Micro-scale ecology regulates particulate organic matter turnover in model marine microbial communities

• Published in: bioRxiv
• Main Authors: Enke, Tim N, Leventhal, Gabriel E, Metzger, Matthew, Saavedra, Jose T, Cordero, Otto X
• Format: Paper
• Language: English
• Published: Cold Spring Harbor Cold Spring Harbor Laboratory Press 01.01.2018
• Subjects: Bacteria; Biodegradation; Carbon cycle; Chitin; Colonization; Community composition; Organic matter; Particulate organic matter
• DOI: 10.1101/241620

The degradation of particulate organic matter in the ocean is a central process in the global carbon cycle, the "mode and tempo" of which is determined by the bacterial communities that assemble on particle surfaces. Although recent studies have shed light on the dynamics of community assembly on particles -which serve as hotspots of microbial activity in the ocean, the mapping from community composition to function, i.e. particle degradation, remains completely unexplored. Using a collection of marine bacteria cultured from different stages of succession on chitin micro-particles we found that the hydrolytic power of communities is highly dependent on community composition. Different particle degrading taxa, all of which were early successional species during colonization, displayed characteristic particle half-lives that differed by ~170 hours, comparable to the residence time of particles in the ocean's mixed layer. These half-lives were in general longer in multispecies communities, where the growth of obligate cross-feeders limited the ability of degraders to colonize and consume particles. Remarkably, above a certain critical initial ratio of cross-feeder to degrader cells, particle degradation was completely blocked along with the growth of all members of the community. We showed that this interaction occurred between a variety of strains of different taxonomic origins and that it only appears when bacteria interact with particles, suggesting a mechanism by which non-degrading secondary consumers occlude access to the particle resource. Overall, our results show that micro-scale community ecology on particle surfaces can have significant impact on carbon turnover in the ocean.