Growth of methanogenic and sulfate-reducing bacteria with cathodic hydrogen

Summary Bacteria contribute to corrosion in various ways. Therefore the consumption of cathodic hydrogen as well as the sulfide production of sulfate-reducing bacteria may influence the anaerobic corrosion of iron. Also methanogenic bacteria are able to use elemental iron as a source of electrons for carbon dioxide reduction. We have studied both processes and have got evidence that cathodic depolarisation does not play a dominant role in methanogenic habitats.     

Elemental sulfur production during mixotrophic growth on hydrogen and thiosulfate of thermophilic hydrogen-oxidizing bacteria

In this study we measured the exogenous production and the intracellular content of elemental sulfur (S⁰) in the thermophilic sulfur-oxidizing bacteriaHydrogenobacter spp. andBacillus schlegelii during mixolithoautotrophic growth on hydrogen and thiosulfate. Under these conditions, all strains produced and released white-yellow hydrophilic S⁰ particles into the growth medium. Hydrophilic S⁰ was separated from cells by a differential low-speed centrifugation procedure. The S⁰ pellets were dried, and the S⁰ was purified by column chromatography and by thin-layer chromatography (TLC). The S⁰ TLC-band could be stained with triphenyltetrazolium chloride and piperidine procedure. Determination of intracellular S⁰ content was performed from fresh cells absolutely free of exogenous S⁰ particles. quantitation of S⁰ was performed by high-performance liquid chromatography, colorimetric thiocyanate procedure, and by UV-spectra analyses. All the strains studied, in particularB. schlegelii strains, released significant quantities of S⁰ into the growth media. In contrast, the intracellular S⁰ content was very low. Significant rhodanese activity in the presence of thiosulfate was measured with toluenepermeabilized cells and cell-free extracts ofB. schlegelii (type strain) andHydrogenobacter spp. (strain T3).     

Cultivation-independent detection of autotrophic hydrogen-oxidizing bacteria by DNA stable-isotope probing

Knallgas bacteria are a physiologically defined group that is primarily studied using cultivation-dependent techniques. Given that current cultivation techniques fail to grow most bacteria, cultivation-independent techniques that selectively detect and identify knallgas bacteria will improve our ability to study their diversity and distribution. We used stable-isotope probing (SIP) to identify knallgas bacteria in rhizosphere soil of legumes and in a microbial mat from Obsidian Pool in Yellowstone National Park. When samples were incubated in the dark, incorporation of (13)CO(2) was H(2) dependent. SIP enabled the detection of knallgas bacteria that were not detected by cultivation, and the majority of bacteria identified in the rhizosphere soils were betaproteobacteria predominantly related to genera previously known to oxidize hydrogen. Bacteria in soil grew on hydrogen at concentrations as low as 100 ppm. A hydB homolog encoding a putative high-affinity NiFe hydrogenase was amplified from (13)C-labeled DNA from both vetch and clover rhizosphere soil. The results indicate that knallgas bacteria can be detected by SIP and populations that respond to different H(2) concentrations can be distinguished. The methods described here should be applicable to a variety of ecosystems and will enable the discovery of additional knallgas bacteria that are resistant to cultivation.     

Synthesis of 3-hydroxybutyrate-CO-4-hydroxybutyrate copolymers by hydrogen-oxidizing bacteria

Synthesis of 3- and 4-hydroxybutyrate copolymer (3HB-co-4HB), the most promising member of the biodegradable polyhydroxyalkanoate (PHA) family, has been studied. Cultivation conditions of naturally occurring strains of hydrogen-oxidizing bacteria Ralstonia eutropha B5786 and Cupriavidus eutrophus B10646 have been optimized to ensure efficient synthesis of the 3HB-co-4HB copolymer. A set of highly pure samples of the 3HB-co-4HB copolymer with 4HB content varying from 8.7 to 24.3 mol% has been obtained. Incorporation of 4HB into the copolymer was shown to cause a more pronounced decrease in polymer crystallinity than the incorporation of 3-hydroxyvalerate or 3-hydroxyhexanoate; samples with a degree of crystallinity below 30% have been obtained. The weight average molecular mass of the 3HB-co-4HB copolymers was shown to be independent on the monomer ratio and to vary broadly (from 540 to 1110 kDa).     

Oxygen tolerance of strictly aerobic hydrogen-oxidizing bacteria

Growth of various bacteria, especially aerobic hydrogen-oxidizing bacteria, in the presence of 2 to 100% (v/v) oxygen in the gas atmosphere was evaluated. The bacterial strains included Alcaligenes eutrophus, A. paradoxus, Aquaspirillum autotrophicum, Arthrobacter spec. strain 11X, Escherichia coli, Arthrobacter globiformis, Nocardia opaca, N. autotrophica, Paracoccus denitrificans, Pseudomonas facilis, P. putida, and Xanthobacter autotrophicus. Under heterotrophic conditions with fructose or gluconate as substrates neither colony formation on solid medium nor the growth rates in liquid media were drastically impaired by up to 100% oxygen. In contrast, autotrophic growth — with hydrogen, carbon dioxide and up to 80% oxygen in the gas atmosphere — was strongly depressed by high oxygen concentrations. However, only the growth rate, not the viability of the cells, was decreased. Growth retardation was accompanied by a decrease of hydrogenase activity.The work was supported by the Deutsche Forschungsgemeinschaft.     

Cytochromes and hydrogen-oxidizing activity in the thermophilic hydrogen-oxidizing bacteria related to the genus Hydrogenobacter

The highly thermophilic, hydrogen-oxidizing aerobic bacteria related to Hydrogenobacter possess a respiratory chain comprising a quinone and b-type (alpha band at 556 nm and 562 nm) and c-type (alpha band at 552 nm) cytochromes. They have no aa₃-type cytochromes and their terminal oxidase is an o-type cytochrome. A polarographic method with an oxygen electrode was used for the measurement of the hydrogen-oxidizing activity. This activity was strongly inhibited by HQNO (2-N-heptyl-4-hydroxyquinoline N-oxide), an inhibitor of the respiratory chain in the quinone-cytochrome b region, and by KCN, an inhibitor of the terminal cytochrome oxidase. This study shows that the electrons released from hydrogen oxidation by the membrane-bound hydrogenase probably enter the respiratory chain at the level of the quinone-cytochrome b region.Abbreviations HQNO 2-N-heptyl-4-hydroxyquinoline N-oxide - TMPD N,N,N',N'-tetramethyl-p-phenylenediamine - DW dry weight     

R-Bodies in newly isolated free-living hydrogen-oxidizing bacteria

R-Bodies have been found in a recently isolated pseudomonas-like free-living hydrogen oxidizing bacterium. Their isolation, fine structure and chemical composition are described and compared with the R-bodies from the kappa particles (Caedobacter), obligate endosymbionts of Paramecium aurelia. The 2K 1 R-bodies exhibited essential characteristics of the kappa R-bodies; however, their size and some other structural aspects proved that they represent a new type of R-bodies. The presence of phage tail-like particles in cells induced with Mitomycin C is in favour of the hypothesis that the R-bodies might be coded by defective prophages, or by extrachromosomal elements.     

Effects of alkyltin compounds on hydrogen-oxidizing anaerobic bacteria

Methyl and butyltin compounds were inhibitory to all anaerobes examined, but there were great variations, depending on the specific alkyltin and bacterium. The methanogens were inhibited more strongly by methyl than by butyl derivatives; more than 50% inhibition occurred with 0.025–0.5 mM of the methyltins, whereas 0.16–1.8 mM butyltins were needed for the same level of inhibition; tri-butyltin was the least toxic.Methanosarcina barkeri was, in general, more resistant than theMethanococcus sp. andMethanobacterium bryantii. TheDesulfovibrio were more strongly inhibited by mono-methyltin than by di- and tri-methyl derivatives; butyltins were, in general, not so toxic. Mono-methyltin at 0.15 mM almost completely inhibited three of the sulfate reducers, butDesulfovibrio thermophilus required 0.7 mM for this level of inhibition. Tri-butyltin at 1.8 mM did not cause major inhibition, whereas mono- and di-butyltins were more inhibitory.Acetobacterium woodii was most affected by mono- and dimethyltins, and least by tri-methyltin and mono-butyltin. In contrast,Wollinella succinogenes was most affected by tri-methyltin. This study suggests several major groups of anaerobes thought to be involved in metal biocorrosion vary greatly in their response to alkyltins; most interesting is the relative insensitivity by methanogens and sulfate reducers to tri-butyltin, which is a major component in commercial antifouling paints. Our results differ considerably from those reported for aerobic microorganisms, which were found to be most affected by tributyltin.     

Characterization of populations of aerobic hydrogen-oxidizing soil bacteria

Abstract Freshly isolated soil bacteria were screened for different characteristics of the H₂ metabolism without prior selection for growth on H₂. The bacteria were isolated from different grain size fractions of a neutral meadow cambisol and an acidic forest cambisol, and then tested (1) for the ability to oxidize H₂, (2) for chemolithoautotrophic growth on H₂ as sole electron donor and energy source, (3) for DNA-DNA-hybridization with two hydrogenase gene fragments from Alcaligenes eutrophus and Rhizobium leguminosarum , and (4) for reduction of 2,3,5-triphenyl-2H-tetrazoliumchloride (TTC) in the presence of H₂. Many (65–90%) of the isolates were able to reduce TTC, but only 30–65% were actually able to oxidize H₂ indicating that the TTC test was not a specific characteristic for H₂ oxidation ability. The TTC test was only reliable in pure cultures of known bacteria with optimized test conditions, here shown for Alcaligenes eutrophus, Bradyrhizobium japonicum and Nocardia opaca , but not in mixed cultures of unknown bacteria. Still less (< 30%) of the isolates were able to grow chemolithoautotrophically indicating that culturable aerobic bacteria with the ability for H₂ oxidation are more abundant than bacteria with the ability for chemolithoautotrophic growth. The DNA-DNA-hybridization test failed to detect many of the bacteria with H₂ oxidation activity, probably since the hydrogenase genes present in the isolates were too diverse to be all detected by the DNA probes applied.     

Isolation of hydrogenase regulatory mutants of hydrogen-oxidizing bacteria by a colony-screening method

Mutants derepressible for hydrogenases (Hox d) have been isolated from the wild type of Alcaligenes hydrogenophilus which is inducible for hydrogenases (Hox i). The mutants are able to form the hydrogenases during growth on gluconate under air while the wild type requires molecular hydrogen for hydrogenase systhesis.Mutant selection involved alternating growth under autotrophic and heterotrophic conditions. Mutants derepressed for hydrogenases after growth on gluconate were recognized by a new colony-screening method allowing differentiation between colonies of hydrogenase-containing and hydrogenase-free cells of aerobic hydrogen-oxidizing bacteria. The method is based on the ability of the colonies to reduce triphenyltetrazolium chloride in the presence of monoiodoacetate and gaseous hydrogen to its water-insoluble purple formazan. Endogenous dye reduction (under nitrogen) and the function of the cytoplasmic NAD-reducing hydrogenase were completely inhibited by monoiodoacetate. The applicability of the method has been demonstrated for wild type strains and mutants of various hydrogen-oxidizing bacteria. When mutants of A. hydrogenophilus and A. eutrophus H16 lacking the Hox-encoding plasmids pHG21-a and pHG1, respectively, were used as recipients and Hox d mutant M 201 of A. hydrogenophilus as a donor transconjugants appeared which had received the Hox d character and the megaplasmid pHG21-a.Abbreviations MIAc monoiodoacetate - TTC 2,3,5-triphenyl-2-tetrazolium chloride - Hox ability to oxidize hydrogen Dedicated to Gerhard Drews on the occasion of his 60th birthday, remembering the education and inspiration we received from our teacher Johannes Buder at the Martin-Luther University of Halle     

Nickel requirement for chemolithotrophic growth in hydrogen-oxidizing bacteria

In a comparative study the requirement of several strains of autotrophic hydrogen-oxidizing bacteria for nickel was examined. Autotrophic growth was studied both in liquid media, previously freed from trace metals; and on solidified media, using a plate diffusion assay. The latter assay was based on the observation that EDTA causes complete inhibition of autotrophic growth on agar medium as a result of nickel deficiency. Nickel was shown to be required as a trace element in five strains of Alcaligenes eutrophus, in two strains of Xanthobacter autotrophicus, in Pseudomonas flava, in Arthrobacter spec. 11X and in strain 12X. In these bacteria nickel was not replaceable by cobalt, copper, manganese or zinc ions. No significant nickel requirement was detected by these methods, however, for Paracoccus denitrificans and Nocardia opaca 1b.     

Growth of thermophilic obligately autotrophic hydrogen-oxidizing bacteria on thiosulfate

Thermophilic obligately autotrophic H₂-oxidizing bacteria from Icelandic hot springs were tested for growth on thiosulfate. Ten strains were tested and all grew on thiosulfate but not on sulfite or sulfur. The product of thiosulfate oxidation was sulfate. The growth rate on thiosulfate was slower (μ=0.12 h^-1) than on H₂ (μ=0.34 h^-1). Washed cells which had been grown on thiosulfate could oxidize thiosulfate rapidly but H₂-grown cells oxidized thiosulfate much more slowly and with about a 3 h lag time. The bacteria would not grow on agar medium under H₂ but grew on agar medium containing thiosulfate.     

The use of disposable gaas generating kits for the growth of hydrogen-oxidizing bacteria and the determination of hydrogen autotrophy

A simplified procedure for the determination of autotropic growth of hydrogen-oxidizing bacteria has been developed. The method uses commercially available disposable hydrogen and carbon dioxide kits, commonly used in anaerobic bacteriology, to produce a gaseous atmosphre containing by volume approximately 41% hydrogen, 6% carbon dioxide, 11% oxygen and 42% nitrogen. The atmosphere was suitable for the growth of strains assigned to the species Alcaligenes eutrophus, Alcaligenes paradoxus, Paracoccus denitrificans, Pseudomonas facilis, Pseudomonas flava, Pseudomonas palleronii, Pseudomonas saccahrophilia and Rhodococcus sp. (‘Nocardia opaca’). The method can also be used for the screening of hydrogen-oxidizing ability in bacterial isolates, thus eliminating the need for complex gas mixing devices or expensive gas mixtures.     

Isolation and characterization of hydrogen-oxidizing bacteria induced following exposure of soil to hydrogen gas and their impact on plant growth

In many legumes, the nitrogen fixing root nodules produce H2 gas that diffuses into soil. It has been demonstrated that such exposure of soil to H2 can promote plant growth. To assess whether this may be due to H2-oxidizing microorganisms, bacteria were isolated from soil treated with H2 under laboratory conditions and from soils collected adjacent to H2 producing soybean nodules. Nineteen isolates of H2-oxidizing bacteria were obtained and all exhibited a half-saturation coefficient (Ks) for H2 of about 1 ml l(-1). The isolates were identified as Variovorax paradoxus, Flavobacterium johnsoniae and Burkholderia spp. using conventional microbiological tests and 16S rRNA gene sequence analysis. Seventeen of the isolates enhanced (57-254%) root elongation of spring wheat seedlings. Using an Arabidopsis thaliana bioassay, plant biomass was increased by 11-27% when inoculated by one of four isolates of V. paradoxus or one isolate of Burkholderia that were selected for evaluation. The isolates of V. paradoxus found in both H2-treated soil and in soil adjacent to soybean nodules had the greatest impact on plant growth. The results are consistent with the hypothesis that H2-oxidizing bacteria in soils have plant growth promoting properties.     

大豆根际土壤中氢氧化细菌的分离、筛选和基本特征

土壤中的氢氧化细菌能够利用土壤中的H2为能源并同化CO2,增加其种群数量并促进作物生长.采用气体循环培养体系(持续通氢气装置),通过电解水的方式产生H2,与通入的空气混合,形成流速为280ml.min-1、含H2量为41.6～125μmol.L-1的混合气体.采用矿质盐固体培养基,在适当的H2、O2和CO2下以H2作为唯一能源分离氢氧化细菌.采用此方法从大豆根际土壤样品中分离出40余株细菌,对其进行耗氢能力测定表明,有20株菌具有氧化氢功能和自养生长能力,初步判断这20株菌为氢氧化细菌,并测定了菌落形态及生理生化特征.     

Physical evidence for plasmids in autotrophic,especially hydrogen-oxidizing bacteria

Agarose gel electrophoresis of crude lysates from 23 species of autotrophic bacteria revealed plasmids of various sizes in 12 species. The plasmid pattern varied considerably. While the majority of the plasmid-bearing species harbored one or two plasmids, one species, Alcaligenes latus, exhibited more than six ccc-DNA bands. With one exception the molecular masses of the plasmids were 50×10⁶ or higher. In Achromobacter carboxydus, Alcaligenes latus, Derxia gummosa and three strains of Paracoccus denitrificans large plasmids of molecular masses higher than 300×10⁶ were resolved. The examination of Thiobacillus A2 resulted in the discovery of two plasmids while Pseudomonas oxalaticus was apparently free of resident plasmid DNA. So far these plasmids can only be characterized as cryptic. Future studies may allow to correlate them with specific metabolic activities of their hosts such as the ability to grow on carbon monoxide or thiosulfate, to fix molecular nitrogen and to form soluble NAD-reducing and/or membrane-bound hydrogenases.     

Excretion of metabolites by hydrogen bacteria

Summary D(–)-3-hydroxybutanoic acid was produced by a double mutant of Alcaligenes eutrophus, unable to synthesize poly-3-hydroxybutanoic acid and to utilize 3-hydroxybutanoate as a substrate. About 3.4 g of 3-hydroxybutanoate/l were produced under optimum conditions at pH 7.0 to 7.3, at a temperature of 30°C after exhaustion of ammonia and at restricted aeration rates allowing 10–12% of the maximum respiratory rate of the cells to occur. D(–)-3-hydroxybutanoic acid was identified by means of gas and ion exchange chromatography, IR-spectrometry and specific rotation.