The TonB Dimeric Crystal Structures Do Not Exist In Vivo

ABSTRACTThe TonB system energizes transport of nutrients across the outer membrane ofEscherichia coliusing cytoplasmic membrane proton motive force (PMF) for energy. Integral cytoplasmic membrane proteins ExbB and ExbD appear to harvest PMF and transduce it to TonB. The carboxy terminus of TonB then physically interacts with outer membrane transporters to allow translocation of ligands into the periplasmic space. The structure of the TonB carboxy terminus (residues ~150 to 239) has been solved several times with similar results. Our previous results hinted thatin vitrostructures might not mimic the dimeric conformations that characterize TonBin vivo. To test structural predictions and to identify irreplaceable residues, the entire carboxy terminus of TonB was scanned with Cys substitutions. TonB I232C and N233C, predicted to efficiently form disulfide-linked dimers in the crystal structures, did not do so. In contrast, Cys substitutions positioned at large distances from one another in the crystal structures efficiently formed dimers. Cys scanning identified seven functionally important residues. However, no single residue was irreplaceable. The phenotypes conferred by changes of the seven residues depended on both the specific assay used and the residue substituted. All seven residues were synergistic with one another. The buried nature of the residues in the structures was also inconsistent with these properties. Taken together, these results indicate that the solved dimeric crystal structures of TonB do not exist. The most likely explanation for the aberrant structures is that they were obtained in the absence of the TonB transmembrane domain, ExbB, ExbD, and/or the PMF.IMPORTANCEThe TonB system of Gram-negative bacteria is an attractive target for development of novel antibiotics because of its importance in iron acquisition and virulence. Logically, therefore, the structure of TonB must be accurately understood. TonB functions as a dimerin vivo, and two different but similar crystal structures of the dimeric carboxy-terminal ~90 amino acids gave rise to mechanistic models. Here we demonstrate that the crystal structures, and therefore the models based on them, are not biologically relevant. The idiosyncratic phenotypes conferred by substitutions at the only seven functionally important residues in the carboxy terminus suggest that similar to interaction of cytochromes P450 with numerous substrates, these residues allow TonB to differentially interact with different outer membrane transporters. Taken together, data suggest that TonB is maintained poised between order and disorder by ExbB, ExbD, and the proton motive force (PMF) before energy transduction to the outer membrane transporters.

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Going Outside the TonB Box: Identification of Novel FepA-TonB Interactions In Vivo

Journal of Bacteriology ◽

10.1128/jb.00649-16 ◽

2017 ◽

Vol 199 (10) ◽

Cited By ~ 8

Author(s):

Michael G. Gresock ◽

Kathleen Postle

Keyword(s):

Membrane Protein ◽

Outer Membrane ◽

Cytoplasmic Membrane ◽

Current Model ◽

Membrane Transporters ◽

Gram Negative Bacteria ◽

Gram Negative ◽

Interaction Sites ◽

Outer Membrane Transporters

ABSTRACT In Gram-negative bacteria, the cytoplasmic membrane protein TonB transmits energy derived from proton motive force to energize transport of important nutrients through TonB-dependent transporters in the outer membrane. Each transporter consists of a beta barrel domain and a lumen-occluding cork domain containing an essential sequence called the TonB box. To date, the only identified site of transporter-TonB interaction is between the TonB box and residues ∼158 to 162 of TonB. While the mechanism of ligand transport is a mystery, a current model based on site-directed spin labeling and molecular dynamics simulations is that, following ligand binding, the otherwise-sequestered TonB box extends into the periplasm for recognition by TonB, which mediates transport by pulling or twisting the cork. In this study, we tested that hypothesis with the outer membrane transporter FepA using in vivo photo-cross-linking to explore interactions of its TonB box and determine whether additional FepA-TonB interaction sites exist. We found numerous specific sites of FepA interaction with TonB on the periplasmic face of the FepA cork in addition to the TonB box. Two residues, T32 and A33, might constitute a ligand-sensitive conformational switch. The facts that some interactions were enhanced in the absence of ligand and that other interactions did not require the TonB box argued against the current model and suggested that the transport process is more complex than originally conceived, with subtleties that might provide a mechanism for discrimination among ligand-loaded transporters. These results constitute the first study on the dynamics of TonB-gated transporter interaction with TonB in vivo. IMPORTANCE The TonB system of Gram-negative bacteria has a noncanonical active transport mechanism involving signal transduction and proteins integral to both membranes. To achieve transport, the cytoplasmic membrane protein TonB physically contacts outer membrane transporters such as FepA. Only one contact between TonB and outer membrane transporters has been identified to date: the TonB box at the transporter amino terminus. The TonB box has low information content, raising the question of how TonB can discriminate among multiple different TonB-dependent transporters present in the bacterium if it is the only means of contact. Here we identified several additional sites through which FepA contacts TonB in vivo, including two neighboring residues that may explain how FepA signals to TonB that ligand has bound.

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Mechanism of Bactericidal Activity of Microcin L inEscherichia coliandSalmonella enterica

Antimicrobial Agents and Chemotherapy ◽

10.1128/aac.01217-10 ◽

2010 ◽

Vol 55 (3) ◽

pp. 997-1007 ◽

Cited By ~ 20

Author(s):

Natacha Morin ◽

Isabelle Lanneluc ◽

Nathalie Connil ◽

Marie Cottenceau ◽

Anne Marie Pons ◽

...

Keyword(s):

Outer Membrane ◽

Bactericidal Activity ◽

Salmonella Enterica ◽

Cytoplasmic Membrane ◽

Genetic System ◽

Proton Motive Force ◽

Motive Force ◽

Membrane Properties ◽

Outer Membrane Receptor ◽

E Coli

ABSTRACTFor the first time, the mechanism of action of microcin L (MccL) was investigated in live bacteria. MccL is a gene-encoded peptide produced byEscherichia coliLR05 that exhibits a strong antibacterial activity against relatedEnterobacteriaceae, includingSalmonella entericaserovars Typhimurium and Enteritidis. We first subcloned the MccL genetic system to remove the sequences not involved in MccL production. We then optimized the MccL purification procedure to obtain large amounts of purified microcin to investigate its antimicrobial and membrane properties. We showed that MccL did not induce outer membrane permeabilization, which indicated that MccL did not use this way to kill the sensitive cell or to enter into it. Using a set ofE. coliandSalmonella entericamutants lacking iron-siderophore receptors, we demonstrated that the MccL uptake required the outer membrane receptor Cir. Moreover, the MccL bactericidal activity was shown to depend on the TonB protein that transduces the proton-motive force of the cytoplasmic membrane to transport iron-siderophore complexes across the outer membrane. Using carbonyl cyanide 3-chlorophenylhydrazone, which is known to fully dissipate the proton-motive force, we proved that the proton-motive force was required for the bactericidal activity of MccL onE. coli. In addition, we showed that a primary target of MccL could be the cytoplasmic membrane: a high level of MccL disrupted the inner membrane potential ofE. colicells. However, no permeabilization of the membrane was detected.

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In Vivo Synthesis of the Periplasmic Domain of TonB Inhibits Transport through the FecA and FhuA Iron Siderophore Transporters of Escherichia coli

Journal of Bacteriology ◽

10.1128/jb.183.20.5885-5895.2001 ◽

2001 ◽

Vol 183 (20) ◽

pp. 5885-5895 ◽

Cited By ~ 30

Author(s):

S. Peter Howard ◽

Christina Herrmann ◽

Chad W. Stratilo ◽

V. Braun

Keyword(s):

Escherichia Coli ◽

Cytoplasmic Membrane ◽

Signal Sequence ◽

Outer Membrane Proteins ◽

Proton Motive Force ◽

Motive Force ◽

In Vivo Studies ◽

Siderophore Transport

ABSTRACT The siderophore transport activities of the two outer membrane proteins FhuA and FecA of Escherichia coli require the proton motive force of the cytoplasmic membrane. The energy of the proton motive force is postulated to be transduced to the transport proteins by a protein complex that consists of the TonB, ExbB, and ExbD proteins. In the present study, TonB fragments lacking the cytoplasmic membrane anchor were exported to the periplasm by fusing them to the cleavable signal sequence of FecA. Overexpressed TonB(33-239), TonB(103-239), and TonB(122-239) fragments inhibited transport of ferrichrome by FhuA and of ferric citrate by FecA, transcriptional induction of the fecABCDE transport genes by FecA, infection by phage φ80, and killing of cells by colicin M via FhuA. Transport of ferrichrome by FhuAΔ5-160 was also inhibited by TonB(33-239), although FhuAΔ5-160 lacks the TonB box which is involved in TonB binding. The results show that TonB fragments as small as the last 118 amino acids of the protein interfere with the function of wild-type TonB, presumably by competing for binding sites at the transporters or by forming mixed dimers with TonB that are nonfunctional. In addition, the interactions that are inhibited by the TonB fragments must include more than the TonB box, since transport through corkless FhuA was also inhibited. Since the periplasmic TonB fragments cannot assume an energized conformation, these in vivo studies also agree with previous cross-linking and in vitro results, suggesting that neither recognition nor binding to loaded siderophore receptors is the energy-requiring step in the TonB-receptor interactions.

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Characterization of Escherichia coli ExbD protein modification in vivo

10.1101/2020.01.29.925446 ◽

2020 ◽

Author(s):

Aruna Kumar ◽

Kathleen Postle

Keyword(s):

Escherichia Coli ◽

Outer Membrane ◽

Active Transport ◽

Protein Modification ◽

Cytoplasmic Membrane ◽

Physical Contact ◽

Protonmotive Force ◽

Iron Starvation ◽

Tonb System

ABSTRACTThe TonB system of Escherichia coli couples the protonmotive force of the cytoplasmic membrane to active transport of nutrients across the outer membrane. In the cytoplasmic membrane, this system consists of three known proteins, TonB, ExbB, and ExbD. ExbB and ExbD appear to harvest the protonmotive force and transmit it to TonB, which then makes direct physical contact with TonB-dependent active transport proteins in the outer membrane. Using two-dimensional gel electrophoresis, we found that ExbD exists as two different species with the same apparent molecular mass but with different pIs. The more basic ExbD species was consistently present, while the more acidic species arose when cells were starved for iron by the addition of iron chelators. The cause of the modification was, however, more complex than simple iron starvation. Absence of either TonB or ExbB protein also gave rise to modified ExbD under iron-replete conditions where the wild-type strain exhibited no ExbD modification. The effect of the tonB or exbB mutations were not entirely due to iron limitation since an equally iron-limited aroB mutation did not replicate the ExbD modification. This constitutes the first report of in vivo modification for any of the TonB system proteins.

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From Homodimer to Heterodimer and Back: Elucidating the TonB Energy Transduction Cycle

Journal of Bacteriology ◽

10.1128/jb.00484-15 ◽

2015 ◽

Vol 197 (21) ◽

pp. 3433-3445 ◽

Cited By ~ 17

Author(s):

Michael G. Gresock ◽

Kyle A. Kastead ◽

Kathleen Postle

Keyword(s):

Outer Membrane ◽

Active Transport ◽

Cytoplasmic Membrane ◽

Transmembrane Domain ◽

Energy Transduction ◽

Proton Gradient ◽

Carboxy Terminus ◽

Gram Negative ◽

Amino Terminal ◽

Tonb System

ABSTRACTThe TonB system actively transports large, scarce, and important nutrients through outer membrane (OM) transporters of Gram-negative bacteria using the proton gradient of the cytoplasmic membrane (CM). InEscherichia coli, the CM proteins ExbB and ExbD harness and transfer proton motive force energy to the CM protein TonB, which spans the periplasmic space and cyclically binds OM transporters. TonB has two activity domains: the amino-terminal transmembrane domain with residue H20 and the periplasmic carboxy terminus, through which it binds to OM transporters. TonB is inactivated by all substitutions at residue H20 except H20N. Here, we show that while TonB trapped as a homodimer through its amino-terminal domain retained full activity, trapping TonB through its carboxy terminus inactivated it by preventing conformational changes needed for interaction with OM transporters. Surprisingly, inactive TonB H20A had little effect on homodimerization through the amino terminus and instead decreased TonB carboxy-terminal homodimer formation prior to reinitiation of an energy transduction cycle. That result suggested that the TonB carboxy terminus ultimately interacts with OM transporters as a monomer. Our findings also suggested the existence of a separate equimolar pool of ExbD homodimers that are not in contact with TonB. A model is proposed where interaction of TonB homodimers with ExbD homodimers initiates the energy transduction cycle, and, ultimately, the ExbD carboxy terminus modulates interactions of a monomeric TonB carboxy terminus with OM transporters. After TonB exchanges its interaction with ExbD for interaction with a transporter, ExbD homodimers undergo a separate cycle needed to re-energize them.IMPORTANCECanonical mechanisms of active transport across cytoplasmic membranes employ ion gradients or hydrolysis of ATP for energy. Gram-negative bacterial outer membranes lack these resources. The TonB system embodies a novel means of active transport across the outer membrane for nutrients that are too large, too scarce, or too important for diffusion-limited transport. A proton gradient across the cytoplasmic membrane is converted by a multiprotein complex into mechanical energy that drives high-affinity active transport across the outer membrane. This system is also of interest since one of its uses in pathogenic bacteria is for competition with the host for the essential element iron. Understanding the mechanism of the TonB system will allow design of antibiotics targeting iron acquisition.

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Identification of New In Vivo TonB-FepA Rendezvous Sites

10.1101/2021.12.08.471779 ◽

2021 ◽

Author(s):

Kathleen Postle ◽

Kelvin Kho ◽

Michael Gresock ◽

Joydeep Ghosh ◽

Ray Larsen

Keyword(s):

Outer Membrane ◽

Cytoplasmic Membrane ◽

Protonmotive Force ◽

Amphipathic Helix ◽

Amino Terminal ◽

Terminal Domain ◽

Tonb System ◽

Carboxy Terminal ◽

Amino Terminal Domain

The TonB system of Gram-negative bacteria uses the protonmotive force of the cytoplasmic membrane to energize active transport of large or scarce nutrients across the outer membrane by means of customized beta-barrels known as TonB-dependent transporters (TBDTs). The lumen of each TBDT is occluded by an amino-terminal domain, called the cork, which must be displaced for transport of nutrients or translocation of the large protein toxins that parasitize the system. A complex of cytoplasmic membrane proteins consisting of TonB, ExbB and ExbD harnesses the protonmotive force that TonB transmits to the TBDT. The specifics of this energy transformation are a source of continuing interest. The amino terminal domain of a TBDT contains a region called the TonB box, that is essential for the reception of energy from TonB. This domain is the only identified site of in vivo interaction between the TBDT and TonB, occurring through a non-essential region centered on TonB residue Q160. Because TonB binds to TBDTs whether or not it is active or even intact, the mechanism and extent of cork movement in vivo has been challenging to discover. In this study, we used in vivo disulfide crosslinking between eight engineered Cys residues in Escherichia coli TonB and 42 Cys substitutions in the TBDT FepA, including the TonB box, to identify novel sites of interaction in vivo. The TonB Cys substitutions in the core of an essential carboxy terminal amphipathic helix (residues 199-216) were compared to TonB Q160C interactions. Functionality of the in vivo interactions was established when the presence of the inactive TonB H20A mutation inhibited them. A previously unknown functional interaction between the hydrophilic face of the amphipathic helix and the FepA TonB box was identified. Interaction of Q160C with the FepA TonB box appeared to be less functionally important. The two different parts of TonB also differed in their interactions with the FepA cork and barrel turns. While the TonB amphipathic helix Cys residues interacted only with Cys residues on the periplasmic face of the FepA cork, TonB Q160C interacted with buried Cys substitutions within the FepA cork, the first such interactions seen with any TBDT. Both sets of interactions required active TonB. Taken together, these data suggest a model where the amphipathic helix binds to the TonB box, causing the mechanically weak domain of the FepA cork to dip sufficiently into the periplasmic space for interaction with the TonB Q160 region, which is an interaction that does not occur if the TonB box is deleted. The TonB amphipathic helix also interacted with periplasmic turns between FepA β-strands in vivo supporting a surveillance mechanism where TonB searched for TBDTs on the periplasmic face of the outer membrane.

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ExbB and ExbD Do Not Function Independently in TonB-Dependent Energy Transduction

Journal of Bacteriology ◽

10.1128/jb.184.18.5170-5173.2002 ◽

2002 ◽

Vol 184 (18) ◽

pp. 5170-5173 ◽

Cited By ~ 40

Author(s):

Kiara G. Held ◽

Kathleen Postle

Keyword(s):

Cytoplasmic Membrane ◽

Recent Observation ◽

Proton Motive Force ◽

Energy Transduction ◽

Motive Force ◽

Membrane Association ◽

High Affinity ◽

Membrane Complex ◽

Tonb System ◽

Energy Transducer

ABSTRACT ExbB and ExbD proteins are part of the TonB-dependent energy transduction system and are encoded by the exb operon in Escherichia coli. TonB, the energy transducer, appears to go through a cycle during energy transduction, with the absence of both ExbB and ExbD creating blocks at two points: (i) in the inability of TonB to respond to the cytoplasmic membrane proton motive force and (ii) in the conversion of TonB from a high-affinity outer membrane association to a high-affinity cytoplasmic membrane association. The recent observation that ExbB exists in 3.5-fold molar excess relative to the molarity of ExbD in E. coli suggests the possibility of two types of complexes, those containing both ExbB and ExbD and those containing only ExbB. Such distinct complexes might individually manifest one of the two activities described above. In the present study this hypothesis was tested and rejected. Specifically, both ExbB and ExbD were found to be required for TonB to conformationally respond to proton motive force. Both ExbB and ExbD were also required for association of TonB with the cytoplasmic membrane. Together, these results support an alternative model where all of the ExbB in the cell occurs in complex with all of the ExbD in the cell. Based on recently determined cellular ratios of TonB system proteins, these results suggest the existence of a cytoplasmic membrane complex that may be as large as 520 kDa.

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The Intrinsically Disordered Region of ExbD Is Required for Signal Transduction

Journal of Bacteriology ◽

10.1128/jb.00687-19 ◽

2020 ◽

Vol 202 (7) ◽

Cited By ~ 1

Author(s):

Dale R. Kopp ◽

Kathleen Postle

Keyword(s):

Signal Transduction ◽

Outer Membrane ◽

Cytoplasmic Membrane ◽

Intrinsic Disorder ◽

Energy Transduction ◽

Cross Linking ◽

Gram Negative ◽

Conserved Motif ◽

Tonb System

ABSTRACT The TonB system actively transports vital nutrients across the unenergized outer membranes of the majority of Gram-negative bacteria. In this system, integral membrane proteins ExbB, ExbD, and TonB work together to transduce the proton motive force (PMF) of the inner membrane to customized active transporters in the outer membrane by direct and cyclic binding of TonB to the transporters. A PMF-dependent TonB-ExbD interaction is prevented by 10-residue deletions within a periplasmic disordered domain of ExbD adjacent to the cytoplasmic membrane. Here, we explored the function of the ExbD disordered domain in more detail. In vivo photo-cross-linking through sequential pBpa substitutions in the ExbD disordered domain captured five different ExbD complexes, some of which had been previously detected using in vivo formaldehyde cross-linking, a technique that lacks the residue-specific information that can be achieved through photo-cross-linking: two ExbB-ExbD heterodimers (one of which had not been detected previously), previously detected ExbD homodimers, previously detected PMF-dependent ExbD-TonB heterodimers, and for the first time, a predicted, ExbD-TonB PMF-independent interaction. The fact that multiple complexes were captured by the same pBpa substitution indicated the dynamic nature of ExbD interactions as the energy transduction cycle proceeded in vivo. In this study, we also discovered that a conserved motif—V45, V47, L49, and P50—within the disordered domain was required for signal transduction to TonB and to the C-terminal domain of ExbD and was the source of motif essentiality. IMPORTANCE The TonB system is a virulence factor for Gram-negative pathogens. The mechanism by which cytoplasmic membrane proteins of the TonB system transduce an electrochemical gradient into mechanical energy is a long-standing mystery. TonB, ExbB, and ExbD primary amino acid sequences are characterized by regions of predicted intrinsic disorder, consistent with a proposed multiplicity of protein-protein contacts as TonB proceeds through an energy transduction cycle, a complex process that has yet to be recapitulated in vitro. This study validates a region of intrinsic disorder near the ExbD transmembrane domain and identifies an essential conserved motif embedded within it that transduces signals to distal regions of ExbD suggested to configure TonB for productive interaction with outer membrane transporters.

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An ExbD Disordered Domain Peptide Inhibits TonB System Activity

10.1101/2020.01.05.895219 ◽

2020 ◽

Author(s):

Dale R. Kopp ◽

Kathleen Postle

Keyword(s):

Outer Membrane ◽

Cytoplasmic Membrane ◽

Protonmotive Force ◽

Gram Negative Bacteria ◽

System Function ◽

Gram Negative ◽

Conserved Motif ◽

Outer Membranes ◽

Tonb System

ABSTRACTThe TonB system energizes transport of essential nutrients, such as iron siderophores, across unenergized outer membranes of Gram-negative bacteria. The integral cytoplasmic membrane proteins of the TonB system--ExbB, ExbD, and TonB--transduce the protonmotive force of the cytoplasmic membrane to TonB-dependent outer membrane transporters for active transport. ExbD protein is anchored in the cytoplasmic membrane, with the majority of it occupying the periplasm. We previously identified a conserved motif within a periplasmic disordered domain that is essential for TonB system function. Here we demonstrated that export of a peptide derived from that motif into the periplasm prevented TonB system function and inhibited all known ExbD interactions in vivo. Formaldehyde crosslinking captured the ExbD peptide in multiple ExbD and TonB complexes. Furthermore, peptides with mutations in the conserved motif not only had significantly reduced ability to inhibit TonB system activity, but they also altered interactions with ExbD and TonB, indicating the specificity of the interaction. Conserved motif peptide interactions with ExbD and TonB mostly occurred between Stage II and Stage III of the TonB energy transduction cycle, a transition that is characterized by the use of protonmotive force. Taken together, the data suggest that the ExbD disordered domain motif has multiple interactions with TonB and ExbD during between Stage II and III of the TonB energization cycle. Because of the essentiality of the motif, it may be a potential template for design of novel antibiotics that target the TonB system.IMPORTANCEGram-negative bacteria are intrinsically antibiotic-resistant due to the diffusion barrier posed by their outer membranes. The TonB system allows them to circumvent this barrier for their own nutritional needs, including iron. The ability of bacteria to acquire iron is a virulence factor for many Gram-negative pathogens. However, no antibiotics currently target the TonB system. Because TonB and ExbD must interact productively in the periplasm for transport across the outer membrane, they constitute attractive targets for potential antibiotic development where chemical characteristics need not accommodate the need to cross the hydrophobic cytoplasmic membrane. Here we show that a small ExbD-derived peptide can interfere with the TonB-ExbD interaction to inhibit the TonB system in vivo.

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Chemical or genetic alteration of proton motive force results in loss of virulence of Burkholderia glumae , the cause of rice bacterial panicle blight.

Applied and Environmental Microbiology ◽

10.1128/aem.00915-21 ◽

2021 ◽

Author(s):

Asif Iqbal ◽

Pradip R. Panta ◽

John Ontoy ◽

Jobelle Bruno ◽

Jong Hyun Ham ◽

...

Keyword(s):

Sodium Bicarbonate ◽

Wild Type Strain ◽

Proton Motive Force ◽

Membrane Transporters ◽

Motive Force ◽

Wild Type ◽

Bacterial Genomes ◽

Burkholderia Glumae ◽

Sheath Rot ◽

Panicle Blight

Rice is an important source of food for more than half the world’s population. Bacterial panicle blight (BPB) is a disease of rice characterized by grain discoloration or sheath rot caused mainly by Burkholderia glumae . B. glumae synthesizes toxoflavin, an essential virulence factor, that is required for symptoms of the disease. The products of the tox operons, ToxABCDE and ToxFGHI, are responsible for the synthesis and the proton motive force (PMF)-dependent secretion of toxoflavin, respectively. The DedA family is a highly conserved membrane protein family found in most bacterial genomes that likely function as membrane transporters. Our previous work has demonstrated that absence of certain DedA family members results in pleiotropic effects, impacting multiple pathways that are energized by PMF. We have demonstrated that a member of the DedA family from Burkholderia thailandensis , named DbcA, is required for the extreme polymyxin resistance observed in this organism. B. glumae encodes a homolog of DbcA with 73% amino acid identity to Burkholderia thailandensis DbcA. Here, we created and characterized a B. glumae Δ dbcA strain. In addition to polymyxin sensitivity, B. glumae Δ dbcA is compromised for virulence in several BPB infection models and secretes only low amounts of toxoflavin (∼15% of wild type levels). Changes in membrane potential in B. glumae Δ dbcA were reproduced in the wild type strain by the addition of sub-inhibitory concentrations of sodium bicarbonate, previously demonstrated to cause disruption of PMF. Sodium bicarbonate inhibited B. glumae virulence in rice suggesting a possible non-toxic chemical intervention for bacterial panicle blight. IMPORTANCE Bacterial panicle blight (BPB) is a disease of rice characterized by grain discoloration or sheath rot caused mainly by Burkholderia glumae . The DedA family is a highly conserved membrane protein family found in most bacterial genomes that likely function as membrane transporters. Here, we constructed a B. glumae mutant with a deletion in a DedA family member named dbcA and report a loss of virulence in models of BPB. Physiological analysis of the mutant shows that the proton motive force is disrupted, leading to reduction of secretion of the essential virulence factor toxoflavin. The mutant phenotypes are reproduced in the virulent wild type strain without an effect on growth using sodium bicarbonate, a nontoxic buffer that has been reported to disrupt the PMF. The results presented here suggest that bicarbonate may be an effective antivirulence agent capable of controlling BPB without imposing an undue burden on the environment.

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