Interspecies interactions determine growth dynamics of biopolymer degrading populations in microbial communities

Abstract Microbial communities perform essential ecosystem functions such as the remineralization of organic carbon that exists as biopolymers. The first step in mineralization is performed by biopolymer degraders, which harbor enzymes that can break down polymers into constituent oligo- or monomeric forms. The released nutrients not only allow degraders to grow, but also promote growth of cells that either consume the breakdown products, i.e., exploiters, or consume metabolites released by the degraders, i.e., scavengers. It is currently not clear how such remineralizing communities assemble at the microscale – how interactions between the different guilds influence their growth and spatial distribution, and hence the development and dynamics of the community. Here we address this knowledge gap by studying marine microbial communities that grow on the abundant marine biopolymer alginate. We used batch growth assays and microfluidics coupled to time-lapse microscopy to quantitatively investigate growth and spatial distribution of single cells. We found that the presence of exploiters or scavengers alters the spatial distribution of degrader cells. In general, exploiters and scavengers – which we collectively refer to as consumer cells – slowed down the growth of degrader cells. In addition, coexistence with consumers altered the production of the extracellular enzymes that breakdown polymers by degrader cells. Our findings reveal that ecological interactions by non-degrading community members have a profound impact on the functions of microbial communities that remineralize carbon biopolymers in nature. Importance Biopolymers are the most abundant source of carbon on the planet and their breakdown by microbial degraders releases metabolic products that allow cross-feeding cells to grow and fuel the assembly of microbial communities. While it is known that the growth of degraders can facilitate growth of downstream cross-feeders in microbial communities, it has remained generally unclear if and how cross-feeders influence growth of degraders. Bridging this knowledge gap is important because degraders primarily drive the remineralization of carbon, a central process in the carbon cycle. We found that the presence cross-feeders can influence the growth of degraders by altering their spatial distribution as well as extracellular breakdown enzyme activity. Our study sheds light on the role of microbial interactions in shaping the rate of carbon remineralization in nature.