https://phys.org/news/2024-06-discovery-reveals-ocean-algae-unexpectedly.html
*By University of East Anglia* *11 June 2024* A common type of ocean algae plays a significant role in producing a massively abundant compound that helps cool the Earth's climate, new research has discovered. The findings of the study by the University of East Anglia (UEA) and Ocean University of China (OUC) could change our understanding of how these tiny marine organisms impact our planet. The work appears in Nature Microbiology. The team identified the bloom-forming Pelagophyceae algae as potentially abundant and important producers of a compound called dimethylsulfoniopropionate, or DMSP. Co-lead author Professor Jonathan Todd, of UEA's School of Biological Sciences, said, "The Pelagophyceae are among the most abundant algae on Earth, yet they were not previously known as important producers of DMSP. This discovery is exciting because DMSP is an abundant antistress compound, food source for other microorganisms and major source of climate-cooling gases." Dr. Jinyan Wang, OUC/UEA Ph.D. student and first author, said, "Understanding the role of Pelagophyceae in DMSP production means we need to rethink how much of this compound is being produced and how it impacts our climate." Every year, billions of tons of DMSP are produced in the Earth's oceans by marine microorganisms, helping them to survive by protecting against various stresses like changes in salinity, cold, high pressure, and oxidative stress. Importantly, DMSP is the main source of a climate active gas called dimethylsulfide (DMS), which is known as the smell of the seaside. This study suggests that DMSP production, and consequently DMS release, is likely higher than previously predicted and emphasizes the key role of microbes in regulating global climate. DMS also acts as a signaling molecule, guiding marine organisms to their food and deterring predators. When DMS is released into the atmosphere, DMS oxidation products help form clouds which reflect sunlight away from the Earth, effectively cooling the planet. This natural process <https://phys.org/tags/natural+process/> is essential for regulating the Earth's climate and is also hugely important for the global sulfur cycle, representing the main route by which sulfur from the oceans is returned to land. UEA and OUC established the Sino-UK Joint Research Centre to promote cutting-edge research and teaching in marine and ocean science. UEA's Dr. Andrew Curson was a key member of the team that identified the novel enzymes responsible for the synthesis of DMSP in diverse bacteria, photosynthetic cyanobacteria and algae. Dr. Curson said, "The identity of these enzymes allowed our team to identify Pelagophyceae as potentially abundant and important DMSP producers." Co-lead author Professor Xiao-Hua Zhang, of OUC's College of Marine Life Science, added, "By identifying the enzymes involved in DMSP production, scientists can better understand and predict the behavior of these ecosystem-disruptive, brown-tide-forming algae and their impact on global climate change. This study has also raised questions about other unidentified versions of the enzymes needed to make DMSP, or entirely different pathways for making it that are currently unknown." The researchers say further study of Pelagophyceae algae in their natural environment is needed, as well as more detailed studies <https://phys.org/tags/detailed+studies/> on other marine organisms. Better measurements of environmental DMSP levels, production and breakdown rates, and the abundance of the enzymes involved in making DMSP are also critical to further advance the field. The research was a collaboration between UEA and OUC, with contributions from Qingdao Agricultural University, the University of Porto, Shandong University and the Laoshan Laboratory in Qingdao, China. *Source: Phys.Org* *_____________________________________________* *RESEARCH PAPER—Alternative dimethylsulfoniopropionate biosynthesis enzymes in diverse and abundant microorganisms* *Authors* Jinyan Wang, Andrew R. J. Curson, Shun Zhou, Ornella Carrión, Ji Liu, Ana R. Vieira, Keanu S. Walsham, Serena Monaco, Chun-Yang Li, Qing-Yu Dong, Yu Wang, Peter Paolo L. Rivera, Xiao-Di Wang, Min Zhang, Libby Hanwell, Matthew Wallace, Xiao-Yu Zhu, Pedro N. Leão, David J. Lea-Smith, Yu-Zhong Zhang, Xiao-Hua Zhang & Jonathan D. Todd *11 June 2024* *Abstract* Dimethylsulfoniopropionate (DMSP) is an abundant marine organosulfur compound with roles in stress protection, chemotaxis, nutrient and sulfur cycling and climate regulation. Here we report the discovery of a bifunctional DMSP biosynthesis enzyme, DsyGD, in the transamination pathway of the rhizobacterium Gynuella sunshinyii and some filamentous cyanobacteria not previously known to produce DMSP. DsyGD produces DMSP through its N-terminal DsyG methylthiohydroxybutyrate S-methyltransferase and C-terminal DsyD dimethylsulfoniohydroxybutyrate decarboxylase domains. Phylogenetically distinct DsyG-like proteins, termed DSYE, with methylthiohydroxybutyrate S-methyltransferase activity were found in diverse and environmentally abundant algae, comprising a mix of low, high and previously unknown DMSP producers. Algae containing DSYE, particularly bloom-forming Pelagophyceae species, were globally more abundant DMSP producers than those with previously described DMSP synthesis genes. This work greatly increases the number and diversity of predicted DMSP-producing organisms and highlights the importance of Pelagophyceae and other DSYE-containing algae in global DMSP production and sulfur cycling*.* Overview of key DMSP biosynthesis enzymes and pathways and their environmental importance. [image: figure 4] <https://www.nature.com/articles/s41564-024-01715-9/figures/4> *Source: Nature Microbiology * -- You received this message because you are subscribed to the Google Groups "geoengineering" group. To unsubscribe from this group and stop receiving emails from it, send an email to [email protected]. To view this discussion on the web visit https://groups.google.com/d/msgid/geoengineering/CAHJsh9_KtZfFdcT4URXJvA7iXPAgCtpiOxW1%2BS1p-xNAHrgfxQ%40mail.gmail.com.
