Validating annotations for uncharacterized proteins in Shewanella oneidensis

Proteins of unknown function are a barrier to our understanding of molecular biology. Assigning function to these "uncharacterized" proteins is imperative, but challenging. The usual approach is similarity searches using annotation databases, which are useful for predicting function. However, since the performance of these databases on uncharacterized proteins is basically unknown, the accuracy of their predictions is suspect, making annotation difficult. To address this challenge, we developed a benchmark annotation dataset of 30 proteins in Shewanella oneidensis. The proteins in the dataset were originally uncharacterized after the initial annotation of the S. oneidensis proteome in 2002. In the intervening 5 years, the accumulation of new experimental evidence has enabled specific functions to be predicted. We utilized this benchmark dataset to evaluate several commonly utilized annotation databases. According to our criteria, six annotation databases accurately predicted functions for at least 60% of proteins in our dataset. Two of these six even had a "conditional accuracy" of 90%. Conditional accuracy is another evaluation metric we developed which excludes results from databases where no function was predicted. Also, 27 of the 30 proteins' functions were correctly predicted by at least one database. These represent one of the first performance evaluations of annotation databases on uncharacterized proteins. Our evaluation indicates that these databases readily incorporate new information and are accurate in predicting functions for uncharacterized proteins, provided that experimental function evidence exists.     

The Plant Mitochondrial TAT Pathway Is Essential for Complex III Biogenesis

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The Glutathione Biosynthetic Pathway of Plasmodium Is Essential for Mosquito Transmission

Infection of red blood cells (RBC) subjects the malaria parasite to oxidative stress. Therefore, efficient antioxidant and redox systems are required to prevent damage by reactive oxygen species. Plasmodium spp. have thioredoxin and glutathione (GSH) systems that are thought to play a major role as antioxidants during blood stage infection. In this report, we analyzed a critical component of the GSH biosynthesis pathway using reverse genetics. Plasmodium berghei parasites lacking expression of gamma-glutamylcysteine synthetase (γ-GCS), the rate limiting enzyme in de novo synthesis of GSH, were generated through targeted gene disruption thus demonstrating, quite unexpectedly, that γ-GCS is not essential for blood stage development. Despite a significant reduction in GSH levels, blood stage forms of pbggcs⁻ parasites showed only a defect in growth as compared to wild type. In contrast, a dramatic effect on development of the parasites in the mosquito was observed. Infection of mosquitoes with pbggcs⁻ parasites resulted in reduced numbers of stunted oocysts that did not produce sporozoites. These results have important implications for the design of drugs aiming at interfering with the GSH redox-system in blood stages and demonstrate that de novo synthesis of GSH is pivotal for development of Plasmodium in the mosquito.     

The Endo-siRNA Pathway Is Essential for Robust Development of the Drosophila Embryo

Background

Robustness to natural temperature fluctuations is critical to proper development in embryos and to cellular functions in adult organisms. However, mechanisms and pathways which govern temperature compensation remain largely unknown beyond circadian rhythms. Pathways which ensure robustness against temperature fluctuations may appear to be nonessential under favorable, uniform environmental conditions used in conventional laboratory experiments where there is little variation for which to compensate. The endo-siRNA pathway, which produces small double-stranded RNAs in Drosophila, appears to be nonessential for robust development of the embryo under ambient uniform temperature and to be necessary only for viral defense. Embryos lacking a functional endo-siRNA pathway develop into phenotypically normal adults. However, we hypothesized that small RNAs may regulate the embryo''s response to temperature, as a ribonucleoprotein complex has been previously shown to mediate mammalian cell response to heat shock.

Principal Findings

Here, we show that the genes DICER-2 and ARGONAUTE2, which code for integral protein components of the endo-siRNA pathway, are essential for robust development and temperature compensation in the Drosophila embryo when exposed to temperature perturbations. The regulatory functions of DICER-2 and ARGONAUTE2 were uncovered by using microfluidics to expose developing Drosophila embryos to a temperature step, in which each half of the embryo develops at a different temperature through developmental cycle 14. Under this temperature perturbation, dicer-2 or argonaute2 embryos displayed abnormal segmentation. The abnormalities in segmentation are presumably due to the inability of the embryo to compensate for temperature-induced differences in rate of development and to coordinate developmental timing in the anterior and posterior halves. A deregulation of the length of nuclear division cycles 10–14 is also observed in dicer-2 embryos at high temperatures.

Conclusions

Results presented herein uncover a novel function of the endo-siRNA pathway in temperature compensation and cell cycle regulation, and we hypothesize that the endo-siRNA pathway may regulate the degradation of maternal cell cycle regulators. Endo-siRNAs may have a more general role buffering against environmental perturbations in other organisms.     

The octahaem SirA catalyses dissimilatory sulfite reduction in Shewanella oneidensis MR-1

Shewanella oneidensis MR-1 is a metal reducer that uses a large number of electron acceptors including thiosulfate, polysulfide and sulfite. The enzyme required for thiosulfate and polysulfide respiration has been recently identified, but the mechanisms of sulfite reduction remained unexplored. Analysis of MR-1 cultures grown anaerobically with sulfite suggested that the dissimilatory sulfite reductase catalyses six-electron reduction of sulfite to sulfide. Reduction of sulfite required menaquinones but was independent of the intermediate electron carrier CymA. Furthermore, the terminal sulfite reductase, SirA, was identified as an octahaem c cytochrome with an atypical haem binding site. The sulfite reductase of S. oneidensis MR-1 does not appear to be a sirohaem enzyme, but represents a new class of sulfite reductases. The gene that encodes SirA is located within a 10-gene locus that is predicted to encode a component of a specialized haem lyase, a menaquinone oxidase and copper transport proteins. This locus was identified in the genomes of several Shewanella species and appears to be linked to the ability of these organisms to reduce sulfite under anaerobic conditions.     

The influence of cultivation methods on Shewanella oneidensis physiology and proteome expression

High-throughput analyses that are central to microbial systems biology and ecophysiology research benefit from highly homogeneous and physiologically well-defined cell cultures. While attention has focused on the technical variation associated with high-throughput technologies, biological variation introduced as a function of cell cultivation methods has been largely overlooked. This study evaluated the impact of cultivation methods, controlled batch or continuous culture in bioreactors versus shake flasks, on the reproducibility of global proteome measurements in Shewanella oneidensis MR-1. Variability in dissolved oxygen concentration and consumption rate, metabolite profiles, and proteome was greater in shake flask than controlled batch or chemostat cultures. Proteins indicative of suboxic and anaerobic growth (e.g., fumarate reductase and decaheme c-type cytochromes) were more abundant in cells from shake flasks compared to bioreactor cultures, a finding consistent with data demonstrating that “aerobic” flask cultures were O₂ deficient due to poor mass transfer kinetics. The work described herein establishes the necessity of controlled cultivation for ensuring highly reproducible and homogenous microbial cultures. By decreasing cell to cell variability, higher quality samples will allow for the interpretive accuracy necessary for drawing conclusions relevant to microbial systems biology research.     

Genetic and molecular characterization of flagellar assembly in Shewanella oneidensis

Shewanella oneidensis is a highly motile organism by virtue of a polar flagellum. Unlike most flagellated bacteria, it contains only one major chromosome segment encoding the components of the flagellum with the exception of the motor proteins. In this region, three genes encode flagellinsaccording to the original genome annotation. However, we find that only flaA and flaB encode functional filament subunits. Although these two genesare under the control of different promoters, they are actively transcribed and subsequently translated, producing a considerable number of flagellin proteins. Additionally, both flagellins are able to interact with their chaperon FliS and are subjected to feedback regulation. Furthermore, FlaA and FlaB are glycosylated by a pathwayinvolving a major glycosylating enzyme,PseB, in spite of the lack of the majority of theconsensus glycosylation sites. In conclusion, flagellar assembly in S. oneidensis has novel features despite the conservation of homologous genes across taxa.     

Secretion of Flavins by Shewanella Species and Their Role in Extracellular Electron Transfer

Fe(III)-respiring bacteria such as Shewanella species play an important role in the global cycle of iron, manganese, and trace metals and are useful for many biotechnological applications, including microbial fuel cells and the bioremediation of waters and sediments contaminated with organics, metals, and radionuclides. Several alternative electron transfer pathways have been postulated for the reduction of insoluble extracellular subsurface minerals, such as Fe(III) oxides, by Shewanella species. One such potential mechanism involves the secretion of an electron shuttle. Here we identify for the first time flavin mononucleotide (FMN) and riboflavin as the extracellular electron shuttles produced by a range of Shewanella species. FMN secretion was strongly correlated with growth and exceeded riboflavin secretion, which was not exclusively growth associated but was maximal in the stationary phase of batch cultures. Flavin adenine dinucleotide was the predominant intracellular flavin but was not released by live cells. The flavin yields were similar under both aerobic and anaerobic conditions, with total flavin concentrations of 2.9 and 2.1 μmol per gram of cellular protein, respectively, after 24 h and were similar under dissimilatory Fe(III)-reducing conditions and when fumarate was supplied as the sole electron acceptor. The flavins were shown to act as electron shuttles and to promote anoxic growth coupled to the accelerated reduction of poorly crystalline Fe(III) oxides. The implications of flavin secretion by Shewanella cells living at redox boundaries, where these mineral phases can be significant electron acceptors for growth, are discussed.     

An Atypical Riboflavin Pathway Is Essential for Brucella abortus Virulence

Brucellosis is a worldwide zoonosis that affects livestock and humans and is caused by closely related Brucella spp., which are adapted to intracellular life within cells of a large variety of mammals. Brucella can be considered a furtive pathogen that infects professional and non-professional phagocytes. In these cells Brucella survives in a replicative niche, which is characterized for having a very low oxygen tension and being deprived from nutrients such as amino acids and vitamins. Among these vitamins, we have focused on riboflavin (vitamin B2). Flavin metabolism has been barely implicated in bacterial virulence. We have recently described that Brucella and other Rhizobiales bear an atypical riboflavin metabolic pathway. In the present work we analyze the role of the flavin metabolism on Brucella virulence. Mutants on the two lumazine synthases (LS) isoenzymes RibH1 and RibH2 and a double RibH mutant were generated. These mutants and different complemented strains were tested for viability and virulence in cells and in mice. In this fashion we have established that at least one LS must be present for B. abortus survival and that RibH2 and not RibH1 is essential for intracellular survival due to its LS activity in vivo. In summary, we show that riboflavin biosynthesis is essential for Brucella survival inside cells or in mice. These results highlight the potential use of flavin biosynthetic pathway enzymes as targets for the chemotherapy of brucellosis.     

Aerated Shewanella oneidensis in continuously fed bioelectrochemical systems for power and hydrogen production

We studied the effects of aeration of Shewanella oneidensis on potentiostatic current production, hydrogen production in a microbial electrolysis cell, and electric power generation in a microbial fuel cell (MFC). The potentiostatic performance of aerated S. oneidensis was considerably enhanced to a maximum current density of 0.45 A/m² or 80.3 A/m³ (mean: 0.34 A/m², 57.2 A/m³) compared to anaerobically grown cultures. Biocatalyzed hydrogen production rates with aerated S. oneidensis were studied within the applied potential range of 0.3–0.9 V and were highest at 0.9 V with 0.3 m³ H₂/m³ day, which has been reported for mixed cultures, but is ～10 times higher than reported for an anaerobic culture of S. oneidensis. Aerated MFC experiments produced a maximum power density of 3.56 W/m³ at a 200‐Ω external resistor. The main reasons for enhanced electrochemical performance are higher levels of active biomass and more efficient substrate utilization under aerobic conditions. Coulombic efficiencies, however, were greatly reduced due to losses of reducing equivalents to aerobic respiration in the anode chamber. The next challenge will be to optimize the aeration rate of the bacterial culture to balance between maximization of bacterial activation and minimization of aerobic respiration in the culture. Biotechnol. Bioeng. 2010;105: 880–888. © 2009 Wiley Periodicals, Inc.     

MotX and MotY Are Required for Flagellar Rotation in Shewanella oneidensis MR-1

The single polar flagellum of Shewanella oneidensis MR-1 is powered by two different stator complexes, the sodium-dependent PomAB and the proton-driven MotAB. In addition, Shewanella harbors two genes with homology to motX and motY of Vibrio species. In Vibrio, the products of these genes are crucial for sodium-dependent flagellar rotation. Resequencing of S. oneidensis MR-1 motY revealed that the gene does not harbor an authentic frameshift as was originally reported. Mutational analysis demonstrated that both MotX and MotY are critical for flagellar rotation of S. oneidensis MR-1 for both sodium- and proton-dependent stator systems but do not affect assembly of the flagellar filament. Fluorescence tagging of MotX and MotY to mCherry revealed that both proteins localize to the flagellated cell pole depending on the presence of the basal flagellar structure. Functional localization of MotX requires MotY, whereas MotY localizes independently of MotX. In contrast to the case in Vibrio, neither protein is crucial for the recruitment of the PomAB or MotAB stator complexes to the flagellated cell pole, nor do they play a major role in the stator selection process. Thus, MotX and MotY are not exclusive features of sodium-dependent flagellar systems. Furthermore, MotX and MotY in Shewanella, and possibly also in other genera, must have functions beyond the recruitment of the stator complexes.Flagellum-mediated swimming motility is a widespread means of locomotion among bacteria. Flagella consist of protein filaments that are rotated at the filament''s base by a membrane-embedded motor (3, 39). Rotation is powered by electrochemical gradients across the cytoplasmic membrane. Thus far, two coupling ions, sodium ions and protons, have been described as energy sources for bacterial flagellar motors (4, 24, 48). Two major components confer the conversion of the ion flux into rotary motion. The first component forms a rotor-mounted ring-like structure at the base of the flagellar basal body and is referred to as the switch complex or the C ring; it is composed of the proteins FliG, FliM, and FliN. The second major component is the stator system, consisting of membrane-embedded stator complexes that surround the C ring (3). Each stator complex is composed of two subunits in a 4:2 stoichiometry. In Escherichia coli, MotA and MotB constitute the stator complex by forming a proton-specific ion channel; the Na⁺-dependent counterpart in Vibrio species consists of the orthologs PomA and PomB (1, 5, 49). MotA and PomA both have four transmembrane domains and are thought to interact with FliG via a cytoplasmic segment to generate torque (2, 50). Stator function is presumably made possible by a peptidoglycan-binding motif located at the C-terminal portion of MotB and PomB that anchors the stator complex to the cell wall (1, 8). In E. coli, at least 11 stator complexes can be synchronously involved in driving flagellar rotation (35). However, a single complex is sufficient for rotation of the filament (36, 40). Despite its tight attachment to the peptidoglycan, the stator ring system was found to form a surprisingly dynamic complex. It has been suggested that inactive precomplexes of the stators form a membrane-located pool before being activated upon incorporation into the stator ring system around the motor (13, 45). In E. coli, the turnover time of stator complexes can be as short as 30 s (21).In Vibrio species, two auxiliary proteins, designated MotX and MotY, are required for motor function of the Na⁺-driven polar flagellar system (22, 23, 28, 31). Recently, it was shown that the proteins associate with the flagellar basal body in Vibrio alginolyticus to form an additional structure, the T ring (42). MotX interacts with MotY and the PomAB stator complexes, and both proteins are thought to be crucial for the acquisition of the stators to the motor of the polar flagellum. (29, 30, 42). A MotY homolog is also associated with the proton-dependent motor system of the lateral flagella of V. alginolyticus that is induced under conditions of elevated viscosity (41).We recently showed that Shewanella oneidensis MR-1 uses two different stator systems to drive the rotation of its single polar flagellum, the Na⁺-dependent PomAB stator and the proton-driven MotAB stator. As suggested by genetic data, the MotAB stator has been acquired by lateral gene transfer, presumably in the process of adaptation from a marine to a freshwater environment (32). The two different stators are recruited to the motor in a way that depends on the sodium ion concentration in the medium. The Na⁺-dependent PomAB stator is present at the flagellated cell pole regardless of the sodium ion concentration, whereas the proton-dependent MotAB stator functionally localizes only under conditions of low sodium or in the absence of PomAB. It is still unclear how stator selection is achieved and whether additional proteins play a role in this process.Orthologs of motX and motY have been annotated in S. oneidensis MR-1. We thus hypothesized that MotX and MotY might play a role in stator selection in S. oneidensis MR-1. However, the originally published sequence of motY harbors a frameshift that would result in a drastically truncated protein lacking a functionally relevant putative peptidoglycan-binding domain at its C terminus (16, 18). This situation seemed inconsistent with a role for MotY in S. oneidensis MR-1.Here we describe a functional analysis of the MotX and MotY orthologs in S. oneidensis MR-1. We found that motY does not, in fact, contain a frameshift mutation, so that MotY is translated in its full-length form. Both MotX and MotY were essential for Na⁺-dependent and proton-dependent motility. Therefore, these proteins have a role in S. oneidensis MR-1 that differs from their function in Vibrio species. We also used fusions to the fluorescent protein mCherry for functional localization studies of MotX and MotY.     

Kinetic Characterization of OmcA and MtrC,Terminal Reductases Involved in Respiratory Electron Transfer for Dissimilatory Iron Reduction in Shewanella oneidensis MR-1

We have used scaling kinetics and the concept of kinetic competence to elucidate the role of hemeproteins OmcA and MtrC in iron reduction by Shewanella oneidensis MR-1. Second-order rate constants for OmcA and MtrC were determined by single-turnover experiments. For soluble iron species, a stopped-flow apparatus was used, and for the less reactive iron oxide goethite, a conventional spectrophotometer was used to measure rates. Steady-state experiments were performed to obtain molecular rate constants by quantifying the OmcA and MtrC contents of membrane fractions and whole cells by Western blot analysis. For reduction of soluble iron, rates determined from transient-state experiments were able to account for rates obtained from steady-state experiments. However, this was not true with goethite; rate constants determined from transient-state experiments were 100 to 1,000 times slower than those calculated from steady-state experiments with membrane fractions and whole cells. In contrast, addition of flavins to the goethite experiments resulted in rates that were consistent with both transient- and steady-state experiments. Kinetic simulations of steady-state results with kinetic constants obtained from transient-state experiments supported flavin involvement. Therefore, we show for the first time that OmcA and MtrC are kinetically competent to account for catalysis of soluble iron reduction in whole Shewanella cells but are not responsible for electron transfer via direct contact alone with insoluble iron-containing minerals. This work supports the hypothesis that electron shuttles are important participants in the reduction of solid Fe phases by this organism.Microbial processes play a central role in the cycling of organic and inorganic compounds on Earth. A select number of these compounds are assimilated by organisms and used as building material for the cell. In addition, a large number of organic and inorganic compounds are used as electron donors and acceptors for respiratory metabolism. Iron, one of the most abundant elements in the Earth''s crust, is both assimilated by life and utilized as an electron donor (Fe²⁺) and acceptor (Fe³⁺) in respiratory metabolism. Due to the importance of iron, microorganisms directly impact the fate and transport of iron, and these Fe impacts indirectly influence the (bio)geochemical cycles of many other elements, including the carbon cycle (38). Furthermore, respiratory metabolism evolved in microorganisms prior to the emergence of oxygenic photosynthesis and was very versatile in using a large number of both organic and inorganic terminal electron acceptors (TEAs) (29). Therefore, the use of iron as a TEA predates the use of molecular oxygen among organisms on Earth. When metals are used as the TEA, this process is referred to as dissimilatory metal reduction (DMR) or, in the case of iron, dissimilatory iron reduction (DIR). Interest in microbial DMR has intensified upon discovery of the ability of DMR bacteria to catalyze reactions of environmentally relevant contaminants, including radionuclides such as U(VI) (1, 19, 20, 24, 30, 45, 47).DMR has been extensively studied in the facultative anaerobe Shewanella oneidensis MR-1 due to its respiratory versatility (for a review, see references 22, 23, 39, and 49). This bacterium also has the ability to utilize soluble and insoluble forms of iron and manganese as TEAs (12, 17, 25, 29, 33, 36). Genetic and biochemical studies show that reduction of the soluble TEAs occurs at the cytoplasmic membrane (CM), the location of the proton motive force-generating electron transport. However, in utilization of insoluble oxides, CM-localized electrons need to traverse the periplasm and the outer membrane (OM) to reach the extracellular matrix. Three mechanisms of transfer of OM-localized electrons to metal oxides have been hypothesized: (i) electron transfer through direct contact with the metal oxide, (ii) cyclic reduction/oxidation of electron shuttles, and (iii) solubilization of the metals with chelators, followed by diffusion to and across the OM to the CM. For a review of the proposed mechanisms, see reference 15.While there are very few reports of bacteria producing chelators for DIR (51), there are more data to support the other two mechanisms. For example, using atomic force microscopy (AFM), Lower et al. (26) measured binding between both OM hemeproteins OmcA and MtrC and the iron oxide hematite and reported that OmcA shows a greater affinity toward hematite than does MtrC. These workers suggested that this tight binding is a prerequisite for direct electron transfer. Xiong et al. (55) also showed tight binding between OmcA and hematite by using dynamic light scattering and fluorescence correlation spectroscopy. Previous work in our laboratory (43, 44) demonstrating the rates of metal oxide reduction by membrane fractions from Shewanella also supported a direct-contact mechanism. Direct contact between cellular components and iron oxides is also consistent with the nanowire mechanism proposed by Gorby et al. (14).In support of the electron shuttle hypothesis, two laboratories independently showed that S. oneidensis produces extracellular flavins, which may act as electron-shuttling agents (31, 52). The involvement of flavins as an electron shuttle would explain previous reports that Shewanella secretes a small, quinone-like compound involved in electron transfer (41) and can utilize sterically sequestered iron located in alginate beads (18).While the previous studies described above provide compelling evidence for their respective mechanisms, none of the mechanisms have been subjected to detailed kinetic analysis. Kinetic studies, while not able to prove a mechanism, can be used to eliminate proposed mechanisms if rates of a reaction measured with purified enzymes, as determined in vitro, cannot account for the rates observed in whole cells. We previously described the importance of kinetic studies and how to apply these kinetic studies to DIR (6, 43, 44). Briefly, rate constants are determined by in vitro studies with purified enzymes. The kinetics of the enzyme of interest is then studied in the whole cell (or in subcellular fractions). The rate constants are then compared between these systems to determine whether the rate of the reactions catalyzed by the enzyme can account for the rates observed in the cell.In our previous work, we performed kinetic studies on membrane fractions of S. oneidensis (43, 44). In the present study, this kinetic characterization is extended to purified enzymes and with whole cells for the purpose of determining kinetic competence. While our major focus is on the reduction of insoluble iron forms, for comparative purposes and as a control to validate our studies with the insoluble oxides, our study also includes a kinetic analysis of soluble chelated iron forms. We have focused our kinetic studies on two OM-localized hemeproteins, OmcA and MtrC. Previous genetic knockout studies show the importance of these enzymes in metal oxide reduction as potential terminal metal reductases (2, 35, 37). We describe both transient- and steady-state kinetic analyses. While both hemeproteins have been studied by stopped-flow analysis (48, 53) and by steady-state methods in whole cells (4), no study has yet attempted to infer mechanisms from scale-up kinetic studies (where kinetic constants from transient-state experiments are compared with those obtained from steady-state experiments). Our studies were thus performed at three different kinetic scales: (i) transient-state iron reduction using purified OmcA and MtrC, (ii) steady-state kinetics with purified total membrane (TM) fractions, and (iii) steady-state whole-cell kinetics.     

The Small Interfering RNA Pathway Is Not Essential for Wolbachia-Mediated Antiviral Protection in Drosophila melanogaster

Wolbachia pipientis delays RNA virus-induced mortality in Drosophila spp. We investigated whether Wolbachia-mediated protection was dependent on the small interfering RNA (siRNA) pathway, a key antiviral defense. Compared to Wolbachia-free flies, virus-induced mortality was delayed in Wolbachia-infected flies with loss-of-function of siRNA pathway components, indicating that Wolbachia-mediated protection functions in the absence of the canonical siRNA pathway.     

Hydrogen sulfide-producing kinetics of Shewanella oneidensis in sulfite and thiosulfate respiration

Shewanella oneidensis is a model species for aquatic ecosystems and plays an important role in bioremediation, biofuel cell manufacturing and biogeochemical cycling. S. oneidensis MR-1 is able to generate hydrogen sulfide from various sulfur species; however, its catalytic kinetics have not been determined. In this study, five in-frame deletion mutants of S. oneidensis were constructed and their H₂S-producing activities were analyzed. SirA and PsrA were the two major contributors to H₂S generation under anoxic cultivation, and the optimum SO₃²⁻ concentration for sulfite respiration was approximately 0.8 mM, while the optimum S₂O₃²⁻ concentration for thiosulfate respiration was approximately 0.4 mM. Sulfite and thiosulfate were observed to interfere with each other during respiration, and a high concentration of sulfite or thiosulfate chelated extracellular free-iron but did not repress the expression of sirA or psrA. Nitrite and nitrate were two preferred electron acceptors during anaerobic respiration; however, under energy-insufficient conditions, S. oneidensis could utilize multiple electron acceptors simultaneously. Elucidiating the stoichiometry of H₂S production in S. oneidensis would be helpful for the application of this species in bioremediation and biofuel cell manufacturing, and would help to characterize the ecophysiology of sulfur cycling.     

The tetraheme cytochrome CymA is required for anaerobic respiration with dimethyl sulfoxide and nitrite in Shewanella oneidensis

The tetraheme c-type cytochrome, CymA, from Shewanella oneidensis MR-1 has previously been shown to be required for respiration with Fe(III), nitrate, and fumarate [Myers, C. R., and Myers, J. M. (1997) J. Bacteriol. 179, 1143-1152]. It is located in the cytoplasmic membrane where the bulk of the protein is exposed to the periplasm, enabling it to transfer electrons to a series of redox partners. We have expressed and purified a soluble derivative of CymA (CymA(sol)) that lacks the N-terminal membrane anchor. We show here, by direct measurements of electron transfer between the purified proteins, that CymA(sol) efficiently reduces S. oneidensis fumarate reductase. This indicates that no further proteins are required for electron transfer between the quinone pool and fumarate if we assume direct reduction of CymA by quinols. By expressing CymA(sol) in a mutant lacking CymA, we have shown that this soluble form of the protein can complement the defect in fumarate respiration. We also demonstrate that CymA is essential for growth with DMSO (dimethyl sulfoxide) and for reduction of nitrite, implicating CymA in at least five different electron transfer pathways in Shewanella.     

Analyses of Current-Generating Mechanisms of Shewanella loihica PV-4 and Shewanella oneidensis MR-1 in Microbial Fuel Cells

Although members of the genus Shewanella have common features (e.g., the presence of decaheme c-type cytochromes [c-cyts]), they are widely variable in genetic and physiological features. The present study compared the current-generating ability of S. loihica PV-4 in microbial fuel cells (MFCs) with that of well-characterized S. oneidensis MR-1 and examined the roles of c-cyts in extracellular electron transfer. We found that strains PV-4 and MR-1 exhibited notable differences in current-generating mechanisms. While the MR-1 MFCs maintained a constant current density over time, the PV-4 MFCs continued to increase in current density and finally surpassed the MR-1 MFCs. Coulombic efficiencies reached 26% in the PV-4 MFC but 16% in the MR-1 MFCs. Although both organisms produced quinone-like compounds, anode exchange experiments showed that anode-attached cells of PV-4 produced sevenfold more current than planktonic cells in the same chamber, while planktonic cells of MR-1 produced twice the current of the anode-attached cells. Examination of the genome sequence indicated that PV-4 has more c-cyt genes in the metal reductase-containing locus than MR-1. Mutational analysis revealed that PV-4 relied predominantly on a homologue of the decaheme c-cyt MtrC in MR-1 for current generation, even though it also possesses two homologues of the decaheme c-cyt OmcA in MR-1. These results suggest that current generation in a PV-4 MFC is in large part accomplished by anode-attached cells, in which the MtrC homologue constitutes the main path of electrons toward the anode.Some species of dissimilatory metal-reducing bacteria (DMRB) are able to reduce solid metal oxides as terminal electron acceptors and generate currents in microbial fuel cells (MFCs) (2, 11, 14, 30, 46). Although mixed cultures are often used in MFC experiments (13), studies seeking a mechanistic understanding of electron transfer to electrode surfaces typically target pure cultures of such DMRB, due to the complexity in microbial communities. Presently, two model DMRB, Shewanella oneidensis MR-1 and Geobacter sulfurreducens PCA (2, 3, 12, 18, 31), are used in most investigations.S. oneidensis MR-1 is a metabolically diverse DMRB that has been studied extensively for its potential use in bioremediation applications. For this reason, MR-1 was the first Shewanella species to have its genome completely sequenced and annotated (10). In addition, since the first report in 1999 when this microorganism was shown to have the ability to transfer electrons to the electrode without an exogenously added mediator (14), it has also become one of the model organisms for the study of electron transfer mechanisms in MFCs.Although the molecular mechanisms for extracellular electron transfer have not yet been elucidated fully, c-type cytochromes (c-cyts) appear to be the key cellular components involved in this process (38). In S. oneidensis MR-1, OmcA and MtrC are outer membrane (OM), decaheme c-cyts that are considered to be involved in the direct (directly attached) electron transfer to solid metal oxides and anodes of MFCs (9, 20, 22, 23, 47). Several pieces of evidence suggest that OmcA and MtrC form a complex and act in a cooperative manner (33, 37, 42), and these results correlate with the fact that the genes encoding these proteins constitute an operon-like cluster in the chromosome (1). It has also been shown that MtrC and OmcA have overlapping functions as terminal reductases of metal oxides (25, 38). OmcA and MtrC are also present on the surface of nanowires and may be involved in the long-range transfer of electrons (8). In addition to direct electron transfer, MR-1 has the ability to produce water-soluble electron-shuttle compounds (quinones and flavins) that are involved in the mediated electron transfer from cells to distant solid electron acceptors (metal oxides or MFC anodes) (21, 27, 44).Recently, the genome sequences of nearly 20 Shewanella strains have been completed and annotated, opening the door to study the diversity of their extracellular electron transfer mechanisms. A comparison of their genomes has shown that although they have some consensus OM c-cyt genes, variations exist in the number and order of these genes in their metal reductase-containing loci (6). One such species is S. loihica strain PV-4, which was recently isolated from an iron-rich microbial mat near a deep-sea hydrothermal vent located on the Loihi Seamount in Hawaii (7, 32). The phenotypic and phylogenetic characteristics of PV-4 were determined, with a subsequent study focusing on the metal reduction and iron biomineralization capabilities of this bacterium (32). Initial experiments performed in our laboratory revealed that PV-4 developed a c-cyt-dependent deep red color that was much more striking than that of strain MR-1 when grown anaerobically with iron oxide as the terminal electron acceptor (26). This allowed us to assume that PV-4 could have a high extracellular electron transfer ability. Accordingly, the present study evaluated the current-producing ability of strain PV-4 in MFCs and examined the roles of some c-cyts in extracellular electron transfer. Special attention was paid to the comparison of PV-4 with MR-1 to reveal differences in mechanisms for extracellular electron transfer. We report herein differences between these strains in the roles of OM c-cyts for extracellular electron transfer, the behaviors and metabolic patterns of MFC, and the resultant MFC performances.