Hitherto Unknown [Fe-Fe]-Hydrogenase Gene Diversity in Anaerobes and Anoxic Enrichments from a Moderately Acidic Fen

Newly designed primers for [Fe-Fe]-hydrogenases indicated that (i) fermenters, acetogens, and undefined species in a fen harbor hitherto unknown hydrogenases and (ii) Clostridium- and Thermosinus-related primary fermenters, as well as secondary fermenters related to sulfate or iron reducers might be responsible for hydrogen production in the fen. Comparative analysis of [Fe-Fe]-hydrogenase and 16S rRNA gene-based phylogenies indicated the presence of homologous multiple hydrogenases per organism and inconsistencies between 16S rRNA gene- and [Fe-Fe]-hydrogenase-based phylogenies, necessitating appropriate qualification of [Fe-Fe]-hydrogenase gene data for diversity analyses.Molecular hydrogen (H₂) is important in intermediary ecosystem metabolism (i.e., processes that link input to output) in wetlands (7, 11, 12, 33) and other anoxic habitats like sewage sludges (34) and the intestinal tracts of animals (9, 37). H₂-producing fermenters have been postulated to form trophic links to H₂-consuming methanogens, acetogens (i.e., organisms capable of using the acetyl-coenzyme A [CoA] pathway for acetate synthesis) (7), Fe(III) reducers (17), and sulfate reducers in a well-studied moderately acidic fen in Germany (11, 12, 16, 18, 22, 33). 16S rRNA gene analysis revealed the presence of Clostridium spp. and Syntrophobacter spp., which represent possible primary and secondary fermenters, as well as H₂ producers in this fen (11, 18, 33). However, H₂-producing bacteria are polyphyletic (30, 31, 29). Thus, a structural marker gene is required to target this functional group by molecular methods. [Fe-Fe]-hydrogenases catalyze H₂ production in fermenters (19, 25, 29, 30, 31), and genes encoding [Fe-Fe]-hydrogenases represent such a marker gene. The objectives of this study were to (i) develop primers specific for highly diverse [Fe-Fe]-hydrogenase genes, (ii) analyze [Fe-Fe]-hydrogenase genes in pure cultures of fermenters, acetogens, and a sulfate reducer, (iii) assess [Fe-Fe]-hydrogenase gene diversity in H₂-producing fen soil enrichments, and (iv) evaluate the limitations of the amplified [Fe-Fe]-hydrogenase fragment as a phylogenetic marker.     

In Vitro Kinetics of Prebiotic Inulin-Type Fructan Fermentation by Butyrate-Producing Colon Bacteria: Implementation of Online Gas Chromatography for Quantitative Analysis of Carbon Dioxide and Hydrogen Gas Production

Kinetic analyses of bacterial growth, carbohydrate consumption, and metabolite production of five butyrate-producing clostridial cluster XIVa colon bacteria grown on acetate plus fructose, oligofructose, inulin, or lactate were performed. A gas chromatography method was set up to assess H₂ and CO₂ production online and to ensure complete coverage of all metabolites produced. Method accuracy was confirmed through the calculation of electron and carbon recoveries. Fermentations with Anaerostipes caccae DSM 14662^T, Roseburia faecis DSM 16840^T, Roseburia hominis DSM 16839^T, and Roseburia intestinalis DSM 14610^T revealed similar patterns of metabolite production with butyrate, CO₂, and H₂ as the main metabolites. R. faecis DSM 16840^T and R. intestinalis DSM 14610^T were able to degrade oligofructose, displaying a nonpreferential breakdown mechanism. Lactate consumption was only observed with A. caccae DSM 14662^T. Roseburia inulinivorans DSM 16841^T was the only strain included in the present study that was able to grow on fructose, oligofructose, and inulin. The metabolites produced were lactate, butyrate, and CO₂, without H₂ production, indicating an energy metabolism distinct from that of other Roseburia species. Oligofructose degradation was nonpreferential. In a coculture of R. inulinivorans DSM 16841^T with the highly competitive strain Bifidobacterium longum subsp. longum LMG 11047 on inulin, hardly any production of butyrate and CO₂ was detected, indicating a lack of competitiveness of the butyrate producer. Complete recovery of metabolites during fermentations of clostridial cluster XIVa butyrate-producing colon bacteria allowed stoichiometric balancing of the metabolic pathway for butyrate production, including H₂ formation.The implementation of 16S rRNA gene-based analytical techniques in the ongoing exploration of the microbial diversity of the human colon ecosystem has both broadened and sharpened the prevailing image of its population (17, 24, 32). While a rather conservative perception of the composition of the colon microbiota has dominated gut research for several decades (36), recent studies have revealed the importance of previously largely neglected bacterial groups and have reduced historically numerically overestimated subpopulations to their actual (marginal) size (8, 22, 52). The human colon has been shown to be a remarkably selective environment, which is reflected by a rather shallow microbial diversity (32). Species belonging to the bacterial divisions Firmicutes, Bacteroidetes, Proteobacteria, and Actinobacteria make up more than 98% of the bacterial population of the human colon (2, 17, 24). However, this superficial uniformity only covers an overwhelming diversity at the lower taxonomic levels; the human colon has been estimated to harbor between 500 and 1,000 species, representing over 7,000 strains, with up to 80% of them considered uncultivable using presently available methodologies (14, 28, 53).Assessing identity and abundance of the major microbial groups composing the colon microbiota is a first and indispensable step toward a better understanding of the ecosystem of the large intestine (48). However, defining a complex ecosystem such as the human colon requires more than the construction of a catalog of its members (32). A major challenge of gastrointestinal microbiology lies in linking phylogenetic subgroups with particular ecological habitats and niches (7, 8, 23). The latter requires further development of highly discriminating 16S rRNA gene-targeted probes to monitor spatial bacterial distribution, combined with renewed efforts toward species isolation through the application of innovative cultivation methods and media, and extensive metabolic characterization of representative strains (19, 35, 48).Recently, a global ecological approach, combining efforts in probe development (1, 27), species isolation (3), and metabolic characterization (4, 11, 15, 20), has led to the identification of a functional group of microorganisms, composed of species belonging to the clostridial clusters IV and XIVa, that are responsible for colon butyrate production. As butyrate is regarded as a key metabolite for the maintenance of colon health, this functional subunit of the colon microbiota could have a major influence on human well-being and might be considered as a target for prebiotic dietary interventions (25, 35, 45). Some recently described lactate- and/or acetate-converting colon butyrate producers have been reported to be able to degrade prebiotic inulin-type fructans, although the kinetics of their respective breakdown mechanisms have hardly been investigated (10, 20). The enhancement of colon butyrate production observed after consumption of oligofructose or inulin (6, 31, 40)—the so-called butyrogenic effect—as well as the limited stimulatory effect of these prebiotics on the clostridial cluster IV and XIVa colon populations (16, 30) have been attributed to cross-feeding with bifidobacteria, which are still considered the primary fructan degraders (5, 38). Anaerostipes caccae as well as Roseburia spp. have been shown to be able to (co)metabolize end products of bifidobacterial fructan fermentation (lactate and/or acetate) or to grow on short oligosaccharides and monosaccharides released by Bifidobacterium spp. during fructan degradation (4, 20).Recently, many clostridial cluster IV and XIVa butyrate producers characterized in detail have been shown to produce gases, mainly CO₂ and H₂ (12, 15, 20, 46). Consequently, they might be responsible for an enhancement of gas production as a result of fructan fermentation, through either cross-feeding or direct degradation of inulin-type fructans (15, 16). Indeed, inulin-type fructan consumption has been reported to cause some gastrointestinal discomfort related to gas production—essentially, flatulence and bloating (43)—while bifidobacteria, the main beneficiaries of dietary fructan intake, do not produce gases (19, 49). Although CO₂ and H₂ production by colon butyrate producers could have implications for human intestinal well-being, (in vitro) production has not been satisfactorily monitored up to now, probably due to limited availability of a performant apparatus for (online) gas analysis (15, 20). Moreover, the currently proposed pathway for colon butyrate production does not provide a conclusive quantitative link between bacterial (co)substrate metabolism and H₂ formation (11).This study investigated the kinetics of inulin-type fructan degradation by representatives of the genera Anaerostipes and Roseburia. A method based on online gas chromatography (GC) was developed to assess gas production qualitatively and quantitatively in a continuously sparged fermentation vessel for complete coverage of metabolite production. The competitiveness of inulin-degrading butyrate producers was investigated through coculture fermentations with Bifidobacterium longum subsp. longum LMG 11047, a strain representing a highly competitive cluster of bifidobacteria that share both high fructose consumption and oligofructose degradation rates and are able to perform partial breakdown of inulin (18, 20). A stoichiometrically balanced pathway for butyrate production, including H₂ production, is proposed.     

Anaerobic Biodegradation of n-Hexadecane by a Nitrate-Reducing Consortium

Nitrate-reducing enrichments, amended with n-hexadecane, were established with petroleum-contaminated sediment from Onondaga Lake. Cultures were serially diluted to yield a sediment-free consortium. Clone libraries and denaturing gradient gel electrophoresis analysis of 16S rRNA gene community PCR products indicated the presence of uncultured alpha- and betaproteobacteria similar to those detected in contaminated, denitrifying environments. Cultures were incubated with H₃₄-hexadecane, fully deuterated hexadecane (d₃₄-hexadecane), or H₃₄-hexadecane and NaH¹³CO₃. Gas chromatography-mass spectrometry analysis of silylated metabolites resulted in the identification of [H₂₉]pentadecanoic acid, [H₂₅]tridecanoic acid, [1-¹³C]pentadecanoic acid, [3-¹³C]heptadecanoic acid, [3-¹³C]10-methylheptadecanoic acid, and d₂₇-pentadecanoic, d₂₅-, and d₂₄-tridecanoic acids. The identification of these metabolites suggests a carbon addition at the C-3 position of hexadecane, with subsequent β-oxidation and transformation reactions (chain elongation and C-10 methylation) that predominantly produce fatty acids with odd numbers of carbons. Mineralization of [1-¹⁴C]hexadecane was demonstrated based on the recovery of ¹⁴CO₂ in active cultures.Linear alkanes account for a large component of crude and refined petroleum products and, therefore, are of environmental significance with respect to their fate and transport (38). The aerobic activation of alkanes is well documented and involves monooxygenase and dioxygenase enzymes in which not only is oxygen required as an electron acceptor but it also serves as a reactant in hydroxylation (2, 16, 17, 32, 34). Alkanes are also degraded under anoxic conditions via novel degradation strategies (34). To date, there are two known pathways of anaerobic n-alkane degradation: (i) alkane addition to fumarate, commonly referred to as fumarate addition, and (ii) a putative pathway, proposed by So et al. (25), involving carboxylation of the alkane. Fumarate addition proceeds via terminal or subterminal addition (C-2 position) of the alkane to the double bond of fumarate, resulting in the formation of an alkylsuccinate. The alkylsuccinate is further degraded via carbon skeleton rearrangement and β-oxidation (4, 6, 8, 12, 13, 21, 37). Alkane addition to fumarate has been documented for a denitrifying isolate (21, 37), sulfate-reducing consortia (4, 8, 12, 13), and five sulfate-reducing isolates (4, 6-8, 12). In addition to being demonstrated in these studies, fumarate addition in a sulfate-reducing enrichment growing on the alicyclic alkane 2-ethylcyclopentane has also been demonstrated (23). In contrast to fumarate addition, which has been shown for both sulfate-reducers and denitrifiers, the putative carboxylation of n-alkanes has been proposed only for the sulfate-reducing isolate strain Hxd3 (25) and for a sulfate-reducing consortium (4). Experiments using NaH¹³CO₃ demonstrated that bicarbonate serves as the source of inorganic carbon for the putative carboxylation reaction (25). Subterminal carboxylation of the alkane at the C-3 position is followed by elimination of the two terminal carbons, to yield a fatty acid that is one carbon shorter than the parent alkane (4, 25). The fatty acids are subject to β-oxidation, chain elongation, and/or C-10 methylation (25).In this study, we characterized an alkane-degrading, nitrate-reducing consortium and surveyed the metabolites of the consortium incubated with either unlabeled or labeled hexadecane in order to elucidate the pathway of n-alkane degradation. We present evidence of a pathway analogous to the proposed carboxylation pathway under nitrate-reducing conditions.     

Different Roles of DosS and DosT in the Hypoxic Adaptation of Mycobacteria

The DosS (DevS) and DosT histidine kinases form a two-component system together with the DosR (DevR) response regulator in Mycobacterium tuberculosis. DosS and DosT, which have high sequence similarity to each other over the length of their amino acid sequences, contain two GAF domains (GAF-A and GAF-B) in their N-terminal sensory domains. Complementation tests in conjunction with phylogenetic analysis showed that DevS of Mycobacterium smegmatis is more closely related to DosT than DosS. We also demonstrated in vivo that DosS and DosT of M. tuberculosis play a differential role in hypoxic adaptation. DosT responds to a decrease in oxygen tension more sensitively and strongly than DosS, which might be attributable to their different autooxidation rates. The different responsiveness of DosS and DosT to hypoxia is due to the difference in their GAF-A domains accommodating the hemes. Multiple alignment analysis of the GAF-A domains of mycobacterial DosS (DosT) homologs and subsequent site-directed mutagenesis revealed that just one substitution of E87, D90, H97, L118, or T169 of DosS with the corresponding residue of DosT is sufficient to convert DosS to DosT with regard to the responsiveness to changes in oxygen tension.Oxygen sensing is important for facultative anaerobes to adapt to changes in metabolic necessities during the transition between aerobic and anaerobic conditions. Although Mycobacterium tuberculosis (MTB) is an obligate aerobe, a gradual depletion of O₂ from its culture is known to lead to a drastic change in gene expression (8, 21, 24, 28, 34, 37, 39). Approximately 48 genes of M. tuberculosis were reported to be induced under early hypoxic conditions, which is mediated by the DosSR (DevSR) two-component system (16, 24, 34). The induction of the DosR regulon is important for survival of M. tuberculosis under hypoxic conditions and for it to enter the nonreplicating dormant state (2, 19). The DosSR two-component system consists of the DosS histidine kinase (HK) and its cognate DosR response regulator (RR) (24, 26, 29). The DosT HK, which shares high sequence similarity to DosS over the length of their primary structures, was also found to cross talk with DosR (26, 30). The N-terminal domains of DosS and DosT contain two tandem GAF domains (GAF-A and GAF-B from their N termini), and the three-dimensional structure of the GAF-A and GAF-B domains was determined (5, 25). A b-type heme is embedded in the GAF-A domain, composed of one five-stranded antiparallel β-sheet and four α-helices (5, 14, 25, 32). The heme is positioned nearly perpendicular to the β-sheet, and H149 and H147 of the polypeptides serve as the proximal axial ligands for DosS and DosT, respectively (5, 25). The ligand-binding state at the distal axial position of heme and the redox state of the heme iron modulate the autokinase activity of DosS and DosT. The O₂-bound (oxyferrous) and ferric forms of the HKs are inactive, whereas the unliganded ferrous (deoxyferrous) form as well as NO- and CO-bound forms are active (17, 36). The heme iron of DosT is stable against autooxidation of Fe²⁺ to Fe³⁺ in the presence of O₂, indicating that its conversion between deoxyferrous and oxyferrous forms is the mechanism by which DosT recognizes O₂ (17). However, the autooxidation property of oxyferrous DosS remains controversial. Kumar et al. (17) and Cho et al. (5) reported that DosS undergoes autooxidation on exposure to O₂, while other research groups demonstrated that the oxyferrous form of DosS is stable against autooxidation (13, 14, 36). Recently, different roles of DosS and DosT in O₂ sensing by M. tuberculosis were suggested. DosT plays a more important role in the early phase of hypoxic conditions than DosS when the growth of M. tuberculosis is transferred from aerobic to hypoxic conditions (11).Mycobacterium smegmatis possesses a single DevS HK that phosphorylates the DevR RR (20). The DevSR two-component system is also implemented in hypoxic adaptation of this bacterium (20). Like DosT of M. tuberculosis, the autokinase activity of M. smegmatis DevS was shown to be controlled by the ligand-binding state of its heme (18). Regarding the autooxidation property, DevS of M. smegmatis was suggested to be similar to DosT rather than DosS; i.e., the heme iron in DevS is resistant to autooxidation from an oxyferrous to a ferric state in the presence of O₂ (18).In this paper we report several lines of evidence for the functional difference between DosS and DosT in the hypoxic adaptation of mycobacteria and discuss the implications of these findings.     

Characterization of Hydrogen Peroxide-Induced DNA Release by Streptococcus sanguinis and Streptococcus gordonii

Extracellular DNA (eDNA) is produced by several bacterial species and appears to contribute to biofilm development and cell-cell adhesion. We present data showing that the oral commensals Streptococcus sanguinis and Streptococcus gordonii release DNA in a process induced by pyruvate oxidase-dependent production of hydrogen peroxide (H₂O₂). Surprisingly, S. sanguinis and S. gordonii cell integrity appears unaffected by conditions that cause autolysis in other eDNA-producing bacteria. Exogenous H₂O₂ causes release of DNA from S. sanguinis and S. gordonii but does not result in obvious lysis of cells. Under DNA-releasing conditions, cell walls appear functionally intact and ribosomes are retained over time. During DNA release, intracellular RNA and ATP are not coreleased. Hence, the release mechanism appears to be highly specific for DNA. Release of DNA without detectable autolysis is suggested to be an adaptation to the competitive oral biofilm environment, where autolysis could create open spaces for competitors to invade. Since eDNA promotes cell-to-cell adhesion, release appears to support oral biofilm formation and facilitates exchange of genetic material among competent strains.The release of bacterial DNA into the environment is of recent interest since this polymer is now recognized to stabilize cell-to-cell adherence and biofilm architecture (1, 35, 37). Treatment of extracellular DNA (eDNA) with DNase results in reduced intercellular stickiness, consistent with an adhesive function for eDNA. Furthermore, eDNA from Neisseria meningitis appears to have sufficient structural integrity to transform competent strains (11), indicating chromosomal origin. Since the abundance of eDNA is influenced by growth conditions, DNA release can also be regulated (40).DNA release is typically a consequence of cell lysis. Linked to DNA release, genetic transformation is the natural ability of competent bacterial species to take up DNA from the environment (13, 34, 42). During competence development, Streptococcus pneumoniae DNA is released by lysis of a subpopulation of cells (30, 42). Cell lysis and DNA release are controlled in a cell density-dependent signal transduction process. The S. pneumoniae comX regulon, carrying late competence genes, also includes the murein hydrolase genes lytA and cbpD (19, 42). Murein hydrolases digest structural components of the peptidoglycan, contributing to remodeling, recycling, and daughter cell separation. Furthermore, murein hydrolases trigger autolytic cell wall digestion, leading to release of DNA and other cellular content into the environment (36). The autolysis of bacterial cells as part of a regulated death program seems to be an important source for eDNA in diverse species, including Staphylococcus aureus (4, 36, 37), Staphylococcus epidermidis (35), Enterococcus faecalis (44), and Pseudomonas aeruginosa (1). In these species, the eDNA contributes to biofilm formation as a component of the extracellular biofilm matrix (35, 37, 44).Unlike for cell lysis-dependent release, the oral streptococci appear to induce eDNA release by a novel mechanism. In dual-species cultures, the oral commensals Streptococcus sanguinis and Streptococcus gordonii release eDNA in a manner dependent on pyruvate oxidase (Pox) generation of hydrogen peroxide (H₂O₂) under the control of ambient oxygen (23). In this report, we now provide direct evidence of selective H₂O₂-induced eDNA release by these oral commensal streptococci.     

Overexpression of Mitochondrial Leishmania major Ascorbate Peroxidase Enhances Tolerance to Oxidative Stress-Induced Programmed Cell Death and Protein Damage

Ascorbate peroxidase from Leishmania major (LmAPX) is one of the key enzymes for scavenging of reactive oxygen species generated from the mitochondrial respiratory chain. We have investigated whether mitochondrial LmAPX has any role in oxidative stress-induced apoptosis. The measurement of reduced glutathione (GSH) and protein carbonyl contents in cellular homogenates indicates that overexpression of LmAPX protects Leishmania cells against depletion of GSH and oxidative damage of proteins by H₂O₂ or camptothecin (CPT) treatment. Confocal microscopy and fluorescence spectroscopy data have revealed that the intracellular elevation of Ca²⁺ attained by the LmAPX-overexpressing cells was always below that attained in control cells. Flow cytometry assay data and confocal microscopy observation strongly suggest that LmAPX overexpression protects cells from H₂O₂-induced mitochondrial membrane depolarization as well as ATP decrease. Western blot data suggest that overexpression of LmAPX shields against H₂O₂- or CPT-induced cytochrome c and endonuclease G release from mitochondria and subsequently their accumulation in the cytoplasm. Caspase activity assay by flow cytometry shows a lower level of caspase-like protease activity in LmAPX-overexpressing cells under apoptotic stimuli. The data on phosphatidylserine exposed on the cell surface and DNA fragmentation results show that overexpression of LmAPX renders the Leishmania cells more resistant to apoptosis provoked by H₂O₂ or CPT treatment. Taken together, these results indicate that constitutive overexpression of LmAPX in the mitochondria of L. major prevents cells from the deleterious effects of oxidative stress, that is, mitochondrial dysfunction and cellular death.In multicellular organisms, mitochondria are the major physiological source of reactive oxygen species (ROS) within cells and also are important checkpoints for the control of programmed cell death (27). There are increasing numbers of reports that describe apoptosis- or programmed cell death-like processes in unicellular organisms also, such as trypanosomatids (4, 60), bacteria (20, 25), yeasts (34), and Plasmodium (3). Among the kinetoplastid parasites, Trypanosoma and Leishmania are the most carefully studied genera where apoptotic features are well established (49). Several reports have shown that mitochondrial dysfunction or an imbalance of antioxidant homeostasis causes an increase in mitochondrion-generated ROS, which include H₂O₂, superoxide radical anions, singlet oxygen, and hydroxyl radicals. These species have all been implicated in apoptosis (16, 26, 28, 41). Increasing evidence has been presented to support that ROS homeostasis regulates two major types of important physiological processes and exerts diverse functions within cells. One type of function includes damage or oxidation of cellular macromolecules (DNA, proteins, and lipids), which can lead to necrotic cell death or protein modification (7). The second type of function includes the activation of cellular signaling cascades that regulate proliferation, detoxification, DNA repair, or apoptosis (11). The detoxification of toxic mitochondrial ROS in cells occurs through a variety of cellular antioxidant enzymes, such as superoxide dismutase, which detoxifies cells from superoxide released into the mitochondrial matrix, and several other antioxidant proteins, such as catalase, glutathione (GSH) peroxidase, and peroxiredoxins, which are known to catalyze further degradation of H₂O₂ (44). During its life cycle, the Leishmania sp. encounters a pool of ROS that is generated either by its own physiological processes or as a result of host immune reaction and drug metabolism. However, unlike most eukaryotes, Leishmania lacks catalase- and selenium-containing GSH peroxidases, enzymes that play a front-line role in detoxifying ROS. Hence, the mechanism by which it resists the toxic effects of H₂O₂ remains poorly understood.Recently, we cloned, expressed and characterized the unusual heme-containing ascorbate peroxidase from Leishmania major (LmAPX) and observed that the expression of LmAPX is increased when Leishmania cells are treated with exogenous H₂O₂ (1, 18). This enzyme is a functional hybrid between cytochrome c peroxidase and APX, owing to its ability to use both ascorbate and cytochrome c as reducing electron donors (58). Colocalization studies by confocal microscopy, submitochondrial fractionation analysis of the isolated mitochondria, and subsequent Western blot analysis with anti-LmAPX antibody have confirmed that the mature enzyme is present in intermembrane space side of the inner membrane. It has also been shown that overexpression of LmAPX causes a decrease in the mitochondrial ROS burden, an increase in tolerance to H₂O₂, and protection against cardiolipin oxidation under oxidative stress (18). Although previous studies have shown that Leishmania species use superoxide dismutase (23), peroxiredoxins (8), intracellular thiols (14), lipophosphoglycan (13), trypanothione (5), HSP 70 (a heat shock protein) (36), tryparedoxin peroxidase (29), and APX (18) for detoxification of ROS, it is still unclear how the antioxidants protect against oxidative stress-induced apoptotic events in the unicellular organism Leishmania.Since the LmAPX protein is localized in the mitochondria, we hypothesized that it would be a key protein for the maintenance of mitochondrial functions due to its antioxidant properties via its ROS-scavenging function (18). To test this hypothesis, we overexpressed LmAPX in Leishmania major cells and investigated whether overexpression of LmAPX can confer resistance to oxidant-mediated mitochondrial damage as well as oxidative stress-induced cell death. In this study, we provide evidence that the overexpression of LmAPX in Leishmania cells can indeed protect against camptothecin (CPT) or H₂O₂-mediated mitochondrial damage as measured by various parameters, including disruption of mitochondrial membrane potential (Δψ_m), decrease of ATP production, and cytochrome c and endonuclease G release from mitochondria. Cells overexpressing LmAPX were also protected against oxidative stress-induced protein carbonylation, DNA fragmentation, and apoptosis. To the best of our knowledge, this is the first report of a mitochondrial hemeperoxidase that controls the ROS-induced mitochondrial death pathway.     

Discovery of [NiFe] Hydrogenase Genes in Metagenomic DNA: Cloning and Heterologous Expression in Thiocapsa roseopersicina

Using a metagenomics approach, we have cloned a piece of environmental DNA from the Sargasso Sea that encodes an [NiFe] hydrogenase showing 60% identity to the large subunit and 64% to the small subunit of a Thiocapsa roseopersicina O₂-tolerant [NiFe] hydrogenase. The DNA sequence of the hydrogenase identified by the metagenomic approach was subsequently found to be 99% identical to the hyaA and hyaB genes of an Alteromonas macleodii hydrogenase, indicating that it belongs to the Alteromonas clade. We were able to express our new Alteromonas hydrogenase in T. roseopersicina. Expression was accomplished by coexpressing only two accessory genes, hyaD and hupH, without the need to express any of the hyp accessory genes (hypABCDEF). These results suggest that the native accessory proteins in T. roseopersicina could substitute for the Alteromonas counterparts that are absent in the host to facilitate the assembly of a functional Alteromonas hydrogenase. To further compare the complex assembly machineries of these two [NiFe] hydrogenases, we performed complementation experiments by introducing the new Alteromonas hyaD gene into the T. roseopersicina hynD mutant. Interestingly, Alteromonas endopeptidase HyaD could complement T. roseopersicina HynD to cleave endoproteolytically the C-terminal end of the T. roseopersicina HynL hydrogenase large subunit and activate the enzyme. This study refines our knowledge on the selectivity and pleiotropy of the elements of the [NiFe] hydrogenase assembly machineries. It also provides a model for functionally analyzing novel enzymes from environmental microbes in a culture-independent manner.Hydrogen is a promising energy carrier for the future (10). Photosynthetic microbes such as cyanobacteria have attracted considerable attention, because they can split water photolytically to produce H₂. However, one major drawback of the processes is that their H₂-evolving hydrogenases are extremely sensitive to O₂, which is an inherent by-product of oxygenic photosynthesis. Thus, transfer of O₂-tolerant [NiFe] hydrogenases into cyanobacteria might be one approach to overcome this O₂ sensitivity issue. A small number of O₂-tolerant hydrogenases has been identified (9, 21, 47). However, they tend to favor H₂ uptake over evolution. Searching for novel O₂-tolerant [NiFe] hydrogenases from environmental microbes therefore becomes an important part of the effort to construct such biophotolytic systems.The oceans harbor an abundance of microorganisms with H₂ production capability. Traditionally, new hydrogenases have been screened only from culturable organisms. However, since only a few microbes can be cultured (14), many of them have not been identified, and their functions remain unknown. Metagenomics is a rapidly growing field, which allows us to obtain information about uncultured microbes and to understand the true diversity of microbes in their natural environments. Metagenomics analysis provides a completely new approach for identifying novel [NiFe] hydrogenases from the oceans in a culture-independent manner. The Global Ocean Sampling (GOS) expedition has produced the largest metagenomic data set to date, providing a rich catalog of proteins and protein families, including those enzymes involved in hydrogen metabolism (45, 52, 56-58). Putative novel [NiFe] hydrogenase enzymes that were identified from marine microbial metagenomic data in these expeditions can be examined to find potentially important new hydrogenases. Because source organisms for metagenomic sequences are not typically known, these hydrogenases have to be heterologously expressed in culturable foreign hosts for protein and functional analyses.Unlike most proteins, hydrogenases have a complex architecture and must be assembled and matured through a multiple-step process (7, 11). Hydrogenases are divided into three distinct groups based on their metal contents (54): Fe-S cluster-free hydrogenases (22, 23, 48), [FeFe] hydrogenases (1, 12, 25), and [NiFe] hydrogenases (2, 3, 55). [NiFe] hydrogenases are heterodimers composed of a large subunit and a small subunit, and their NiFe catalytic centers are located in the large subunits (2, 15, 19, 40). A whole set of accessory proteins are required to properly assemble the catalytic centers (7). The accessory protein HypE first interacts with HypF to form a HypF-HypE complex, and the carbamyl group linked to HypF is then dehydrated by HypE in the presence of ATP to release the CN group that is transferred to iron through a HypC-HypD-HypE complex (6). The origin of the CO ligand that is also bound to the iron is not clear, and possibly it comes from formate, formyl-tetrahydrofolate, or acetate. The liganded Fe atom is inserted into the immature large subunit, in which HypC proteins function as chaperones to facilitate the metal insertion (5, 34, 36). Ni is delivered to the catalytic center by the zinc-metalloenzyme HypA that interacts with HypB, a nickel-binding and GTP-hydrolyzing protein. The final step in the maturation process is endoproteolytic cleavage. Once the nickel is transferred to the active site, the endopeptidase, such as HyaD or HynD, cleaves the C-terminal end of the large subunit (33, 43), which triggers a conformational change of the protein so that the Ni-Fe catalytic center can be internalized.Heterologous expression of functional [NiFe] hydrogenases has been demonstrated in several studies (4, 18, 31, 39, 44, 50), suggesting that it could be a feasible approach to express novel hydrogenases from the environment for functional analysis. In this study, we sought to prove the concept that metagenomically derived environmental DNA can give rise to a functional [NiFe] hydrogenase through expression in a foreign host and that novel [NiFe] hydrogenases from environmental microbes can be studied in a culture-independent manner. We cloned environmental DNA that harbors the genes of a putative novel hydrogenase that shows strong homology to a known O₂-tolerant hydrogenase, HynSL, from the phototrophic purple sulfur bacterium Thiocapsa roseopersicina (21, 28, 41, 59). We heterologously expressed the two structural genes (hyaA and hyaB) and two accessory genes (hupH and hyaD) of this novel environmental hydrogenase in T. roseopersicina, a foreign host that may already have the necessary machinery required to process the environmental hydrogenase since it carries the homologous hydrogenase HynSL. We analyzed the new hydrogenase protein and its functions. In addition, we compared the maturation mechanisms between the two homolog hydrogenases by performing complementation experiments.     

Thiol Peroxidase Protects Salmonella enterica from Hydrogen Peroxide Stress In Vitro and Facilitates Intracellular Growth

At present, Salmonella is considered to express two peroxiredoxin-type peroxidases, TsaA and AhpC. Here we describe an additional peroxiredoxin, Tpx, in Salmonella enterica and show that a single tpx mutant is susceptible to exogenous hydrogen peroxide (H₂O₂), that it has a reduced capacity to degrade H₂O₂ compared to the ahpCF and tsaA mutants, and that its growth is affected in activated macrophages. These results suggest that Tpx contributes significantly to the sophisticated defense system that the pathogen has evolved to survive oxidative stress.Salmonella is an important human pathogen which causes a variety of diseases, including gastroenteritis, septicemia, and typhoid fever. In the host, salmonellae reside inside phagocytic cells and are exposed to various host defense mechanisms, including oxidative stress (13). The production of superoxide anion (O₂⁻) is crucial, as individuals with chronic granulomatous disease, which is due to a defective phagocyte NADPH oxidase, are more susceptible to infections with Salmonella (10). Likewise, diminished NADPH oxidase activity leads to increased susceptibility to Salmonella in murine macrophages (20-22, 25). Superoxide anion (O₂⁻) is weakly reactive and fails to pass through the bacterial cell wall. After conversion to H₂O₂ by either spontaneous or enzymatic dismutation by superoxide dismutases, it readily diffuses into the bacterial cell and forms reactive hydroxyl radicals (OH) that damage macromolecules such as DNA, proteins, and lipids (12, 17).In principle, Salmonella possesses two classes of enzymes to degrade H₂O₂. Catalases degrade H₂O₂ to water and molecular oxygen independent of an additional reductant. Peroxiredoxin-type peroxidases (peroxiredoxins) reduce organic hydroperoxides to alcohols and hydrogen peroxide to water at the expense of NADH or NADPH. In a recent study by Hébrard et al., three members of the catalase family, KatG, KatE, and KatN, and two members of the peroxiredoxin family, AhpC and TsaA, were characterized in Salmonella (14). Previously it had been shown that single katE, katG, and katN Salmonella mutants did not show increased susceptibility to exogenous H₂O₂ (3, 24). In macrophages a katG katE katN triple mutant had no growth defect, whereas an ahpCF tsaA double mutant showed a reduced growth rate in macrophages (14). These observations point out the multiple routes that have evolved in Salmonella to protect the pathogen against oxidative stress and suggest that peroxiredoxins play a dominant role in the antioxidant defense during infection. In this study we characterized a third peroxiredoxin-type peroxidase, Tpx. Surprisingly, a simple tpx mutant of Salmonella enterica serovar Typhimurium (S. Typhimurium) was more susceptible to exogenous H₂O₂ than the wild type (WT). The mutant grew less well in activated macrophages and showed a reduced peroxidase activity toward H₂O₂.     

A Role for DNA Polymerase μ in the Emerging DJH Rearrangements of the Postgastrulation Mouse Embryo

The molecular complexes involved in the nonhomologous end-joining process that resolves recombination-activating gene (RAG)-induced double-strand breaks and results in V(D)J gene rearrangements vary during mammalian ontogeny. In the mouse, the first immunoglobulin gene rearrangements emerge during midgestation periods, but their repertoires have not been analyzed in detail. We decided to study the postgastrulation DJ_H joints and compare them with those present in later life. The embryo DJ_H joints differed from those observed in perinatal life by the presence of short stretches of nontemplated (N) nucleotides. Whereas most adult N nucleotides are introduced by terminal deoxynucleotidyl transferase (TdT), the embryo N nucleotides were due to the activity of the homologous DNA polymerase μ (Polμ), which was widely expressed in the early ontogeny, as shown by analysis of Polμ^−/− embryos. Based on its DNA-dependent polymerization ability, which TdT lacks, Polμ also filled in small sequence gaps at the coding ends and contributed to the ligation of highly processed ends, frequently found in the embryo, by pairing to internal microhomology sites. These findings show that Polμ participates in the repair of early-embryo, RAG-induced double-strand breaks and subsequently may contribute to preserve the genomic stability and cellular homeostasis of lymphohematopoietic precursors during development.The adaptive immune system is characterized by the great diversity of its antigen receptors, which result from the activities of enzymatic complexes that cut and paste the genomic DNA of antigen receptor loci. The nonhomologous end-joining (NHEJ) machinery is then recruited to repair the double-strand DNA breaks (DSBs) inflicted by the products of the recombination-activating genes (RAGs) (45, 65). Within B cells, each immunoglobulin (Ig) receptor represents a singular shuffling of two heavy (H) and two light (L) chains, which are derived from the recombination of V, D, and J gene segments of the IgH locus and of V and J for IgL (71). Besides these combinatorial possibilities, most Ig variability derives from extensive processing of the coding ends, including exonucleolytic trimming of DNA ends, together with the addition of palindromic (P) nucleotides templated by the adjacent germ line sequence and of nontemplated (N) nucleotides secondary to the activity of the terminal deoxynucleotidyl transferase (TdT), a lymphoid-specific member of family X of DNA polymerases (reviewed in reference 56). During B-lineage differentiation, IgH rearrangements occur before those of the IgL locus, and D-to-J_H rearrangements precede V-to-DJ_H rearrangements (62). DJ_H joints are formed in any of the three open reading frames (ORFs). ORF1 is predominantly used in mature Igs, ORF2 is transcribed as a Dμ protein that provides negative signals to the B-cell precursors, and ORF3 frequently leads to stop codons (32, 33, 37). Germ line V, D, and J gene segments display short stretches of mutually homologous nucleotides (SSH), which are frequently used in gene rearrangements during perinatal periods, when N additions are absent (27, 32, 55, 57). The actual Ig V-region repertoires represent both the results of the NHEJ process associated with genomic VDJ recombination and those of antigen-independent and -dependent selection events. Although the core NHEJ components (Ku-Artemis-DNA-PK and XLF-XRCC4-DNA ligase IV) are by themselves able to join RAG-induced, incompatible DNA ends, family X DNA polymerases can be recruited to fill gaps created by imprecise coding ends with 3′ overhangs (DNA polymerase μ [Polμ] and Polλ) and/or to promote diversity through the addition of N nucleotides (TdT) (34, 56).The lymphoid differentiation pathways and clonotypic repertoires are developmentally regulated and differ between the embryo-fetal and adult periods (2, 44, 68). The perinatal B cells result from a wave of B lymphopoiesis occurring during the last third of mouse gestation (13, 14, 21, 70). Perinatal V_H gene usage differs from that predominating in the adult (1, 69), and the former VDJ joints rarely display N additions, leading to V-region repertoires enriched in multi- and self-reactive specificities (36, 40). The program of B-cell differentiation starts at embryonic days 10 to 11 (E10 to E11) in embryo hematopoietic sites, after the emergence of multipotent progenitors (at E8.5 to E9.5) (18, 19, 23, 31, 51, 73). DJ_H rearrangements were detected in these early embryos, whereas full VDJ_H sequences were not observed before E14 (14, 18, 51, 66), when VJκ rearrangements were also found (63). The earliest mouse DJ_H/VDJ_H Ig sequences analyzed to date corresponded to late fetuses (E16) (14, 53). We reasoned that the true baseline of the Ig rearrangement process occurs in midgestation embryos, when the first DJ_Hs are not yet transcribed and, consequently, not subjected to selection and are conditioned only for the evolutionarily established and developmentally regulated usage of distinct NHEJ machineries.We report here the sequence profiles of the earliest embryo E10 to E12 DJ_H joints. Unexpected frequencies of embryonic DJ_H joints bearing N nucleotides, in the absence of detectable TdT expression, were found. Moreover, the embryo DJ_H joints lacking N nucleotides (N⁻) used fewer SSH to recombine than newborn DJ_Hs, and these SSH were widely dispersed along the embryo D sequences, in contrast to the most joint-proximal ones, which predominated in newborn DJ_Hs. Considering that Polμ is the closest relative of TdT (42% amino acid identity) (22), which is able to introduce N nucleotides in vitro (4, 22, 34, 39, 49) and to join DNA ends with minimal or even null complementarity (17, 58), and that it is expressed in early-embryo organs, we decided to investigate its putative contribution to the first embryo DJ_H joints. The DJ_H joints obtained from Polμ^−/− embryos (48) showed a significant reduction of N nucleotides compared to wild-type (WT) embryos. Moreover, highly preserved DJ_H joints (with <3 deleted nucleotides) were selectively depleted in the Polμ^−/− mouse embryos, while the remaining DJ_Hs preferentially relied upon longer stretches of homology for end ligation. These findings support the idea that Polμ is active during early-embryo DJ_H rearrangements and that both its template-dependent and -independent ambivalent functions may be used to fill in small nucleotide gaps generated after asymmetric hairpin nicking and also to extend coding ends via a limited TdT-like activity.     

Identification of a Novel Class of Membrane-Bound [NiFe]-Hydrogenases in Thermococcus onnurineus NA1 by In Silico Analysis

In silico analysis of group 4 [NiFe]-hydrogenases from a hyperthermophilic archaeon, Thermococcus onnurineus NA1, revealed a novel tripartite gene cluster consisting of dehydrogenase-hydrogenase-cation/proton antiporter subunits, which may be classified as the new subgroup 4b of [NiFe]-hydrogenases-based on sequence motifs.Hydrogenases are the key enzymes involved in the metabolism of H₂, catalyzing the following chemical reaction: 2H⁺ + 2e⁻ ↔ H₂. Hydrogenases can be classified into [NiFe]-hydrogenases, [FeFe]-hydrogenases, and [Fe]-hydrogenases, based on their distinctive functional core containing the catalytic metal center (11, 17).The genomic analysis of Thermococcus onnurineus NA1, a hyperthermophilic archaeon isolated from a deep-sea hydrothermal vent area, revealed the presence of several distinct gene clusters encoding seven [NiFe]-hydrogenases and one homolog similar to Mbx (membrane-bound oxidoreductase) from Pyrococcus furiosus (1, 6, 8, 12). According to the classification system of hydrogenases by Vignais et al. (17), three hydrogenases (one F₄₂₀-reducing and two NADP-reducing hydrogenases) belong to group 3 [NiFe]-hydrogenases, and four hydrogenases belong to group 4 [NiFe]-hydrogenases. The group 4 hydrogenases are widely distributed among bacteria and archaea (17), with Hyc and Hyf (hydrogenase 3 and 4, respectively) from Escherichia coli (19), Coo (CO-induced hydrogenase) from Rhodospirillum rubrum (4), Ech (energy-converting hydrogenase) from Methanosarcina barkeri (7), and Mbh (membrane-bound hydrogenase) from P. furiosus (6, 10, 12) being relatively well-characterized hydrogenases in this group. One of the four group 4 hydrogenases from T. onnurineus NA1 was found to be similar in sequence to that of P. furiosus Mbh (10).