Blar i forfatter "Svenning, Mette Marianne"

Viser treff 21-26 av 26

    • Organic carbon transformations in high-Arctic peat soils: key functions and microorganisms 

      Tveit, Alexander Tøsdal; Schwacke, Rainer; Svenning, Mette Marianne; Urich, Tim (Journal article; Tidsskriftartikkel; Peer reviewed, 2012)
      A substantial part of the Earths’ soil organic carbon (SOC) is stored in Arctic permafrost peatlands, which represent large potential sources for increased emissions of the greenhouse gases CH4 and CO2 in a warming climate. The microbial communities and their genetic repertoire involved in the breakdown and mineralisation of SOC in these soils are, however, poorly understood. In this study, we applied ...

    • Seasonal shifts of microbial methane oxidation in Arctic shelf waters above gas seeps 

      Gründger, Friederike; Probandt, David; Knittel, Katrin; Carrier, Vincent; Kalenitchenko, Dimitri; Silyakova, Anna; Serov, Pavel; Ferré, Benedicte; Svenning, Mette Marianne; Niemann, Helge (Journal article; Tidsskriftartikkel; Peer reviewed, 2021-04-07)
      The Arctic Ocean subseabed holds vast reservoirs of the potent greenhouse gas methane (CH<sub>4</sub>), often seeping into the ocean water column. In a continuously warming ocean as a result of climate change an increase of CH<sub>4</sub> seepage from the seabed is hypothesized. Today, CH<sub>4</sub> is largely retained in the water column due to the activity of methane-oxidizing bacteria (MOB) that ...

    • Shifts in methanogenic community composition and methane fluxes along the degradation of discontinuous permafrost 

      Liebner, Susanne; Ganzert, Lars; Kiss, Andrea; Yang, Sizhong; Wagner, Dirk; Svenning, Mette Marianne (Journal article; Tidsskriftartikkel; Peer reviewed, 2015-05-12)
      The response of methanogens to thawing permafrost is an important factor for the global greenhouse gas budget. We tracked methanogenic community structure, activity, and abundance along the degradation of sub-Arctic palsa peatland permafrost. We observed the development of pronounced methane production, release, and abundance of functional (mcrA) methanogenic gene numbers following the transitions ...

    • Simultaneous Oxidation of Atmospheric Methane, Carbon Monoxide and Hydrogen for Bacterial Growth 

      Tveit, Alexander Tøsdal; Schmider, Tilman; Hestnes, Anne Grethe; Lindgren, Matteus; Didriksen, Alena; Svenning, Mette Marianne (Journal article; Tidsskriftartikkel; Peer reviewed, 2021-01-12)
      The second largest sink for atmospheric methane (CH<sub>4</sub>) is atmospheric methane oxidizing-bacteria (atmMOB). How atmMOB are able to sustain life on the low CH<sub>4</sub> concentrations in air is unknown. Here, we show that during growth, with air as its only source for energy and carbon, the recently isolated atmospheric methane-oxidizer <i>Methylocapsa gorgona</i> MG08 (USCα) oxidizes three ...

    • Thermal acclimation of methanotrophs from the genus Methylobacter 

      Tveit, Alexander; Söllinger, Andrea; Rainer, Edda Marie; Didriksen, Alena; Hestnes, Anne Grethe; Motleleng, Liabo; Hellinger, Hans-Jörg; Rattei, Thomas; Svenning, Mette Marianne (Journal article; Tidsskriftartikkel; Peer reviewed, 2023-01-18)
      Methanotrophs oxidize most of the methane (CH<sub>4</sub>) produced in natural and anthropogenic ecosystems. Often living close to soil surfaces, these microorganisms must frequently adjust to temperature change. While many environmental studies have addressed temperature effects on CH<sub>4</sub> oxidation and methanotrophic communities, there is little knowledge about the physiological adjustments ...

    • Widespread soil bacterium that oxidizes atmospheric methane 

      Tveit, Alexander Tøsdal; Hestnes, Anne Grethe; Robinson, Serina Lee; Schintlmeister, Arno; Dedysh, Svetlana N; Jehmlich, Nico; Bergen, Martin von; Herbold, Craig; Wagner, Michael; Richter, Andreas; Svenning, Mette Marianne (Journal article; Tidsskriftartikkel; Peer reviewed, 2019-04-08)
      Increasing atmospheric methane concentrations contribute significantly to global warming. The only known biological sink for atmospheric methane is oxidation by methane oxidizing bacteria (MOB). Due to the lack of pure cultures, the physiology and metabolic potential of MOB that oxidize atmospheric methane remains a mystery. Here, we report on isolation and characterization of a MOB that can grow ...