to mid‐log phase. Antibiotic susceptibility of surviving colonies was determined by agar dilution. Two carbapenem‐resistant colonies hypersusceptible to non‐carbapenem antibiotics were selected for further analysis. Antibiotic resistance gene expression was evaluated by RT‐rtPCR and OprD production by SDS‐PAGE. PA34 and isogenic mutants were evaluated with whole genome sequencing. Sequence variants were confirmed by Sanger sequencing, and cognate genes in eight carbapenem‐resistant clinical isolates hypersusceptible to non‐carbapenem antibiotics were sequenced. Lipopolysaccharide preparations of PA34 and hypersusceptible mutants were evaluated with ProQ‐Emerald stain. Results Isogenic mutants showed 4‐ to 8‐fold MIC increase for imipenem, meropenem, and doripenem. However, they were hypersusceptible (≥4‐fold MIC decrease) to aminoglycosides, fluoroquinolones, and non‐carbapenem β‐lactams. Expression of ampC or mex‐opr efflux pumps was unchanged, but OprD production was decreased. Mutations causing Q86H AlgU and G77C LptG amino acid substitutions and nonsense mutations within OprD were observed in both mutants. Lipopolysaccharide modifications were observed between isogenic mutants and PA34. Non‐synonymous mutations in LptF or LptG were observed in 6/8 hypersusceptible clinical isolates resistant to carbapenem antibiotics. Conclusion Evaluation of hypersusceptible mutants identified the association between lptG and a hypersusceptible phenotype. Modifications in lipopolysaccharide profiles suggests LptG modification interferes with lipopolysaccharide transport and contributes to hypersusceptibility., This study identifies mutations resulting in hypersusceptibility in isogenic mutants and clinical isolates of Pseudomonas aeruginosa. Mutations in the gene encoding the LptG subunit of the LptFG heterodimer were found to alter lipopolysaccharide (LPS) profiles in isogenic mutants. Modifications in LPS profiles suggest LptG modification interferes with LPS transport and contributes to hypersusceptibility.

Published

2019

49. Mutations inpmrBconfer cross-resistance to the LptD inhibitor POL7080 and colistin inPseudomonas aeruginosa

Author

Phuong H. Nguyen, Thulasi Warrier, Azin Saebi, Deborah T. Hung, Bradley E. Poulsen, Alexander R. Loftis, Keith P. Romano, and Bradley L. Pentelute

Subjects

0303 health sciences, 030306 microbiology, medicine.drug_class, Pseudomonas aeruginosa, Chemistry, Polymyxin, Antibiotics, medicine.disease_cause, 3. Good health, Microbiology, Lipid A, Lipopolysaccharide transport, 03 medical and health sciences, Antibiotic resistance, medicine, Colistin, Cross-resistance, 030304 developmental biology, medicine.drug

Abstract

Pseudomonas aeruginosais a major bacterial pathogen for which there is rising antibiotic resistance. We evaluated the resistance mechanisms ofP. aeruginosaagainst POL7080, a species-specific, first-in-class antibiotic in phase 3 clinical trials targeting the lipopolysaccharide transport protein LptD. We found resistance mutations in the two-component regulatorpmrB. Genome-wide transcriptomics and confocal microscopy studies together suggest that POL7080 is vulnerable to the same resistance mechanisms described previously for polymyxins, including colistin, that involve lipid A modifications to mitigate antibiotic cell surface binding.

Published

2019

50. Thanatin targets the intermembrane protein complex required for lipopolysaccharide transport inEscherichia coli

Author

Milon Mondal, Stefan U. Vetterli, Matthias Urfer, John A. Robinson, Kerstin Moehle, Alessandra Vitale, Maik Müller, Leo Eberl, Katja Zerbe, Gabriella Pessi, Oliver Zerbe, Shuang-Yan Wang, Bernd Wollscheid, University of Zurich, and Robinson, John A

Subjects

10120 Department of Chemistry, 0301 basic medicine, chemistry.chemical_classification, 1000 Multidisciplinary, Multidisciplinary, 030106 microbiology, Peptide, Periplasmic space, medicine.disease_cause, Cell biology, antibiotics thanatin LPS biogenesis beta, Lipopolysaccharide transport, 03 medical and health sciences, 030104 developmental biology, chemistry, Cytoplasm, 540 Chemistry, hairpin, medicine, Inner membrane, Bacterial outer membrane, Escherichia coli, Biogenesis

Abstract

With the increasing resistance of many Gram-negative bacteria to existing classes of antibiotics, identifying new paradigms in antimicrobial discovery is an important research priority. Of special interest are the proteins required for the biogenesis of the asymmetric Gram-negative bacterial outer membrane (OM). Seven Lpt proteins (LptA to LptG) associate in most Gram-negative bacteria to form a macromolecular complex spanning the entire envelope, which transports lipopolysaccharide (LPS) molecules from their site of assembly at the inner membrane to the cell surface, powered by adenosine 5′-triphosphate hydrolysis in the cytoplasm. The periplasmic protein LptA comprises the protein bridge across the periplasm, which connects LptB2FGC at the inner membrane to LptD/E anchored in the OM. We show here that the naturally occurring, insect-derived antimicrobial peptide thanatin targets LptA and LptD in the network of periplasmic protein-protein interactions required to assemble the Lpt complex, leading to the inhibition of LPS transport and OM biogenesis in Escherichia coli., Science Advances, 4 (11), ISSN:2375-2548

Published

2018