Dissolved oxygen concentrations influence microbial diversity, abundance and dominant players in an oxygen minimum zone

Expansion of marine global oxygen minimum zones (OMZs) can have profound impacts on resident macrofauna. Less obvious is the influence OMZs will have on the diversity and abundance of planktonic microbes. This is particularly true in understudied OMZs such as the northern Benguela Upwelling System (nBUS). Here, we analyzed the influence of oxygen concentrations on the microbial community in the nBUS OMZ using 16S rRNA gene (iTag) sequence data. In the nBUS oxygen was a primary driver influencing microbial community structure and diversity. Diversity was highest in dysoxic samples and lowest in suboxic samples, which was primarily due to changes in community evenness in relationship to oxygen concentrations. For example, evenness decreased in suboxic samples due to oscillations in the abundance of microbial groups such as Thioglobaceae (SUP05), which was found to be the most abundant microbe in the nBUS OMZ and significantly increased in abundance as oxygen decreased. This finding prompted an analysis of 217 publicly available medium to high quality Thioglobaceae genomes, including cultured representatives, from the nBUS and other OMZs. Genome annotation of these Thioglobaceae indicated important roles in carbon cycling, sulfur oxidation and denitrification. Importantly, few Thioglobaceae possess the genetic potential to carry out complete denitrification, as most lack the gene that codes for nitrous oxide reductase (NosZ), which converts nitrous oxide (N₂O), a potent greenhouse gas, to nitrogen gas. As OMZs expand in size and severity, decreasing microbial diversity and a concomitant increase in Thioglobaceae abundances, could lead to enhanced N₂O production through incomplete denitrification.