Your search keyword '"Metabolic interactions"' showing total 4 results

1. Simple Porifera holobiont reveals complex interactions between the host, an archaeon, a bacterium, and a phage.

Author

Garritano AN, Zhang Z, Jia Y, Allen MA, Hill LJ, Kuzhiumparambil U, Hinkley C, Raina JB, Peixoto RS, and Thomas T

Subjects

Animals, Ammonia metabolism, Microbiota, Phylogeny, Vitamin B 12 metabolism, Symbiosis, Archaea metabolism, Archaea genetics, Bacteriophages physiology, Bacteriophages genetics, Porifera microbiology, Bacteria metabolism, Bacteria genetics, Bacteria classification

Abstract

The basal metazoan phylum Porifera (sponges) is increasingly used as a model to investigate ecological and evolutionary features of microbe-animal symbioses. However, sponges often host complex microbiomes, which has hampered our understanding of their interactions with their microbial symbionts. Here, we describe the discovery and characterization of the simplest sponge holobiont reported to date, consisting of the deep-sea glass sponge Aphrocallistes beatrix and two newly-described microbial symbionts: an autotrophic ammonia-oxidizing archaeon and a bacterial heterotroph. Omics analyses and metabolic modeling revealed the dependency of the ammonia-oxidizing archaea on sponge-derived ammonia to drive primary production, which in turn supports the bacterium's growth by providing the dicarboxylate fumarate. Furthermore, virus-mediated archaeal lysis appears crucial to overcome the bacterium's vitamin B12 auxotrophy. These findings reveal that the exchanges of vitamin B12 and dicarboxylate may be evolutionarily conserved features of symbiosis as they can also be found in interactions between free-living marine bacteria, and between microbes and plants or diatoms., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

2. Ammonia leakage can underpin nitrogen-sharing among soil microorganisms.

Author

Richards L, Cremin K, Coates M, Vigor F, Schäfer P, and Soyer OS

Subjects

Soil chemistry, Microbial Interactions, Hydrogen-Ion Concentration, Ammonium Compounds metabolism, Ammonia metabolism, Soil Microbiology, Nitrogen metabolism, Nitrates metabolism, Bacillus subtilis metabolism, Bacillus subtilis growth & development, Bacillus subtilis genetics

Abstract

Soil microbial communities host a large number of microbial species that support important ecological functions such as biogeochemical cycling and plant nutrition. The extent and stability of these functions are affected by inter-species interactions among soil microorganisms, yet the different mechanisms underpinning microbial interactions in the soil are not fully understood. Here, we study the extent of nutrient-based interactions among two model, plant-supporting soil microorganisms, the fungi Serendipita indica, and the bacteria Bacillus subtilis. We found that S. indica is unable to grow with nitrate - a common nitrogen source in the soil - but this inability could be rescued, and growth restored in the presence of B. subtilis. We demonstrate that this effect is due to B. subtilis utilising nitrate and releasing ammonia, which can be used by S. indica. We refer to this type of mechanism as ammonia mediated nitrogen sharing (N-sharing). Using a mathematical model, we demonstrated that the pH dependent equilibrium between ammonia (NH3) and ammonium (NH+4) results in an inherent cellular leakiness, and that reduced amonnium uptake or assimilation rates could result in higher levels of leaked ammonia. In line with this model, a mutant B. subtilis - devoid of ammonia uptake - showed higher S. indica growth support in nitrate media. These findings highlight that ammonia based N-sharing can be a previously under-appreciated mechanism underpinning interaction among soil microorganisms and could be influenced by microbial or abiotic alteration of pH in microenvironments., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

3. Bacterial growth and environmental adaptation via thiamine biosynthesis and thiamine-mediated metabolic interactions.

Author

Xu X, Li C, Cao W, Yan L, Cao L, Han Q, Gao M, Chen Y, Shen Z, Jiang J, and Chen C

Subjects

Adaptation, Physiological, Aerobiosis, Biosynthetic Pathways, Genome, Bacterial, Anaerobiosis, Thiamine biosynthesis, Thiamine metabolism, Soil Microbiology, Bacteria metabolism, Bacteria genetics, Bacteria classification, Phylogeny

Abstract

Understanding the ancestral transition from anaerobic to aerobic lifestyles is essential for comprehending life's early evolution. However, the biological adaptations occurring during this crucial transition remain largely unexplored. Thiamine is an important cofactor involved in central carbon metabolism and aerobic respiration. Here, we explored the phylogenetic and global distribution of thiamine-auxotrophic and thiamine-prototrophic bacteria based on the thiamine biosynthetic pathway in 154 838 bacterial genomes. We observed strong coincidences of the origin of thiamine-synthetic bacteria with the "Great Oxygenation Event," indicating that thiamine biosynthesis in bacteria emerged as an adaptation to aerobic respiration. Furthermore, we demonstrated that thiamine-mediated metabolic interactions are fundamental factors influencing the assembly and diversity of bacterial communities by a global survey across 4245 soil samples. Through our newly established stable isotope probing-metabolic modeling method, we uncovered the active utilization of thiamine-mediated metabolic interactions by bacterial communities in response to changing environments, thus revealing an environmental adaptation strategy employed by bacteria at the community level. Our study demonstrates the widespread thiamine-mediated metabolic interactions in bacterial communities and their crucial roles in setting the stage for an evolutionary transition from anaerobic to aerobic lifestyles and subsequent environmental adaptation. These findings provide new insights into early bacterial evolution and their subsequent growth and adaptations to environments., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

4. Phylogenetic distribution and experimental characterization of corrinoid production and dependence in soil bacterial isolates.

Author

Alvarez-Aponte ZI, Govindaraju AM, Hallberg ZF, Nicolas AM, Green MA, Mok KC, Fonseca-García C, Coleman-Derr D, Brodie EL, Carlson HK, and Taga ME

Subjects

Microbiota, Soil chemistry, Vitamin B 12 metabolism, RNA, Ribosomal, 16S genetics, Soil Microbiology, Phylogeny, Bacteria genetics, Bacteria classification, Bacteria metabolism, Bacteria isolation & purification, Corrinoids metabolism

Abstract

Soil microbial communities impact carbon sequestration and release, biogeochemical cycling, and agricultural yields. These global effects rely on metabolic interactions that modulate community composition and function. However, the physicochemical and taxonomic complexity of soil and the scarcity of available isolates for phenotypic testing are significant barriers to studying soil microbial interactions. Corrinoids-the vitamin B12 family of cofactors-are critical for microbial metabolism, yet they are synthesized by only a subset of microbiome members. Here, we evaluated corrinoid production and dependence in soil bacteria as a model to investigate the ecological roles of microorganisms involved in metabolic interactions. We isolated and characterized a taxonomically diverse collection of 161 soil bacteria from a single study site. Most corrinoid-dependent bacteria in the collection prefer B12 over other corrinoids, while all tested producers synthesize B12, indicating metabolic compatibility between producers and dependents in the collection. Furthermore, a subset of producers release B12 at levels sufficient to support dependent isolates in laboratory culture at estimated ratios of up to 1000 dependents per producer. Within our isolate collection, we did not find strong phylogenetic patterns in corrinoid production or dependence. Upon investigating trends in the phylogenetic dispersion of corrinoid metabolism categories across sequenced bacteria from various environments, we found that these traits are conserved in 47 out of 85 genera. Together, these phenotypic and genomic results provide evidence for corrinoid-based metabolic interactions among bacteria and provide a framework for the study of nutrient-sharing ecological interactions in microbial communities., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024