Growth of a bacterium that apparently uses arsenic instead of phosphorus is a consequence of massive ribosome breakdown

A recent study (Wolfe-Simon, F., Switzer Blum, J., Kulp, T. R., Gordon, G. W., Hoeft, S. E., Pett-Ridge, J., Stolz, J. F., Webb, S. M., Weber, P. K., Davies, P. C., Anbar, A. D., and Oremland, R. S. (2011) Science 332, 1163-1166) described the isolation of a special bacterial strain, GFAJ-1, that could grow in medium containing arsenate, but lacking phosphate, and that supposedly could substitute arsenic for phosphorus in its biological macromolecules. Here, we provide an alternative explanation for these observations and show that they can be reproduced in a laboratory strain of Escherichia coli. We find that arsenate induces massive ribosome degradation, which provides a source of phosphate. A small number of arsenate-tolerant cells arise during the long lag period prior to initiation of growth in +As/-P medium, and it is this population that undergoes the very slow, limited growth observed for both E. coli and GFAJ-1. These results provide a simple explanation for the reported growth of GFAJ-1 in arsenate without invoking replacement of phosphorus by arsenic in biological macromolecules.     

Corynebacterium glutamicum as a model bacterium for the bioremediation of arsenic.

Arsenic is an extremely toxic metalloid that, when present in high concentrations, severely threatens the biota and human health. Arsenic contamination of soil, water, and air is a global growing environmental problem due to leaching from geological formations, the burning of fossil fuels, wastes generated by the gold mining industry present in uncontrolled landfills, and improper agriculture or medical uses. Unlike organic contaminants, which are degraded into harmless chemical species, metals and metalloids cannot be destroyed, but they can be immobilized or transformed into less toxic forms. The ubiquity of arsenic in the environment has led to the evolution in microbes of arsenic defense mechanisms. The most common of these mechanisms is based on the presence of the arsenic resistance operon (ars), which codes for: (i) a regulatory protein, ArsR; (ii) an arsenite permease, ArsB; and (iii) an enzyme involved in arsenate reduction, ArsC. Corynebacterium glutamicum, which is used for the industrial production of amino acids and nucleotides, is one of the most arsenic-resistant microorganisms described to date (up to 12 mM arsenite and >400 mM arseniate). Analysis of the C. glutamicum genome revealed the presence of two complete ars operons (ars1 and ars2) comprising the typical three-gene structure arsRBC, with an extra arsC1 located downstream from arsC1 (ars1 operon), and two orphan genes (arsB3 and arsC4). The involvement of both ars operons in arsenic resistance in C. glutamicum was confirmed by disruption and amplification of those genes. The strains obtained were resistant to up to 60 mM arsenite, one of the highest levels of bacterial resistance to arsenite so far described. Using tools for the genetic manipulation of C. glutamicum that were developed in our laboratory, we are attempting to obtain C. glutamicum mutant strains able to remove arsenic from contaminated water.     

Ricoseius loxocheles,a phytoseiid mite that feeds on coffee leaf rust

One of the most important diseases of coffee plants is the coffee leaf rust fungus Hemileia vastatrix Berkeley and Broome (Uredinales). It can cause 30 % yield loss in some varieties of Coffea arabica (L.). Besides fungus, the coffee plants are attacked by phytophagous mites. The most common species is the coffee red mite, Oligonychus ilicis McGregor (Acari: Tetranychidae). Predatory mites of the Phytoseiidae family are well-known for their potential to control herbivorous mites and insects, but they can also develop and reproduce on various other food sources, such as plant pathogenic fungi. In a field survey, we found Ricoseius loxocheles (De Leon) (Acari: Phytoseiidae) on the necrotic areas caused by the coffee leaf rust fungus during the reproductive phase of the pathogen. We therefore assessed the development, survivorship and reproduction of R. loxocheles feeding on coffee leaf rust fungus and measured predation and oviposition of this phytoseiid having coffee red mite as prey under laboratory conditions. The mite fed, survived, developed and reproduced successfully on this pathogen but it was not able to prey on O. ilicis. Survival and oviposition with only prey were the same as without food. This phytoseiid mite does not really use O. ilicis as food. It is suggested that R. loxocheles is one phytoseiid that uses fungi as a main food source.     

Redox cycling of arsenic by the hydrothermal marine bacterium Marinobacter santoriniensis

Marinobacter santoriniensis NKSG1^T is a mesophilic, dissimilatory arsenate-reducing and arsenite-oxidizing bacterium isolated from an arsenate-reducing enrichment culture. The inoculum was obtained from arsenic-rich shallow marine hydrothermal sediment from Santorini, Greece, with evidence of arsenic redox cycling. Growth studies demonstrated M. santoriniensis NKSG1^T is capable of conserving energy from the reduction of arsenate [As(V)] with acetate or lactate as the electron donor, and of oxidizing arsenite [As(III)] heterotrophically with oxygen as the electron acceptor. The oxidation of As(III) coincided with the expression of the aoxB gene encoding for the catalytic molybdopterin subunit of the heterodimeric arsenite oxidase operon, indicating the reaction is enzymatically controlled, and M. santoriniensis NKSG1^T is a heterotrophic As(III)-oxidizing bacterium. Although it is clear that this organism also performs dissimilatory As(V) reduction, no amplification of the arrA arsenate reductase gene was attained using a range of primers and PCR conditions. Marinobacter santoriniensis NKSG1^T belongs to a genus of bacteria widely occurring in marine environments, including hydrothermal sediments, and is among the first marine bacteria shown to be capable of either anaerobic As(V) respiration or aerobic As(III) oxidation.     

Characterization of a novel Spirillum-like bacterium that degrades ferrioxamine-type siderophores

A novel Gram-negative Spirillum-like bacterium (ASP-1) was isolated from lake water by enrichment culture on desferrioxamine B as sole source of carbon and energy. ASP-1 was able to degrade the siderophores desferrioxamine B and E. The property of siderophore degradation was inducible in the presence of desferrioxamine B. The ferric complexes, however, were not measurably degraded but served as an iron source. Degradation of desferrioxamines in culture was followed by measuring the residual ferrioxamines colorimetrically at 430 nm after addition of iron. Degradation in cell-free assays was followed quantitatively by HPLC on a reversed-phase column measuring the time-dependent disappearance of the desferrioxamines B and E. Cell-free assays also revealed that degradation of the cyclic desferrioxamine E was rapid and complete, whereas degradation of the linear desferrioxamine B yielded two intermediate iron-binding metabolites of shorter chain length. Preparative isolation by HPLC and mass spectrometric analysis of the metabolites revealed masses at 361 and 419 a.m.u., respectively, suggesting a splitting at the two amide bonds. ASP-1 is a nitrogen fixing Spirillum bacterium which could also use ammonium and glucose or several organic acids as a carbon source but grew poorly with amino acids. Physiological comparisons with Aquaspirillum and Azospirillum failed to assign ASP-1 to any of the presently known Spirillum species. Based on 16S rDNA sequence analysis the strain could be placed within the radiation of the Azospirillum/Rhodocista group. The closest relative was Azospirillum irakense, showing 98.8% similarity.     

Nourishing Relations: Controversy over the Conga Mining Project in Northern Peru

This article extends debates on ontological multiplicity and considers the potential and limitations of this analytical lens for understanding the dynamics of mining activity in Cajamarca, Peru. Peasant farmers from El Tambo organised themselves to protect the lagoons in the Conga project area. We examine different conceptions of ‘nourishment’ to understand people’s relationship with land and water, and the company’s environmental management plans, including a proposal to replace the lagoons with artificial reservoirs. Competing ‘designs on the land’ reveal complex relations among humans and elements of the environment, which are re-created and transformed in situations of conflict. Ethnographic attention to designs on the land elucidates the processes through which ontologies or ‘worlds’ are made. We emphasise the connection between past practices and recent events, recognising people’s long-standing relationships and commitments to the land without ignoring the political creativity that made the lagoons into a source of life to be defended.     

Isolation of a bacterium that causes anaaki disease of the red algae Porphyra yezoensis

Anaaki disease causes severe damage to the red algae Porphyra yezoensis from which the Japanese traditional food 'nori'is produced. The causative agent of anaaki disease was isolated by several repeats of single-colony isolation and infection experiments, and was identified as Flavobacterium sp. LAD-1. The bacterium showed hydrolytic activity toward porphyran but not toward other polysaccharides composing the thallus of Porphyra , such as β-1,3-xylan or β-1,4-mannan. The bacterium also showed β-D-galactosidase activity.     

Isolation and characterization of a sulfate-reducing bacterium that anaerobically degrades alkanes.

An alkane-degrading, sulfate-reducing bacterial strain, AK-01, was isolated from an estuarine sediment with a history of chronic petroleum contamination. The bacterium is a short, nonmotile, non-spore-forming, gram-negative rod. It is mesophilic and grows optimally at pH 6.9 to 7.0 and at an NaCl concentration of 1%. Formate, fatty acids (C4 to C16) and hydrogen were readily utilized as electron donors. Sulfate, sulfite, and thiosulfate were used as electron acceptors, but sulfur, nitrite, and nitrate were not. Phenotypic characterization and phylogenetic analysis based on 16S rRNA gene sequence indicate that AK-01 is most closely related to the genera Desulfosarcina, Desulfonema, and Desulfococcus in the delta subdivision of the class Proteobacteria. It is phenotypically and phylogenetically different from strains Hxd3 and TD3, two previously reported isolates of alkane-degrading, sulfate-reducing bacteria. The alkanes tested to support growth of AK-01 had chain lengths of C13 to C18. 1-Alkenes (C15 and C16) and 1-alkanols (C15 and C16) also supported growth. The doubling time for growth on hexadecane was 3 days, about four times longer than that for growth on hexadecanoate. Mineralization of hexadecane was indicated by the recovery of 14CO2 from cultures grown on [1-14C]hexadecane. Degradation of hexadecane was dependent on sulfate reduction. The stoichiometric ratio (as moles of sulfate reduced per mole of hexadecane degraded) was 10.6, which is very close to the theoretical ratio of 12.25, assuming a complete oxidation to CO2. Anaerobic alkane degradation by sulfate reducers may be a more widespread phenomenon than was previously thought.     

Characterization of a new keratinolytic bacterium that completely degrades native feather keratin

A novel feather-degrading microorganism was isolated from poultry waste, producing a high keratinolytic activity when cultured on broth containing native feather. Complete feather degradation was achieved during cultivation. The bacterium presents potential use for biotechnological processes involving keratin hydrolysis. Chryseobacterium sp. strain kr6 was identified based on morphological and biochemical tests and 16S rRNA sequencing. The bacterium presented optimum growth at pH 8.0 and 30 degrees C; under these conditions, maximum feather-degrading activity was also achieved. Maximum keratinase production was reached at 25 degrees C, while concentration of soluble protein was similar at both 25 and 30 degrees C. Reduction of disulfide bridges was also observed, increasing with cultivation time. The keratinase of strain kr6 was active on azokeratin and azocasein as substrates, and presented optimum pH and temperature of 7.5 and 55 degrees C, respectively. The keratinase activity was inhibited by 1,10-phenanthroline, EDTA, Hg(2+), and Cu(2+) and stimulated by Ca(2+).     

Marine lysozyme from a marine bacterium that inhibits angiogenesis and tumor growth

Recent studies suggest that lysozyme, rich in hen egg, has an antitumor function. In the present study, we investigated the antitumor and antiangiogenesis effects of a newly isolated marine lysozyme both in vitro and in vivo. First, we showed that this marine-derived lysozyme specifically inhibits the proliferation of endothelial cells (ECV304) in a dose-dependent manner with no cytotoxicity (IC₅₀ = 3.64 μM). Second, we showed that this marine lysozyme directly suppresses neovascularization in chicken embryos using chorioallantoic membrane assay. Third, we demonstrated that this marine lysozyme markedly inhibits tumor growth in mice bearing either sarcoma 180 or hepatoma 22. Unexpectedly, hen egg lysozyme has no effects on the proliferation of endothelial cells in vitro or neovascularization in chicken embryos or tumor growth in nude mice at the same dosage range. Taken together, our studies clearly show that the newly identified marine lysozyme is a potent antitumor molecule, which may inhibit tumor growth and inhibit angiogenesis. We believe that this marine lysozyme may have a therapeutic value in antitumor drug development.     

一株将甜菊苷转化为甜茶甙的细菌鉴定及转化特性

摘要：【目的】筛选一株对甜菊苷具有特异转化性能的细菌,并对该菌及转化产物进行鉴定,探讨转化酶及酶对甜菊苷的转化特性。【方法】通过16S rDNA序列分析,构建该菌系统进化树,结合菌体形态及菌落特征,确立该菌系统发育学地位。通过高效液相色谱（HPLC）及液质联用（LC－MS）法检测并鉴定转化产物。用菌液直接对甜菊苷进行转化以研究菌的转化能力。用静息细胞、胞外液和胞内液对甜菊糖分别转化法,确定转化酶与菌体的关系,并用该酶液进行转化特性研究。【结果】该菌株与黄杆菌属的16S rDNA序列相似性为99%,结合菌体     

Isolation and characterization of a bacterium that degrades various polyester-based biodegradable plastics

Microorganisms isolated from soil samples were screened for their ability to degrade various biodegradable polyester-based plastics. The most active strain, designated as strain TB-13, was selected as the best strain for degrading these plastics. From its phenotypic and genetic characteristics, strain TB-13 was closely related to Paenibacillus amylolyticus. It could degrade poly(lactic acid), poly(butylene succinate), poly(butylene succinate-co-adipate), poly(caprolactone) and poly(ethylene succinate) but not poly(hydroxybutylate-co-valerate). However, it could not utilize these plastics as sole carbon sources. Both protease and esterase activities, which may be involved in the degradation of plastic, were constitutively detected in the culture broth.     

Bioadsorption of arsenic from aqueous solution by the extremophilic bacterium Acidithiobacillus ferrooxidans DLC-5

The bioadsorption of heavy metal ions to process industrial and solid wastes is an attractive technology from an economical and environmental point of view. This study investigated the equilibrium, thermodynamics and bioadsorption characteristics of arsenite (iAs^III) and dimethylarsinate (DMA^V) by Acidithiobacillus ferrooxidans (A. ferrooxidans) DLC-5 in aqueous solution. Optimum bioadsorption conditions were determined by identifying the optimum temperature, pH, biomass dosage, initial arsenic concentration and contact time. The equilibrium data were then applied to Langmuir and Freundlich isotherm models. The results indicated that the bioadsorption processes for both iAs^III and DMA^V involved pseudo-second-order kinetics. Additionally, the bioadsorption of iAs^III and DMA^V by A. ferrooxidans DLC-5 was feasible, spontaneous and endothermic under the tested conditions. Fourier transform infrared spectroscopy (FT-IR) showed that –OH and –NH groups were involved in the bioadsorption process. A. ferrooxidans DLC-5 demonstrates potential for use in removing arsenic from aqueous solutions, especially those with very low arsenic concentrations.