Your search keyword '"Hulth S"' showing total 4 results

1. Anaerobic ammonium oxidation by marine and freshwater planctomycete-like bacteria.

Author

Jetten, M. S.M., Sliekers, O., Kuypers, M., Dalsgaard, T., Van Niftrik, L., Cirpus, I., Van de Pas-Schoonen, K., Lavik, G., Thamdrup, B., Le Paslier, D., Op den Camp, H. J. M., Hulth, S., Nielsen, L. P., Abma, W., Third, K., Engström, P., Kuenen, J. G., Jørgensen, B. B., Canfield, D. E., and Damsté, J. S. Sinninghe

Subjects

MARINE bacteria, MARINE organisms, AMMONIUM, PHYSIOLOGICAL oxidation, ORGANELLES

Abstract

Recently, two fresh water species, "Candidatus Brocadia anammoxidans" and "Candidatus Kuenenia stuttgartiensis", and one marine species, "Candidatus Scalindua sorokinii", of planctomycete anammox bacteria have been identified. "Candidatus Scalindua sorokinii" was discovered in the Black Sea, and contributed substantially to the loss of fixed nitrogen. All three species contain a unique organelle—the anammoxosome—in their cytoplasm. The anammoxosome contains the hydrazine/hydroxylamine oxidoreductase enzyme, and is thus the site of anammox catabolism. The anammoxosome is surrounded by a very dense membrane composed almost exclusively of linearly concatenated cyclobutane-containing lipids. These so-called 'ladderanes' are connected to the glycerol moiety via both ester and ether bonds. In natural and man-made ecosystems, anammox bacteria can cooperate with aerobic ammonium-oxidising bacteria, which protect them from harmful oxygen, and provide the necessary nitrite. The cooperation of these two groups of ammonium-oxidising bacteria is the microbial basis for a sustainable one reactor system, CANON (completely autotrophic nitrogen-removal over nitrite) to remove ammonia from high strength wastewater. [ABSTRACT FROM AUTHOR]

Published

2003

2. Arctic sediments (Svalbard): pore water and solid phase distributions of C, N, P and Si.

Author

Hulth, S., Hall, P., Landén, A., and Blackburn, T.

Abstract

Pore water and solid phase distributions of C, N, P and Si in sediments of the Arctic Ocean (Svalbard area) have been investigated. Concentrations of organic carbon (C) in the solid phase of the sediment varied from 1.3 to 2.8% (mean 1.9%), with highest concentrations found at shallow stations south/southwest of Svalbard. Relatively low concentrations were obtained at the deeper stations north/northeast of Svalbard. Atomic carbon to nitrogen ratios in the surface sediment ranged from below 8 to above 10. For some stations, high C/N ratios together with high concentrations of C suggest that sedimentary organic matter is mainly of terrigenous origin and not from overall biological activity in the water column. Organic matter reactivity (defined as the total sediment oxygen consumption rate normalized to the organic carbon content of the surface sediment) correlated with water depth at all investigated stations. However, the stations could be divided into two separate groups with different reactivity characteristics, representing the two most dominant hydrographic regimes: the region west of Svalbard mainly influenced by the West Spitsbergen Current, and the area east of Svalbard where Arctic polar water set the environmental conditions. Decreasing sediment reactivity with water depth was confirmed by the partitioning between organic and inorganic carbon of the surface sediment. The ratio between organic and inorganic carbon at the sediment-water interface decreased exponentially with water depth: from indefinite values at shallow stations in the central Barents Sea, to approximately 1 at deep stations north of Svalbard. At stations east of Svalbard there was an inverse linear correlation between the organic matter reactivity (as defined above) and concentration of dissolved organic carbon (DOC) in the pore water. The more reactive the sediment, the less DOC existed in the pore water and the more total carbonate (C or ΣCO) was present. This observation suggests that DOC produced in reactive sediments is easily metabolizable to CO. Sediment accumulation rates of opaline silica ranged from 0.35 to 5.7 µmol SiO md (mean 1.3 µmol SiO md), i.e. almost 300 times lower than rates previously reported for the Ross Sea, Antarctica. Concentrations of ammonium and nitrate in the pore water at the sediment-water interface were related to organic matter input and water depth. In shallow regions with highly reactive organic matter, a pool of ammonium was present in the pore water, while nitrate conoentrations were low. In areas where less reactive organic matter was deposited at the sediment surface, the deeper zone of nitrification caused a build-up of nitrate in the pore water while ammonium was almost depleted. Nitrate penetrated from 1.8 to ≥ 5.8 cm into the investigated sediments. Significantly higher concentrations of 'total' dissolved nitrogen (defined as the sum of NO, NO, NH and urea) in sediment pore water were found west compared to east of Svalbard. The differences in organic matter reactivity, as well as in pore water distribution patterns of 'total' dissolved nitrogen between the two areas, probably reflect hydrographic factors (such as ice coverage and production/import of particulate organic material) related to the dominant water mass (Atlantic or Arctic Polar) in each of the two areas. [ABSTRACT FROM AUTHOR]

Published

1996

3. Autonomous deep-ocean lander vehicles; modular approaches to design and operation.

Author

Priede, I.G., Addison, S., Bradley, S., Bagley, P.M., Gray, P., Yau, C., Rolin, J.-F., Blandin, J., Legrand, J., Cremer, A., Witte, U., Pfannkuche, O., Tengberg, A., Hulth, S., Helder, W., and Van Weering, T.

Published

1998

4. Autonomous deep-ocean lander vehicles; modular approaches to design and operation.

Author

Priede, I.G., Addison, S., Bradley, S., Bagley, P.M., Gray, P., Yau, C., Rolin, J.-F., Blandin, J., Legrand, J., Khripounoff, A., Vangriesheim, A., Cremer, A., Witte, U., Pfannkuche, O., Tengberg, A., Hulth, S., Hall, P., Helder, W., Van Weering, T., and Duineveld, G.

Published

1998