Communities of microbes (microbiomes), particularly in soils, can be startlingly diverse, with as many as 10,000 species in just a cup of material. Scientists are working to understand how microbiomes and their members respond to their environments. These processes can profoundly shape the properties and composition of soils.
In a pair of studies published in The ISME Journal, researchers investigated how different species of microbes interact with one another and exchange resources such as vitamins. The studies focused on corrinoids, the vitamin B12 family of nutrients. Many bacteria in the environment cannot produce these chemicals.
Focusing on a single type of nutrient enables the study of microbiomes in greater detail. The two studies further synergized by focusing on the same California grassland soil, allowing the researchers to generate a framework for understanding nutrient cycling in this system.
The first study focused on the impact of corrinoids on individual bacteria. The researchers isolated more than 100 soil bacteria, 37 of which were novel species, and tested whether they could produce corrinoids or would need to rely on others to supply corrinoids.
Of these bacteria, 60% produced corrinoids, but only a few released them from the cell when cultured in the laboratory. The finding suggests that corrinoid-releasing organisms might supply these critical nutrients to other microbiome community members and have a large impact on shaping microbiome assembly and activity in the environment.
The second study investigated corrinoids in soils. Chemical analysis revealed that soils contain corrinoids at levels that exceed those required for maximal microbial growth, though most are tightly bound to the soil matrix. The study further demonstrated that adding different corrinoids to soil can transiently alter the soil microbiome. This suggests that corrinoids may offer an opportunity to influence the structure and behavior of complex microbiomes in engineered and environmental systems.
The Earth’s soils are critically important to maintaining ecosystem health through their ability to store organic matter, cycle nutrients, hold and filter water, and provide physical support and nutrients for plants. Microbes play an important role in these and other soil properties. This means that the ability to manipulate microbiome behavior may offer ways to improve what soils contribute.
These two studies demonstrated that the presence of corrinoids can influence how individual soil bacteria grow in the laboratory and how they survive and coexist in soil. These observations open the door to developing new ways to manipulate microbiomes to promote soil health.
More information:
Zoila I Alvarez-Aponte et al, Phylogenetic distribution and experimental characterization of corrinoid production and dependence in soil bacterial isolates, The ISME Journal (2024). DOI: 10.1093/ismejo/wrae068 Zachary F
Hallberg et al, Soil microbial community response to corrinoids is shaped by a natural reservoir of vitamin B12, The ISME Journal (2024). DOI: 10.1093/ismejo/wrae094
Citation:
Nutrients related to vitamin B12 influence microbial growth and reshape soil microbiomes, research finds (2024, December 2)
retrieved 3 December 2024
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