A set of genetically diverged Saccharomyces cerevisiae strains with markerless deletions of multiple auxotrophic genes.

Genome analysis of over 70 Saccharomyces strains revealed the existence of five groups of genetically diverged S. cerevisiae wild-type isolates, which feature distinct genetic backgrounds and reflect the natural diversity existing among the species. The strains originated from different geographical and ecological niches (Malaysian, West African, North American, Wine/European and Sake) and represent clean, non-mosaic lineages of S. cerevisiae, meaning that their genomes differ essentially by monomorphic and private SNPs. In this study, one representative strain for each of the five S. cerevisiae clean lineages was selected and mutated for several auxotroph genes by clean markerless deletions, so that all dominant markers remained available for further genetic manipulations. A set of 50 strains was assembled, including eight haploid and two diploid strains for each lineage. These strains carry different combinations of leu2∆0, lys2∆0, met15∆0, ura3∆0 and/or ura3∆::KanMX-barcoded deletions with marker configurations resembling that of the BY series, which will allow large-scale crossing with existing deletion collections. This new set of genetically tractable strains provides a powerful tool kit to explore the impact of natural variation on complex biological processes.

Structural and functional characterization of an orphan ATP-binding cassette ATPase involved in manganese utilization and tolerance in Leptospira spp.

Pathogenic Leptospira species are the etiological agents of the widespread zoonotic disease leptospirosis. Most organisms, including Leptospira, require divalent cations for proper growth, but because of their high reactivity, these metals are toxic at high concentrations. Therefore, bacteria have acquired strategies to maintain metal homeostasis, such as metal import and efflux. By screening Leptospira biflexa transposon mutants for their ability to use Mn(2+), we have identified a gene encoding a putative orphan ATP-binding cassette (ABC) ATPase of unknown function. Inactivation of this gene in both L. biflexa and L. interrogans strains led to mutants unable to grow in medium in which iron was replaced by Mn(2+), suggesting an involvement of this ABC ATPase in divalent cation uptake. A mutation in this ATPase-coding gene increased susceptibility to Mn(2+) toxicity. Recombinant ABC ATPase of the pathogen L. interrogans exhibited Mg(2+)-dependent ATPase activity involving a P-loop motif. The structure of this ATPase was solved from a crystal containing two monomers in the asymmetric unit. Each monomer adopted a canonical two-subdomain organization of the ABC ATPase fold with an α/ß subdomain containing the Walker motifs and an α subdomain containing the ABC signature motif (LSSGE). The two monomers were arranged in a head-to-tail orientation, forming a V-shaped particle with all the conserved ABC motifs at the dimer interface, similar to functional ABC ATPases. These results provide the first structural and functional characterization of a leptospiral ABC ATPase.

Hereditary hemochromatosis restores the virulence of plague vaccine strains.

Nonpigmented Yersinia pestis (pgm) strains are defective in scavenging host iron and have been used in live-attenuated vaccines to combat plague epidemics. Recently, a Y. pestis pgm strain was isolated from a researcher with hereditary hemochromatosis who died from laboratory-acquired plague. We used hemojuvelin-knockout (Hjv(-/-)) mice to examine whether iron-storage disease restores the virulence defects of nonpigmented Y. pestis. Unlike wild-type mice, Hjv(-/-) mice developed lethal plague when challenged with Y. pestis pgm strains. Immunization of Hjv(-/-) mice with a subunit vaccine that blocks Y. pestis type III secretion generated protection against plague. Thus, individuals with hereditary hemochromatosis may be protected with subunit vaccines but should not be exposed to live-attenuated plague vaccines.

The Fur iron regulator-like protein is cryptic in the hyperthermophilic archaeon Thermococcus kodakaraensis.

Archaea, which regroup organisms with extreme living conditions, possess many predicted iron-containing proteins that may be metabolically critical; however, their need for iron remains poorly documented. In this report, iron acquisition mechanisms were investigated in the hyperthermophilic archaeon Thermococcus kodakaraensis. Thermococcus kodakaraensis requires iron for its growth and possesses many putative iron uptake systems, including several ATP-binding cassette-like transporters and two FeoAB-like receptors, showing that this organism shares similar features with bacteria. One homolog of the major bacterial iron regulator, ferric uptake regulator (Fur), with about 50% similarity to Escherichia coli Fur was also identified. Thermococcus kodakaraensis Fur was found to be able to specifically bind to a Fur-binding site consensus-like sequence of its own gene promoter. However, its expression has been hindered by a -1 frameshift mutation and the chromosomal repair of this mutation did not affect T. kodakaraensis in vivo phenotypes. Microarrays analyses helped to further characterize T. kodakaraensis iron-dependent growth and revealed no role for the Fur homolog in the global regulatory response of the cells to iron. In contrast, additional evidences indicated that the T. kodakaraensis diphtheria toxin regulator (DtxR) homolog may control the expression of the major iron acquisition effectors, while its inactivation enabled higher resistance to iron deficiency.

Archaeal chromatin proteins histone HMtB and Alba have lost DNA-binding ability in laboratory strains of Methanothermobacter thermautotrophicus.

Alignments of the sequences of the all members of the archaeal histone and Alba1 families of chromatin proteins identified isoleucine residues, I19 in HMtB and I39 in MtAlba, in Methanothermobacter thermautotrophicus, at locations predicted to be directly involved in DNA binding. In all other HMfB family members, residue 19 is an arginine (R19), and either arginine or lysine is present in almost all other Alba1 family members at the structural site equivalent to I39 in MtAlba. Electrophoretic mobility shift assays revealed that recombinant HMtB and MtAlba do not bind DNA, but variants constructed with R19 and R39, respectively, bound DNA; and whereas MtAlba(I19) did not bind RNA, MtAlba(R19) bound both single stranded RNA and tRNA. Amplification and sequencing of MT0254 (encodes HMtB) and MT1483 (encodes MtAlba) from several Methanothermobacter thermautotrophicus lineages has revealed that HMtB and MtAlba had arginine residues at positions 19 and 39, respectively, in the original isolate and that spontaneous mutations must have occurred, and been fixed, in some laboratory lineages that now have HMtB(I19) and MtAlba(I39). The retention of these variants suggests some continuing functions and fusion of the HMtB(I19) sequence to HMtA2 resulted in a protein that folds to form a histone fold heterodimer that binds and compacts DNA. The loss of DNA binding by HMtB(I19) does not therefore prevent HMtB from participating in DNA interactions as one partner of an archaeal histone heterodimer.

Heme rescues a two-component system Leptospira biflexa mutant.

BACKGROUND: Heme is typically a major iron source for bacteria, but little is known about how bacteria of the Leptospira genus, composed of both saprophytic and pathogenic species, access heme. RESULTS: In this study, we analysed a two-component system of the saprophyte Leptospira biflexa. In vitro phosphorylation and site-directed mutagenesis assays showed that Hklep is a histidine kinase which, after autophosphorylation of a conserved histidine, transfers the phosphate to an essential aspartate of the response regulator Rrlep. Hklep/Rrlep two-component system mutants were generated in L. biflexa. The mutants could only grow in medium supplemented with hemin or delta-aminolevulinic acid (ALA). In the pathogen L. interrogans, the hklep and rrlep orthologous genes are located between hemE and hemL genes, which encode proteins involved in heme biosynthesis. The L. biflexa hklep mutant could be complemented with a replicative plasmid harbouring the L. interrogans orthologous gene, suggesting that these two-component systems are functionally similar. By real-time quantitative reverse transcription-PCR, we also observed that this two-component system might influence the expression of heme biosynthetic genes. CONCLUSION: These findings demonstrate that the Hklep/Rrlep regulatory system is critical for the in vitro growth of L. biflexa, and suggest that this two-component system is involved in a complex mechanism that regulates the heme biosynthetic pathway.

Genetic manipulation of Leptospira biflexa.

The genus Leptospira belongs to the order Spirochaetales and is composed of both saprophytic and pathogenic members, such as Leptospira biflexa and L. interrogans, respectively. A major factor contributing to our ignorance of spirochetal biology has been the lack of methods available for genetic analysis of these organisms. In recent years, an E. coli-L. biflexa shuttle vector has been constructed and a system for targeted mutagenesis and random transposon mutagenesis of the saprophyte L. biflexa has been developed. These studies enable the use of L. biflexa as a model bacterium among spirochetes.

Random insertional mutagenesis of Leptospira interrogans, the agent of leptospirosis, using a mariner transposon.

The recent availability of the complete genome sequences of Leptospira interrogans, the agent of leptospirosis, has allowed the identification of several putative virulence factors. However, to our knowledge, attempts to carry out gene transfer in pathogenic Leptospira spp. have failed so far. In this study, we show that the Himar1 mariner transposon permits random mutagenesis in the pathogen L. interrogans. We have identified genes that have been interrupted by Himar1 insertion in 35 L. interrogans mutants. This approach of transposon mutagenesis will be useful for understanding the spirochetal physiology and the pathogenic mechanisms of Leptospira, which remain largely unknown.

Isolation and characterization of FecA- and FeoB-mediated iron acquisition systems of the spirochete Leptospira biflexa by random insertional mutagenesis.

The specific mechanisms by which Leptospira spp. acquire iron from their ecological niches are unknown. A major factor contributing to our ignorance of spirochetal biology is the lack of methods for genetic analysis of these organisms. In this study, we have developed a system for random transposon mutagenesis of Leptospira biflexa using a mariner transposon, Himar1. To demonstrate the validity of Himar1 in vivo transposon mutagenesis in L. biflexa, a screen of mutants for clones impaired in amino acid biosynthesis was first performed, enabling the identification of tryptophan and glutamate auxotrophs. To investigate iron transporters, 2,000 L. biflexa transposon mutants were screened onto media with and without hemin, thus allowing the identification of five hemin-requiring mutants, and the putative genes responsible for this phenotype were identified. Three mutants had distinct insertions in a gene encoding a protein which shares homology with the TonB-dependent receptor FecA, involved in ferric citrate transport. We also identified two mutants with a Himar1 insertion into a feoB-like gene, the product of which is required for ferrous iron uptake in many bacterial organisms. Interestingly, the growth inhibition exhibited by the fecA and feoB mutants was relieved by deferoxamine, suggesting the presence of a ferric hydroxamate transporter. These results confirm the importance of iron for the growth of Leptospira and its ability to use multiple iron sources.