Bacitracin sensing and resistance in Staphylococcus aureus

Bacterial two-component systems (TCSs) have been demonstrated to be associated with not only the expression of virulence factors, but also the susceptibility to antibacterial agents. In Staphylococcus aureus, 16 types of TCSs have been identified. We previously found that the inactivation of one uncharacterized TCS (designated as BceRS, MW gene ID: MW2545-2544) resulted in an increase in susceptibility to bacitracin. In this study, we focused on this TCS and tried to identify the TCS-controlled factors affecting the susceptibility to bacitracin. We found that two ABC transporters were associated with the susceptibility to bacitracin. One transporter designated as BceAB (MW2543-2542) is downstream of this TCS, while another (formerly designated as VraDE: MW2620-2621) is separate from this TCS. Both transporters showed homology with several bacitracin-resistance factors in Gram-positive bacteria. Inactivation of each of these two transporters increased the susceptibility to bacitracin. Expressions of these transporters were significantly increased by the addition of bacitracin, while this induction was not observed in the TCS-inactivated mutant. These results indicate that this TCS senses bacitracin, and also positively regulates the expression of two ABC transporters.     

Coevolution of ABC transporters and two-component regulatory systems as resistance modules against antimicrobial peptides in Firmicutes Bacteria

In Firmicutes bacteria, ATP-binding cassette (ABC) transporters have been recognized as important resistance determinants against antimicrobial peptides. Together with neighboring two-component systems (TCSs), which regulate their expression, they form specific detoxification modules. Both the transport permease and sensor kinase components show unusual domain architecture: the permeases contain a large extracellular domain, while the sensor kinases lack an obvious input domain. One of the best-characterized examples is the bacitracin resistance module BceRS-BceAB of Bacillus subtilis. Strikingly, in this system, the ABC transporter and TCS have an absolute mutual requirement for each other in both sensing of and resistance to bacitracin, suggesting a novel mode of signal transduction in which the transporter constitutes the actual sensor. We identified over 250 such BceAB-like ABC transporters in the current databases. They occurred almost exclusively in Firmicutes bacteria, and 80% of the transporters were associated with a BceRS-like TCS. Phylogenetic analyses of the permease and sensor kinase components revealed a tight evolutionary correlation. Our findings suggest a direct regulatory interaction between the ABC transporters and TCSs, mediating communication between both components. Based on their observed coclustering and conservation of response regulator binding sites, we could identify putative corresponding two-component systems for transporters lacking a regulatory system in their immediate neighborhood. Taken together, our results show that these types of ABC transporters and TCSs have coevolved to form self-sufficient detoxification modules against antimicrobial peptides, widely distributed among Firmicutes bacteria.     

Bacitracin sensing in Bacillus subtilis

The extracellular presence of antibiotics is a common threat in microbial life. Their sensitive detection and subsequent induction of appropriate resistance mechanisms is therefore a prerequisite for survival. The bacitracin stress response network of Bacillus subtilis consists of four signal-transducing systems, the two-component systems (TCS) BceRS, YvcPQ and LiaRS, and the extracytoplasmic function (ECF) σ factor σ^M. Here, we investigated the mechanism of bacitracin perception and the response hierarchy within this network. The BceRS–BceAB TCS/ABC transporter module is the most sensitive and efficient bacitracin resistance determinant. The ABC transporter BceAB not only acts as a bacitracin detoxification pump, but is also crucial for bacitracin sensing, indicative of a novel mechanism of stimulus perception, conserved in Firmicutes bacteria. The Bce system seems to respond to bacitracin directly (drug sensing), whereas the LiaRS TCS and σ^M respond only at higher concentrations and indirectly to bacitracin action (damage sensing). The YvcPQ–YvcRS system is subject to cross-activation via the paralogous Bce system, and is therefore only indirectly induced by bacitracin. The bacitracin stress response network is optimized to respond to antibiotic gradients in a way that maximizes the gain and minimizes the costs of this stress response.     

The BceRS two-component regulatory system induces expression of the bacitracin transporter,BceAB, in Bacillus subtilis

BceA and bceB encode a nucleotide-binding domain (NBD) and membrane-spanning domain (MSD) subunit, respectively, of an ATP-binding cassette (ABC) transporter in Bacillus subtilis. Disruption of these genes resulted in hypersensitivity to bacitracin, a peptide antibiotic that is non-ribosomally synthesized in some strains of Bacillus. Northern hybridization analyses showed that expression of the bceAB operon is induced by bacitracin present in the growth medium. The bceRS genes encoding a two-component regulatory system are located immediately upstream of bceAB. Deletion analyses of the bceAB promoter together with DNase I footprinting experiments revealed that a sensor kinase, BceS, responds to extracellular bacitracin either directly or indirectly and transmits a signal to a cognate response regulator, BceR. The regulator binds directly to the upstream region of the bceAB promoter and upregulates the expression of bceAB genes. The bcrC gene product is additionally involved in bacitracin resistance. The expression of bcrC is dependent on the ECF sigma factors, sigmaM and sigmaX, but not on the BceRS two-component system. In view of these results, possible roles of BceA, BceB and BcrC in bacitracin resistance of B. subtilis 168 are discussed.     

Regulation of the Bacillus subtilis bcrC bacitracin resistance gene by two extracytoplasmic function sigma factors

Bacitracin resistance is normally conferred by either of two major mechanisms, the BcrABC transporter, which pumps out bacitracin, or BacA, an undecaprenol kinase that provides C(55)-isoprenyl phosphate by de novo synthesis. We demonstrate that the Bacillus subtilis bcrC (ywoA) gene, encoding a putative bacitracin transport permease, is an important bacitracin resistance determinant. A bcrC mutant strain had an eightfold-higher sensitivity to bacitracin. Expression of bcrC initiated from a single promoter site that could be recognized by either of two extracytoplasmic function (ECF) sigma factors, sigma(X) or sigma(M). Bacitracin induced expression of bcrC, and this induction was dependent on sigma(M) but not on sigma(X). Under inducing conditions, expression was primarily dependent on sigma(M). As a consequence, a sigM mutant was fourfold more sensitive to bacitracin, while the sigX mutant was only slightly sensitive. A sigX sigM double mutant was similar to a bcrC mutant in sensitivity. These results support the suggestion that one function of B. subtilis ECF sigma factors is to coordinate antibiotic stress responses.     

A Sensory Complex Consisting of an ATP-binding Cassette Transporter and a Two-component Regulatory System Controls Bacitracin Resistance in Bacillus subtilis

Resistance against antimicrobial peptides in many Firmicutes bacteria is mediated by detoxification systems that are composed of a two-component regulatory system (TCS) and an ATP-binding cassette (ABC) transporter. The histidine kinases of these systems depend entirely on the transporter for sensing of antimicrobial peptides, suggesting a novel mode of signal transduction where the transporter constitutes the actual sensor. The aim of this study was to investigate the molecular mechanisms of this unusual signaling pathway in more detail, using the bacitracin resistance system BceRS-BceAB of Bacillus subtilis as an example. To analyze the proposed communication between TCS and the ABC transporter, we characterized their interactions by bacterial two-hybrid analyses and could show that the permease BceB and the histidine kinase BceS interact directly. In vitro pulldown assays confirmed this interaction, which was found to be independent of bacitracin. Because it was unknown whether BceAB-type transporters could detect their substrate peptides directly or instead recognized the peptide-target complex in the cell envelope, we next analyzed substrate binding by the transport permease, BceB. Direct and specific binding of bacitracin by BceB was demonstrated by surface plasmon resonance spectroscopy. Finally, in vitro signal transduction assays indicated that complex formation with the transporter influenced the autophosphorylation activity of the histidine kinase. Taken together, our findings clearly show the existence of a sensory complex composed of TCS and ABC transporters and provide the first functional insights into the mechanisms of stimulus perception, signal transduction, and antimicrobial resistance employed by Bce-like detoxification systems.     

Characterization of Genes Encoding for Acquired Bacitracin Resistance in Clostridium perfringens

Phenotypic bacitracin resistance has been reported in Clostridium perfringens. However, the genes responsible for the resistance have not yet been characterized. Ninety-nine C. perfringens isolates recovered from broilers and turkeys were tested for phenotypic bacitracin resistance. Bacitracin MIC(90) (>256 μg/ml) was identical for both turkey and chicken isolates; whereas MIC(50) was higher in turkey isolates (6 μg/ml) than in chicken isolates (3 μg/ml). Twenty-four of the 99 isolates showed high-level bacitracin resistance (MIC breakpoint >256 μg/ml) and the genes encoding for this resistance were characterized in C. perfringens c1261_A strain using primer walking. Sequence analysis and percentages of amino acid identity revealed putative genes encoding for both an ABC transporter and an overproduced undecaprenol kinase in C. perfringens c1261_A strain. These two mechanisms were shown to be both encoded by the putative bcrABD operon under the control of a regulatory gene, bcrR. Efflux pump inhibitor thioridazine was shown to increase significantly the susceptibility of strain c1261_A to bacitracin. Upstream and downstream from the bcr cluster was an IS1216-like element, which may play a role in the dissemination of this resistance determinant. Pulsed-field gel electrophoresis with prior double digestion with I-CeuI/MluI enzymes followed by hybridization analyses revealed that the bacitracin resistance genes bcrABDR were located on the chromosome. Semi-quantitative RT-PCR demonstrated that this gene cluster is expressed under bacitracin stress. Microarray analysis revealed the presence of these genes in all bacitracin resistant strains. This study reports the discovery of genes encoding for a putative ABC transporter and an overproduced undecaprenol kinase associated with high-level bacitracin resistance in C. perfringens isolates from turkeys and broiler chickens.     

Accumulation of heptaprenyl diphosphate sensitizes Bacillus subtilis to bacitracin: implications for the mechanism of resistance mediated by the BceAB transporter

Heptaprenyl diphosphate (C₃₅‐PP) is an isoprenoid intermediate in the synthesis of both menaquinone and the sesquarterpenoids. We demonstrate that inactivation of ytpB, encoding a C₃₅‐PP utilizing enzyme required for sesquarterpenoid synthesis, leads to an increased sensitivity to bacitracin, an antibiotic that binds undecaprenyl pyrophosphate (C₅₅‐PP), a key intermediate in cell wall synthesis. Genetic studies indicate that bacitracin sensitivity is due to accumulation of C₃₅‐PP, rather than the absence of sesquarterpenoids. Sensitivity is accentuated in a ytpB menA double mutant, lacking both known C₃₅‐PP consuming enzymes, and in a ytpB strain overexpressing the HepST enzyme that synthesizes C₃₅‐PP. Conversely, sensitivity in the ytpB background is suppressed by mutation of hepT or by supplementation with 1,4‐dihydroxy‐2‐naphthoate, a co‐substrate with C₃₅‐PP for MenA. Bacitracin sensitivity results from impairment of the BceAB and BcrC resistance mechanisms by C₃₅‐PP: in a bceAB bcrC double mutant disruption of ytpB no longer increases bacitracin sensitivity. These results suggest that C₃₅‐PP inhibits both BcrC (a C₅₅‐PP phosphatase) and BceAB (an ABC transporter that confers bacitracin resistance). These findings lead to a model in which BceAB protects against bacitracin by transfer of the target, C₅₅‐PP, rather than the antibiotic across the membrane.     

Characterization of the Mechanism of the Staphylococcus aureus Cell Envelope by Bacitracin and Bacitracin-Metal Ions

Bacitracin is a metal-dependent dodecapeptide antipeptide produced by Bacillus species. Microcalorimetry was used to study the antimicrobial activity of bacitracin and bacitracin-metal ion complexation inhibited on Staphylococcus aureus at 37 degrees C. The affinity of metal ions binding to bacitracin was investigated by isothermal titration calorimetry and was as follows: Cu(II) >or= Ni(II) > Co(II) > Zn(II) >or= Mn(II). The metal ion binding affinity is not relative to the antimicrobial activity of bacitracin-metal complexation. Atomic force microscopic images revealed that the surface of S. aureus treated by bacitracin-Zn(II) was rather rough compared to that treated by bacitracin only. The central cell surface displayed small depressed grooves around the septal annulus at the onset of division. Bacitracin mainly inhibited the splitting system within the thick cross walls as seen by transmission electron microscopy (TEM). The inhibition mechanism of bacitracin may be relative to the assistance of Zn(II) coordination with the cell surface as seen by TEM. We can put forward that the activity of bacitracin only inhibited growth and division initially from the synthesis of the cell wall, especially the cell wall of the septal annulus. The divalent metal ions function to increase the adsorption of bacitracin onto the cell surface.     

The two-component regulatory system BacRS is associated with bacitracin 'self-resistance' of Bacillus licheniformis ATCC 10716.

Bacitracin is a peptide antibiotic produced by several Bacillus licheniformis strains that is most active against other Gram-positive microorganisms, but not against the producer strain itself. Recently, heterologous expression of the bacitracin resistance mediating BcrABC transporter in Bacillus subtilis and Escherichia coli was described. In this study we could determine that the transporter encoding bcrABC genes are localized about 3 kb downstream of the 44-kb bacitracin biosynthetic operon bacABC. Between the bac operon and the bcrABC genes two orfs, designated bacR and bacS, were identified. They code for proteins with high homology to regulator and sensor proteins of two-component systems. A disruption mutant of the bacRS genes was constructed. While the mutant displayed no effects on the bacitracin production it exhibited highly increased bacitracin sensitivity compared to the wild-type strain. Western blot analysis of the expression of BcrA, the ATP-binding cassette of the transporter, showed in the wild-type a moderate BcrA induction in late stationary cells that accumulate bacitracin, whereas in the bacRS mutant cells the BcrA expression was constitutive. A comparison of bacitracin stressed and nonstressed wild-type cells in Western blot analysis revealed increasing amounts of BcrA and a decrease in BacR in the stressed cells. From these findings we infer that BacR acts as a negative regulator for controlling the expression of the bcrABC transporter genes.     

YtsCD and YwoA, two independent systems that confer bacitracin resistance to Bacillus subtilis

The Bacillus subtilis yts, yxd and yvc gene clusters encode a putative ABC transporter and a functionally coupled two-component system. When tested for their sensitivity towards a series of antibiotics, null yts mutants were found to be sensitive to bacitracin. Real-time polymerase chain reaction (PCR) experiments demonstrated that the presence of bacitracin in the growth medium strongly stimulates the expression of the ytsCD genes encoding the ABC transporter and that this stimulation strictly depends on the YtsA response regulator. The ywoA gene encodes a protein known to confer some resistance to bacitracin on the bacterium. When it was mutated in a null yts background, the ywoA yts double mutant was found to be five times more sensitive than the yts one. We propose that (i) the YtsCD ABC transporter exports the bacitracin; (ii) YwoA, the protein that contains an acidPPc (PAP2 or PgpB) domain, is not part of an ABC transporter but competes with bacitracin for the dephosphorylation of the C55-isoprenyl pyrophosphate (IPP); (iii) the two resistance mechanisms are independent and complementary.     

Metal binding and structure-activity relationship of the metalloantibiotic peptide bacitracin

Bacitracin is a widely used metallopeptide antibiotic produced by Bacillus subtilis and Bacillus licheniformis with a potent bactericidal activity directed primarily against Gram-positive organisms. This antibiotic requires a divalent metal ion such as Zn(2+) for its biological activity, and has been reported to bind several other transition metal ions, including Mn(2+), Co(2+), Ni(2+), and Cu(2+). Despite the widespread use of bacitracin since its discovery in the early 1940s, the structure-activity relationship of this drug has not been established and the coordination chemistry of its metal complexes was not fully determined until recently. This antibiotic has been suggested to influence cell functioning through more than one route. Since bacterial resistance against bacitracin is still rare despite several decades of widespread use, this antibiotic can serve as an ideal lead for the design of potent peptidyl antibiotics lacking bacterial resistance. In this review, the results of physical (including NMR, EPR, and EXAFS) and molecular biological studies regarding the synthesis and structure of bacitracin, the coordination chemistry of its metal derivatives, the mechanism of its antibiotic actions, its influence on membrane function, and its structure and function relationship are discussed.     

Three Distinct Two-Component Systems Are Involved in Resistance to the Class I Bacteriocins,Nukacin ISK-1 and Nisin A,in Staphylococcus aureus

Staphylococcus aureus uses two-component systems (TCSs) to adapt to stressful environmental conditions. To colonize a host, S. aureus must resist bacteriocins produced by commensal bacteria. In a comprehensive analysis using individual TCS inactivation mutants, the inactivation of two TCSs, graRS and braRS, significantly increased the susceptibility to the class I bacteriocins, nukacin ISK-1 and nisin A, and inactivation of vraSR slightly increased the susceptibility to nukacin ISK-1. In addition, two ABC transporters (BraAB and VraDE) regulated by BraRS and one transporter (VraFG) regulated by GraRS were associated with resistance to nukacin ISK-1 and nisin A. We investigated the role of these three TCSs of S. aureus in co-culture with S. warneri, which produces nukacin ISK-1, and Lactococcus lactis, which produces nisin A. When co-cultured with S. warneri or L. lactis, the braRS mutant showed a significant decrease in its population compared with the wild-type, whereas the graRS and vraSR mutants showed slight decreases. Expression of vraDE was elevated significantly in S. aureus co-cultured with nisin A/nukacin ISK-1-producing strains. These results suggest that three distinct TCSs are involved in the resistance to nisin A and nukacin ISK-1. Additionally, braRS and its related transporters played a central role in S. aureus survival in co-culture with the strains producing nisin A and nukacin ISK-1.     

A new highly conserved antibiotic sensing/resistance pathway in firmicutes involves an ABC transporter interplaying with a signal transduction system

Signal transduction systems and ABC transporters often contribute jointly to adaptive bacterial responses to environmental changes. In Bacillus subtilis, three such pairs are involved in responses to antibiotics: BceRSAB, YvcPQRS and YxdJKLM. They are characterized by a histidine kinase belonging to the intramembrane sensing kinase family and by a translocator possessing an unusually large extracytoplasmic loop. It was established here using a phylogenomic approach that systems of this kind are specific but widespread in Firmicutes, where they originated. The present phylogenetic analyses brought to light a highly dynamic evolutionary history involving numerous horizontal gene transfers, duplications and lost events, leading to a great variety of Bce-like repertories in members of this bacterial phylum. Based on these phylogenetic analyses, it was proposed to subdivide the Bce-like modules into six well-defined subfamilies. Functional studies were performed on members of subfamily IV comprising BceRSAB from B. subtilis, the expression of which was found to require the signal transduction system as well as the ABC transporter itself. The present results suggest, for the members of this subfamily, the occurrence of interactions between one component of each partner, the kinase and the corresponding translocator. At functional and/or structural levels, bacitracin dependent expression of bceAB and bacitracin resistance processes require the presence of the BceB translocator loop. Some other members of subfamily IV were also found to participate in bacitracin resistance processes. Taken together our study suggests that this regulatory mechanism might constitute an important common antibiotic resistance mechanism in Firmicutes. [Supplemental material is available online at http://www.genome.org.].     

The yydFGHIJ operon of Bacillus subtilis encodes a peptide that induces the LiaRS two-component system

The Bacillus subtilis LiaRS two-component system (TCS) responds to perturbations of the cell envelope induced by lipid II-interacting antibiotics, such as vancomycin, ramoplanin, nisin, and bacitracin. Here, we characterize Tn7-generated mutations that induce the liaRS TCS. In addition to insertions in liaF, a known negative regulator of the LiaRS TCS, we identified two disruptions in the last two genes of the yydFGHIJ operon. This operon is predicted to encode a 49-amino-acid peptide (YydF), a modification enzyme (YydG), a membrane-embedded protease (YydH), and an ATP-binding cassette (ABC) transporter (YydIJ). Genome sequence comparisons suggest that the yydFGHIJ operon may have been acquired by horizontal transfer. Inactivation of the YydIJ transporter resulted in increased expression from the LiaR-dependent P_liaI promoter only in the presence of the yydFGH genes. Cells harboring the complete yydFGHIJ operon induced LiaR activity in cocultured cells lacking either this transporter or the complete operon. These results suggest that this operon is involved in the synthesis and export of a modified peptide (YydF*) that elicits cell envelope stress sensed by the LiaRS TCS.     

The role of the bacitracin ABC transporter in bacitracin resistance and collateral detergent sensitivity

The bacitracin resistance of Bacillus licheniformis, a producer of bacitracin, is mediated by the ABC transporter Bcr. Bacillus subtilis cells carrying bcr genes on high-copy number plasmids developed collateral detergent sensitivity, as did human cells with overexpressed multidrug resistance P-glycoprotein. Resistance against bacitracin and sensitivity of resistant cells to detergents were shown to be inseparable phenomena associated with the membrane part of Bcr transporter, namely protein BcrC. A fused protein, consisting of ATP-binding protein BcrA and membrane component BcrC was constructed. It resembled a half molecule of P-glycoprotein and was capable of providing a significant degree of antibiotic resistance and detergent sensitivity.