Discovery and metagenomic analysis of an anammox bacterial enrichment related to Candidatus "Brocadia caroliniensis" in a full-scale glycerol-fed nitritation-denitritation separate centrate treatment process.

A distinctive red biofilm was observed in a glycerol-fed digester liquid effluent treatment process coupling partial nitrification (nitritation) and partial denitrification (denitritation) processes. Based on initial phylogenetic screening using 16S rRNA clone libraries and quantitative polymerase chain reaction, the biofilm was enriched in novel anaerobic ammonium oxidizing bacteria (AMX/anammox) closely related to Candidatus "Brocadia caroliniensis". The metabolic functionality of the C. "Brocadia caroliniensis" enrichment was further explored using high-throughput sequencing and de novo metagenome assembly. The population anammox genome that was binned from the metagenome consisted of 209 contigs with a total of 3.73 Mbp consensus sequences having 43.3% GC content, and 27.4 average coverage depth. The assembled metagenome bin was comprised of 3582 open reading frames (ORFs). Based on 16S rRNA similarity the binned metagenome was closely related with Candidatus "Brocadia caroliniensis", Candidatus "Brocadia fulgida", planctomycete KSU-1, and Candidatus "Kuenenia stuttgartiensis" with 99%, 96%, 92% and 93% similarity, respectively. Essential genes in anammox metabolic functions including ammonium and nitrite transport, hydrazine synthesis, electron transfer for catabolism, and inorganic carbon fixation, among several other anabolic pathways, were also observed in the population genome of the C. "Brocadia caroliniensis" related enrichment. Our results demonstrate the wider profusion of anammox bacteria in engineered nitrogen removal systems than expected. The utility of metagenomics approaches to deciphering such novel functionality in these systems is also highlighted.

Factors controlling nitrous oxide emissions from a full-scale activated sludge system in the tropics.

Despite interest in characterizing nitrous oxide (N2O) emissions from wastewater treatment plants (WWTPs) in several parts of the globe, there are few studies in tropical zones. This study focus on the contribution of the scientific knowledge of anthropogenic nitrogen greenhouse gas emissions to climate change in tropical countries, investigating factors controlling N2O emissions in a non-biological nitrogen removal municipal WWTP. In terms of operational parameters, dissolved oxygen (DO) concentrations displayed a biphasic impact on N2O production and emission, with the highest emission at DO of 2.0 mg O2 L(-1). The low solids retention time of 3 days also played a significant role, leading to nitrite accumulation, which is an important trigger for N2O production during nitrification. Furthermore, other factor especially important for tropical countries, namely, temperature, also had a positive correlation with N2O production. Emission factors estimated for this study were 0.12 (0.02-0.31)% of the influent total nitrogen load and 8.1 (3-17) g N2O person(-1) year(-1), 2.5 times higher than currently proposed emission factors. Therefore, the highly variability and dependence on operational parameters reinforce the use of a single emission factor is inadequate, especially for developing countries with limited or variable extent of biological wastewater treatment and in regions of the world with widely varying climate patterns.