Abstract
Background In this study, individual anaerobic granular biofilms were used as true community replicates to assess whole-microbial-community responses to environmental cues. The aggregates originated from three different biomass sources, i.e. three different engineered biological wastewater treatment systems, were each size-separated into three fractions – small, medium and large – and characterised according to organic matter concentrations and rates of methanogenic activity. Differences in the microbial community structure of each size fraction from each source were determined using 16S rRNA gene sequencing. Subsequently, single granules from the large size fraction of one of the sources were separately subjected controlled environmental cues in novel micro batch reactors (mBRs). Results Organic content, methanogenic activity, and microbial community were significantly different between the three size fractions, with diversity trajectories replicated across the three sludge sources – indicating a potential development model as granules age. Individual large granules from one of these sources were statistically identical with respect to the structure of the active community based on cDNA analysis. It was observed that the active microbial community of individual granules, at the depth of 16S rRNA sequencing, produced reproducible responses to environmental conditions. While each condition resulted in the up-regulation of particular OTUs and clades, the core microbiome, consisting of many fermentative bacteria along with methanogenic archaea, namely, Methanosarcina and Methanobacterium , persisted. Conclusions At this level, single anaerobic granules can be considered highly-replicated whole-ecosystems, opening the door to high-throughput studies in Microbial Ecology.
Bioenergetic Aspects of Halophilism
