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

1. Habitat partitioning of marine benthic denitrifier communities in response to oxygen availability.

Author

Wittorf L, Bonilla-Rosso G, Jones CM, Bäckman O, Hulth S, and Hallin S

Subjects

Aerobiosis, Anaerobiosis, Denitrification, Oxidation-Reduction, Geologic Sediments microbiology, Microbiota, Nitrous Oxide metabolism, Oxygen analysis, Seawater chemistry

Abstract

Denitrification is of global significance for the marine nitrogen budget and the main process for nitrogen loss in coastal sediments. This facultative anaerobic respiratory pathway is modular in nature and the final step, the reduction of nitrous oxide (N2 O), is performed by microorganisms with a complete denitrification pathway as well as those only capable of N2 O reduction. Fluctuating oxygen availability is a significant driver of denitrification in sediments, but the effects on the overall N2 O-reducing community that ultimately controls the emission of N2 O from marine sediments is not well known. To investigate the effects of different oxygen regimes on N2 O reducing communities, coastal marine surface sediment was incubated in microcosms under oxic, anoxic or oscillating oxygen conditions in the overlying water for 137 days. Quantification of the genetic potential for denitrification, anammox and respiratory ammonification indicated that denitrification supported nitrogen removal in these sediments. Furthermore, denitrifiers with a complete pathway were identified as the dominant community involved in N2 O reduction, rather than organisms that are only N2 O reducers. Specific lineages within each group were associated with different oxygen regimes suggesting that oxygen availability in the overlying water is associated with habitat partitioning of N2 O reducers in coastal marine surface sediments., (© 2016 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2016

2. Functioning of a shallow-water sediment system during experimental warming and nutrient enrichment.

Author

Alsterberg C, Sundbäck K, and Hulth S

Subjects

Autotrophic Processes physiology, Heterotrophic Processes physiology, Marine Biology, Microalgae physiology, Oxygen metabolism, Seasons, Temperature, Water Microbiology, Climate Change, Geologic Sediments microbiology, Nitrogen metabolism, Phytoplankton microbiology, Phytoplankton physiology

Abstract

Effects of warming and nutrient enrichment on intact unvegetated shallow-water sediment were investigated for 5 weeks in the autumn under simulated natural field conditions, with a main focus on trophic state and benthic nitrogen cycling. In a flow-through system, sediment was exposed to either seawater at ambient temperature or seawater heated 4°C above ambient, with either natural or nutrient enriched water. Sediment-water fluxes of oxygen and inorganic nutrients, nitrogen mineralization, and denitrification were measured. Warming resulted in an earlier shift to net heterotrophy due to increased community respiration; primary production was not affected by temperature but (slightly) by nutrient enrichment. The heterotrophic state was, however, not further strengthened by warming, but was rather weakened, probably because increased mineralization induced a shortage of labile organic matter. Climate-related warming of seawater during autumn could therefore, in contrast to previous predictions, induce shorter but more intensive heterotrophic periods in shallow-water sediments, followed by longer autotrophic periods. Increased nitrogen mineralization and subsequent effluxes of ammonium during warming suggested a preferential response of organisms driving nitrogen mineralization when compared to sinks of ammonium such as nitrification and algal assimilation. Warming and nutrient enrichment resulted in non-additive effects on nitrogen mineralization and denitrification (synergism), as well as on benthic fluxes of phosphate (antagonism). The mode of interaction appears to be related to the trophic level of the organisms that are the main drivers of the affected processes. Despite the weak response of benthic microalgae to both warming and nutrient enrichment, the assimilation of nitrogen by microalgae was similar in magnitude to rates of nitrogen mineralization. This implies a sustained filter function and retention capacity of nutrients by the sediment.

Published

2012

3. Analytical performance during ratiometric long-term imaging of pH in bioturbated sediments.

Author

Hakonen A, Hulth S, and Dufour S

Subjects

Animals, Bivalvia, Calibration, Geologic Sediments chemistry, Hydrogen-Ion Concentration, Image Processing, Computer-Assisted, Microscopy, Fluorescence methods, Reproducibility of Results, Spectrometry, Fluorescence methods, Temperature, Water chemistry, Water Pollutants, Chemical analysis, Biosensing Techniques, Chemistry Techniques, Analytical, Geologic Sediments analysis

Abstract

In this study, the long-term analytical performance of a high-resolution ratiometric imaging sensor for pH was quantitatively determined. The sensor was applied in an experimental microcosm to illustrate biogeochemical consequences from mining activities by the chemosymbiotic bivalve Thyasira sarsi. Utilizing time-correlated pixel-by-pixel calibration protocols during imaging, close to 90% of the pixels were associated with a precision (S.D.) of <0.05 pH units at the end of an experimental period of 17 days. For comparison, a precision of <0.05 pH units was achieved for less than 50% of the pixels throughout experiments using conventional pre-sample calibration procedures. The average standard deviation of pixels was 0.01 pH units. Image analysis of single pixel derivatives and pH measurements over time suggested that T. sarsi affect pH distributions and general sediment geochemistry more than would be expected based on the small size of the bivalves. A significant decrease of pH in the overlying water suggested a considerable release of reduced compounds from the exhalent stream of the thyasirids. Strong pH gradients were demonstrated not only across the sediment-water interface but, also associated with bioturbation activities immediately adjacent to T. sarsi burrowing tracts, inhalant tubes and pedal tracts in the sediment matrix. Gradients of up to 1.16 pH units per mm were observed.

Published

2010

4. Biogeochemistry in highly reduced mussel farm sediments during macrofaunal recolonization by Amphiura filiformis and Nephtys sp.

Author

Lindqvist S, Norling K, and Hulth S

Subjects

Animals, Aquaculture, Seawater analysis, Bivalvia physiology, Echinodermata physiology, Geologic Sediments analysis, Polychaeta physiology

Abstract

Mussel farming is considered a viable means for reducing coastal eutrophication. This study assessed the importance of bioturbation by recolonizing fauna for benthic solute fluxes and porewater distributions in manipulated mussel farm sediments. Three consecutive time-series flux incubations were performed during an experimental period of three weeks in sieved farm sediment treated with the brittle star Amphiura filiformis and the polychaete Nephtys sp. The functional behavior of Nephtys sp. and interactions between Nephtys sp. and the spontaneously colonizing spionid Malacoceros fuliginosus determined the biogeochemical response in the Nephtys sp. treatment. For example, the oxic zone was restricted and benthic nitrate and silicate fluxes were reduced compared to the brittle star treatment. A. filiformis seemed to enhance the bioadvective solute transport, although an increased supply of oxygen was due to the highly reducing conditions of the sediment mainly seen as secondary effects related to porewater distributions and benthic nutrient fluxes.

Published

2009