New insights into the degradation dynamics of organic material in the seafloor

For their study, the team fed organic material labeled with ¹³C carbon -- either an algae-lipid mix or crude proteins -- and observed it in the laboratory for 400 days. The microbial communities originate from a sediment core obtained off Helgoland. The initial question was: What happens to fresh biomass and which microorganisms are involved in its processing? This was the first time that the formation of new biomass from secondary producers and its turnover was quantified more precisely.

The team has found that microbial communities can be stimulated by the addition of lipids and proteins and not only decompose fresh biomass that is easier to digest, but also decompose more of the old organic carbon that is otherwise difficult to break down. This new finding is relevant because the input of fresh organic matter is increased by human-made, climate-induced environmental changes, such as expanding low oxygen zones in the ocean, melting sea ice or glacier retreat.

"Our study is the first to link the degradation of labile organic matter to the growth of microbes and the consequences for the composition of the organic matter that is eventually buried in marine sediment. We were surprised to find that the addition of fresh organic matter had a disproportionately large and long-lasting effect on the degradation of old, supposed to be refractory organic matter," says Prof Jack Middelburg from Utrecht University (Netherlands), co-author of the study and Professor of Excellence in the Cluster of Excellence "The Ocean Floor -- Earth's Unexplored Interface" at MARUM. As part of this cluster's research, the study has provided crucial insights into the link between organic matter deposition events and the long-term preservation of organic carbon and thus connects the research units Receiver, Reactor and Recorder.

The input of fresh organic matter into the seafloor could increase due to climate-related changes in the environment. These will not only have a direct impact on the microorganisms living on and in the ocean floor, but also on the carbon cycle and thus on the feedback with the climate system in a way that is still largely unexplored.

MARUM produces fundamental scientific knowledge about the role of the ocean and the seafloor in the total Earth system. The dynamics of the oceans and the seabed significantly impact the entire Earth system through the interaction of geological, physical, biological and chemical processes. These influence both the climate and the global carbon cycle, resulting in the creation of unique biological systems. MARUM is committed to fundamental and unbiased research in the interests of society, the marine environment, and in accordance with the sustainability goals of the United Nations. It publishes its quality-assured scientific data to make it publicly available. MARUM informs the public about new discoveries in the marine environment and provides practical knowledge through its dialogue with society. MARUM cooperation with companies and industrial partners is carried out in accordance with its goal of protecting the marine environment.