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.].

Sposensor: a whole-bacterial biosensor that uses immobilized Bacillus subtilis spores and a one-step incubation/detection process.

A generic whole-cell bacterial sensor called sposensor was developed with immobilized spores from engineered Bacillus subtilis. Sposensor contains two different types of spores: reporting spores that contain a reporter gene fused to a promoter responding to a compound to be detected, and control spores use to monitor cell germination and viability. A one-step incubation/detection process was developed to meet the constraints of on-site analysis. Spores were directly incubated with culture medium containing the compound to be detected. beta-Galactosidase was chosen as a reporter protein in both cases and its activity followed by a colorimetric assay. Results showed that sposensor was efficient in detecting two different compounds, a metal (Zn(2+)) and a peptidic antibiotic (bacitracin). Owing to the stability and robustness of spores, sposensor is a very efficient and easy tool to manipulate for analyzing the presence of toxic compounds in natural settings.

Resistance to bacitracin in Bacillus subtilis: unexpected requirement of the BceAB ABC transporter in the control of expression of its own structural genes.

The Bacillus subtilis BceAB ABC transporter involved in a defense mechanism against bacitracin is composed of a membrane-spanning domain and a nucleotide-binding domain. Induction of the structural bceAB genes requires the BceR response regulator and the BceS histidine kinase of a signal transduction system. However, despite the presence of such a transduction system and of bacitracin, no transcription from an unaltered bceA promoter is observed in cells lacking the BceAB transporter. Expression in trans of the BceAB transporter in these bceAB cells restores the transcription from the bceA promoter. Cells possessing a mutated nucleotide-binding domain of the transporter are also no longer able to trigger transcription from the bceA promoter in the presence of bacitracin, although the mutated ABC transporter is still bound to the membrane. In these cells, expression of the bceA promoter can no longer be detected, indicating that the ABC transporter not only must be present in the cell membrane, but also must be expressed in a native form for the induction of the bceAB genes. Several hypotheses are discussed to explain the simultaneous need for bacitracin, a native signal transduction system, and an active BceAB ABC transporter to trigger transcription from the bceA promoter.

BcrC from Bacillus subtilis acts as an undecaprenyl pyrophosphate phosphatase in bacitracin resistance.

Overexpression of the BcrC(Bs) protein, formerly called YwoA, in Escherichia coli or in Bacillus subtilis allows these bacteria to stand higher concentrations of bacitracin. It was suggested that BcrC(Bs) was a membrane-spanning domain of an ATP binding cassette (ABC) transporter involved in bacitracin resistance. However, we hypothesized that this protein has an undecaprenyl pyrophosphate (UPP) phosphatase activity able to compete with bacitracin for UPP. We found that overexpression of a recombinant His6-BcrC(Bs) protein in E. coli (i) increased the resistance of the cells to bacitracin and (ii) increased UPP phosphatase activity in membrane preparations by 600-fold. We solubilized and prepared an electrophoretically pure protein exhibiting a strong UPP phosphatase activity. BcrC(Bs), which belongs to the type 2 phosphatidic acid phosphatase (PAP2) phosphatase superfamily (PF01569), differs totally from the already known BacA UPP phosphatase from E. coli, a member of the PF02673 family of the Protein family (Pfam) database. Thus, BcrC(Bs) and its orthologs form a new class of proteins within the PAP2 phosphatase superfamily, and likely all of them share a UPP phosphatase activity.

Characterization of the Bacillus subtilis YxdJ response regulator as the inducer of expression for the cognate ABC transporter YxdLM.

The genome of Bacillus subtilis, like those of some other AT-rich Gram-positive bacteria, has the uncommon feature of containing several copies of arrangements in which the genes encoding two-component and cognate ABC transporter systems are adjacent. As the function of one of these systems, the product of the yxd locus, is still unknown, it was analysed further in order to get some clues on the physiological role of the gene products it encodes. The yxdJ gene was shown to encode a DNA-binding protein that directly controls transcription of the neighbouring operon encoding the ABC transporter YxdLM. Primer extension and DNase protection experiments allowed precise definition of the yxdLM transcription start and controlling region. Two putative direct repeats were identified that are proposed to be the YxdJ response regulator binding sites. Whole-cell transcriptome analyses revealed that the YxdJ regulon is extremely restricted. In addition to the yxdJKLMyxeA operon, only a few genes involved in modifications of the bacterial cell wall were shown to be regulated by YxdJ.

Characterization of YvcC (BmrA), a multidrug ABC transporter constitutively expressed in Bacillus subtilis.

The involvement of transporters in multidrug resistance of bacteria is an increasingly challenging problem, and most of the pumps identified so far use the protonmotive gradient as the energy source. A new member of the ATP-binding cassette (ABC) family, known in Bacillus subtilis as YvcC and homologous to each half of mammalian P-glycoprotein and to LmrA of Lactococcus lactis, has been studied here. The yvcC gene was constitutively expressed in B. subtilis throughout its growth, and a knockout mutant showed a lower rate of ethidium efflux than the wild-type strain. Overexpression of yvcC in Escherichia coli allowed the preparation of highly enriched inverted-membrane vesicles that exhibited high transport activities of three fluorescent drugs, namely, Hoechst 33342, doxorubicin, and 7-aminoactinomycin D. After solubilization with n-dodecyl beta-D-maltoside, the hexahistidine-tagged YvcC was purified by a one-step affinity chromatography, and its ability to bind many P-glycoprotein effectors was evidenced by fluorescence spectroscopy experiments. Collectively, these results showed that YvcC is a multidrug ABC transporter functionally active in wild-type B. subtilis, and YvcC was therefore renamed BmrA for Bacillus multidrug resistance ATP. Besides, reconstitution of YvcC into liposomes led to the highest, vanadate-sensitive, ATPase activity reported so far for an ABC transporter. Interestingly, such a high ATP hydrolysis proceeds with a positive cooperativity mechanism, a property only found so far with ABC importers.

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.

Regulatory relationship of two-component and ABC transport systems and clustering of their genes in the Bacillus/Clostridium group, suggest a functional link between them.

On the Bacillus subtilis chromosome there are five examples of genes encoding two-component systems with response regulators of the OmpR family adjacent to genes encoding sub-family 9 ABC transport systems. Three of these (yts, yvc, yxd) are very similar in gene organization and in sequence. We demonstrate that the TCS and ABC transporter genes do not belong to the same transcriptional unit. The ABC transport and TCS systems are functionally linked, each response regulator controlling the expression of its cognate ABC transporter genes but not its own. Analysis of 48 bacterial genomes revealed that such family clusters only exist in the Bacillus/Clostridium group. Evolutionary analyses indicated that almost all clustered OmpR response regulators constitute two groups ("GI" and "GIIl") whereas almost all clustered sub-family 9 nucleotide-binding domains belong to two other groups ("9A" and "9B"). Interestingly, there is a mutually exclusive clustering between genes encoding "GI" or a "GII" response regulators and genes encoding "9A" or a "9B" nucleotide binding proteins. We propose that a two-component system and its cognate ABC transporter genes have evolved as a unit in Bacillus/Clostridium, both systems participating in a common physiological process.