In anaerobic reactors the microbial community structure depends on feed type, with no "keystone" species tied to COD removal

Olutooni Ajayi¹William A Arnold¹Natasha Wright¹Jeremy S Guest²Paige J. Novak^1*

• ¹University of Minnesota Twin Cities, St. Paul, United States
• ²University of Illinois at Urbana-Champaign, Champaign, Illinois, United States

Two-stage anaerobic digestion (AD) systems provide treatment for high strength wastewater with high stability and performance. Encapsulation technology can intensify AD to facilitate the separation of the solids retention time from the hydraulic retention time (HRT), offering lower HRTs, smaller reactors, and high effluent quality. To support successful deployment, however, the encapsulated community must contain all the needed microorganisms for successful treatment and be flexible enough to treat a variety of wastewaters. Here, a two-stage system was investigated in which microbial cultures were enriched on various high-strength wastewaters in suspended flow-through systems to determine how feed type influenced performance and microbial community structure. The hypothesis was that specific genera, or so-called "keystone species" would positively correlate to organic carbon degradation for a given feed, enabling construction of a well-functioning community for encapsulation. Results showed that the number of total bacteria (as 16S rRNA gene copies) did not correlate to soluble chemical oxygen demand (sCOD) removal, indicating that the community structure and/or members were important for good performance. Results also showed that feed type strongly influenced carbon removal and microbial community structure for 1st-stage fermenting communities, but not 2nd-stage methanogenic communities. In this study, the "core" community members were defined as organisms common to all of either the 1st-or 2nd-stage reactors irrespective of the feed they received and were present in at least 50% of the samples throughout the entire experiment. "Unique" community members were specific to a single feed, and hence, only present in either the 1st-or 2nd-stage reactors receiving that feed. In both 1st-and 2nd-stage communities, only one core genera and no unique genera were positively and significantly correlated to sCOD removal. Verification experiments performed with encapsulated communities showed that organisms identified in flow-through system and correlated with carbon degradation, though not significantly, seemed to be important for performance. Our results suggest that one cannot construct a community containing specific populations in lieu of enrichment. Nevertheless, a single diverse encapsulated anaerobic community should provide good (>80%) carbon removal when fed a variety of influents, if time is provided for enrichment after deployment.