Multi-omics uncovers nutrient stress-driven interactions in the Prymnesium parvum holobiont, with vitamin B12 limitation highlighting mutualism
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CC-BY-NC-ND-4.0
Abstract
Microalgal-bacterial interactions are central to nutrient cycling and ecosystem functioning in marine habitats, yet the mechanisms structuring these associations under defined nutrient constraints remain poorly resolved. Using a synthetic 15-member bacterial community (SynCom) and controlled nitrogen (N), phosphorus (P), and vitamin B12 limitation, we investigated how nutrient scarcity shapes the physiology, metabolism, and transcriptional activity of the harmful alga Prymnesium parvum and its associated microbiota. Under N- and P-limitation, the SynCom had minimal impact on algal growth despite nutrient-dependent shifts in toxin production and metabolite profiles. In contrast, B12-limitation triggered a strong mutualistic interaction in which the SynCom enabled a three-fold increase in algal biomass and drove restructuring of intracellular and extracellular metabolomes, including the accumulation of ectoine and membrane-associated lipids and the depletion of thiamine-like and stress-associated metabolites. Metabarcoding revealed stable community composition but enrichment of B12-producing taxa under B12-limited conditions, while metatranscriptomics uncovered functional divergence among SynCom members. Bacteria segregated into specialized B12- or N-responsive strains and metabolically plastic generalists sustaining broad transcriptional activity across all nutrient regimes. B12 producers ( Marinovum algicola , Roseobacter sp., Halomonas sp.) upregulated cobalamin biosynthesis exclusively under B12 limitation, whereas several dependent taxa induced B12 transport and B12-requiring enzymes, indicating active vitamin exchange within the holobiont. P. parvum displayed nutrient-specific transcriptional programs, with B12-limited co-cultures shifting toward growth-associated gene expression despite constitutive expression of the B12-dependent metH gene. These results demonstrate that vitamin auxotrophy acts as a key metabolic lever reorganizing holobiont function, driving reciprocal benefits and reprogramming algal-bacterial metabolism in our synthetic system.
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- europepmc
- last seen: 2026-05-20T01:45:00.602351+00:00
- unpaywall
- last seen: 2026-05-27T02:00:06.600101+00:00
License: CC-BY-NC-ND-4.0