Isolation of Tn917 insertional mutants of Bacillus subtilis that are resistant to the protonophore carbonyl cyanide m-chlorophenylhydrazone

Functional Characteristics of TauA Binding Protein from TauABC Escherichia coli System

Although TauA shares few common characteristics with other known periplasmic binding protein, TauA is a putative periplasmic binding protein, part of tauABCD gene cluster involved in sulfonate transport in sulphate starvation condition. This protein was expressed in E. coli BL 21 and purified before to assess its binding functionalities. Measurement of K (d) value (mean 11.3 nM) by binding/dialysis studies revealed high affinity and specificity with taurine and also indicated that TauA possessed a unique binding site for its ligand. Comparisons with other periplasmic binding proteins suggests TauA plays a major role in ABC transport system and could be ideal candidate to serve as taurine catcher in biological fluids.

Structural classification of bacterial response regulators: diversity of output domains and domain combinations

CheY-like phosphoacceptor (or receiver [REC]) domain is a common module in a variety of response regulators of the bacterial signal transduction systems. In this work, 4,610 response regulators, encoded in complete genomes of 200 bacterial and archaeal species, were identified and classified by their domain architectures. Previously uncharacterized output domains were analyzed and, in some cases, assigned to known domain families. Transcriptional regulators of the OmpR, NarL, and NtrC families were found to comprise almost 60% of all response regulators; transcriptional regulators with other DNA-binding domains (LytTR, AraC, Spo0A, Fis, YcbB, RpoE, and MerR) account for an additional 6%. The remaining one-third is represented by the stand-alone REC domain (approximately 14%) and its combinations with a variety of enzymatic (GGDEF, EAL, HD-GYP, CheB, CheC, PP2C, and HisK), RNA-binding (ANTAR and CsrA), protein- or ligand-binding (PAS, GAF, TPR, CAP_ED, and HPt) domains, or newly described domains of unknown function. The diversity of domain architectures and the abundance of alternative domain combinations suggest that fusions between the REC domain and various output domains is a widespread evolutionary mechanism that allows bacterial cells to regulate transcription, enzyme activity, and/or protein-protein interactions in response to environmental challenges. The complete list of response regulators encoded in each of the 200 analyzed genomes is available online at http://www.ncbi.nlm.nih.gov/Complete_Genomes/RRcensus.html.

Mutants of Mycobacterium smegmatis unable to grow at acidic pH in the presence of the protonophore carbonyl cyanide m-chlorophenylhydrazone

Mycobacterium smegmatis is able to grow and survive at acidic pH, and exhibits intracellular pH homeostasis under these conditions. In this study, the authors have identified low proton permeability of the cytoplasmic membrane, and high cytoplasmic buffering capacity, as determinants of intrinsic acid resistance of M. smegmatis. To identify genes encoding proteins involved in protecting cells from acid stress, a screening method was developed using the electrogenic protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP). CCCP was used to suppress intrinsic acid resistance of M. smegmatis. The screen involved exposing cells to pH 5.0 in the presence of CCCP, and survivors were rescued at various time intervals on solid medium at pH 7.5. Cells capable of responding to intracellular acidification (due to CCCP-induced proton equilibration) will survive longer under these conditions than acid-sensitive cells. From a total pool of 5000 transposon (Tn611) insertion mutants screened, eight acid-sensitive M. smegmatis mutants were isolated. These acid-sensitive mutants were unable to grow at pH 5.0 in the presence of 1-5 microM CCCP, a concentration not lethal to the wild-type strain mc2155. The DNA flanking the site of Tn611 was identified using marker rescue in Escherichia coli, and DNA sequencing to identify the disrupted locus. Acid-sensitive mutants of M. smegmatis were disrupted in genes involved in phosphonate/phosphite assimilation, methionine biosynthesis, the PPE multigene family, xenobiotic-response regulation and lipid biosynthesis. Several of the acid-sensitive mutants were also defective in stationary-phase survival, suggesting that overlapping stress protection systems exist in M. smegmatis.

A novel reduced flavin mononucleotide-dependent methanesulfonate sulfonatase encoded by the sulfur-regulated msu operon of Pseudomonas aeruginosa

When Pseudomonas aeruginosa is grown with organosulfur compounds as sulfur sources, it synthesizes a set of proteins whose synthesis is repressed in the presence of sulfate, cysteine, or thiocyanate (so-called sulfate starvation-induced proteins). The gene encoding one of these proteins, PA13, was isolated from a cosmid library of P. aeruginosa PAO1 and sequenced. It encoded a 381-amino-acid protein that was related to several reduced flavin mononucleotide (FMNH2)-dependent monooxygenases, and it was the second in an operon of three genes, which we have named msuEDC. The MsuD protein catalyzed the desulfonation of alkanesulfonates, requiring oxygen and FMNH2 for the reaction, and showed highest activity with methanesulfonate. MsuE was an NADH-dependent flavin mononucleotide (FMN) reductase, which provided reduced FMN for the MsuD enzyme. Expression of the msu operon was analyzed with a transcriptional msuD::xylE fusion and was found to be repressed in the presence of sulfate, sulfite, sulfide, or cysteine and derepressed during growth with methionine or alkanesulfonates. Growth with methanesulfonate required an intact cysB gene, and the msu operon is therefore part of the cys regulon, since sulfite utilization was found to be CysB independent in this species. Measurements of msuD::xylE expression in cysN and cysI genetic backgrounds showed that sulfate, sulfite, and sulfide or cysteine play independent roles in negatively regulating msu expression, and sulfonate utilization therefore appears to be tightly regulated.

Transmembrane topology of the two FhuB domains representing the hydrophobic components of bacterial ABC transporters involved in the uptake of siderophores, haem and vitamin B12

Transport of siderophores of the hydroxamate type across the Escherichia coli cytoplasmic membrane depends on a periplasmic binding-protein-dependent (PBT) system. This uptake system consists of the binding protein FhuD, the membrane-associated putative ATP-hydrolase FhuC and the integral membrane protein FhuB. The two halves of FhuB [FhuB(N) and FhuB(C)], both essential for transport, are similar with respect to structure and function. Regions were identified in FhuB(N) and FhuB(C) which are presumably involved in the interaction of the two FhuB halves with each other or with other components of the uptake system, or with the different substrates. To determine the topology of the membrane-embedded polypeptide chain, FhuB'-'beta-lactamase protein fusions were analysed. The experimental data suggest that each half of the FhuB is able to fold autonomously into the lipid bilayer, which is a prerequisite for the assembly of both halves into a transport-competent formation. The hydrophobic components from PBT systems involved in the uptake of siderophores, haem and vitamin B12 define a subclass of polytopic integral membrane proteins. The topology of these 'siderophore family' proteins differs from that of the equivalent components of other PBT systems in that each polypeptide (and each half of FhuB) consists of 10 membrane-spanning regions, with the N- and C-termini located in the cytoplasm. The conserved region at a distance of about 90 amino acids from the C-terminus, typical of all hydrophobic PBT proteins, is also oriented to the cytoplasm. However, in the 'siderophore family' proteins this putative ATPase interaction loop is followed by four instead of two transmembrane spans.

Bacillus subtilis genes for the utilization of sulfur from aliphatic sulfonates

A 5 kb region upstream of katA at 82 degrees on the Bacillus subtilis chromosome contains five ORFs organized in an operon-like structure. Based on sequence similarity, three of the ORFs are likely to encode an ABC transport system (ssuBAC) and another to encode a monooxygenase (ssuD). The deduced amino acid sequence of the last ORF (ygaN) shows no similarity to any known protein. B. subtilis can utilize a range of aliphatic sulfonates such as alkanesulfonates, taurine, isethionate and sulfoacetate as a source of sulfur, but not when ssuA and ssuC are disrupted by insertion of a neomycin-resistance gene. Utilization of aliphatic sulfonates was not affected in a strain lacking 3'-phosphoadenosine 5'-phosphosulfate (PAPS) sulfotransferase, indicating that sulfate is not an intermediate in the assimilation of sulfonate-sulfur. Sulfate or cysteine prevented expression of beta-galactosidase from a transcriptional ssuD::lacZ fusion. It is proposed that ssuBACD encode a system for ATP-dependent transport of alkanesulfonates and an oxygenase required for their desulfonation.

Regulation of the sulfate starvation response in Pseudomonas aeruginosa: role of cysteine biosynthetic intermediates

Pseudomonas aeruginosa PAO1 grew in defined synthetic medium with any of a broad variety of single sulfur sources, including sulfate, cysteine, thiocyanate, alkanesulfonates, organosulfate esters and methionine, but not with aromatic sulfonates, thiophenols or organothiocyanates or isothiocyanates. During growth with any of these compounds except sulfate, cysteine or thiocyanate, a set of 10 sulfate starvation-induced (SSI) proteins was strongly up-regulated, as observed by two-dimensional protein electrophoresis of total cell extracts. A comparable level of up-regulation was found for the hydrolytic enzyme arylsulfatase, which has previously been used as a marker enzyme for the sulfate starvation response. One of the SSI proteins was identified by N-terminal sequencing as a high-affinity periplasmic sulfate-binding protein, and another was related to thiol-specific antioxidants, but the N-terminal sequences of the other SSI proteins revealed no similarity to N-termini of proteins of known function, and they probably represent uncharacterized enzymes involved in sulfur scavenging when preferred sulfur sources are absent. To study the role that cysteine biosynthetic intermediates play in the synthesis of these proteins in vivo, we isolated mini-Tn5 transposon mutants of P. aeruginosa with insertions in the cysN and cysI genes, which encode subunits of ATP-sulfurylase and sulfite reductase, respectively. These two genes were cloned and sequenced. cysI showed high similarity to the cognate gene in Escherichia coli, whereas cysN encoded a 69.3 kDa protein with two domains corresponding to the E. coli CysN and CysC proteins. Sulfate no longer repressed synthesis of the SSI proteins in cysN mutants, but repression was restored by sulfite; in the cysI mutant, sulfate, sulfite and sulfide all led to repression of SSI protein synthesis. This suggests that there are at least two independent corepressors of the sulfate starvation response in this species.

Arac/XylS family of transcriptional regulators

The ArC/XylS family of prokaryotic positive transcriptional regulators includes more than 100 proteins and polypeptides derived from open reading frames translated from DNA sequences. Members of this family are widely distributed and have been found in the gamma subgroup of the proteobacteria, low- and high-G + C-content gram-positive bacteria, and cyanobacteria. These proteins are defined by a profile that can be accessed from PROSITE PS01124. Members of the family are about 300 amino acids long and have three main regulatory functions in common: carbon metabolism, stress response, and pathogenesis. Multiple alignments of the proteins of the family define a conserved stretch of 99 amino acids usually located at the C-terminal region of the regulator and connected to a nonconserved region via a linker. The conserved stretch contains all the elements required to bind DNA target sequences and to activate transcription from cognate promoters. Secondary analysis of the conserved region suggests that it contains two potential alpha-helix-turn-alpha-helix DNA binding motifs. The first, and better-fitting motif is supported by biochemical data, whereas existing biochemical data neither support nor refute the proposal that the second region possesses this structure. The phylogenetic relationship suggests that members of the family have recruited the nonconserved domain(s) into a series of existing domains involved in DNA recognition and transcription stimulation and that this recruited domain governs the role that the regulator carries out. For some regulators, it has been demonstrated that the nonconserved region contains the dimerization domain. For the regulators involved in carbon metabolism, the effector binding determinants are also in this region. Most regulators belonging to the AraC/XylS family recognize multiple binding sites in the regulated promoters. One of the motifs usually overlaps or is adjacent to the -35 region of the cognate promoters. Footprinting assays have suggested that these regulators protect a stretch of up to 20 bp in the target promoters, and multiple alignments of binding sites for a number of regulators have shown that the proteins recognize short motifs within the protected region.

Characterization of lipoprotein IRP1 from Corynebacterium diphtheriae, which is regulated by the diphtheria toxin repressor (DtxR) and iron

The Corynebacterium diphtheriae irp1 gene is negatively regulated by DtxR and iron. The nucleotide sequence of irp1 revealed that it has homology with genes involved in iron acquisition. Expression of the irp1 gene showed that it encodes a lipoprotein (IRP1) with a predicted size of 38 kDa. Northern blot experiments indicated that transcription from the irp1 promoter is repressed in high-iron medium and suggested that irp1 is part of an iron-regulated operon.

Sequence and analysis of a 31 kb segment of the Bacillus subtilis chromosome in the area of the rrnH and rrnG operons

A 31141 bp continuous nucleotide sequence in the region from trnl to pNEXT52 in the Bacillus subtilis 168 genome was determined. In the region, there were 22 ORFs, two complete rRNA operons, and five tRNA genes. It was deduced that the function of one of the ORFs was similar to that of a sigma factor belonging to the ECF (extra-cytoplasmic functions) subfamily. The gene cluster feuA, B, C reported previously for other strains of B. subtilis was also found in strain 168 and located in this region.

Cloning and sequencing of a 35.7 kb in the 70 degree-73 degree region of the Bacillus subtilis genome reveal genes for a new two-component system, three spore germination proteins, an iron uptake system and a general stress response protein

In the framework of the international project aimed at sequencing the Bacillus subtilis (Bs) genome, a 35.7-kb chromosome segment around the pel locus has been cloned and sequenced. This region (35,745 bp; 70 degrees-73 degrees of the genetic map) contains two partial and 38 complete orfs. A homology search for the products deduced from the 39 orfs revealed that 26 of them exhibit significant similarity to known proteins, e.g. germination proteins, sodium-alanine symporter, PTS system, methionine amino peptidase, 2-oxoglutarate/malate translocater, pectate lyase, general stress response protein, RNA helicase, iron uptake and two-component systems.

A Bacillus cereus member of the SNF2 family

The complete sequence of a Bacillus cereus member of the SNF2 family of putative helicases showed conservation of all seven motifs typical of this family. Bcsnf predicted a protein of 1064 aa where the conserved SNF2 domain was located at the carboxy terminus, whereas the 633 amino-terminal aa showed no homology to any protein in the databases. A putative transcriptional start was identified by primer extension, indicating that Bcsnf is not a part of a larger operon. No phenotypical changes were observed after insertional inactivation of Bcsnf. The completely sequenced genomes of Mycoplasma genitalium and Haemophilus influenzae contain one ORF each with similarity to the SNF2 family: MG018 and HI0616, respectively. A phylogenetic tree of the SNF2 family showed that BcSNF and MG018 were most closely related, and appeared closer to the eukaryotic members of the SNF2 family than to the two other bacterial members of the family, HepA from Escherichia coli and HI0616.

Identification of sulfate starvation-regulated genes in Escherichia coli: a gene cluster involved in the utilization of taurine as a sulfur source

Genes whose expression is regulated by sulfate starvation in Escherichia coli were identified by generating random translational lacZ fusions in the chromosome with the lambda placMu9 system. Nine lacZ fusion strains which expressed beta-galactosidase after growth under sulfate starvation conditions but not after growth in the presence of sulfate were found. These included two strains with insertions in the dmsA and rhsD genes, respectively, and seven strains in which the insertions were located within a 1.8-kb region downstream of hemB at 8.5 minutes on the E. coli chromosome. Analysis of the nucleotide sequence of this region indicated the presence of four open reading frames designated tauABCD. Disruption of these genes resulted in the loss of the ability to utilize taurine (2-aminoethanesulfonate) as a source of sulfur but did not affect the utilization of a range of other aliphatic sulfonates as sulfur sources. The TauA protein contained a putative signal peptide for transport into the periplasm; the TauB and TauC proteins showed sequence similarity to ATP-binding proteins and membrane proteins, respectively, of ABC-type transport systems; and the TauD protein was related in sequence to a dichlorophenoxyacetic acid dioxygenase. We therefore suggest that the proteins encoded by tauABC constitute an uptake system for taurine and that the product of tauD is involved in the oxygenolytic release of sulfite from taurine. The transcription initiation site was detected 26 to 27 bp upstream of the translational start site of tauA. Expression of the tauD gene was dependent on CysB, the transcriptional activator of the cysteine regulon.

A polyferredoxin with eight [4Fe-4S] clusters as a subunit of molybdenum formylmethanofuran dehydrogenase from Methanosarcina barkeri

Formylmethanofuran dehydrogenase (Fmd) from Methanosarcina barkeri is a molybdenum iron-sulfur protein involved in methanogenesis. The enzyme contains approximately 30 mol non-heme iron/mol and 30 mol acid-labile sulfur/mol. We report here the cloning and sequencing of the encoding genes, and that these genes form a transcription unit fmdEFACDB. Evidence is provided that the subunit FmdB harbours the molybdenum-containing active site and may bind one [4Fe-4S] cluster. fmdF encodes a protein with four tandemly repeated bacterial-ferredoxin-like domains and is predicted to be a polyferredoxin that could contain as many as 32 iron atoms in eight [4Fe-4S] clusters. The other genes code for proteins without sequence motifs characteristic for iron-sulfur proteins. These findings suggest that most of the iron-sulfur clusters present in the purified formylmethanofuran dehydrogenase are associated with the subunit FmdF. The finding that FmdF forms a tight complex with the other subunits of formylmethanofuran dehydrogenase indicates a function of the polyferredoxin in the reaction catalyzed by the enzyme. fmdE encodes a protein not present in the purified enzyme. All six genes of the fmd operon were expressed in Escherichia coli and yielded proteins of expected molecular masses. A malE-fmdF gene fusion was constructed and expressed in E. coli, making the apoprotein of the polyferredoxin available in preparative amounts.