废水中的脱氮除硫研究

随着氮、硫污染物对江河湖泊污染的扩大,同步脱氮除硫已成为净化水体的一个重要课题。试验中采用UASB反应器,接种含有厌氧氨氧化菌的污泥处理含有氮硫的废水。通过硫酸盐取代亚硝酸作为电子受体,驯化同步脱氮除硫。进水浓氨氮和硫酸盐浓度分别控制在50～60mg·L^-1和210～240mg·L^-1的情况下,60天后得到一定的稳定处理效果,出水氨氮和硫酸盐浓度为30mg·L和160mg·L^-1。这种新型的脱氮除硫现象有助于为氮硫循环开辟新的途径。     

Enumeration of bacteria forming acetate from H2 and CO2 in anaerobic habitats

A method has been worked out that allows the detection and isolation of bacteria fermenting molecular hydrogen and carbon dioxide to acetic acid.The ratio of methanogenic to acetogenic bacteria in sludge and lake sediment samples has been found to be approximately 100 to 1. Acetogenic bacteria could not be detected in rumen samples.     

Physicochemical characteristics of anaerobic H2-producing granular sludge

Granule-based biological H₂ production processes are gaining great popularity in recent years. An efficient and stable operating of such systems relies heavily on the performance of the H₂-producing granules (HPGs), which possess many unique properties compared with floc sludge and methanogenic granules. Hence, a full understanding of the sludge characteristics is essential. Especially, the physicochemical properties of HPGs may provide useful information for effective evaluation of system status. This review offers a systematical introduction of the physicochemical properties of HPGs, including size, morphology, settling velocity, permeability, rheology, surface charge, hydrophobicity and extracellular polymeric substances (EPS). We also analyze the relationships between these physicochemical factors and the system performance, and discuss the remaining challenges and future implications for sludge characterization and process monitoring. This work may facilitate a better understanding of granule-based biological H₂ production processes and offer a basis for timely process monitoring and manipulation.     

Diffusion of N2, O2, H2S and SO2 in MFI and 4A zeolites by molecular dynamics simulations

This paper presents diffusion data of N₂, O₂, H₂S and SO₂ in MFI and 4A zeolites obtained by molecular dynamics simulations, especially its dependence on temperature and loading. At high loadings and temperatures, the order of self-diffusivity of guests in two zeolites is O₂ > N₂ > H₂S>SO₂. The diffusion behaviour is different in different zeolites at lower loadings, reflecting different influences from straight channels (MFI) and α-cages (4A). Furthermore, with increasing loading, the self-diffusivity of guest molecules decreases in MFI but generally increases in 4A. The centre of mass (COM) probability densities and diffusion trajectories of guests give insight into molecular-level diffusion process. The simulation results reveal that with increasing loading, the diffusion mechanism would change from the inter-pore to intra-pore diffusion in MFI. However, in 4A, the intra-pore diffusion is predominant at low and high loadings, but inter-pore diffusion is more important at moderate loadings.     

H2S protects from oxidative stress-driven ACE2 expression and cardiac aging

Cystathionine gamma-lyase (CSE)-derived hydrogen sulfide (H₂S) plays an essential role in preserving cardiac functions. Angiotensin-converting enzyme 2 (ACE2) acts as the negative regulator of the renin-angiotensin system, exerting anti-oxidative stress and anti-inflammatory properties within the body. The interplays of CSE/H₂S signaling and ACE2 in cardiac aging are unclear. In this study, the regulatory roles of H₂S on ACE2 expression in mouse heart tissue and rat cardiomyocytes under different stress conditions were investigated. It was found that ACE2 protein level was lower in heart tissues from old mice (56-week-old) than young mice (8-week-old), and the knockout of CSE (CSE KO) induced moderate oxidative stress and further inhibited ACE2 protein level in mouse hearts at both young and old age. Incubation of rat cardiac cells (H9C2) with a low dose of H₂O₂ (50 µM) suppressed ACE2 protein level and induced cellular senescence, which was completely reversed by co-incubation with 30 µM NaHS (a H₂S donor). Prolonged nutrient excess is an increased risk of heart disorders by causing metabolic dysfunction and cardiac remodeling. We further found high-fat diet feeding stimulated ACE2 expression and induced severe oxidative stress in CSE KO heart in comparison with wild-type heart. Lipid overload in H9C2 cells to mimic a status of nutrient excess also enhanced the expression of ACE2 protein and induced severe oxidative stress and cell senescence, which were significantly attenuated by the supplementation of exogenous H₂S. Furthermore, the manipulation of ACE2 expression partially abolished the protective role of H₂S against cellular senescence. These results demonstrate the dynamic roles of H₂S in the maintenance of ACE2 levels under different levels of oxidative stress, pointing to the potential implications in targeting the CSE/H₂S system for the interruption of aging and diabetes-related heart disorders.

     

Performance study of biofilter developed to treat H2S from wastewater odour

Biofiltration is an efficient biotechnological process used for waste gas abatement in various industrial processes. It offers low operating and capital costs and produces minimal secondary waste streams. The objective of this study was to evaluate the performance of a pilot scale biofilter in terms of pollutants’ removal efficiencies and the bacterial dynamics under different inlet concentrations of H₂S. The treatment of odourous pollutants by biofiltration was investigated at a municipal wastewater treatment plant (WWTP) (Charguia, Tunis, Tunisia). Sampling and analyses were conducted for 150 days. Inlet H₂S concentration recorded was between 200 and 1300 mg H₂S.m⁻³. Removal efficiencies reached 99% for the majority of the running time at an empty bed retention time (EBRT) of 60 s. Heterotrophic bacteria were found to be the dominant microorganisms in the biofilter. The bacteria were identified as the members of the genus Bacillus, Pseudomonas and xanthomonadacea bacterium. The polymerase chain reaction-single stranded conformation polymorphism (PCR-SSCP) method showed that bacterial community profiles changed with the H₂S inlet concentration. Our results indicated that the biofilter system, containing peat as the packing material, was proved able to remove H₂S from the WWTP odourous pollutants.     

Biological removal of H2S from the livestock manure using a biofilter

In this paper, the biological removal of H₂S from air had been investigated using a self-made biofilter with efficient bioceramics and a polyhedral hollow ball. The biological removal efficiency of H₂S had been analyzed at different experimental conditions, such as inlet H₂S concentration, residence time, initial pH value, and reaction temperature etc. The results showed that the initial pH value had a slight effect on H₂S removal efficiency from pH 3 to 9. The optimal initial pH value was 5.5, while the H₂S removal efficiency was 100%. The H₂S removal efficiency increased with increases in the nutrient solution spraying rate. The appropriate temperature was 25°C in the temperature range from 15 to 30°C. The H₂S removal efficiency dropped with the increase of air input and inlet H₂S concentration. After being isolated and screened, six strains of heterotrophic sulfide oxidizing bacteria and one strain autotrophic sulfide oxidizing bacteria were determined to be involved in the removal of H₂S within the biofilter. The reaction kinetics of H₂S was in accordance with first order reaction kinetics.     

Microbial biodegradation of a novel fluorotelomer alcohol, 1H,1H,2H,2H,8H,8H-perfluorododecanol, yields short fluorinated acids

The accumulation of perfluorooctanoic acid (PFOA) has been detected in wildlife, soil, and water. Further, 8:2 fluorotelomer alcohol (8:2 FTOH) is used for the industrial synthesis of other fluorotelomer compounds, surfactants, and polymeric materials; however, it was recently found to be a potential source of PFOA contamination in the environment. 1H,1H,2H,2H,8H,8H-perfluorododecanol (degradable telomer fluoroalcohol (DTFA)), which is a newly developed fluorotelomer, contains the –CH₂– group in the fluorinated carbon backbone, making it potentially degradable through biological reactions. In this study, we investigated the biodegradation of DTFA in a mixed bacterial culture obtained from activated sludge. Optimized quantitative liquid chromatography–mass spectrometry analysis of the predicted metabolites generated in the culture revealed accumulations of the transformation products from DTFA to 2H,2H,8H,8H-PFDoA and 2H,8H,8H-2-PFUDoA via multiple processes. Furthermore, the production of short fluorinated compounds, perfluorobutanoic acid, perfluoropentanoic acid, and perfluoropentanedioic acid, which are believed to have lower accumulation potential and toxicity toward organisms than PFOA, was determined.     

H2 production of Rhodospirillum rubrum during adaptation to anaerobic dark conditions

Rhodospirillum rubrum is able to produce H₂ during fermentation anaerobically in the dark in two ways, namely through formate hydrogen lyase and through the nitrogenase. After chemotrophic preculture aerobically in the dark formate hydrogen lyase was synthesized after a lag phase, whilst after phototrophic preculture a slight activity was present from the beginning of the anaerobic dark culture. During fermentation metabolism its activity increased noticeably. Hydrogen production through the nitrogenase occurred if the nitrogenase had been activated during phototrophic preculture. It ceased during fermentation metabolism after about 3 1/2 h anaerobic dark culture. The CO insensitive H₂ production by the nitrogenase could be partially inhibited by N₂. Potential activity of this system, however, remained and could be increased under conditions of nitrogenase induction. It seems therefore possible that synthesis of nitrogenase under N-deficiency can occur during fermentation metabolism in the same way as the formation of the photosynthetic apparatus in order to prepare for subsequent phototrophic metabolism.Abbreviations CAP chloramphenicol - DSM Deutsche Sammlung von Mikroorganismen, Göttingen - FHL formate hydrogen lyase - O.D optical density - PFL pyruvate formate lyase     

Cancer immunoediting of the NK group 2D ligand H60a

Cancer immunoediting describes the process whereby highly immunogenic tumor cells are removed, or edited, from the primary tumor repertoire by the immune system. In immunodeficient mice, the editing process is hampered, and "unedited" tumor cells can be recovered and studied. In this study, we compared unedited and edited tumors for their expression of NK group 2D (NKG2D) ligands, a family of surface proteins expressed on tumor cells that can activate NK cell cytotoxic activity. We found that the expression of the NKG2D ligand H60a was more heterogeneous in groups of unedited 3'-methylcholanthrene sarcoma cell lines compared with that in edited 3'-methylcholanthrene sarcoma cell lines (i.e., some unedited cell lines expressed very high levels of H60a, whereas other unedited and edited cell lines expressed very low levels). We also found that some highly immunogenic cell lines displayed a bimodal distribution consisting of H60a-hi and H60a-lo cells. In one of these cell lines, the H60a-hi cells could be removed by passaging the cells through RAG2(-/-) mice, resulting in edited cell lines that were poor targets for NK cells and that displayed progressive tumor growth. This editing of H60a-hi cells required NK cells and NKG2D. Our studies show that the expression of H60a on tumors cells can be actively modulated by the immune system, thereby implicating this NKG2D ligand in tumor immunosurveillance.     

Function of a low molecular weight peptide from Trichoderma pseudokoningii S38 during cellulose biodegradation

The biochemical mechanism for cellulose decomposition by a low molecular weight peptide, named short fiber generating factor (SFGF), derived from the culture supernatant of a cellulolytic fungus Trichoderma pseudokoningii S-38, was determined. Sufficient information obtained by biochemical and biophysical studies and combined with observation with a scanning electron microscope provided further evidence for the earlier studies that the SFGF had a high capacity for chelating and reducing ferric ions, and could produce free radical by reduction of Fe(3+) to Fe(2+) in the presence of oxygen molecule. These studies suggested that the effect of SFGF on cellulose is directly related to an oxidative reaction and is different from the hydrolysis of cellulose by cellulases. The alcoholic hydroxyl groups in cellulose can be oxidized by SFGF, which leads to destruction of the hydrogen bond network in cellulose and cleavage of glycosidic linkages. Both effects led to the de-polymerization of cellulose and the formation of short fibers, and increase of reducing groups in residual cellulose, then the cellulose substrates became more susceptible for hydrolysis by cellulases.     

Facilitated transfer of IscU-[2Fe2S] clusters by chaperone-mediated ligand exchange

The scaffold protein IscU and molecular chaperones HscA and HscB play central roles in biological assembly of iron-sulfur clusters and maturation of iron-sulfur proteins. However, the structure of IscU-FeS complexes and the molecular mechanism whereby the chaperones facilitate cluster transfer to acceptor proteins are not well understood. We have prepared amino acid substitution mutants of Escherichia coli IscU in which potential ligands to the FeS cluster (Cys-37, Cys-63, His-105, and Cys-106) were individually replaced with alanine. The properties of the IscU-FeS complexes formed were investigated by measuring both their ability to transfer preformed FeS clusters to apo-ferredoxin and the activity of the IscU proteins in catalyzing cluster assembly on apo-ferredoxin using inorganic iron with inorganic sulfide or with IscS and cysteine as a sulfur source. The ability of the HscA/HscB chaperone system to accelerate ATP-dependent cluster transfer from each IscU substitution mutant to apo-ferredoxin was also determined. All of the mutants formed FeS complexes with a stoichiometry similar to the wild-type holo-protein, i.e., IscU(2)[2Fe2S], raising the possibility that different cluster ligation states may occur during iron-sulfur protein maturation. Spectroscopic properties of the mutants and the kinetics of transfer of performed IscU-FeS clusters to apo-ferredoxin indicate that the most stable form of holo-IscU involves iron coordination by Cys-63 and Cys-106. Results of studies on the ability of mutants to catalyze formation of holo-ferredoxin using iron and different sulfur sources were consistent with proposed roles for Cys-63 and Cys-106 in FeS cluster binding and also indicated an essential role for Cys-106 in sulfide transfer to IscU from IscS. Measurements of the ability of the chaperones HscA and HscB to facilitate cluster transfer from holo-IscU to apo-ferredoxin showed that only IscU(H105A) behaved similarly to wild-type IscU in exhibiting ATP-dependent stimulation of cluster transfer. IscU(C63A) and IscU(C106A) displayed elevated rates of cluster transfer in the ±ATP whereas IscU(C37A) exhibited low rates of cluster transfer ±ATP. In interpreting these findings, we propose that IscU(2)[2Fe2S] is able undergo structural isomerization to yield conformers having different cysteine residues bound to the cluster. On the basis of the crystal structure of HscA complexed with an IscU-derived peptide, we propose that the chaperone binds and stabilizes an isomer of IscU(2)[2Fe2S] in which the cluster is bound by cysteine residues 37 and 63 and that the [2Fe2S] cluster, being held less tightly than that coordinated by Cys-63 and Cys-106 in free IscU(2)[2Fe2S], is more readily transferred to acceptor proteins such as apo-ferredoxin.     

Subunit composition of the H+-ATPase complex from anaerobic bacterium Lactobacillus casei

The H+-ATPase complex has been isolated from the membranes of the anaerobic bacterium Lactobacillus casei by two independent methods. 1. The crossed-immunoelectrophoresis of the 14C-labelled ATPase complex against antibodies to a highly purified soluble ATPase has been used. The subunit composition of the complex has been established by autoradiography. The soluble part of L. casei ATPase, in contrast to coupling factor F1-ATPases of aerobic bacteria, chloroplasts and mitochondria which include two kinds of large subunit (alpha and beta), consists of one kind of large subunit with a molecular mass of 43 kDa. Moreover, a minor polypeptide of 25 kDa has been found in the soluble ATPase. Factor F0 of L. casei ATPase complex consists of a 16-kDa subunit and two subunits with molecular masses less than 14 kDa. 2. A dicyclohexylcarbodiimide-sensitive ATPase complex has been isolated from L. casei membranes by treating them with a mixture of octyl glucoside and sodium cholate. The complex, purified by centrifugation on a sucrose density gradient, contains the main subunits with molecular masses of 43 kDa, 25 kDa and 16 kDa and a dicyclohexylcarbodiimide-binding subunit with a molecular mass less than 14 kDa.     

农业废弃物分解产生CO2的影响因素研究

在正交预备试验得出有机废弃物分解产生CO2适宜条件的基础上,逐一进行单因子试验,以获得利用农业废弃物分解产生的CO2进行棚室栽培CO2施肥的最适发酵条件,结果表明,利用有机废弃物(稻草+猪粪)生物发酵产生CO2的最佳条件分别为：温度50℃、含水量70％、初始pH6．0～7．0．初始C／N比因发酵目的不同有较大变化,以堆肥为目的时为30／1,而以产生CO2为目的时,则以40／1为宜,在4个因素中,初始C／N比和含水量对CO2释放的影响较大,其次是温度,初始pH的影响最小。     

PCR-amplification of mixed 16S rRNA genes from an anaerobic, cyanide-degrading consortium

Abstract The microorganisms participating in the anaerobic biodegradation of cyanide were characterized using 16S rRNA genes as genetic markers of diversity. Segments of mixed population 16S rRNA genes were amplified using the polymerase chain reaction (PCR) and prokaryote-specific amplification primers. Restriction fragment length polymorphism (RFLPs) and screening with the 926f universal sequencing primer were used to categorized the cloned PCR products. Six unique prokaryote sequence were obtained, including four similar to methanogens and two similar to Gram-positive eubacteria.     

H2S contributed from CSE during cellular senescence suppresses inflammation and nitrosative stress

Aging involves the time-dependent deterioration of physiological functions attributed to various intracellular and extracellular factors. Cellular senescence is akin to aging and involves alteration in redox homeostasis. This is primarily marked by increased reactive oxygen/nitrogen species (ROS/RNS), inflammatory gene expression, and senescence-associated beta-galactosidase activity, all hallmarks of aging. It is proposed that gasotransmitters which include hydrogen sulfide (H₂S), carbon monoxide (CO), and nitric oxide (NO), may affect redox homeostasis during senescence. H₂S has been independently shown to induce DNA damage and suppress oxidative stress. While an increase in NO levels during aging is well established, the role of H₂S has remained controversial. To understand the role of H₂S during aging, we evaluated H₂S homeostasis in non-senescent and senescent cells, using a combination of direct measurements with a fluorescent reporter dye (WSP-5) and protein sulfhydration analysis. The free intracellular H₂S and total protein sulfhydration levels are high during senescence, concomitant to cystathionine gamma-lyase (CSE) expression induction. Using lentiviral shRNA-mediated expression knockdown, we identified that H₂S contributed by CSE alters global gene expression, which regulates key inflammatory processes during cellular senescence. We propose that H₂S decreases inflammation during cellular senescence by reducing phosphorylation of IκBα and the p65 subunit of nuclear factor kappa B (NF-κB). H₂S was also found to reduce NO levels, a significant source of nitrosative stress during cellular senescence. Overall, we establish H₂S as a key gasotransmitter molecule that regulates inflammatory phenotype and nitrosative stress during cellular senescence.     

Production of H2S by 3-mercaptopyruvate sulphurtransferase

Hydrogen sulfide (H(2)S) has been established as the third gaseous signaling molecule following nitric oxide and carbon monoxide and participates in a variety of cellular functions such as modulation of neuronal transmission, endothelium-dependent vasorelaxation, stimulation of angiogenesis and regulation of insulin release. Although cystathionine β-synthase and cystathionine γ-lyase have been regarded as the main producers of H(2)S in many tissues including brain, liver and kidney, Kimura and his colleagues have recently communicated that 3-mercaptopyruvate sulphurtransferase coupled with cysteine (aspartate) aminotransferase is responsible for the production of H(2)S in the vascular endothelium of the thoracic aorta [Shibuya et al. (2009) J. Biochem. 146, 623-626]. This finding provides a new insight into the production of the physiologically important signaling molecule.