Host selection and stochastic effects influence bacterial community assembly on the microalgal phycosphere

Microalgae have major functions in global biogeochemical cycles and are promising sources of renewable energy, yet the relationships between algal hosts and their associated microbiomes remain relatively underexplored. Understanding community organization of microalgal microbiomes, such as how algal species identity influences bacterial community structure, will aid in efforts to engineer more efficient phototrophic ecosystems. Here, we examined the community assembly of phycosphere-associated (attached) and free-living bacterial taxa associated with two marine microalgae: the diatom Phaeodactylum tricornutum and eustigmatophyte Microchloropsis salina. Samples were collected from outdoor mesocosms, raceway ponds, and laboratory enrichments, and bacterial taxa identified by 16S rRNA gene sequences. In outdoor mesocosms, we found distinct bacterial taxa associated with each algal species, including the Cytophagaceae and Rhodobacteraceae families with P. tricornutum, and Rhodobacteraceae, Hyphomonadaceae, and Saprospiraceae with M. salina. Additionally, there were host-specific differences in the bacterial genera associated with the phycosphere, including Novosphingobium and Rhodopirellula with P. tricornutum, and Methylophaga and Dyadobacter with M. salina. Bacterial communities from outdoor monoalgal P. tricornutum and polyalgal P. tricornutum/M. salina samples were used as inocula for laboratory enrichments with axenic P. tricornutum. Here, similar bacterial communities emerged, suggesting that the algal host exerts substantial influence over bacterial community assembly. Further enrichments for phycosphere-association revealed differing outcomes of community assembly processes contingent on the initial community composition. Phycosphere-associated communities from monoalgal P. tricornutum mesocosms were highly similar to one another, suggesting deterministic processes, whereas cultures from mixed M. salina/P. tricornutum raceways followed two apparent paths differentiated by the stochastic loss of specific community members and convergence towards or further deviation from the monoalgal samples. These results demonstrate that algal-associated bacterial communities are controlled by algal host, culture conditions, and the initial inoculum composition of the algal microbiome, and this knowledge can inform the engineering of more productive algal systems.