Planktonic and Sessile Artificial Colonic Microbiota Harbor Distinct Composition and Reestablish Differently upon Frozen and Freeze-Dried Long-Term Storage

Biofilm-associated, sessile communities represent the major bacterial lifestyle, whereas planktonic cells mainly appear during initial colonization of new surfaces. Previous research, mainly performed with pathogens, demonstrated increased environmental stress tolerance of biofilm-growing compared to planktonic bacteria. The lifestyle-specific stress response of colonic microbiota, both natural and fermentation produced, has not been addressed before. Planktonic and sessile “artificial” colonic microbiota delivered by PolyFermS continuous fermentation models can provide a controllable and reproducible alternative to fecal transplantation in treating gastrointestinal disorders. We therefore characterized planktonic and sessile microbiota produced in two PolyFermS models inoculated with immobilized fecal microbiota and comparatively tested their levels of tolerance of frozen storage (–80°C) and freeze-dried storage (4°C) for 9 months to mimic preservation strategies for therapeutic applications. Sessile microbiota harbored next to shared taxa a unique community distinguishable from planktonic microbiota. Synergistetes and Proteobacteria were highly represented in sessile microbiota, while Firmicutes were more abundant in planktonic microbiota. The community structure and metabolic activity of both microbiota, monitored during standardized reactivation batch fermentations, were better preserved after frozen storage than dried storage, indicated by higher Bray-Curtis similarity and enhanced recovery of metabolite production. For both lifestyles, reestablishment of Bacteroidaceae was impaired after frozen and dried storage along with reduced propionate formation. In contrast, butyrate production was maintained after reactivation despite compositional rearrangements within the butyrate-producing community. Unexpectedly, the rate of recovery of metabolite production was lower after preservation of sessile than planktonic microbiota. We speculate that higher functional dependencies between microbes might have led to the lower stress tolerance of sessile than planktonic microbiota. IMPORTANCE Fecal microbiota transplantation has been successfully applied in the treatment of recurrent Clostridium difficile infection and has been suggested as an alternative therapy for other intestinal disorders such as inflammatory bowel disease or metabolic syndrome. “Artificial” colonic microbiota delivered by PolyFermS continuous fermentation models can provide a controllable and reproducible alternative to fecal transplantation, but effective preservation strategies must be developed. In this study, we systematically investigated the response of sessile and planktonic artificial colonic microbiota to cryopreservation and lyophilization. We suggest that functional redundancy is an important factor in providing functional stability with respect to exposure to stress during processing and storage. Functional redundancy in compositionally reduced microbial systems may be considered when designing microbial products for therapy.