Polysaccharide breakdown by bacteria requires the activity of enzymes that degrade polymers either intra- or extra-cellularly. The latter mechanism generates a localized pool of breakdown products that are accessible to the enzyme producers themselves as well as to other organisms. Marine bacterial taxa often show marked differences in the production and secretion of degradative enzymes that break down polysaccharides. These differences can have profound effects on the pool of diffusible breakdown products and hence on the ecological dynamics. However, the consequences of differences in enzymatic secretions on cellular growth dynamics and interactions are unclear. Here we study growth dynamics of single cells within populations of marine Vibrionaceae strains that grow on the abundant marine polymer alginate, using microfluidics coupled to quantitative single-cell analysis and mathematical modelling. We find that strains that have low extracellular secretions of alginate lyases aggregate more strongly than strains that secrete high levels of enzymes. One plausible reason for this observation is that low secretors require a higher cellular density to achieve maximal growth rates in comparison with high secretors. Our findings indicate that increased aggregation increases intercellular synergy amongst cells of low-secreting strains. By mathematically modelling the impact of the level of degradative enzyme secretion on the rate of diffusive oligomer loss, we find that enzymatic secretion capability modulates the propensity of cells within clonal populations to cooperate or compete with each other. Our experiments and models demonstrate that enzymatic secretion capabilities can be linked with the propensity of cell aggregation in marine bacteria that extracellularly catabolize polysaccharides.
Microbial breakdown of carbon polymers is an essential process in all ecosystems. Carbon polymers generally require extracellular breakdown by secreted exoenzymes. Exoenzymes and breakdown products can be lost through diffusion or flow. This diffusional loss is reduced when bacteria grow in surface-associated populations where they benefit from each other's metabolic activities. The aquatic organism Caulobacter crescentus was recently shown to form clonal microcolonies on the carbon polymer xylan, but to grow solitary on the monosaccharide xylose. The underlying mechanisms of this substrate-mediated microcolony formation are unknown. In particular, the importance of extracellular appendages such as pili, adhesive holdfast, and flagellum in governing the spatial arrangement of surface-grown cells is unclear. Using microfluidics coupled to automated time-lapse microscopy and quantitative image analysis, we compared the temporal and spatial dynamics of C. crescentus wildtype and mutant strains grown on xylan, xylose, or glucose. We found that mutants lacking type IV pili or holdfast showed altered spatial patterns in microcolonies and were unable to maintain cell densities above a threshold required for maximal growth rates on the xylan polymer, whereas mutants lacking flagella showed increased cell densities that potentially lead to increased local competition. Our results demonstrate that extracellular appendages allow bacteria to reach local cell densities that maximize single-cell growth rates in response to their nutrient environment.
Polysaccharide breakdown by bacteria requires the activity of enzymes that degrade polymers extracellularly. This generates a localized pool of breakdown products that are accessible to the enzyme producers themselves as well as to other organisms. Marine bacterial taxa often show marked differences in the production and secretion of degradative enzymes that break down polysaccharides. These differences can have profound effects on the pool of diffusible breakdown products and hence on the ecological dynamics. However, the consequences of differences in enzymatic secretions on cellular growth dynamics and interactions are unclear. Here we combine experiments and models to study the growth dynamics of single cells within populations of marine Vibrionaceae strains that grow on the abundant marine polymer alginate, using microfluidics coupled to quantitative single-cell analysis and mathematical modelling. We find that strains that have low extracellular secretions of alginate lyases show stronger aggregative behaviors compared to strains that secrete high levels of enzymes. One plausible reason for this observation is that low secretors require a higher cellular density to achieve maximal growth rates in comparison with high secretors. Our findings indicate that increased aggregation increases intercellular synergy amongst cells of low-secreting strains. By mathematically modelling the impact of the level of degradative enzyme secretion on the rate of oligomer loss to diffusion, we find that enzymatic capability modulates the propensity of cells within clonal populations to cooperate or compete with each other. Our experiments and models demonstrate that marine bacteria display distinct aggregative behaviors and intercellular interactions based on their enzymatic secretion capabilities when growing on polysaccharides.
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