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Marine microorganisms produce large amounts of nitrous oxide, a highly potent greenhouse gas. A Basel-based researcher investigated the exact processes involved during an expedition to the Pacific. The results are important for climate modeling.
To many people, nitrous oxide, or laughing gas, is only known as a party drug or from the dentist. However, the nitrogenous substance also contributes significantly to global warming. As a greenhouse gas, its effect in the atmosphere is almost three hundred times more powerful than that of CO2, and it also attacks the ozone layer.
“The emission of this almost forgotten greenhouse gas is decisive for the global climate,” says Dr. Claudia Frey from the Department of Environmental Sciences at the University of Basel. The biogeochemist has now investigated the conditions under which microorganisms produce nitrous oxide in the ocean.
Since the 19th century, nitrous oxide concentrations in the atmosphere have been steadily increasing, mainly due to human activities, such as the use of fossil fuels and the intensification of agriculture. For example, fertilizer contains a lot of nitrogen, which then ends up in rivers, lakes and oceans in the form of nitrate. There, bacteria convert the nitrogenous substances into food and energy. This process also produces nitrous oxide, which then escapes into the atmosphere.
Focus on hypoxic zones
The processes involved in the production of nitrous oxide in the ocean are complex and only partially understood so far. However, it is known that a particularly high amount of it is released in hypoxic, or low-oxygen, water. This is home to special microbial communities that convert nitrate into nitrous oxide to generate energy. Frey has therefore taken a closer look at the processes that take place in these zones.
The researcher spent six weeks on a research vessel along the coasts of California and Mexico. This is where the largest hypoxic areas of the Pacific are located. She collected hundreds of water samples at different depths and carried out some analyses and experiments while still on board. “Since time on the boat is so precious, we practically worked day and night,” she recalls. In order to preserve the samples in their original condition, they had to be examined without oxygen and in cold rooms – all while the vessel was moving through tropical waters.
Bacterial metabolism works differently than expected
The investigations yielded several surprising results. Until now, it had been assumed that the conversion of nitrate into nitrous oxide only worked at extremely low oxygen concentrations. In her water samples, however, Frey was able to provide proof that the microbes can also do this at much higher oxygen concentrations – namely when a lot of organic material is present in the hypoxic zones in the form of small dead algae, for example.
Another unexpected finding: the bacteria always preferred to go through the entire multi-stage metabolic pathway from nitrate to nitrous oxide. Research had previously thought that the bacteria would switch to a shorter pathway if an intermediate product required for this was provided in the water. The assumption was that the shortcut required less energy. The experiments showed that this is not true.
Frey used the new findings to close gaps in a model for the ecosystem in hypoxic zones. This now takes into account, for example, that the presence of organic material increases the oxygen tolerance of the bacteria. This also increases the number of regions in which nitrous oxide production is possible.
“When it comes to climate predictions, it is crucial to understand what happens in these peripheral zones,” says Frey. Especially as people continue to add more and more nitrogen to water bodies. “What happens in the oceans is relevant to us, because they cover two-thirds of our planet.”
Dr. Claudia Frey, University of Basel, Department of Environmental Sciences, tel. +41 61 207 35 96, email: claudia.frey@unibas.ch
Xin Sun, Claudia Frey, Daniel McCoy, Matthias B. A. Spieler, Colette L. Kelly, Ashley E. Maloney, Emilio Garcia-Robledo, Moritz F. Lehmann, Bess B. Ward & Emily J. Zakem
Mechanistic understanding of nitrate reduction as the dominant production pathway of nitrous oxide in marine oxygen minimum zones
Nature Communications (2025), doi: 10.1038/s41467-025-63989-9
https://doi.org/10.1038/s41467-025-63989-9
To investigate the conversion of nitrate into nitrous oxide in the ocean, hundreds of water samples ...
Source: Claudia Frey
Copyright: Claudia Frey
While still on board, biogeochemist Dr. Claudia Frey carried out analyses and experiments. A nitroge ...
Source: Xin Sun
Copyright: Xin Sun
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